Project Document
Lake Manzala Engineered Wetland
Project: EGY/93/G31
Contract: EGY/93/G31/SUB2
Prepared for:
United Nations Development Agency
One United Nations Plaza
New York, New York
United States 10017
Prepared by:
Tennessee Valley Authority
400 W. Summit Hill Drive
Knoxville, Tennessee 37902
March 31, 1997
UNDP PROJECT DOCUMENT
EGYPTIAN ENGINEERED WETLANDS
Project: EGY/93/G31
Contract: EGY/93/G31/SUB2
Prepared for:
United Nations Development Agency
One United Nations Plaza
New York, New York
United States 10017
Prepared by:
Tennessee Valley Authority
400 W. Summit Hill Drive
Knoxville, Tennessee 37902
March 31, 1997
UNITED NATIONS DEVELOPMENT PROGRAM (UNDP)
Project of the Government of
Egypt
Project Document
EGY/93/G31/B/lG/99
Number & Title: Global Environmental Facility/Egyptian Engineered
Wetlands - Construction of Wetland Project Components
Duration: Five years
Project Site: Port Said & Cairo, Egypt
UNDP and cost sharing
ACC/UNDP sector & subsector:
financing
0320 Land and Water
1030 Environmental Health / Pollution Control
UNDP
Government section and subsector:
IPF $4.0 x 106
Environment / Water
Other(specify) $
Executing Agency: Egyptian Environmental Affairs Agency
Govt. or third-party
(EEAA)
cost sharing
Estimated starting date: July 1997
(specify) (109) $
Government inputs: (local currency)
UNDP & cost sharing (99)
(in kind) 1,980,000 L.E.
Total $4.0 x 106
(in cash) ____________
______________________________________________________________________________
Brief description:
A major environmental and economic concern in Egypt is the poor quality of the north flowing
drainage waters. Presently, only 4 percent of the country is inhabited, primarily because of
inadequate fresh water supplies. Much of the heavily polluted drain water crossing the Nile
Delta enters large coastal lakes such as Lake Manzala before flowing into the Mediterranean
Sea. Water entering the Lake carries pollutants into the Sea which are in violation of
international agreements signed by Egypt. Objectives of the project are to: (1) promote
sustainable development by enhancing environmental and economic opportunities at the local
and national level; and (2) construct and operate a demonstration wetland that will treat 25,000
to 50,000 m3 per day of wastewater before it enters Lake Manzala. The treatment capacity
depends on available funds and site conditions. A capacity of 50,000 m3 per day is anticipated
for a site with 1 meter of ground elevation above the normal subsurface water level. The
capacity would be reduced to approximately 25,000 m3 per day for a site with 0.5 meter of
ground elevation. The final capacity will be determined during project design, based on actual
site conditions and detail cost estimates.
______________________________________________________________________________
On behalf of:
Signature
Date
Name/title (please type)
The Government
Executing Agency: _________________________ _______
Egyptian Environmental
Affairs Agency (EEAA)
UNDP: _________________________ _______
Operational Unit for
Development
Assistance
(OUDA)
United Nations' official exchange rate at date of last signature of project document:
$1.00 = 3.34 LE
UNDP PROJECT DOCUMENT
TABLE OF CONTENTS
List of Abbreviations.....................................................................................................................................................3
A CONTEXT ............................................................................................................................................................5
A.1
Description of Subsector............................................................................................................................5
A.2
Host Country Strategy .............................................................................................................................10
A.3
Prior or Ongoing Assistance ....................................................................................................................11
A.4 Institutional
Framework...........................................................................................................................12
B PROJECT
JUSTIFICATION ...........................................................................................................................13
B.1
Problems to be Addressed and Present Situation.....................................................................................13
B.2
Expected Project Benefits ........................................................................................................................13
B.3 Target
Beneficiaries .................................................................................................................................15
B.4
Project Strategy and Implementation Arrangements ...............................................................................16
B.5
Reasons for External Assistance..............................................................................................................19
B.6 Special
Considerations.............................................................................................................................19
B.7 Coordination Arrangements.....................................................................................................................20
B.8
Counterpart Support Capacity..................................................................................................................20
C DEVELOPMENT
OBJECTIVES ....................................................................................................................21
D IMMEDIATE OBJECTIVES, OUTPUTS, AND ACTIVITIES ...................................................................22
D.1 Immediate
Objective 1.............................................................................................................................22
D.2 Immediate
Objective 2.............................................................................................................................24
E INPUTS ...............................................................................................................................................................27
E.1
Government of Egypt Inputs....................................................................................................................28
E.2 UNDP
Inputs ...........................................................................................................................................28
F RISKS
.................................................................................................................................................................29
F.1 Implementation
Schedule.........................................................................................................................29
F.2 Plant
Availability or Propagation.............................................................................................................30
F.3
Pump Power Failure.................................................................................................................................30
F.4 Variability
in Water Quality ....................................................................................................................30
F.5
Market Value of Outputs .........................................................................................................................30
F.6
Toxicity of Outputs..................................................................................................................................31
F.7 Coordination ............................................................................................................................................31
F.8
Vandalism of Site and Equipment ...........................................................................................................31
G PRIOR
OBLIGATIONS
AND PREREQUISITES.........................................................................................31
G.1 Prior
Obligations......................................................................................................................................31
G.2 Prerequisites.............................................................................................................................................32
H PROJECT REVIEW, REPORTING, AND EVALUATION.........................................................................34
I LEGAL
CONTEXT ...........................................................................................................................................35
J BUDGET .............................................................................................................................................................35
1
K ANNEXES...........................................................................................................................................................39
ANNEX I
Project Description and Rationale for Design ...........................................................................41
ANNEX II
Work Schedule ..........................................................................................................................63
ANNEX III
Project Review, Reporting, and Evaluation Plan.......................................................................71
ANNEX IV
Preliminary Design Calculations and Construction Cost Estimates ..........................................75
ANNEX
V Preliminary Monitoring Plan ...................................................................................................105
ANNEX VI
National and International Participation Framework and National Job Descriptions .............113
ANNEX VII
International Contract and International Job Descriptions ......................................................123
ANNEX VIII Equipment Requirements.........................................................................................................133
ANNEX
IX Budget Details .........................................................................................................................137
ANNEX X
Financial and Accounting Arrangements ................................................................................143
ANNEX
XI Bibliography ............................................................................................................................157
2
LIST OF ABBREVIATIONS
BOD
Biological Oxygen Demand
Cd Cadmium
CEC
Cation Exchange Capacity
cm Centimeter
COD
Chemical Oxygen Demand
d Day
EEAA
Egyptian Environmental Affairs Agency
EIA
Environmental Impact Assessment
EMR
Environmental Management Report
Fe Iron
GADF
General Authority for the Development of Fisheries
GIS
Geographic Information System
GOE
Government of Egypt
GPS
Global Positioning System
GS Ground
Surface
ha Hectares
Hg Mercury
HP Horse
Power
kWh Kilowatt
hour
L Liter
m Meter
mg Milligrams
microhoms/cm
Microhoms per centimeter
MOU
Memorandum of Understanding
mm Millimeter
Mn Manganese
msl
Mean Sea Level
MSS Multispectral
Scanner
NGO Nongovernmental
Organization
OUDA
Operational Unit for Development Assistance
Pb Lead
pH
Measure of acidity or alkalinity of a solution
PMC
Project Management Committee
ppb
Parts per billion
ppm
Parts per million
PVC
Polyvinyl chloride pipe
Q
Discharge in m3/s
QA/QC
Quality Assurance/Quality Control (in laboratory analysis)
RBV
Return Beam Vidicon
SAR
Sodium Adsorption Ratio
T/yr
Tons per year
TFP
Technical Focal Points
TM Thematic
Mapper
TN Total
Nitrogen
TP Total
Phosphorous
TSS
Total Suspended Solids
UN United
Nations
UNDP
United Nations Development Program
VEC(s)
Valued Environmental Component(s)
Zn Zinc
3
blank
4
SECTION A CONTEXT
A.1 Description of Subsector
A.1.1 Interaction of Lake Manzala and the Mediterranean Sea
Lake Manzala is located on the northeastern edge of the Nile Delta, between Damietta and Port
Said (Figures 1 and 2). It is separated from the Mediterranean Sea by a sandy beach ridge which
has three open connections between the Lake and the Sea. These open connections allow an
exchange of water between the Lake and the Sea. For example, the northern portion of Lake
Manzala is characterized by high salinities ranging from 3000 mg/L to 35,000 mg/L, due to the
influence of the Mediterranean Sea. Tidal flow measurements for Lake Manzala in 1986
revealed that 6878 x 106 m3 of water flow into the Lake, but 9007 x 106 m3 are returned to the
Sea. The net balance flows from the Lake to the Sea and represents a consistent annual input to
the Mediterranean Sea. A major land reclamation project and associated irrigation program by
the Government of Egypt is expected to increase the level of interaction of the Lake with the Sea
by altering the existing flows such that the polluted waters of the Bahr El Baqar drain will have
faster and more direct access to the Mediterranean Sea.
A.1.2 Characteristics of Lake Manzala
Lake Manzala is a shallow brackish lake with an area of approximately 1000 km2. Road banks
and islands, zones of dense emergent vegetation, and "hoshas" (illegal fish enclosures) limit
water circulation and form basins with very different water and sediment characteristics. The
flow of water into Lake Manzala comes from several drains. The Bahr El Baqar drain
dominates, both in highest water flow and highest pollutant load. Wind is a key factor in the
Lake's circulation. Evaporation during the summer season is an important factor in the Lake's
water balance.
The Lake is exposed to high inputs of pollutants from industrial, domestic, and agricultural
sources. Pollution originates in urban centers such as Cairo and also along the lengths of the
drains. The most important sources are in eastern Cairo. Untreated and poorly treated
wastewater is transported to Lake Manzala by the Bahr El Baqar drain over a distance of 170
km. The drain is heavily polluted and anoxic over its entire length. Methane and hydrogen
sulfide bubble up to the surface and release climate gases. Large amounts of particulate matter,
nutrients, bacteria, heavy metals, and toxic organics are transported to the Lake via the drain.
Where the anoxic water from the Bahr El Baqar drain enters Lake Manzala, reduced iron is
oxidized and precipitated as hydroxide in a zone of gray water between the black drain water and
the green Lake water. The oxidized iron precipitates on fish gills, causing tissue damage and
mortality. As a result, only the hardiest organisms can tolerate Lake Manzala near the entrance
of the Bahr El Baqar drain. Among these species, malformations, discoloration, and stunted
growth are common.
5
Mediterranean Sea
iver
ile R
N
Port Said
El Salam
Lake
Can
Manzala
al
rain
D
tir
ashB
l
a
Project
a
n
C
ez
Area
Su
Drain
N
0
5
10
15
20
Bahr El Baqar
kilometers
Figure 1. Project Area
6
page for figure 2
7
The Lake is highly eutrophic with both macrophytes and planktonic algae contributing to
extensive carbon fixation. The nutrient input comes from fresh water inflows such that
productivity decreases as salinity increases nearer the Mediterranean Sea. The nutrient input,
particularly through the Bahr El Baqar drain, has a relative excess of phosphorous compared to
nitrogen. A large proportion of the primary production occurs in macrophytes which constitute a
"blind path" in the aquatic food web. Fish production in the Lake is high with a total catch of
approximately 45,000 tons. The average catch per hectare (10,000 m2) is 450 kg with catch
amounts in excess of 900 kg/ha in the southeastern portion of the Lake.
Historically, the salinity of Lake Manzala was higher and the nutrient and toxic loads were much
lower. The fish catch was smaller; however, and species composition was more varied with
highly valued marine species including mullets and sea bass constituting an important portion of
the overall catch. Currently, approximately 90 percent of the total catch consists of four species
of tilapia with the majority of individual fish less than ten centimeters in length.
Although the southeastern basin area near the Bahr El Baqar drain is the most productive fishing
area, only tilapia spp. and catfish survive. Catches are dominated by the smallest and hardiest of
the tilapia species, T. zilli. This species shows a high frequency (85 percent) of organ
malformation and discoloration, caused by environmental and contaminant stress. Among the
Port Said inhabitants, Lake Manzala fish have a reputation for being chemically and microbially
contaminated and, thus, unhealthy to eat. The public are afraid to eat fish from a Lake that once
provided 30 percent of all Egypt's fish. This has had a severe social and economic impact on
Lake residents as well as local and national political repercussions.
The most important local problem is the quality of water in the area. Contaminated drain water
is used for washing dishes and vegetables. Drinking water must be transported to the area.
Imported water from nearby Port Said and Mataryia is often not suitable for human use.
Contaminated drinking water is responsible for enteric diseases such as gastritis, infective
hepatitis, amoebic dysentery, Ascaris and other parasitic infections, schistosomiasis, and
dermatitis.
With regard to biodiversity, there has been a substantial reduction over the last few decades in
both fish and bird species. The single most important factor may be the decrease in water
salinity, except for the northwestern basin where an embankment has led to a negative water
balance, hypersalinity, and loss of species diversity. In the southeast, water pollution and
excessive eutrophication have caused the disappearance of many species. In some areas of the
Lake, the benthic fauna has been impacted by contaminants from the drain inflows. Extreme
fishing pressure and hunting of birds have further reduced biodiversity.
Extensive land reclamation during this century has reduced the Lake surface area to less than
half of its original size. The reclamation is progressing at an accelerating pace. The satellite
image maps from 1990 showed water in many places where land had subsequently been created
and islands enlarged. Most of the lake south of the El Salam Canal has been reclaimed. There
are plans for further land reclamation north of the El Salam Canal.
Additional illegal land reclamation and the intensive fishery, partly with illegal methods, are
indicative of the increasing human population pressure on Lake Manzala. Even though the area
has a low population density by Egyptian standards, the number of inhabitants is increasing
8
rapidly. Much of this colonization is illegal and unauthorized. The living standard, including
income, education, and health, is worse than the Egyptian average. There are also conflicts
between the new settlers and the established inhabitants. Legally, the status of land claims is
often uncertain even after generations of occupancy. Law enforcement is inadequate in regard to
land use, illegal fishing, and other human activities.
Other physical, chemical, and biological alterations to the Lake are causing social and economic
disruptions. The El Salam Canal, a one billion dollar water diversion project, will take some of
the cleaner drain water to the Sinai. It will no longer flow into the Lake. Of the 200,000 feddans
that will be irrigated on the Lake side of the Suez Canal, return water will contain increased
amounts of agricultural chemicals and nutrients. This project is expected to modify Lake
circulation and water quality, in particular, salinity. Associated roads and shoreline alterations
will lead to reduced water circulation. Dredging and aquaculture activities within the Lake also
contribute to the regional cumulative effects and overall deterioration of the Lake. As the
salinity of the Lake is altered, farmers on the islands will find it more difficult to obtain fresh
water supplies for livestock.
Although cumulative effects are dramatic and concern is widespread, only a poor scientific
database exists for Lake management. No predictive modeling tools exist. There is little
agreement on priorities for using the Lake. Clearly, local residents are concerned about the use
and quality of Lake Manzala. Politicians at the local and national levels are demanding
corrective actions, but scientists and environmental managers lack sufficient tools and data to
determine and develop support for effective management actions. Cumulative effects like those
to Lake Manzala and the Mediterranean Sea are the single greatest contributor to global
deterioration and represent major impediments to achieving sustainable development.
A.1.3 Waste Management Control
Responsibilities for environmental protection in Egypt are dispersed among a number of federal
ministries and Governorates. A central focus is provided by the Egyptian Environmental Affairs
Agency (EEAA) established in 1982. EEAA has executive powers for inspection and
enforcement. In Egypt, pollution control and treatment facilities are generally inadequate. In
many cases, pollution occurs unabated. When environmental legislation has been passed, it
often lacks realistic guidelines or has inadequate measures for enforcement. All of these factors
contribute to the increasing pollution of Lake Manzala and, therefore, of the Mediterranean Sea.
The Egyptian Government has launched an extensive program for construction of wastewater
treatment facilities in greater Cairo and other large population centers. Complete coverage of all
major sources of industrial and municipal waste, however, is not foreseen in the next 30 years.
The new wastewater treatment facilities have concentrated on conventional treatment. The high
costs associated with such waste management programs have prolonged implementation of the
program. Nutrient and toxic removal by conventional primary and secondary treatment is low
(0-30 percent). Even with expensive treatment facilities, the pollution load entering Lake
Manzala and the Mediterranean Sea will be substantial. The focus on conventional facilities has
limited the use of alternative wastewater treatment systems (such as engineered wetlands) which
may be more suitable to Egypt's needs and capabilities. In addition, conventional treatment
systems do not address nonpoint sources of pollution such as agricultural inputs.
9
The national wastewater treatment program and new powers of the EEAA facilitate better
monitoring and protection of the water resources in the long term. They do not provide the
immediate action required to remedy the serious problems in Lake Manzala and the
Mediterranean Sea caused by untreated or poorly treated wastewater. Most of the other
cumulative effects are not assessed or managed.
A.2 Host Country Strategy
In 1982, the Egyptian Environmental Affairs Agency (EEAA) was established under Presidential
Decree No. 631 of 1982. The Agency is attached to the Presidency of the Council of Ministers
and is responsible for preparing Egypt's policy on the management of the environment. Initially,
the EEAA focused on the accumulation of scientific and technical data needed for the
formulation of the country's National Environmental Action Plan, which was released in March
1992. The National Environmental Action Plan identified Lake Manzala as an alarming example
of water pollution in Egypt. This environment has been termed a "black spot" by the
Government of Egypt.
During the last two decades, Egypt paid increasing attention to environmental issues at both the
national and international levels. Egypt was among the first countries to call for environmental
protection at the international level and joined, at its inception, the United Nations Environment
Program (UNEP). It is a party to a number of international agreements, including the:
·
Convention Relative to the Preservation of Fauna and Flora in their Natural State.
·
African Convention on the Conservation of Nature and Natural Resources.
·
Convention on Wetlands of International Importance Especially as Waterfowl Habitat.
·
Convention on International Trade in Endangered Species of Wild Fauna and Flora.
·
Convention for the Protection of the Mediterranean Sea against Pollution.
·
Protocol for the Protection of the Mediterranean Sea against Pollution from Land-Based
Sources.
·
Protocol Concerning Mediterranean Specially Protected Areas.
·
Convention on the Conservation of Migratory Species of Wild Animals.
·
United Nations Convention on the Law of the Sea.
·
Framework Convention on Climate Change.
·
Convention on Biological Diversity.
·
World Charter and Agenda 21.
10
Internationally, Egypt has been an active participant in the UNEP sponsored and coordinated
Mediterranean Action Plan and since 1978, has been a contracting part to the Convention for the
Protection of the Mediterranean Sea Against Pollution. The country requires assistance,
however, if it is going to fully comply and participate in these international efforts.
In 1991, Egypt signed a protocol to host the Regional Center for Environment and Development
for the Arab Region and Europe, funded jointly by the United Nations and countries within the
region. This autonomous body assists in developing programs and policies to resolve
environmental problems in the region.
Relevant national legislation in force in Egypt includes the:
· Law No. 48 (1982) for the Protection of the River Nile and Water Channels.
· Minister of Industry's Decree No. 380 (1982).
· Law No. 102 (1983) for Natural Reserves and Conservation of Nature.
· Law No. 124 (1983) for Fishing, Aquatics, and Regulating Fish Farms.
· Law No. 12 (1984) for Drainage and Irrigation.
Additionally, the National Environmental Action Plan is intended to deal with the environmental
problems that will be confronting Egypt in the short, medium and long terms. In order to
strengthen the environmental structure and management process of the country, the Egyptian
parliament is considering a new environmental law to provide greater cooperation and
coordination among government ministries and agencies. It also gives the EEAA increased
powers and duties for inspection, enforcement, and environmental assessment.
A.3 Prior or Ongoing Assistance
A variety of international agencies have given support to various initiatives developed by the
Government of Egypt to overcome serious environmental problems. Those projects related to
the development of an engineered wetland treatment facility in Lake Manzala include:
· The Fariskur Waste Management Pilot Project by USAID, conducted to evaluate appropriate
waste treatment technologies for use in small local communities.
· The Greater Cairo Wastewater Project which involves the construction of an extensive
sewerage network and six major treatment plants with assistance from the Arab Fund for
Economic and Social Development, designed to reduce industrial and municipal pollution
levels emanating from the Egyptian capital.
· The Canal Cities Water and Wastewater Project to review wastewater treatment effluent and
sludge disposal alternatives for the cities of Suez, Ismalia, and Port Said, funded by USAID.
11
Several institutes are conducting related studies, including:
· The pilot rock-reed wetland at Ismalia operated by the Suez Canal University in
collaboration with Portsmouth Polytechnic in the UK, and a study located at the Tenth of
Ramadar.
· The Water Hyacinth Institute, which is working on the commercialization of water hyacinth
products. The engineered wetland provides an opportunity to turn bench scale results into
commercial successes.
· The Drainage Research Institute of the Water Research Center, which has studies and
ongoing monitoring programs related to the main drains such as Bahr El Baqar. The
wetlands project technology has potential application to other water pollution problems of
concern to scientists at the Water Research Center.
· The Central Laboratory for Fish Research at Abassa and the Institute of Oceanography at
Alexandria have scientific studies underway on the Lake.
A.4 Institutional Framework
In 1991, a national conference on Lake Manzala Environment was held in Port Said. One of the
outcomes of this conference was a Supreme Committee for the Rehabilitation of Lake Manzala
to ensure coordination among various authorities and agencies, to improve Lake management,
and to protect the Lake environment. The Supreme Committee lacks substantial authority to
make changes and does not have the budget necessary to conduct the scientific studies. The
Supreme Committee, however, is a useful forerunner of a more permanent authority for
managing the Lake. It brings together many of the key governmental agencies. At present, the
prime legal authority for the Lake resides with the General Fish Authority within the Ministry of
Agriculture.
No single line ministry of the Egyptian Government has the requisite expertise to address and
manage this type of project. The Ministry of Agriculture promotes land reclamation for
increased agricultural production at the expense of Lake Manzala. The Ministry of Public
Works and Water Resources has centered upon the reuse of all appropriate water for irrigation
and agricultural development at the expense of Lake Manzala.
Because of the inexperience of Egypt's ministries in large interdisciplinary projects and the lack
of anyone with a broad enough mandate in regard to the project, the EEAA will be the Executing
Agency. EEAA has the legal authority to coordinate among ministries for problems relating to
the environment. It also has the authority by law to execute pilot projects and new approaches to
environmental protection and management. EEAA is attached directly to the Cabinet of
Ministers which facilitates communication and implementation. EEAA also has a lead role in all
similar environmental rehabilitation projects in the country and has right-of-access to
information from all other ministries.
Other areas of government that are involved in jurisdictional issues related to the range of
interdisciplinary topics this project involves include: the Governorate of Port Said, the General
Fish Authority (Ministry of Agriculture), the Ministry of Agriculture, the Ministry of Public
12
Works and Water Resources, the Ministry of Housing and Reconstruction (Potable Water and
Sewage Authority), the Ministry of Health, and various scientific institutions including the
Central Laboratory for Aquaculture at Abassa, the Water Research Center and its related
institutes, the National Research Council Laboratory, Suez Canal University, the National
Institute of Oceanography and Fisheries at Alexandria, and the Water Hyacinth Institute at
Zagazig University.
SECTION B PROJECT JUSTIFICATION
B.1 Problems to be Addressed and Present Situation
Deteriorating water quality is the major impediment to development in Egypt. The problem to
be addressed by this project is how to achieve sustainable development for the people living in
the Lake Manzala area (and in particular, the residents of the Bahr El Baqar drain area) while
improving water quality and the Lake environment. This is one of the most poorly serviced
areas in Egypt. Local residents do not have access to what would be considered the minimum
requisites for life. Deteriorating water quality and fish stocks with the concurrent human and
ecosystem health risks are major problems. Many people live as squatters precariously on
Government land and lack the security of land ownership and economic stability. The
environmental deterioration is detailed in Section A.
The proposed project demonstrates one approach to achieving sustainable development. During
the five-year project period, an engineered wetland will be constructed to improve water quality,
aquatic habitat, biodiversity, and reduce climatic gases. The project will increase social and
economic sustainability through local cooperatives, empowerment of local residents,
Nongovernmental Organizations (NGO) activities, training, and national capacity building to
achieve Egyptian self-sufficiency in this form of biotechnology. The engineered wetland will
produce 25,000 to 50,000 m3 of clean water per day, depending on site conditions. Biomass will
be harvested and processed into marketable products. The clean effluent water will be used for
an aquaculture facility that will provide juvenile fish for restocking the Lake and for other
aquaculture ventures.
B.2 Expected Project Benefits
The expected benefits from construction and operation of the engineered wetland at the northern
portion of the Bahr El Baqar drain are as follows:
· The wetland will demonstrate a sustainable low cost alternative to traditional waste treatment
in Egypt and a national self-sufficiency to implement this technology throughout the country.
· Institutional strengthening will occur at the local, and national level through the cooperative
efforts required to plan and manage the wetland, and to market wetland by-products.
· The quality of life for the local participants will improve as the wetland generates
employment, reduces the risk of disease from contaminated water and fish, and improves
local fisheries.
13
· The local participants will be assisted in operating the aquaculture facility, and in harvesting
and marketing biomass products, such as fuel pellets and animal feed.
· An integrated environmental monitoring and information program will be implemented to
record, compile, and assess the wetland operating efficiency, including pollution reduction,
biophysical changes, and socioeconomic improvements.
· The level of pollutants flowing into Lake Manzala and the Mediterranean Sea will decrease.
· The improved quality of water entering the Lake through the Bahr El Baqar drain will
promote biodiversity and enhance habitats for fish and bird species that are unable to survive
in the present aquatic ecosystem.
· The production of greenhouse gases from the polluted Bahr El Baqar drain flowing into Lake
Manzala will be reduced and the generation of oxygen will increase.
At the end of the five year project, there will be a fully operational, engineered wetland treating
25,000 to 50,000 m3 per day of highly-polluted drain water. There will be a biomass harvesting
and aquaculture facility operated by local employees and assisted by NGOs. The project will
provide an example of sustainable development in practice, with improvements in both the local
economy and the environment.
With extrapolation and wider use of this technology by local residents, both Lake Manzala and
the Mediterranean Sea will have improved water and sediment quality as inflow contaminants
are reduced. There will be enhanced fish habitats, healthier fish, more fish and bird biodiversity,
and a reduction in climate gases of the anoxic drain water. The health of the local population
will be improved with the enhanced environmental quality.
The project team, governmental technical focal points, and selected graduate students will be
familiar with the biotechnology and will be able to lead Egypt's efforts in wetland
self-sufficiency. The project team will compile economic and monitoring data on the
effectiveness of the wetland and aquaculture systems over a range of conditions. Information
will be obtained concerning wetland function, operation, and transferability to other sites in
Egypt.
The potential for this technology exceeds the 25,000 to 50,000 m3/d of drain water to be treated.
There can be little successful development in Egypt without a safe and affordable water supply.
Waste management, as in many other developing countries, has concentrated on costly
conventional treatment facilities that often do not provide the level of treatment needed. The
costs involved with the long-term management of wetland treatment facilities are within Egypt's
capability and will provide an incentive to extend the process to other highly polluted areas.
EEAA will have an enhanced role and reputation as a leader in the provision and protection of
environmental quality in Egypt. EEAA will gain institutional strength in project delivery and
implementation that can be transferred to other Egyptian problem areas.
By the end of the project, the engineered wetland will be fully operational. There will be a
wetland authority that will be responsible for the facility. The institutional arrangements for
14
long-term operation of the facility will be determined before the project ends. At the end of the
project, much of the routine operations and maintenance will be conducted by the local
employees who are selling biomass and fish products. There will be a continuing need for the
Government of Egypt to provide the electricity to the facility and oversight management and
monitoring.
B.3 Target Beneficiaries
The beneficiaries of the project will include:
· Local residents and in particular, those that are involved in operating the wetland for biomass
products and aquaculture.
· Local residents who will be employees in the construction and operation of the wetland.
· Local fishermen who adopt improved fish farming techniques demonstrated by the
aquaculture facility.
· NGOs that participate in the wetland demonstration and focus on the project area and its
development. This will enhance the benefits of the project to the local economy and improve
the NGOs' ability to deliver programs in the area.
· All residents regardless of economic category because of the enhanced environmental
awareness and emphasis on the health risk associated with water pollution.
· Regional scientific institutions and individual scientists that use the wetland facility for
research studies and training.
· The Governorate of Port Said.
· National governmental bodies, and in particular, the EEAA.
· The country of Egypt in its standing internationally on environmental protection and
rehabilitation.
The project will demonstrate how to improve the quality of the environment as well as the
quality of life of the people in the Bahr El Baqar area. New employment, new skills, new
businesses, and higher incomes will lead to an improved standard of living including better
health and educational opportunities. Approximately ten new jobs will be created in the
operation and maintenance of the wetland. Fewer chronic diseases and healthier food intake are
expected to result from broader application of the wastewater treatment and aquacultural
techniques demonstrated by the engineered wetlands.
Environmental awareness will develop among the local population as the project attracts the
attention of the people to environmental issues such as the pollution of the Lake and drains.
Through success of the project, knowledge will be passed on to a wider group of beneficiaries
within the watershed, the Egyptian Government, research organizations, and other environmental
agencies and interest groups.
15
Adoption of the wetland systems will benefit other Mediterranean countries by reducing
international water pollution. The project can have far-reaching effects by demonstrating a cost-
effective alternative to conventional wastewater treatment in reducing contaminant loadings to
international waters.
Species diversity of several major groups of animals such as birds, fish and lower trophic
dwellers will ultimately increase through habitat enhancement. Many aquatic wildlife species, a
number of which have seriously declined, will benefit by improved wastewater treatment.
Aquatic plants and animals will benefit from wider adoption engineered wetlands.
B.4 Project Strategy and Implementation Arrangements
The predominant feature of the project is that it will be Egyptian executed with the EEAA taking
overall responsibility for the project. EEAA will act as the conduit for project communications
between the UNDP and the Government of Egypt. The overall project organization appears in
Figure 3.
The Engineered Wetlands Project centers on protecting of the global environment. Inherent to
the project is a set of diverse interdisciplinary needs. No single line ministry has the expertise to
address and manage this type of interdisciplinary project. In some cases, the mandate of a line
ministry is in conflict with the project. For example, the Ministry of Agriculture promotes land
reclamation for increased agricultural production at the expense of impacting Lake Manzala.
The Ministry of Public Works and Water Resources focuses on the reuse of water for irrigation
and agricultural development, also impacting Lake Manzala. Neither ministry has significant
direct experience in large interdisciplinary projects. These ministries are invaluable, however,
for the expertise and resources they can contribute to the project.
In addition, because many ministries are potentially involved, no one has a clear mandate and set
of functions to manage the others. After much consideration and discussion with the line
ministries, the EEAA appears to be the most suitable Executing Agency. The primary EEAA
mandate centers on protection of the environment and rehabilitation of the so called
"environmental black spots," including Lake Manzala which is prominently featured in the
recent National Environmental Action Plan and in the formulation of the Supreme Committee for
the Rehabilitation of Lake Manzala.
In addition to a mandate commensurate with the project objectives, EEAA has a number of
advantages as an Executing Agency. First, by law, EEAA has the authority to coordinate among
ministries for environmental problems. Second, it has the legal authority to execute pilot
projects. Third, it is attached directly to the Cabinet of Ministers which facilitates short
circuiting of bureaucratic layers. The Minister for Cabinet Affairs also chairs EEAA. Fourth, it
has a lead role in all similar environmental rehabilitation projects in the country. Fifth,
according to law, it has access to all information from all other ministries; no line ministry has
this authority. Sixth, although EEAA is short staffed, the priority given to the project to date and
the
16
Figure 3
Organizational Chart
Egyptian Wetlands Project
LAKE
LAKE MANZ
MANZALA
WE
WETLAN
TLANDS PR
DS PROJE
OJ CT
ECT
PROJECT MANAGEMENT BOARD
HIGHER COMMITTEE
FOR LAKE MANZALA
TECHNICAL ADVISOR
PROJECT MANAGER
DESIGN
CONSTRUCTION
OPERATOR
CONSULTANT
CONTRACTOR
17
competency and efficiency which the EEAA staff devoted to the Feasibility and
Pre-implementation Phases, establishes a successful track record in regard to project
management.
In addition, the Agency is presently undergoing considerable strengthening. Agency personnel
have rapport with other ministries and were effective in coordinating the Feasibility Study.
EEAA can successfully execute the project given that a strong Project Manager is appointed with
the requisite array of national and international experts, the adequate support of the Government
of Egypt, and the timely acquisition of permits and approvals. Much of the construction of the
wetlands will be conducted by specialized private contractors hired locally. This is the standard
operating procedure for line ministries implementing physical works.
The Project Management Board (PMB) will consist of representatives of concerned agencies
with relevant decision-making authority. It will be headed by EEAA as represented by the Head
of Water and Coastal Area Protection Projects. The Project Manager will serve as the
Rapporteur of the PMB. The roles of the PMB are to oversee project operation and
accountability, which will be enforced by the Executing Agency; to facilitate interagency
coordination; and to ensure that the project commitments of the Government of Egypt are met in
a timely manner. The PMB will also review project reports prepared by the Project Manager
before submission to the UNDP.
The PMB will consist of senior level personnel designated by the heads of their respective
agencies who would have authority to ensure that the actions needed from the Government of
Egypt will be undertaken effectively. The membership of the PMB overlap with that of the
Supreme Committee for the Rehabilitation of Lake Manzala so as to enhance the expertise and
understanding of the overall problems and management solutions for the Lake.
The PMB will regularly review project performance relative to project objectives. The PMB
will assist the Project Manager, but also offer critical comment, recommend additional actions,
and modify plans as necessary to facilitate project implementation. Each member of the PSC
will designate one or more Technical Focal Points from their ministry to serve as resource
persons for the Project Manager.
The PMB will be comprised of representatives from the:
· Governorate of Port Said
· General Authority for Development of Fisheries
· Egyptian Environmental Affairs Agency
· Local Fisherman NGO
· Ministry of Agriculture
· Ministry of Public Works and Water Resources
· National Organization for Potable Water and Sanitary Drainage
· Suez Canal University
· United Nations Development Program
18
B.5 Reasons for External Assistance
The Government of Egypt's commitment to environmental protection has been demonstrated by
various actions in recent years, including the formulation of the National Environmental Action
Plan to identify and address the most alarming examples of water pollution in the country. The
passage of the new environment legislation also strengthens environmental regulations and the
EEAA.
Without a demonstration project to prove the benefits of the low cost engineered wetland
treatment, large quantities of pollutants will continue to contaminate the Nile River drainage
system, Lake Manzala, and the Mediterranean Sea. The costs of wetland treatment facilities are
well within the national capability of the Government of Egypt. The low cost and potential
income from aquacultural operations will provide an incentive for extending wetland
biotechnology to other highly polluted areas. It is anticipated that the engineered wetland will
constitute a key rehabilitation measure under the country's National Environmental Action Plan.
The project will create an international visibility for wetland systems as a proven technology,
making the activities more relevant in Egypt, as well as internationally.
B.6 Special Considerations
Environmental neglect in Egypt has resulted in serious "black spots" such as Lake Manzala. The
political will is present to address these problems with appropriate technical assistance and
financial resources.
B.6.1 Poverty Alleviation
The project area is occupied by poor and lower middle class families. Most earn a living by
fishing in the Lake using traditional methods. Gross earnings are limited by the daily catch and
prices offered by middlemen. Prices are usually low. Only one or two persons in the family are
employed full time. One of the primary objectives of the project will be to employ local
inhabitants in the construction and operation of the wetland.
The project will produce substantial employment opportunities for unskilled and skilled local
workers. Jobs will include excavation, construction, road building, and transportation during the
construction phase. Additional work will be associated with harvesting and planting seedlings
within the wetlands. In subsequent phases, the project will generate jobs related to the
maintenance of the wetland system, monitoring, aquaculture facility, biomass harvesting, and
sludge dredging.
The biomass harvested from the wetland system will be used as compost and animal feed.
Currently there are about 27,000 cows and buffaloes in the region. Expanded use of wetlands
can provide a cheap source of high-protein animal feed that will aid animal production and
increase local incomes. Biomass might also be used to manufacture fuel pellets for domestic and
industrial uses. Brood stock from the aquaculture operation can be made available to fish
farmers to enhance fish productivity and annual catches.
19
B.6.2 Participatory Activities
The project will increase local awareness of environmental pollution, health risks from
contaminated food and water, personal hygiene, and maintenance of sanitary conditions. The
project has attracted favorable attention among the local population through public meetings and
the media. This publicity has generated a positive attitude toward reducing environmental
pollution. Construction and operation are designed to maximize participation by local residents.
The wetland will offer opportunities for the local residents to participate in operation and
maintenance, impact monitoring, biomass utilization, and utilization of brood stock from the
wetland fishery.
One of the advantages of engineered wetland treatment systems (as compared to conventional
treatment systems) is creation of support services and small scale manufacturing ventures.
Possibilities include plant harvesting and propagation of seedlings for stocking the wetland,
production of fill material from the sedimentation basin, fuel and animal feed pellets from the
harvested biomass, harvesting of aquatic plants from the wetlands. Once the project reaches
operation, private sector participation will be used to demonstrate the economic potential of the
wetland and aquaculture facility.
B.6.3 Gender Issue
Although there are inherent restrictions to the emancipation of women in terms of education,
employment, and social participation, the project will generate opportunities for cottage
industries and economic ventures that will offer employment opportunities for women.
B.6.4 NGOs
Strong NGO support will be needed to fully realize all of the potential benefits of the
demonstration wetland. NGOs will participate in the formation and operation of the biomass
harvesting and aquaculture operations. NGOs will also assist in operating and monitoring the
wetland facilities. NGO financial support will be obtained to assist in performance monitoring,
training, and technology transfer activities.
B.7 Coordination Arrangements
The engineered wetland project relates to the mandates and ongoing activities of several
ministries and governmental agencies. Much of the coordination and sharing of information will
be accomplished through the Project Management Board and the Technical Focal Points. The
EEAA will serve as a coordinating liaison working with the Project Manager. The project
organization chart (Figure 3) illustrates interrelationships. Additional ad hoc committees may be
established by the Project Manager as needed. The coordination role of the EEAA is expected to
strengthen EEAA's capabilities as an Executing Agency and help translate the Lake Manzala
experience into practical results in other parts of the country.
B.8 Counterpart Support Capacity
From the initial project identification mission, the Government of Egypt (GOE) has supported
the project and endeavored to ensure success. The GOE and EEAA have made personnel and
20
facilities available and served as a liaison with other federal agencies and the Governorate of
Port Said. They have working relationships that are crucial to implementation of the project.
This support was evident in obtaining agreement on the transfer of title for the original project
site, although alternative sites are now being considered. Securing the title to a suitable project
site will be a prior obligation to project approval.
In addition to environmental initiatives such as the National Environmental Action Plan and the
environmental legislation, EEAA has shown leadership in political support for addressing the
broader problem of deterioration in Lake Manzala and its watershed. Agency personnel have
focused attention on a comprehensive regional approach to managing water quality in the Lake.
The Government of Egypt is committed to supporting the project through the next five years by
providing a project site and government personnel from EEAA, other federal units, and the
Governorate of Port Said. At the end of the five-year project, the GOE will ensure that suitable
arrangements are established for long-term operation of the facility. The GOE will also promote
technology transfer and broader adoption of the wetland and aquaculture systems.
SECTION C DEVELOPMENT OBJECTIVES
The overall objective of the project is to improve the global environment and national to global
environment linkages by reducing international water pollution. This will be accomplished by:
(1) promoting sustainable development through enhanced environmental and economic
opportunities at the local and national levels; and (2) demonstrating engineered wetland
technology as a low cost and efficient method for treating large bodies of water in Egypt (thus
addressing serious impediments to national and regional development, namely, poor water
quality and low incomes).
First, this project will demonstrate cost-effective methods for improving the quality of water
entering Lake Manzala and the Mediterranean Sea, thus contributing to the protection of an
international body of water of considerable importance. The project will facilitate the transfer of
a low cost biotechnology to a developing country. Engineered wetlands provide an
economically and environmentally sound alternative to traditional wastewater treatment
facilities. A local hiring policy and a technical assistance program will facilitate successful
operation of the wetlands and transfer of the technology to other parts of the country.
Second, the major impediment to national development is the lack of a clean water supply. This
project constitutes a sustainable development methodology that can provide Egypt with a greatly
enhanced development potential. Achieving the second development objective will ensure that
the environmental and economic benefits of sustainable development are fully realized. Many
benefits are expected as a result of cleaner water. These include job opportunities for local
residents, small scale industries that utilize biomass by-products; opportunities for the women in
the local community; support and reinforcement of regional efforts to manage the resources of
Lake Manzala and the coastal Mediterranean area; an improved fishery in Lake Manzala;
decreased health risk associated with consumption of Lake Manzala fish; and decreased health
risk associated with contact with the water from Lake Manzala.
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SECTION D IMMEDIATE OBJECTIVES, OUTPUTS, AND ACTIVITIES
D.1 Immediate Objective 1:
Capacity building for sustainable development in managing Lake Manzala, including local
and national participation.
Output 1.1 Strengthen and promote community involvement in environmental
management activities.
Activity 1.1.1 Assist local residents in becoming full partners in development and operation of
the wetland by implementing an appropriate social, economic, and NGO support framework.
The Bahr El Baqar area is almost devoid of services (health care, water, roads, public transport,
electricity, education). There are no NGOs working in the immediate project area, and few are
close to the project. Local residents do not expect much support from the government. In
addition, the lack of sensitivity to local needs in the building of the E1 Salam Canal resulted in
considerable suspicion of the governorate and federal authorities.
Early in the project, the Project Manager will confer with local residents and NGOs to identify
those interested in participating in the project. NGOs and local representatives will help
organize the entrepreneurial activities associated with planting and harvesting biomass and
developing the wetland and aquaculture facilities.
Activity 1.1.2 Involve local residents in focusing project objectives on human resource and
economic development in the project area. During the preconstruction phase, the Project
Management Team will meet with the local fishermen, farmers, and other local residents to
discuss socioeconomic needs. During the construction and operational phases, local residents
will provide input on employment opportunities, environmental improvements, and operational
techniques that should be included in the facility. A working partnership will be maintained
throughout the project to promote practical design, operation, and long-term acceptance of the
demonstration technologies.
Activity 1.1.3 Increase environmental awareness in the local community and Governorate of
Port Said. The Project Manager will work with the local media to develop a program of
interactive education. Environmental management principles and practice will be conveyed and
discussed. The public will be encouraged to participate and suggest how the local community
can benefit from the project.
Activity 1.1.4 Assist local participants in business development. Wetland treatment technology
will generate a resource-base for sustainable development. Commercial operations will be
developed from the aquaculture facilities and biomass produced by the engineered wetland.
The Project Manager will assist local participants in generating income from construction
activities, marketing biomass products, and operating the aquaculture facility. Examples of
potential biomass products include: animal feed, building materials, and fuel pellets. There are,
however, other products that can be manufactured from water hyacinths, bamboo, papyrus, or
other plants that may be grown on site. For example, the Water Hyacinth Institute in Egypt has
identified and is developing 18 commercial uses for the plant biomass.
22
Activity 1.1.5 Identify local construction and maintenance personnel for building and operating
the engineered wetland. Local residents will be involved in construction and operation of the
engineered wetland. In order to promote the use of local personnel and labor intensive
construction techniques, the Project Manager will develop specific guidelines to be followed by
the construction contractor. The guidelines will be explicitly incorporated into the design and
specifications for the project.
Output 1.2 Capacity building and human resource development to ensure that the
engineered wetland can be operated and replicated on a regional scale.
Activity 1.2.1 Identify the government and academic/research organizations and personnel that
will participate in the project and establish communication. There are several ways that
governmental departments and research institutions will be involved in the project, for example,
through membership on the Project Management Board, as Technical Focal Points, and through
direct participation in monitoring and operational studies. Proper participation will help ensure
that the project becomes a sustainable development model for Egypt and other countries in the
region. This will also provide future Egyptian wetland facilities with the national expertise to
undertake the work without having to import scientific assistance from other countries.
The Project Manager and EEAA will identify personnel of various agencies and NGOs that will
participate in the oversight, review, and monitoring studies. Relevant agencies may nominate
these individuals. Roles will be clearly defined to ensure a smooth transition to long-term
operation and management. The national engineers, technicians, scientists, and managers will
become familiar with the basic concepts, scientific and technical principles, operation and
maintenance requirements of the wetland technology, as well as the administrative and
socioeconomic facets.
Output 1.3 Disseminate lessons and experiences of wetlands project at global, national,
and community levels.
Activity 1.3.1 Prepare and distribute annual reports by the Project Manager to all interested
local and national parties. The wetland at Lake Manzala is expected to demonstrate the
feasibility of wetland technology under Egyptian conditions. The Project Management Board
will ensure that the Egyptian Government is monitoring the progress of the project through
EEAA and other line agencies which are mandated to oversee the country's water resources,
fisheries, agriculture, and environment. The annual reports will document project results,
including costs, performance, operations, local benefits, income, problems, and solutions. The
reports will be distributed to all relevant government departments, research institutions, and the
donor agencies. National distribution will ensure that the country's planners are aware of the
technology and its potential for treating agricultural, municipal, and industrial wastewaters.
Activity 1.3.2 Prepare and distribute scientific papers and reports to interested wetland scientists
and institutions through both the primary and secondary literature. When the system is in full
operation, detailed scientific reports and papers will be published for distribution among national
and international agencies, journals, and wetland scientists. These will elicit scientific and
technical responses from similar operations around the world. Donor agencies will be
encouraged to use the scientific results in implementing similar projects in other countries.
23
Other international wetland operations wishing to exchange data and experiences will be
encouraged to do so through the Project Manager. The technical reports will be made available
to other countries in the region.
Activity 1.3.3 Prepare and distribute socioeconomic results. The project will also generate
socioeconomic information related to the improvement of rural water quality, enhancement of
human environmental links, development of biomass-based businesses, and the impact on rural
families. The information will have immediate relevance to other rural communities in Egypt.
The media will be given access to the data and project personnel for developing documentaries
and news reports for local and national distribution.
D.2 Immediate Objective 2
Demonstration of engineered wetland technology as a low-cost and efficient method of
treating large bodies of water in Egypt and promoting a cleaner Mediterranean Sea.
Output 2.1 Successfully complete preconstruction work for a demonstration scale wetland
to treat wastewater.
Activity 2.1.1 Select project team and initiate preconstruction activities. The project will be
managed by a national Project Manager. Support staff will include a Senior Project Engineer,
Secretary, and Technical Assistant. Detailed terms of reference for the Project Manager and
Senior Project Engineer are provided in Annex VI. The Project Manager will be a senior
professional with experience in developing and managing large contracts, supervising a large
number of technical and professional people, and working with international agencies. The
Project Manager will solicit proposals and coordinate the selection of a Design and Construction
Supervision Contractor.
Activity 2.1.2 Prepare detailed design drawings and specifications. The Project Manager will
be assisted by Egyptian Design and Construction Contractors. During the preconstruction and
construction phases, the Design Contractor will prepare civil, electrical, and mechanical
drawings and specifications for tendering; evaluate tenders; award contracts and subcontracts;
supervise construction; and ensure that contractors adhere to the plans and specifications.
Activity 2.1.3 Establish project offices and laboratory facilities. A project office will be
established in Cairo with an office space to accommodate the Project Manager and the office
secretarial and support staff. The line of communications between the Project Manager and the
Egyptian Government departments and research institutions will be established with the
assistance of the EEAA. In addition to the main project office, an office-laboratory-storage
facility will be constructed at the project site. The Project Manager will be based in Cairo to
maintain a liaison among government agencies, to ensure interagency cooperation, and to obtain
permits and approvals. The Senior Project Engineer will be based at the project site and Port
Said to oversee site and socioeconomic activities.
Activity 2.1.4 Tender the international contract. An International Consultant will provide
technical assistance for the project. A single contract will cover all international expertise
requirements for the construction and operation phases of the project. The contract will cover a
24
five-year period and will include an International Coordinator, International Wetland Designer,
International Wetland Advisor, and International Field Manager.
The International Coordinator will head the international team. This will be a senior scientist
with expertise in project management of large interdisciplinary projects, a Ph.D. in engineering,
limnology or a related discipline, and management experience (both theoretical and practical) of
large watersheds. The International Wetland Designer and the International Wetland Advisor
share responsibilities to ensure availability continuously throughout the project. Terms of
Reference and other conditions for the International Consultant are given in Annex VII.
Activity 2.1.5 Undertake necessary field surveys. Ground, soil, and hydrogeology surveys will
be completed to delineate the site topography, soil characteristics, and the water table elevations.
Soil samples will be obtained from the site area from various depths but within the zone of
excavation and analyzed for standard soil parameters such as cation exchange capacity (CEC),
size distribution, clay, slit and sand content, organic matter, sodium adsorption ratio (SAR) and
permeability. Topographic surveys will help to align the system within the allotted area and will
provide data for optimizing the excavation and compaction work. Hydrogeology data collection
will provide the data on water table elevation, hydraulic gradients, and hydraulic conductivities.
Activity 2.1.6 Collect hydrometric and water quality data from Bahr El Baqar drain and the
Bashtir Canal. These data will include: depth, flow velocity, base sediment load, suspended
sediment load, and the water quality parameters. The data will be analyzed by the Project
Manager and the Design Contractor to finalize the design and tender specifications. The data
will also be used by the international experts to incorporate any changes in the conceptual
design.
Activity 2.1.7 Prepare and award tenders. All tenders will be prepared in accordance with the
construction regulations and codes of good engineering practice in Egypt. The tender documents
will be released for bidding. Documents received from the tendering firms will be evaluated and
processed for awarding the primary and subsidiary contracts. Various deadlines and time
schedules will be determined for compliance of contracting and subcontracting firms as well as
environmental management guidelines to ensure that there is as little environmental disruption as
possible during construction.
Activity 2.1.8 Prepare scientific study and monitoring workplan. Protocols and schedules will
be prepared to assess wetland operations and monitor treatment performance. Protocols will be
established for measuring water quality and ecological parameters. Analytical laboratories will
be identified and contracted on an annual basis. All routine, low technology parameters will be
analyzed on site. This will ensure consistency in measurement and a cost savings. Graduate
students will use the on-site laboratory facilities for research studies. More specialized analyses,
such as heavy metals and organics, will be contracted. Procedures and schedules for the QA/QC
work will be developed by the Project Manager. The monitoring program is discussed in Annex
V.
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Output 2.2 Construct a 120 feddan demonstration wetland treatment system consisting of
sedimentation pond, engineered wetlands, and aquaculture facility. The system will be
capable of treating 25,000 to 50,000 cubic meters per day.
Activity 2.2.1 Order hardware. All hardware required for the wetland system will be purchased
ahead of the construction phase so that any delays by the manufacturer in the delivery of the
items will not hold up construction and operation. Hardware will include: pumps, the pump
intake structures, piping, valves, couplers, gates, and culverts.
Activity 2.2.2 Install water intake and pumping station. The intake will be installed so that the
intake water is representative of the Bahr El Baqar drain. An intake manifold will be constructed
to limit the uptake of bottom sediment. This will reduce the sediment load into the
sedimentation pond and the dredging frequency. Intake pumps will run on electric power. The
project will install site transmission lines and tap power from existing lines provided to the site
by the GOE.
Activity 2.2.3 Construct sedimentation pond, wetland channels, aquaculture, facility, drying
beds, plant propagation facility, and office/laboratory complex. After the tendering process is
complete, the selected contractor will construct the engineered wetland. Labor intensive
construction techniques will be used to maximize local employment of unskilled workers.
Conceptual design and preliminary cost estimates are given in Annex IV. These will serve as a
starting point for detailed design. Modifications will be made as necessary to accommodate
sound engineering practices and site conditions.
Construction will be supervised by the Design Contractor in consultation with the Project
Manager. The Senior Project Engineer will serve as the on-site contact throughout the
construction period and will serve as the on-site manager as needed during construction. The
International Wetland Designer and International Wetland Advisor will be available for
assistance as requested by the Project Manager.
Activity 2.2.4 Conduct plant propagation operation. The engineered wetlands will require a
large supply of wetland plants such as cattail, bulrush, phragmites, duckweed, chara, and water
hyacinth. These must be available as soon as the civil construction is completed so that there is
little delay in the planting and operation of the system. Local plants and harvesting by residents
will be used whenever possible. If necessary, a plant propagation facility will be established at
the project site and will employ local residents for building the facility, developing seed beds,
and tending the seedlings.
Activity 2.2.5 Ensure the participation of the local residents during the construction phase. The
participation of the local residents in all aspects of the project before and during the construction
will be emphasized whenever skilled and unskilled labor are hired. The project will involve the
local residents from the inception of the project to the end of project period, so that the local
population will develop a growing affiliation with the project and begin to assume ownership
through the activities of the cooperatives, as well as direct project functions. This will facilitate
the transfer of technology and socioeconomic benefits to the families and individuals of the area.
The Project Manager through the Senior Project Engineer will be responsible for fostering this
participation.
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Output 2.3 Implement an innovative wetland technology to treat 25,000 to 50,000 cubic
meters of polluted water per day, provide a viable basis for sustainable development, and
create opportunities for socioeconomic growth in an environmentally sound manner.
Activity 2.3.1 Develop wetland products and markets that will provide jobs, increase local
income, and partially offset operating costs. Wetland by-products of commercial value will be
produced and market mechanisms developed. To the extent practical, wetland operations will
promote local employment, increased incomes, and revenues to offset operating costs. The
Project Manager through the Senior Project Engineer will be responsible for this activity.
Activity 2.3.2 Assess environmental and economic improvements and inform local residents.
The ability of the wetland technology to increase family income, reduce pollution, and improve
Lake quality will be communicated and demonstrated to local residents. Information will be
provided to the local residents through media coverage, site visits, and local programs. The
project benefits will be interpreted in terms of increased income to the people, reduced pollution,
reduced occurrences of fish contamination, and a more sustainable fishery.
The potential impact to the Lake of expanded use of the wetland technology will be quantified.
The long term environmental and economic benefits will be quantified in terms of Egyptian
pounds per cubic meter of clean water produced and the economic worth of the products and
labor produced. This will be compared with the costs and benefits of conventional technologies.
Output 2.4 Establish a monitoring and evaluation system to enable the Egyptian
Environmental Affairs Agency (EEAA) to maintain expected performance levels.
Activity 2.4.1 Implement the monitoring plan on system performance and operation and
establish an information distribution network. The Project Manager is responsible for
determining the nature and scope of the data to be obtained from the engineered wetland. The
Project Manager is also responsible for communicating the performance results to relevant
government agencies, and developing a system of routine operational procedures. The operating
organization will develop a checklist of parameters to act as performance indicators. Monitoring
protocols will be evaluated on a six-month basis for relevance, procedural accuracy, reliability,
sources of error, and adjusted as necessary by the Project Manager.
Activity 2.4.2 System operation to establish operating guidelines. Initial system operations will
involve testing of alternative operating methods and procedures. Guidelines will be prepared
recommending routine operating procedures.
SECTION E INPUTS
The technical discussion of key project components is given in Annexes I, IV, and V on project
description, engineering design, and monitoring. Details on input quantities and estimated costs
are provided in Annexes VII, VIII, and IX. A summary of the inputs by general project activity
is given below.
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E.1 Government of Egypt Inputs
Personnel
Person Months
EEAA Representative
8
Project Management Board
15
Technical Focal Points
15
Land
Project Site
200 feddans
(84 hectares)
Miscellaneous
Egyptian visas and work permits
Necessary governmental approvals
E.2 UNDP Inputs
Personnel
Person Months
Project Manager
60
Senior Project Engineer
60
Secretary 60
Assistant/Driver 60
Legal Counsel
3
Operations Foreman
30
Unskilled Labor
120
Skilled Labor
30
Duty Travel
National Personnel
Mission Costs
Headquarters monitoring
Midform evaluation
Cairo Office
Person Months
Office space
60
Office furnishings
Office equipment
Car
Operating expenses
60
Project Equipment
Truck and Trailer
Maintenance equipment
Monitoring and laboratory equipment
28
Project Operations Person
Months
Electricity
30
Expendable materials
30
Maintenance, repair, and replacement
of parts
25
Subcontracts
Person Months
International wetland advisor
24
Design and construction supervision
Construction
Training and Monitoring
Miscellaneous
UNDP Administration
SECTION F RISKS
As far as possible, the project is designed to minimize potential risks. For example, the wetland
operates by gravity flow, contains redundant features, and minimizes mechanical and electrical
complexity. No risks are present that call into question the viability or reliable operation of the
project.
A review of the project identified potential operational and environmental risks that may occur
with both routine activities and nonroutine events. The potential risks and contingency plans for
dealing with each are as follows:
F.1 Implementation Schedule
After the approval of the project, local legal or sociopolitical problems could hinder
implementation as scheduled.
Estimated Probability: Medium
Possible Corrective Measure: The GOE must obtain a project site in a location and manner
which minimizes resistance to the project, ensures local support, and results in adequate security
and access on the site.
The Project Manager must also ensure adherence to the project schedule. Potential delays in the
schedule must be anticipated and resolved. Where necessary, sociopolitical problems should be
immediately communicated to the EEAA and the responsible national agency. The Project
Manager must ensure that problems are effectively solved and maintain the support of national
and local decision makers.
29
F.2 Plant Availability or Propagation
The system design dictates the use of several types of aquatic plants, such as Phragmites,
duckweed, and water hyacinths. There is a risk that the availability or rate of propagation of the
plants will be lower than expected.
Estimated Probability: Low to medium
Possible Corrective Measure: If this occurs, the treatment system will be modified to
temporarily use alternative plants.
F3. Pump Power Failure
Power failures in the project are not uncommon and will disrupt operation of the intake pump
and other electrical facilities at the site.
Estimated Probability: High
Possible Corrective Measures: Short-term power failures will not be disruptive to operation of
the wetland treatment system. No changes in operation are anticipated for outages of several
hours. Longer outages during hot and dry periods could stress plants. In this case, the sediment
basin will be drawn down below normal levels to provide minimum flows through the system.
F4. Variability in Water Quality
There is the possibility of variability in the quality of the source water flowing to the system
which could slightly affect the stability and efficiency of treatment.
Estimated Probability: Low
Possible Corrective Measure: Flow rates and residence times within the system will be modified
to maintain functionality. Operational modifications and monitoring will be used to develop
effective operating procedures.
F.5 Market Value of Outputs
The harvested plant material or aquacultural output may not be utilized or may not produce the
expected economic value.
Estimated Probability: Medium
Possible Corrective Measure: An environmentally and economically sound plan for storage or
disposal of the accumulated material will be prepared. Operational modifications and market
surveys will be used to maximize the net value of system outputs and by-products.
30
F6. Toxicity of Outputs
The dredged sediments, harvested plant material, or the aqua cultural products may contain toxic
substances of human health significance or that render them unsuitable for some uses.
Estimated Probability: Medium
Possible Corrective Measures: All system by-products will be monitored for hazardous
pollutants. Water, sediment, and biological samples will be collected and analyzed for metals,
toxins, and other pollutants. Materials with unacceptable levels or a potential for adverse
impacts will be disposed in an environmentally acceptable manner.
F7. Coordination
Implementation and coordination difficulties due to the number of national agencies and
organizations involved in the project.
Estimated Probability: Medium
Possible Corrective Measure: The Project Manager will communicate regularly with all
participants and modify plans as required to adapt to changing priorities and new opportunities.
Regular evaluations of the project will be undertaken by the Project Manager, International
Consultant, and UNDP staff. The Project Management Board will be encouraged to actively
participate in the project through regular presentations and field trips.
F8. Vandalism of Site and Equipment
Vandalism of the project site and equipment could result in downtime or additional replacement
and repair costs.
Estimated Probability: Medium
Possible Corrective Measures: A maximum on-site presence will be maintained. Regular police
patrols will be encouraged. A good rapport with the local community, treating local participants
fairly, and regular information concerning the benefits of the project will be priority items and
insurance against vandalism.
SECTION G PRIOR OBLIGATIONS AND PREREQUISITES
G.1 Prior Obligations
Site acquisition, security, access, and the provision of electric power are prior obligations to be
fulfilled by the GOE before the project document is signed. The site will be a minimum of 200
feddans in size, have an average land elevation of approximately 1 meter above the normal
ground water elevation, and be located on the Bahr El Baqar drain in the vicinity of the El Salam
Canal.
31
The project document will be signed by the UNDP, and the UNDP assistance to the project will
be provided only if these prior obligations have been met to the satisfaction of UNDP.
G.2 Prerequisites
1. The GOE will give title for the 200 feddan (84 hectare) project site to the project without
remuneration in care of EEAA as the Executing Agency.
2. The Government of Egypt agrees to contribute all GOE inputs described for them in their
budget.
3. The GOE agrees that EEAA will act as the Executing Agency; that relevant government
ministries will provide staff as needed for the Project Management Board and Technical
Focal Points; and that other information and data will be provided as may be available on the
project site and Lake Manzala.
4. The Government of Egypt agrees to participate fully and openly in a dialogue with all
interested parties in regard to the future of Lake Manzala and to help forge the political will
to reverse the significant deterioration of this water body.
5. As part of the GOE's contribution to the Engineered Wetland Project, all necessary permits,
licenses and administrative requirements will need to be processed and approved in the first
year of the project to permit the timely and efficient implementation of the project schedule.
This undertaking will involve, inter alia, processing the following:
5.1 Approval from the Council of Ministers under the provisions of Article 14 of Law No.
143 of 1981 to set aside the 200 feddans of land required for the establishment of the
wetland and supporting facilities.
5.2 Certification that the disposal of the designated area for the construction of the wetland
shall be pursuant to the conditions and procedures outlined under the provisions of
Article 2 of Law No 143 of 1981 Concerning Desert Lands.
5.3 Permission from the General Authority for Reconstruction and Agricultural
Development Projects under Article 10 of Law No 143 of 1981 for the establishment of
buildings and other works required for the construction of the wetland.
5.4 Certification from the inter-Ministerial Committee under the provisions of Article 20 of
Law No. 124 (1983) regarding Fisheries, Aquatic Organisms, and the Organization of
Fish Farms that any affected area of lake designated for the establishment of the
wetland may be allowed to dry and be utilized for purposes other than fishery
development.
5.5 Exemption from the provisions of Article 18 of Law No. 124 (1983) regarding
Fisheries, Aquatic Organisms, and the Organization of Fish Farms which prohibits the
growing of any reeds or rhizome plants in fishing areas, together with the filling of any
fishing area.
32
5.6 Approval under the provisions of Article 11 of Law No. 93 of 1962 in relation to
Wastewater Disposal permitting the discharge of wastewater from the wetlands facility
into the lake or any other watercourse.
5.7 Permission under the provisions of Article 14 Law No. 93 of 1962 to permit the
discharge of treated water from the wetland facility, together with confirmation of the
standards and requirements approved by the Minister of Health, and issued in a
resolution by the Minister of Housing and Public Utilities.
5.8 Certification that the discharges from the wetland comply with the standards and
specifications contained in Resolution No. 649 for 1962 pertaining to discharges into
seas and lakes.
5.9 Issue by the Ministry of Irrigation of the license required under Article 2 of Law No. 48
(1982) Regarding the Protection of the River Nile and Waterways from Pollution
together with the specification of the standards and requirements pertaining to
discharges from the wetland, which shall be determined in consultation with the
Minister of Health.
5.10 Exemption from the provisions of Article 12 of Law No. 48 of 1982 which prohibits the
reuse of drainage water for any purpose.
5.11 Permission from the Ministry of Irrigation to discharge sediment upon the banks where
necessary to construct the wetland, as required under the provisions of Articles 2 and 3
of Executive Regulations for the administration of Law No. 48 of 1982 provided in
Ministerial Decree No. 8 (1983).
5.12 Permission from the Ministry of Irrigation to discharge from the wetland into Lake
Manzala as required under the provisions of Article 38 of Law No. 48 of 1982.
5.13 Certification that the wastewater discharged from the wetland complies with the
standards specified in Articles 66, 68, and 69 of Law No. 48 of 1982.
5.14 Exemption from the provisions of Article 15 of Law No. 124 of 1983 which prohibits
the placement or discharge of any plant or residue into any waterway.
5.15 Certification that any pipes used for the construction of the wetland comply with
standards specified in Articles 9 and 10 of Decree No. 8 of 1983 and Standard
Specification No. 165 (1962) concerning Waste and Ventilation Pipes.
5.16 Certification that any fish farm established as part of the wetland complies with
requirements under Section 3 of Law No. 124 of 1983.
5.17 Certification that any potable water utilized in the wetland project or generated as a
result complies with requirements specified in Law No 27 (1978) on the organization of
Public Sources of Potable Water and Water for Human Use.
33
5.18 Certification that the wetland engineering design complies with requirements specified
under Law No. 106 (1976) concerning Building Works (as amended by Law No. 30 of
1983, Law No. 54 of 1984, and Law No. 99 of 1986).
5.19 Permission to utilize pumps for the wetland as required under Article 13 of Law No.
124 (1983) regarding Fisheries, Aquatic Organisms and the Organization of Fish
Farms.
5.20 Certification that any bricks produced as a result of utilizing the waste material
produced from the wetland project complies with standards specified in Standard
Specification No. 1109 (1971) concerning Aggregates from Natural Sources and brick
making facility which may be established complies with Decree No. 470 (1971)
concerning the Norms of Atmospheric Pollution.
Additionally, the GOE will ensure that the project provides appropriate compensation to any
displaced persons, as well as the deposit required under the provisions of Article 81 Law No. 48
(1982).
The GOE will also ensure that there is an appropriate body to manage the Engineered Wetland at
the end of the five-year project period (including but not limited to the provision of power for
pumping and other operational needs). The GOE will take steps to ensure that there is an orderly
transition to this body from EEAA should EEAA not be the selected organization.
The project document will be signed by the UNDP, and UNDP assistance to the project will be
provided, subject to the UNDP receiving satisfaction that the prerequisites listed above have
been fulfilled or are likely to be fulfilled. When anticipated fulfillment of one or more
prerequisites fails to materialize, UNDP may, at its discretion, either suspend or terminate its
assistance.
SECTION H PROJECT REVIEW, REPORTING, AND EVALUATION
The project will be subject to tripartite review (joint review by representatives of the
Government, Executing Agency, and UNDP) once every 12 months, the first such meeting to be
held within the first 12 months of implementation. The Project Manager will prepare a Project
Performance Evaluation Report (PPER) and submit to the UNDP prior to each tripartite review
meeting. Additional PPERs may be requested, if necessary, during the project.
Every 12 months the International Consultant will conduct an independent review of the project's
progress and submit a summary report to the Project Management Board, UNDP, and the
Executing Agency.
An annual report to the Project Management Board will be prepared by the Project Manager.
The report will summarize progress, results, system performance, local participation, and
expenditures. Copies will be distributed to relevant agencies and project participants. A
midterm evaluation will be conducted after 30 months. The evaluation will be carried out by
persons independent of the project in order to provide an objective evaluation.
34
A project terminal report will be prepared for consideration at the terminal tripartite review
meeting. It will be prepared in draft sufficiently in advance to allow review and technical
clearance by the Executing Agency at least four months prior to the terminal tripartite review.
Additional details for this component are presented in Annex III.
SECTION I LEGAL CONTEXT
This project document shall be the instrument referred to as such in Article 1 of the Standard
Basic Assistance Agreement between the Government of Egypt and the United Nations
Development Program, signed by the parties on 19 January 1987. The host country
implementing agency shall, for the purpose of the Standard Basic Assistance Agreement, refer to
the government cooperating agency described in that Agreement.
The following types of revisions may be made to this project document with the signature of the
UNDP resident representative only, provided he or she is assured that the other signatories of the
project document have no objections to the proposed changes:
A. Revisions in, or addition of, any of the annexes of the project document.
B. Revisions which do not involve significant changes in the immediate objectives, outputs, or
activities of a project, but are caused by the rearrangement of inputs already agreed to or, by
cost increases, due to inflation.
C. Mandatory annual revisions which rephase the delivery of agreed project inputs, or reflect
increased expert or other costs due to inflation, or take into account agency expenditure
flexibility.
SECTION J BUDGET
Budget tables are provided for the Government of Egypt's contribution in kind (in L.E.) and for
the UNDP (in U.S. $). Annex IX contains a detailed listing and additional explanation of the
individual budget lines.
35
Table 1. Project budget for government of Egypt contribution in L.E.
Budget Line
TOTAL
YEAR 1
YEAR 2
YEAR 3
YEAR 4
YEAR 5
Person/Months
LE
Person/Months
LE
Person/Months
LE
Person/Months
LE
Person/Months
LE
Person/Months
LE
10
Personnel
11.01
EEAA Representative
8
80,420
2 19,000
2 19,580
1 10,080
1 10,380
2 21,380
11.02
Project Management Board
15
189,650
4 48,000
4 49,440
2 25,460
2 26,220
3 40,530
11.03
Technical Focal Points
15
110,640
4 28,000
4 28,840
2 14,860
2 15,300
3 23,640
19
Personnel Component Total
38
380,710
10 95,000
10 97,860
5 50,400
5 51,900
8 85,550
40
Equipment
43.01
Land for Project
200 Feddans 1,600,000
49
Equipment Component Total
1,600,000
50
Miscellaneous
51
Egyptian visas and work permits
52
Necessary governmental approvals
59
Miscellaneous Component Total
TOTAL
38 1,980,710
10 95,000
10 97,860
5 50,400
5 51,900
8 85,550
Table 2. Project budget for UNDP contribution in U.S. $.
Budget Line
TOTAL
YEAR 1
YEAR 2
YEAR 3
YEAR 4
YEAR 5
Person/Months
US $
Person/Months
US $
Person/Months
US $
Person/Months
US $
Person/Months
US $
Person/Months
US $
10
Project Personnel
15
Duty Travel
15.01 National personnel
40,000
8,000
8,000
8,000
8,000
8,000
15.99 Subtotal duty travel
40,000
8,000
8,000
8,000
8,000
8,000
17
National Project Professional Personnel (NPPP)
17.01 Project Manager
60
210,000
12
39,600
12
40,800
12
42,000
12
43,200
12
44,400
17.02 Senior Project Engineer
60
173,500
12
32,400
12
33,600
12
34,800
12
35,800
12
36,900
17.03 Secretary
60
48,000
12
9,024
12
9,312
12
9,600
12
9,888
12
10,176
17.04 Assistant/Driver
60
60,000
12
11,280
12
11,640
12
12,000
12
12,360
12
12,720
17.05 Legal Counsel
3
9,000
3
9,000
17.06 Operations Foreman
30
12,000
6
2,280
12
4,800
12
4,920
17.07 Unskilled Labor
120
24,000
24
4,560
48
9,600
48
9,840
17.08 Skilled Labor
30
10,500
6
1,995
12
4,200
12
4,305
17.99 Subtotal NPPP
423
547,000
51 101,304
48
95,352
84
107,235
120 119,848
120 123,261
19
Personnel Component Total
423
587,000
51 109,304
48
103,352
84
115,235
120 127,848
120 131,261
20
Subcontracts
21
International wetland consultant
24
450,000
6 110,000
5
90,000
5
90,000
4
80,000
4
80,000
22
Design and construction supervision
290,000
190,000
70,000
30,000
23
Construction
1,970,000
1,300,000
670,000
24
Design modifications
30,000
30,000
25
Monitoring and analyses
27
100,000
3
10,000
12
35,000
12
55,000
29
Subcontracts Component Total
51 2,840,000
6 300,000
5 1,460,000
8
830,000
16 115,000
16 135,000
40
Equipment
41
Expendable equipment
41.01 Office utilities/supplies
60
42,000
12
8,400
12
8,400
12
8,400
12
8,400
12
8,400
41.02 Site utilities
30
56,000
6
10,600
12
22,400
12
23,000
41.03 Site materials
30
48,000
6
9,600
12
19,200
12
19,200
42
Non-expendable equipment
42.01 Office furnishings
5,000
5,000
42.02 Office equipment
15,000
15,000
42.03 Office car
20,000
20,000
42.04 Site truck and trailer
30,000
30,000
42.05 Site maintenance equipment
15,000
15,000
42.06 Site monitoring equipment
36,000
36,000
42.07 Site laboratory equipment
64,000
64,000
43
Premises
43.01 Office space
60
60,000
12
12,000
12
12,000
12
12,000
12
12,000
12
12,000
49
Equipment Component Total
180
391,000
24
60,400
24
20,400
36
185,600
48
62,000
48
62,600
50
Miscellaneous
50.01 Site maintenance, repair, and replacement of equipment
25
62,000
1
2,480
12
29,760
12
29,760
50.02 UNDP Administration
120,000
24,000
24,000
24,000
24,000
24,000
59
Miscellaneous Component Total
25
182,000
24,000
24,000
1
26,480
12
53,760
12
53,760
TOTAL
679 4,000,000
81 493,704
77 1,607,752
129 1,157,315
196 358,608
196 382,621
blank
38
SECTION K ANNEXES
ANNEX I
Project Description and Rationale for Design ......................................................................... 41
ANNEX II
Work Schedule ........................................................................................................................ 63
ANNEX III
Project Review, Reporting, and Evaluation Plan..................................................................... 71
ANNEX IV
Preliminary Design Calculations and Construction Cost Estimates ........................................ 75
ANNEX V
Preliminary Monitoring Plan ................................................................................................. 105
ANNEX VI
National and International Participation Framework and National Job Descriptions ........... 113
ANNEX VII
International Contract and International Job Descriptions .................................................... 123
ANNEX VIII
Equipment Requirements....................................................................................................... 133
ANNEX IX
Budget Details ....................................................................................................................... 137
ANNEX X
Financial and Accounting Arrangements .............................................................................. 143
ANNEX XI
Bibliography .......................................................................................................................... 157
39
blank page
40
ANNEX I. PROJECT DESCRIPTION AND RATIONALE FOR DESIGN
1.0 GENERAL PROJECT SETTING AND DESIGN RATIONALE
2.0 CHARACTERISTICS OF WATER IN THE BAHR EL BAQAR DRAIN
3.0 WETLAND DESIGN
3.1 Basic Engineering Design of the Treatment System
3.2 Wastewater Treatment Components
3.2.1 Sedimentation Pond
3.2.2 Engineered Wetlands: Emergent Plants
3.2.3 Engineered Wetlands: Floating Plants
3.2.4 Reciprocating Gravel Wetland System and Aquaculture Facility
3.3
Wetland
Performance
3.4 Removal of Heavy Metals by the Treatment System
41
ANNEX I
blank page
42
ANNEX I
ANNEX I PROJECT DESCRIPTION AND RATIONALE FOR DESIGN
1.0 General Project Setting and Design Rationale
Of the five major drains that carry wastewater into Lake Manzala, the Bahr El Baqar drain is the
most polluted and contains a large range of particulates, nutrients, metals, organics, and other
toxic compounds. The drain receives inputs from numerous point and nonpoint sources before
reaching the Lake. Sewage from Cairo, wastewaters from industries, agricultural discharges
from farms, and discharges and spills from boat traffic are major sources of pollution.
The short-term objectives of this project include designing, constructing, operating, and
monitoring an engineered constructed wetland. The purpose of the wetland demonstration
project is to illustrate the utility of an inexpensive wastewater treatment complex to treat up to
50,000 m3/day* of effluent from the Bahr El Baqar drain and to provide economic benefits to
local residents. The long-term objectives include expediting adoption of the most promising
components of the technology to provide additional treatment and local economic benefits. The
impact of these actions will benefit Lake Manzala, the Mediterranean Sea and the local
population. Wetland treatment systems are effective and often provide more affordable
treatment than conventional methods. Wetlands offer opportunities for sustainable rural and
urban economic growth, with good potential for commercial utilization of biomass and sludge.
The preliminary design will incorporate a diversity of treatment options to allow primary,
secondary, and tertiary treatments (i.e., sedimentation, substantial treatment and removal, and
final polishing), along with resource recovery of plant proteins (duckweed and canary grass) and
aquaculture from the Lake Manzala strain of tilapia. The design of the treatment system will
incorporate functional objectives which focus on improving the water quality of Lake Manzala.
The design will be based on the following site-specific characteristics:
A. Wastewater in Bahr El Baqar drain is composed of particulates, nutrients, heavy
metals, hydrocarbons, and residues of toxic compounds such as herbicides and
pesticides. During high flow, the drain water also has large quantities of suspended
sand, silt, and clay which provide adsorption sites for dissolved metals and other
contaminants.
B. Flow volumes undergo significant diurnal and seasonal fluctuations created by
fluctuating water uses and discharges along the drain.
C. Many of the pollutants are adsorbed by the settleable and suspended solids in the
water and are subsequently transported to Lake Manzala where they settle out in the
shallow bottoms.
* Actual treatment capacity could be less than 50,000 m3/day if the ground elevation of the project site requires
excessive fill and/or dewatering. All subsequent preliminary design calculations and cost estimates in the document
are based on a site elevation of 1 meter above the normal groundwater level and a treatment capacity of
50,000 m3/day.
43
ANNEX I
D. Lake Manzala and the Bahr El Baqar drain are vital to the local population. There is
an expectation that international technical and scientific assistance can lead to a
greater and safer use of the waters for traditional practices, such as fish farming and
agriculture. The socioeconomic and cultural infrastructure in the region supports the
use of low-technology and sustainable development strategies. This suggests the
need for developing wastewater treatment designs which can also produce
opportunities for commercial utilization of the biomass. This requires that a
significant part of the biomass produced in the wetland will be protected from the
toxicity of the metals and chemicals. Thus, metals and toxic compounds must be
removed before they are accumulated in plant or fish tissues.
E. Lake Manzala is a hydraulic link between the influent drains and the Mediterranean
Sea. If the wetland technology is adopted at other sites, it can enhance the lake
environment and protect the Mediterranean Sea. It is envisaged that the success of
this initiative will result in the development of similar systems in other areas of Egypt
and the Arab region.
2.0 Characteristics of Water in the Bahr El Baqar Drain
Water quality characteristics, as revealed by data collected in 1992 and 1993, indicate
considerable diurnal and seasonal variations. The high sediment load in the drains consists of
approximately 65 percent sand, 23 percent silt, and 12 percent clay material. Although the
settleability of the sand fraction is rapid, the deposits undergo constant accretion and erosion
creating a mobile sediment bed in the drain channel. Sediment-adsorbed organic carbon ranges
from about 17 percent to 75 percent of the total organic carbon levels and is indicative of a high
potential for adsorption of metals. This is further supported by the trace metal data in the water
and sediments. Table I-1 shows the partition of selected heavy metals in the water and
sediments.
Table I-1. Selected heavy metals in water and sediments.
Metals
Units
Zn
Mn
Fe
Pb
Hg
Cd
Water
ppb
0.076
0.35
0.45
0.32
0.37
0.40
Sediment
ppm
164.21
481.70
2.45
95.3
0.44
0.15
Note: Water samples were analyzed by the Central Laboratory for Aquaculture Research, Abbassa.
Sediment samples were analyzed by the National Institute for Oceanography and Fisheries,
Alexandria. Data are from 1993 sampling (Lane and Associates Limited, 1993).
Since the sediment carries a large fraction of the metal contaminants, removal by the
sedimentation basin will provide primary pretreatment prior to secondary and tertiary treatment
in the constructed wetlands.
Constantly fluctuating pollutant and sediment concentrations in the drain water are due to
variations in the flow velocity, flow depth, and influent quality produced by hundreds of inputs
and discharges into and from the drain along the route to Lake Manzala. Hydrometric
measurements conducted in 1992 and 1993 show that both water depth and current velocity can
44
ANNEX I
change rapidly within a day and between various sampling sites on the same day. Between
June 6 and June 10, 1993, at Station 93-1, the current velocity changed from 0.44 m/s to 0.14
m/s. At station 93.1, past records show that the annual variation in the monthly mean flow
ranged from about 5 m3/s in July of 1988 to about 35 m3/s in January of 1989, and decreased to
about 8 m3/s in July of 1989.
The variation in total suspended solids (TSS) was studied for a 24 hour period at Station 93-1
and for a 12 hour period at Station 93-6. Station 93-1 showed a continuous fluctuation of TSS
between a maximum value of 280 mg/L and a minimum value of 60 mg/L. This variation was
composed of several cyclical changes in TSS, with periods alternating between two and three
hour intervals. The cycle beginning at 2100 hours had a four hour period, and the second highest
maximum. In contrast, the 12 hour measurements taken at Station 93-6 during the same
timeframe showed very little variation in TSS values. All TSS samples were taken at about 0.5
m below the surface. This further augments the difficulty in estimation of the trend in the
sediment load and, hence, the pollutant load carried by the sediments. As mentioned before, the
sediment concentration is the most important water quality parameter for the design of the
treatment system. The following table shows data obtained from hydrometric and bed level
measurements conducted in 1988 and 1989 at the Bahr El Baqar bridge by the Drainage
Research Institute.
Table I-2. Changes in flow rate and bottom bed level in Bahr El Baqar drain at the bridge.
Parameter
Units 20/07/88 21/11/88 04/12/88 17/01/89 14/02/89 26/03/89
Flow Rate (m3/s) m3/s 3.19
22.49
25.07
34.90
24.73
16.37
Bed Level below msl
m
1.51
1.69
1.70
1.89
1.83
1.88
Parameter
16/04/89 24/05/89 28/06/89 08/07/89 02/08/89
-
Flow Rate
m3/s 12.38
8.51
12.21
10.20 8.08
-
Bed Level (m) below msl
m
1.90
1.93
1.87
1.92
1.81
-
Erosion of the sediment bed is predominant when flows increase in the drain and both erosion
and accretion become evident from February to July when flow rates begin to decrease. The
sediment load in the drain follows a similar variation during the year. Settleability tests
conducted in 1992 showed that the average TSS in the sediment profile reached a near
equilibrium concentration of about 660 mg/L in about 48 hours. However, this value is based on
high sediment loads and whole column water sampling. An inflow TSS value of 160 mg/L more
accurately reflects concentrations in the upper reaches of the water column from which the
inflow will be obtained.
Initially, operation of the wetland treatment system will be in experimental mode to optimize
treatment efficacy based on loading rates, retention times, and the physical, chemical, and
biological treatment processes. This will allow development of operating procedures based on
site-specific conditions.
Table I-3 summarizes expected influent water quality to the treatment system. Water quality
values are based on averages derived from various monitoring efforts within the past five years.
45
ANNEX I
Table I-3. Design water quality data (influent) for treat-
ment by engineered wetland system.
Parameter
Units
Value
Daily flow
m3 50,000*
Total BOD
mg/L
30
Total COD
mg/L
100
Total Suspended Solids
mg/L
160
Total Phosphorus
mg/L
5
Total Nitrogen
mg/L
10
pH
7.5
Conductivity micromhos/cm
2300
3.0 Wetland Design
3.1 Basic Engineering Design of the Treatment System
Each of the components of the proposed system and their relative positions are illustrated in
Figures I-1 and I-2. Figure I-3 provides a longitudinal cross section of the wetland beds in
relation to the existing grade and sea level.
The following are the principal components of the treatment system:
A. Sedimentation Basin;
B. Engineered Surface-flow Wetland Treatment Beds (primary and secondary), planted
to aquatic macrophytes and/or floating duckweed;
C. Engineered Subsurface flow Wetland (reciprocating system), planted to emergent
aquatic and/or terrestrial species with emphasis on high value;
D. Aquaculture Hatchery and Fingerling Production Ponds, with emphasis on the Lake
Manzala strain of tilapia (Oreochromis niloticus)
* Actual treatment capacity could be less than 50,000 m3/day if the ground elevation of the project site requires
excessive fill and/or dewatering. All subsequent preliminary design calculations and cost estimates in the document
are based on a site elevation of 1 meter above the normal groundwater level and a treatment capacity of
50,000 m3/day.
46
ANNEX I
Project Site
road
1400 m
47
m
Wetland
Future
0
expansion
0
6
i
n
r
aD
Total area = 200 feddans
AN
NE
X I
Figure I-1. Proposed site area for development of Lake Manzala wetland.
blank page
Site Plan
road
Flow
Total area = 120 feddans
850 m
reed bed
reed bed
4
n
9
m
t
i
o
0
t
a
0
i
n
n
e
s
i
n
duckweed pond
6
r
a
a
D
i
m
b
d
reed bed
s
e
sediment
gravel bed / aquaculture
drying beds
building
pump station
Primary
Secondary
Tertiary / Resource
AN
NE
recovery
X
I
Figure I-2. Plan view of proposed Egyptian engineered wetlands complex with aquaculture resource recovery option
blank page
Wetland Profile
3 m
3 m
2.3 m
1.7 m
51
existing grade
sea level
0 m
pr
se
te
d
im
co
r
r
ti
a
a
n
a
i
r
n
ry
da
y
ry
Figure I-3. Preliminary illustration of Egyptian engineered wetland complex with respect to existing grade and sea level.
Primary sector represents a cross-section view of the sedimentation basin, while the secondary and tertiary
sectors refer to serial wetland compartments inclduing reed beds, duckweed beds, reciprocating gravel beds,
AN
and aquaculture ponds.
NE
X I
Blank page
The proposed engineered wetland complex and associated facilities include:
A. Intake structure (offset from the drain), and water delivery system including the
intake manifold, sumps, pump housing and the delivery weir to the sedimentation
basin;
B. Sedimentation basin.
C. Discharge structure to convey wastewater from the sedimentation basin to the
surface-flow engineered wetlands.
D. Delivery and discharge structures to convey water from secondary wetland beds to
tertiary treatment beds, including reed bed, duckweed bed, and subsurface-flow
reciprocating system.
E. Delivery and discharge structures to convey water from reciprocating system to
aquaculture hatchery and fingerling ponds.
F. Discharge structures to convey water from the aquaculture facilities and secondary
treatment beds (reed beds and duck weed) to the Lake.
The intake structure will be designed and offset from the main canal to minimize current velocity
and entrainment of bottom sediments. The drain water will be channeled into the offset pumping
station which will be outfitted with a screen to remove floating debris and plant material (water
hyacinths). The final entry into the next stage of the pumping scheme will be a control structure
such as a weir. The wetwell will provide sufficient volume and depth for efficient pumping
cycling.
Water will be conveyed to the pump through a short section of intake pipe. It is suggested that
centrifugal, screw, or similar pumps be used that are suitable for high volume, low head, nonclog
service. The pump discharge will be piped to the sediment basin, entering near the drying bed.
Conceptual design and operational guidelines are provided in Annex IV.
3.2 Wastewater Treatment Components
Tables I-4 and I-5 summarize design parameters for each system component. The following
sections describe the function of each component in the overall wastewater treatment process.
3.2.1 Sedimentation Pond
Wastewater will be pumped into a rectangular sedimentation basin through a weir-type inlet.
The sedimentation basin will have a volume of 100,000 m3 and a hydraulic retention time of two
days. Preliminary tests indicate that the inflow suspended solids contain about 65 percent sand
fraction and 35 percent silt and clay fraction. The sedimentation basin will be designed for a
minimum settling efficiency of 50 percent. Parallel cells or other flow barriers will be used as
needed to prevent short circuiting and facilitate sediment removal. The sediment accumulation
will be dredged or manually removed to conventional drying beds several times per year.
Approximately 1500 m3/year are anticipated. The dried sediment will be tested for contaminants
and, if suitable, used for construction or fill material.
53
ANNEX I
Table I-4. Drain water inflow characteristics.
Inflow
Units Total BOD Total COD
TSS
TP
TN
Concentration
mg/L
30
100
160
5
10
Daily
tons
1.50
5.00
8.00
0.25
0.50
Yearly tons
548
1825
2920
91
182
Table I-5. Preliminary design parameters for the Egyptian Engineered Wetlands Project, 1996.
High flow
Low flow
Tertiary
Tertiary
Tertiary
Hatchery and
Sediment
Secondary
Secondary
Reed
Duckweed
Recip.
Fingerling
Parameters
Units
Basin
Reed Bed
Reed Bed
Bed
Bed
Gravel Bed
Ponds
Flow
m3/d
50,000
41,000
9,000
41,000
7,000
2,000
2,000
Volume*
m3 100,000*
37,500
37,500
25,00
0
25,000
4,000
*
30,000
Area
m2
50,000
75,000
75,000
50,000
50,000
10,000
30,000
Depth
m
2
0.5
0.5
0.5
0.5
1
1
Detention
d
2
0.9
4.2
0.6
3.6
2
12
*Active storage volume, excluding sediment storage, plant biomass, and gravel volume.
3.2.2 Engineered Wetlands: Emergent Plants
Emergent plants such as cattail (Typha latifolia), bulrush (Scirpus spp.), and reed
(Phragmites communis) act as efficient filters for suspended solids, and can probably be
used interchangeably in wetland treatment systems. For this application, a monoculture
of the endemic common reed (Phragmites communis) as the emergent plant is
recommended since it has high biomass potential, responds to selective harvesting, and
has potential commercial uses.
Emergent plants will be used in the secondary treatment section of the wetland to
substantially improve water quality before the wastewater reaches the tertiary series of
wetland beds. The tertiary beds will contain either common reed or canary grass
(Phalaris arundinacea) and duckweed for effluent polishing. In some treatment
wetlands, TSS removal rates as high as 90 percent or more have been observed.
Emergent plants can also absorb and sequester heavy metals from water and sediments
mostly in the rhizomes, or in the outer oxidized layer (scale-like formation) of the roots
and root hairs. A small portion of the metals thus absorbed can be translocated from the
roots and rhizomes to the above-ground stems, leaves, and seeds.
Considerable improvement in the secchi depth or turbidity can be achieved in the
wastewater during passage through the secondary treatment emergent wetland. This
enhances the transmission of light which encourages photosynthesis in attached and
benthic algae. Algae are specifically effective in absorbing heavy metals from water and
sediments and adding oxygen to enhance removal of biological oxygen demand. Various
species of green and blue-green algae have been used in natural and engineered wetland
systems to treat mining effluents and remove metals. The major role of the secondary
wetland beds is removal of TSS, BOD, and heavy metals.
3.2.3 Engineered Wetlands: Floating Plants
Water hyacinths have been used extensively to remove nutrients, suspended sediments
and pollutants from wastewaters in engineered wetlands. Water hyacinth can be
managed to produce high biomass yields and marketable products such as animal feed,
fuel pellets and methane. It is essential to ensure that the biomass is free of toxic
pollutants so that the end products do not pose health and environmental hazards.
Duckweed (Lemna spp,) is another alternative floating plant that can remove algal and
particulate turbidity, nutrients and dissolved metals. Duckweeds are especially beneficial
in a resource recovery program because of their high protein content (30-40 percent
protein on a dry matter basis), and their near optimum amino acid profile. These small
floating plants are easily harvested by skimming and netting, and have a high digestibility
coefficient when fed to tilapias and grass carp. It is proposed that one of the tertiary
treatment beds be planted to duckweed and canary grass, both of which can be harvested
for use as fodder and feed for tilapia and grass carp, respectively. It is anticipated that up
to 5 percent of the duckweed biomass can be harvested on a weekly basis without
reducing overall productivity and treatment efficacy. Canary grass can also be harvested
(leaves and stems) but usually only on a monthly basis and only to the extent that it is
cropped back to the original planting arrangement. The primary function of the canary
55
ANNEX I
grass, which spreads slowly, is to act as a living hedge row to prevent the duckweed
from being windswept to the shoreline. Canary grass, also has a high protein content and
a high palatability for grass carp and ruminants.
The choice of using emergent macrophytes, benthic and attached algae, and floating
plants in the proposed sequence will ensure that: 1) suspended solids are removed well
before the wastewater flows to the secondary wetland beds for nutrient polishing,
2) substantial water clarity is achieved in the submergent wetland for better light
penetration and photosynthesis; and 3) heavy metals and toxic chemicals are removed
before reaching the floating plant beds so that the harvested plants (canary grass and/or
duckweeds) are free from any toxic contamination. The wetland design will emphasize
the unique economic and environmental benefits which can be derived from wetland
treatment systems, particularly in a developing country.
3.2.4 Reciprocating Gravel Wetland System and Aquaculture Facility
The aquaculture facility will receive effluent water from a 1 hectare (ha) reciprocating
wetland system designed for tertiary treatment. The aquaculture resource recovery
module will consist of four hatchery ponds, each with about 0.1 ha surface area and two
fingerling production ponds, each with approximately 1 ha of surface area. The ponds
will be approximately 1 m deep with bottom slopes sufficient to drain into internal catch
basins to facilitate complete harvesting. Figure I-4 provides a plan view of the proposed
aquaculture facility and reciprocating wetlands module. The aquaculture facility will be
a proof-of-concept facility to demonstrate that the wetlands are capable of cleaning water
to the extent that fish culture activities can be safely and economically practiced.
Furthermore, the hatchery can be the basis for development of a restocking program to
augment tilapia production in Lake Manzala. It is anticipated that with current pond-
based hatchery technology, it will be possible to produce up to 5,000,000 fingerlings per
year. No special operating procedures are expected since the growing season in northern
Egypt extends throughout most of the year. Although daytime temperatures can
approach 15 degrees C in the winter, the impact on fish and aquatic plants is small
because of the relatively short winter. Diurnal temperature variations in the fish ponds
are less than air variations because of the thermal holding capacity of water.
3.3 Wetland Performance
The wetlands are proposed to operate under three treatment options. All treatment
options involve 50,000 m3/d through the sedimentation basin. A high-flow treatment
consists of 41,000 m3/d through a secondary reed bed and then through a tertiary reed
bed. The other two treatment options have the remaining 9000 m3/d passing through a
secondary reed bed. Of this 9000 m3/d, 7000 m3/d passes through a tertiary duckweed
bed. The third treatment option consists of 2000 m3/d passing through a reciprocating
gravel-bed wetland.
Using the flow patterns described above, conservative estimates for the removal of TSS,
TP, TN, and BOD have been determined for the effectiveness of the sedimentation basin
and individual wetland components. Tables I-6, 7, and 8 provide estimates of removal
56
ANNEX I
RESOURCE RECOVERY W ITH AQUACULTURE
EFFLUENT FROM SECONDARY TREATMENT WETLANDS
FINGERLING
FINGERLING
POND A
POND B
HATCHERY
PONDS
RECIPROCATING
W ETLANDS
(TERTIARY TREATMENT)
DRAIN TO IRRIGATION
Figure I-4. Proposed layout of aquaculture facility including reciprocating module for tertiary wastewater treatment, four
tilapia hatchery ponds and two fingerling production ponds. Respective areas of the components are 1 ha.
reciprocating unit, 0.1 ha (four each) hatchery ponds, and 1 ha. (two each) fingerling production ponds.
Blank page
Table I-6. Estimated removal efficiencies* for individual wetland components.
Bahr El Baqar drain
High Flow Secondary
Low Flow Secondary
Initial Conditions
Sedimentation Pond
Reed Bed
Reed Bed
Influent
Drain
Influent Effluent Removal Influen Effluent Removal Influent Effluent Removal
conc.
conc.
conc.
Efficiency
t
conc.
Efficiency
conc.
conc.
Efficiency
Parameter
mg/L
mg/L
mg/L
%
conc.
mg/L
%
mg/L
mg/L
%
mg/L
TSS 16
0
160
80
50
80
18.3
39
80
17.9
39
BOD 4
0
40
24
40
24
21.0
8
24
13.6
26
Total P
5
5
4
25
4
3.5
4
4
2.9
18
Total N
12
12
12
0
12
10.9
9
12
7.9
35
Organic N
2
2
2
0
2
2.0
2
2
1.8
8
Ammonium N
10
10
10
0
10
8.9
11
10
6.0
40
Tertiary Reciprocating
Tertiary Reed Bed
Tertiary Duckweed Bed
Gravel Bed
Influent Effluent Removal Influen Effluent Removal Influent Effluent Removal
conc.
conc.
Efficiency
t
conc.
Efficiency
conc.
conc.
Efficiency
mg/L
mg/L
%
conc.
mg/L
%
mg/L
mg/L
%
mg/L
TSS 16
0
18.3
8.4
6
17.9
9.0
6
17.9
9.0
6
BOD 4
0
21.0
19.3
4
13.6
6.8
17
13.6
6.8
17
Total P
5
3.5
3.4
3
2.9
1.4
29
2.9
0.6
46
Total N
12
10.9
10.3
5
7.9
3.9
33
7.9
0.8
59
Organic N
2
2.0
1.9
1
1.8
0.9
46
1.8
0.2
83
Ammonium N
10
8.9
8.3
6
6.0
3.0
30
6.0
0.6
54
*Removal efficiencies are calculated as a percentage reduction relative to the influent drain concentration. Removal efficiencies for individual wetland
components are not shown, but can be calculated as: (component influent concentration-component effluent concentration) x 100 / component influent
concentration.
Table I-7. Estimated treatment efficiency as a function of alternative flow paths.
Low Flow/Reciprocating
High Flow Volume1
Low Flow Volume2
Gravel Bed3
Removal
Removal
Removal
Influent conc. Effluent conc. Efficiency Effluent conc. Efficiency Effluent conc.
Efficiency
Parameter4
mg/L
mg/L
%
mg/L
%
mg/L
(%)
TSS
160
8.4
95
9.0
94
9.0
94
BOD
40
19.3
52
6.8
83
6.8
83
Total P
5
3.4
32
1.4
71
0.6
89
Total N
12
10.3
15
3.9
67
0.8
93
Organic N
2
1.9
3
0.9
54
0.2
91
Ammonium N
10
8.3
17
3.0
70
0.6
94
1. High flow = 41,000 m3/d (82% of influent flow) through the secondary reed bed and tertiary reed bed.
2. Low flow = 7000 m3/d (14% of influent flow) through secondary reed bed and tertiary duckweed pond.
3. Low flow w/gravel bed = 2000 m3/d (4 percent of influent flow) through secondary reed bed and reciprocating gravel bed.
4. Dissolved oxygen is expected to be 2 mg/L in the effluent. Salinity will be transported through the wetland without significant
removal. Salinity may actually increase by 10-15 percent due to evapotranspiration.
rates based on the first-order removal models of Kadlec and Knight, 1996, and
information provided in WPCF FD-16 (1990). All of the N, and most of the P, is
assumed to move through the sediment pond as soluble forms or in association with fine
solids that do not settle.
Table I-8. Estimated final water quality
Total BOD
Total COD
TSS
TP
TN
mg/L
mg/L
mg/L
mg/L
mg/L
< 10
< 40
< 117
< 2.2
< 2.1
3.4 Removal of Heavy Metals by the Treatment System
Heavy metals such as copper, nickel, lead, zinc, chromium, and cadmium are found
primarily adsorbed to the sediments in the wastewater. Sedimentation and adsorption of
these metals by the wetland plants will be the primary removal mechanism. Benthic and
attached forms of algae which are endemic to most emergent wetland systems have been
used in Canada and the United States to clean up mining effluents and tailings containing
high concentration of heavy metals. Cattail, bulrush, common reeds, and canary grass are
capable of absorbing metals from water and sediments and, therefore, will contribute to
the treatment system's removal efficiency. In addition, anaerobic conditions that
normally prevail near the sediment/water interface will contribute to reduced conditions
for precipitation of any dissolved metals as metal sulfides. Thus, there are several metal
removal mechanisms in the proposed system which will ensure that the metal
concentrations in the water are rapidly reduced before the wastewater flow reaches the
duckweed wetland from which plant biomass will be harvested. The following are
conservative estimates of metal removal in the treatment system.
Table I-9. Removal of heavy metals by the treatment system. (Based on influent of
50,000 m3/day)
Removal
Input
Sedimentation Harvested Discharged Efficiency
Metal
kg/yr
kg/yr
kg/yr
kg/yr
%
Copper (Cu)
390
330
42.4
12
97
Nickel (Ni)
236
203
18
13.6
94
Lead (Pb)
250
215
1.5
33
87
Zinc (Zn)
707
607
92
6
99
Chromium(Cr) 463
400
52
13.6
97
Iron (Fe)
96300
91500
5
4795
95
Manganese (Mn)
1490
1400
5
85
94
Mercury (Hg)
8.03
2.06
0
5.97
26
Cadmium (Cd)
886
762
0
124
86
62
ANNEX I
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63
ANNEX I
ANNEX II. WORK SCHEDULE
1.0 CAPACITY BUILDING FOR SUSTAINABLE DEVELOPMENT
1.1 Community Participation
1.2 Capacity Building and Human Resource Development
1.3 Disseminate Wetland Lessons and Experience Gained
2.0 CLEAN WATER, LESS POLLUTION, AND ENHANCED AQUATIC HABITATS AND BIODIVERSITY
2.1 Complete Preconstruction Work for a Demonstration Scale Wetland
2.2 Construction Demonstration Wetland
2.3 Create Opportunities for Sustainable Socioeconomic Growth
2.4 Establish a Monitoring and Evaluation System to Maintain Expected Performance Levels
64
ANNEX II
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65
ANNEX II
ANNEX II WORK SCHEDULE
The proposed work is described in Section D by objective, output, and activity. A
summary and schedule for each activity is as follows:
1.0 Capacity Building for Sustainable Development
1.1 Community Participation
Activity 1.1.1 Assist local residents in becoming full partners. Early in the project, the
Project Manager will confer with local residents and NGOs to identify those interested in
participating in the project. NGOs and local representatives will help organize the
entrepreneurial activities associated with planting and harvesting biomass and developing
the wetland and aquaculture facilities.
Activity 1.1.2 Involve local residents in human resource and economic development.
During the preconstruction phase, the Project Management Team will meet with local
residents to identify human resource and economic development opportunities. A
working partnership will be maintained to provide local labor and participation in project
construction and operation.
Activity 1.1.3 Increase environmental awareness in the local community and
Governorate of Port Said. The Project Manager will work with the local media to
develop a program of interactive education. Environmental management principles and
practice will be conveyed and discussed. The public will be encouraged to participate
and suggest how the local community can benefit from the project.
Activity 1.1.4 Assist local participants in business development. Wetland treatment
technology will generate a resource-base for sustainable development. Commercial
operations will be developed from the aquaculture facilities and biomass produced by the
engineered wetland.
Activity 1.1.5 Identify local personnel for wetland construction and operation. The
Project Manager will develop specific guidelines to be followed by the construction
contractor. The guidelines will be explicitly incorporated into the design and
specifications for the project.
1.2 Capacity Building and Human Resource Development
Activity 1.2.1 Identify governmental and academic organizations and personnel and
establish communication. The Project Manager and EEAA will identify personnel of
various agencies and NGOs that will participate in the oversight, review, and monitoring
studies. Relevant agencies may nominate many of these individuals.
66
ANNEX II
1.3 Disseminate Wetland Lessons and Experience Gained
Activity 1.3.1 Prepare and distribute annual reports. Reports will be produced annually
on the progress of the project to be distributed to all relevant persons and agencies.
Activity 1.3.2 Prepare and distribute scientific papers. Once the wetland is in operation,
scientific papers will be produced using the data collected from the wetland.
Activity 1.3.3 Prepare and distribute socioeconomic results. The project will also
generate socioeconomic information related to the improvement of rural water quality,
enhancement of human environmental links, development of biomass-based businesses,
and the impact on rural families.
In the operation phase, papers and reports will be prepared using the socioeconomic data
generated from the wetland.
2.0 Clean Water, Less Pollution, and Enhanced Aquatic Habitats and Biodiversity
2.1 Complete Preconstruction Work for a Demonstration Scale Wetland
Activity 2.1.1 Select project team and initiate preconstruction activities. At the outset of
preconstruction, the national Project Management Team members will be hired. The
team, under direction of the Project Manager, will solicit proposals and coordinate the
selection of a Design and Construction Supervision Contractor.
Activity 2.1.2 Prepare detailed design drawings and specifications. The design
contractor will prepare civil, electrical, and mechanical drawings and specifications for
tendering, evaluate tenders, award contracts and subcontracts, supervise construction, and
ensure that contractors adhere to the plans and specifications.
Activity 2.1.3 Establish project offices and laboratory facilities. Offices will be set up in
Cairo and Port Said (and/or the project site) prior to the initiation of preconstruction
surveys.
Activity 2.1.4 Tender and award international contract. Once the national team
members have been hired, the contract for the international team members will be
tendered and awarded.
Activity 2.1.5 Undertake field surveys. Topographic, soil, and hydrogeology surveys
will be initiated to define site conditions suitable for engineering design.
Activity 2.1.6 Collect hydrometric and water quality data. Hydrometric and water
quality data will be collected to define inflow water characteristics and treatment
requirements.
67
ANNEX II
Activity 2.1.7 Prepare and award tenders. The tenders for the wetland construction
subcontract will be prepared using design drawings and specifications and the
information collected during field surveys.
Activity 2.1.8 Prepare scientific study and monitoring workplans. Define workscope,
protocols, and schedules for scientific studies and water quality monitoring of wetland
performance. Laboratories will be contracted to conduct specific analyses.
2.2 Construction Demonstration Wetland
Activity 2.2.1 Order hardware. Order all necessary hardware so as to avoid delivery
delays to construction.
Activity 2.2.2 Install water intake and pumping station. Install intake manifold and
pumps to deliver waters to the wetland system.
Activity 2.2.3 Construct wetlands facilities. After the tendering process is complete, the
selected contractor will undertake the construction of the engineered wetland. Labor
intensive construction techniques will be used to maximize local employment of
unskilled workers.
Activity 2.2.4 Conduct plant procurement/propagation operation. A plant procurement
operation or propagation facility will be used to provide the necessary wetland plants.
Local residents and plants will be used to the maximum extent feasible.
Activity 2.2.5 Participation by local residents. Hiring for project construction and
operation will give priority to local residents. A local labor preference and manual labor
premium will be included in all construction and operations.
2.3 Create Opportunities for Sustainable Socioeconomic Growth
Activity 2.3.1 Develop wetland products and markets that will provide jobs, increase
local income, and partially offset operating costs. Wetland by-products of commercial
value will be produced and market mechanisms developed. To the extent practical,
wetland operations will promote local employment, increased incomes, and revenues to
offset operating costs.
Activity 2.3.2 Assess environmental and economic improvements and inform local
residents. The ability of the wetland technology to increase family income, reduce
pollution, and improve Lake water quality will be communicated and demonstrated to
local residents. Information will be provided to the local residents through media
coverage, site visits, and local programs. The project benefits will be interpreted in terms
of increased income to the people, reduced pollution, reduced occurrences of fish
contamination, and a more sustainable fishery.
68
ANNEX II
The potential impact on the Lake of expanded use of the wetland technology will be
quantified. The long-term environmental and economic benefits will be quantified in
terms of Egyptian pounds per cubic meter of clean water produced and the economic
worth of the products and labor produced. This will be compared with the costs and
benefits of conventional technologies.
2.4 Establish a Monitoring and Evaluation System to Maintain Expected
Performance Levels
Activity 2.4.1 Implement the monitoring plans and establish information distribution
network on system performance and operation. The Project Manager is responsible for
determining the nature and scope of the data to be obtained from the engineered wetland.
The Project Manager is also responsible for communicating the performance results to
relevant government agencies and developing a system of routine operational procedures.
Activity 2.4.2 System operation to establish operating guidelines. Initial system
operations will involve testing of alternative operating methods and procedures.
Guidelines will be prepared recommending routine operating procedures.
Table II-1 Schedule of Major Project Outputs
Objective/Output
Year 1 Year 2 Year 3 Year 4 Year 5
Objective 1--Capacity Building for Sustainable Development
1.1
Community
participation
1.2
Capacity
building
1.3
Dissemination
of
information
Objective 2--Demonstrate Wetland Technology
2.1
Preconstruction
activities
2.2
Wetland
construction
2.3
Socioeconomic
improvements
2.4 Performance
monitoring
and operation
69
ANNEX II
Table II-2 Schedule by Activity
Output/Activity
Year 1
Year 2
Year 3
Year 4
Year 5
1.1 Community
Participation
1.1.1 Develop
local
partnerships
1.1.2 Secure local participation in
planning, construction, and
operation
1.1.3 Increase
environmental
awareness
1.1.4 Develop
local
businesses
1.1.5 Utilize
local
labor
force
1.2 Capacity
Building
1.2.1 Governmental and academic
participation
1.3 Technology
Transfer
1.3.1 Prepare and distribute annual
reports
1.3.2 Prepare and distribute
scientific papers
1.3.3 Prepare and distribute socio-
economic results
2.1 Preconstruction
work
2.1.1 Select project team and initiate
design activities
2.1.2 Design
and
supervision
2.1.3 Establish
offices
2.1.4 Secure
international
team
2.1.5 Conduct
field
surveys
2.1.6 Collect
water
resource
data
2.1.7 Prepare and award construction
tenders
2.1.8 Prepare scientific study and
monitoring workplans
2.2 Wetland
Construction
2.2.1 Order
hardware
2.2.2 Install
water
intake
and
pumps
2.2.3 Construct
wetland
facilities
2.2.4 Conduct plant procurement/
propagation operation
2.2.5 Local participation in
construction and operation
2.3 Socioeconomic
Opportunities
2.3.1 Develop
products
and
markets
2.3.2 Assess
improvements
2.4 Operation
and
Monitoring
2.4.1 Performance
monitoring
2.4.2 Operating
guidelines
70
ANNEX II
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71
ANNEX III
ANNEX III. PROJECT REVIEW, REPORTING, AND EVALUATION PLAN
1.0 TRIPARTITE REVIEWS AND REPORTS
2.0 INDEPENDENT ANNUAL REVIEW
3.0 ANNUAL REPORTS
4.0 TERMINAL REVIEW AND REPORT
72
ANNEX III
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73
ANNEX III
ANNEX III PROJECT REVIEW, REPORTING, AND EVALUATION PLAN
Table III-1 provides a schedule for the following project review and evaluation activities.
1.0 Tripartite Reviews and Reports
In the 10th month of each of the first four years, a Project Performance Evaluation Report
(PPER) will be prepared by the Project Manager, reviewed by the Project Management Board,
and submitted to the UNDP. The PPER will review the activities and outputs in the context of
the entire project schedule. In the 12th month of each of the first four years, the UNDP, the
Executing Agency and the Government representatives will meet to review the PPER.
2.0 Independent Annual Review
Every 12 months the International Consultant will conduct an independent review of the project's
progress and submit a summary report to the Project Management Board, UNDP and the
Executing Agency.
3.0 Annual Reports
Each year, an Annual Report will be prepared by the Project Manager. The report will
summarize the progress of the project, results of the monitoring and academic research
programs, system performance, local participation, and expenditures. The report will be
distributed to relevant government departments, research institutions, and donor agencies.
4.0 Terminal Review and Report
In the 8th month of the final year, the Terminal Report will be submitted (the final PPER). In the
10th month of the final year, the UNDP, Executing Agency, and Government representatives
will meet to review the Terminal Report for the project.
Table III-1 Project review, report, and evaluation.
Activity
Year 1
Year 2
Year 3
Year 4
Year 5
Project Performance Evalua-
tion Reports (PPER) and
Tripartite Review
Independent Annual Review
and Summary Reports
Annual
Project
Reports
Midterm Evaluation
Terminal Review and Report
74
ANNEX III
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75
ANNEX III
ANNEX IV. PRELIMINARY DESIGN CALCULATIONS AND CONSTRUCTION
COST ESTIMATES
1.0 INTRODUCTION
2.0 WASTEWATER INTAKE
2.1 Intake Structure
2.2 Pumping Station
3.0 SEDIMENTATION BASIN
4.0 SECONDARY TREATMENT WETLANDS
5.0 TERTIARY TREATMENT WETLANDS
5.1 Emergent Plant Wetland
5.2 Floating Plant Wetland
5.3 Reciprocating Wetland
6.0 AQUACULTURE FACILITY
7.0 DRYING BEDS
8.0 WATER DISTRIBUTION STRUCTURES
9.0 PRELIMINARY COST ESTIMATES
9.1 Intake and Pumping Station
9.2 Sedimentation Basin
9.3 Secondary Treatment Wetlands
9.4 Tertiary Treatment Wetlands
9.5 Aquaculture Facility
9.6 Support Facilities and Other Costs
9.7 Summary of Cost Estimates
10.0 UNIT PRICE ESTIMATES
76
ANNEX IV
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77
ANNEX IV
ANNEX IV. PRELIMINARY DESIGN CALCULATIONS AND CONSTRUCTION
COST ESTIMATES
1.0 Introduction
The engineered wetland treatment system includes wastewater withdrawal, pumping, treatment,
and discharge of the treated effluent. The function of each major component of the system is
discussed in Annex I. This annex presents preliminary design parameters for the following
components:
A. Intake structure for pumping water from the Bahr El Baqar drain, including intake manifold,
wetwell, and pump house.
B. Sedimentation basin.
C. Secondary treatment emergent plant wetlands.
D. Three tertiary treatment wetlands consisting of 1) emergent plant wetlands, 2) floating plant
wetlands, and 3) reciprocating wetlands.
E. Aquaculture facility.
F. Drying beds.
Basic site conditions for the system are given in Table IV-1. The following sections describe
preliminary design criteria and variables. Changes will be made as necessary during the detailed
design phase to accommodate site conditions, equipment requirements, and cost considerations.
Detailed specifications will be developed for critical project elements, such as grading plans,
liners to control seepage, and flow measuring and control devices. The project scale and cost are
extremely sensitive to site conditions, particularly ground elevation. If a site is not available that
meets the assumed elevation above groundwater (i.e., 1 meter), a reduction in project scale may
be necessary.*
Detailed design drawings and specifications will be prepared under a subcontract. The Design
Contractor will design and coordinate site surveys; prepare civil, electrical, and mechanical
drawings and specifications for tendering; evaluate tenders; award contracts and subcontracts;
supervise construction; and ensure that contractors adhere to the plans and specifications. If
necessary, a separate contract may be developed during the operational phase of the project for
minor design modifications.
* Actual treatment capacity could be less than 50,000 m3/day if the ground elevation of the project site requires
excessive fill and/or dewatering. All subsequent preliminary design calculations and cost estimates in the document
are based on a site elevation of 1 meter above the normal groundwater level and a treatment capacity of
50,000 m3/day.
78
ANNEX IV
Table IV-1. Characteristics of the project site.
Parameter
Units
Value
Total wetland system area
feddans
120
Future expansion area
feddans
80
Design flow rate
m3/d 50,000*
Average lake surface elevation
m, msl
0
Average ground surface elevation
m, msl
1
Average depth to groundwater
m
1
Average drain depth
m
3
Average drain flow rate
m3/d
3 x 106
2.0 Wastewater Intake
2.1 Intake Structure
The intake structure from the Bahr El Baqar drain will be designed to withdraw flow from the
drain to the pumping station. Offsetting the pumping to a side channel will minimize potential
sediment problems that may result from in-channel pumping. The wastewater intake will be
designed for flow velocities of less than 0.4 m/s to minimize the uptake of sediment. The intake
structure will be screened to avoid transport of large objects. A trash rack screen may be used to
trap large debris (e.g., openings 38 to 150 mm). The trash rack will be followed by a coarse
screen to remove solids about half the size of the largest material that can be pumped (typically
25 to 50 mm). The approach to the screens will be straight to ensure good velocity distribution.
Velocities through the manually cleaned screens will be 0.3 to 0.6 m/s.
The flow velocities in the pipes or channel transporting influent wastewater from the drain to the
pumping sump will be greater than 0.8 m/s to keep suspended solids in solution and avoid
accumulation in the transfer lines.
Wetwell water levels for optimum pump operation will comply with equipment manufacturer's
recommendations.
2.2 Pumping Station
A reinforced concrete building will be constructed to house the pumps and mechanical,
electrical, and civil appurtenances. Influent wastewater will be pumped with centrifugal, screw,
or similar pumps suited for low lift, high capacity, and nonclog service. The pumps will be high
efficiency and relatively simple in design and operation to minimize pumping costs and
maintenance requirements. A separate system for pump cooling is not anticipated. At least two
* Actual treatment capacity could be less than 50,000 m3/day if the ground elevation of the project site requires
excessive fill and/or dewatering. All subsequent preliminary design calculations and cost estimates in the document
are based on a site elevation of 1 meter above the normal groundwater level and a treatment capacity of
50,000 m3/day.
79
ANNEX IV
parallel pumps will be used to provide full standby and backup capacity. Long-term reliability
and maintenance will be key considerations. The pumping conditions are summarized in Table
IV-2.
Table IV-2. Approximate intake pumping conditions.
Parameter
Units
Value
Average daily flow rate
m3/s 0.58
Pumping head
m
3-5
Pumping efficiency
%
70
Annual power use
kWh
284,000
2-Pump capacity
hp
50/pump
3-Pump capacity
hp
25/pump
3.0 Sedimentation Basin
The sedimentation basin is assumed to be rectangular. The final shape and configuration will be
determined during the design phase based on site conditions and cost considerations. Separate
cells will be used as needed to facilitate settling, control dredging disturbances, and prevent short
circuiting. Table IV-3 shows the parameters and values for the sizing of the sedimentation basin:
Table IV-3. Preliminary design parameters for
sedimentation basin.*
Parameter
Units
Value
Average flow rate
m3/d 50,000
Retention time
days
2
Total depth
m
3
Operating depth
m
2
Volume of water
m3 100,000
Area m2 50,000
Length m
440
Width m
114
Side slope
3.5:1
Bottom slope
%
0
Freeboard m 1
*Liner specifications will be developed based on site conditions
and allowable leakage.
The following equation estimates the width of the intake weir for the sedimentation basin:
Q = 2/3 Cd B 21/2 g H3/2
80
ANNEX IV
where, Q
= Discharge, m3/s
Cd = Discharge coefficient
B
= Width of the weir, m
g
= Gravity acceleration, m/s2
H = Head above weir crest, m
if
Q
= 0.58 m3/s
Cd = 0.65
g
= 9.81 m/s2
h
=
0.25
then B = 2.4 m or approximately 3 m
4.0 Secondary Treatment Wetlands
Wastewater will move from the sedimentation basin to the secondary treatment cells (Figure I-
2). Water will enter the secondary treatment reed beds through a header system spaced over the
width of each cell. The header system should achieve uniform flow distribution across the width
of the cells. A section of limestone will be placed beneath the flow distribution system to help
equalize flow.
Table IV-4 shows the parameters used preliminary sizing of the two emergent plant wetlands:
Table IV-4. Preliminary design parameters for secondary treatment cells.
Parameter
Units
Value
Flow rate*
m3/d
41,000 and 9,000
Hydraulic loading rate*
m/d
0.55 and 0.12
Retention time*
d
0.9 and 4.2
Outlet water depth
m
0.5
Inlet water depth for high-flow wetland
m (see below)
0.6
Inlet water depth for low-flow wetland
m (see below)
0.54
Volume of water per cell
m3 37,500
Surface area per cell
m2 75,000
Length m
375
Width m
200
Aspect ratio (length/width)
-
1.87
Berm side slope
-
3.5:1
Bottom slope
%
0
Freeboard m
1
* The high-flow emergent wetland will be operated at 0.9 d retention time with a flow rate and
loading rate of 41,000 m3/d and 0.55 m/d, respectively. The low-flow emergent wetland will be
operated at 4.2 d retention time with a flow rate and loading rate of 9000 m3/d and 0.12 m/d,
respectively.
81
ANNEX IV
The hydraulic design will take into account the resistance offered by the vegetation in each
wetland cell. The frictional resistance is a function of plant density, plant stem volume, and
depth of flow. For densely vegetated wetlands, Manning's frictional coefficient "a" is
1x107m-1d-1 (Kadlec and Knight, 1996).
A modified Manning equation for wetlands can be used to calculate the head required to
maintain a 9000 m3/d (low-flow wetland) or 41,000 m3/d (high-flow wetland) flow. The
equation as presented in Kadlec and Knight (1996, p.204) is:
M
4
1 = q L2 / aho = y3 (-dy/dz - S1)
where q is the hydraulic loading rage in m/d, L is the wetland length in m, a is a friction
coefficient equal to 1 x 107 d-1 m-1, ho is the water depth at outlet in m, z is fractional distance
along the length of the wetland, y = h/ho where h is water depth at z, and S1 is proportional to
the bottom slope. Using a bottom slope of zero, the equation becomes:
M
4
1 = q L2 / aho = y3 (-dy/dz)
M1 can be determined from design parameters and integration of the above equation yields the
ratio of inlet water depth to outlet water depth (RATIO = hi/ho) for a given M1. The inlet water
depth is determined as:
hi = RATIO (ho)
required head difference = hi - ho
For the emergent wetland at high-flow and low retention time, the following parameters apply:
q = 0.55 m/d, L = 375 m, and ho = 0.5 m
Therefore, M1 = 0.124. From Fig. 9-14 in Kadlec and Knight (1996), RATIO = 1.2. The
required head difference is then 10 cm.
For the emergent wetland at low-flow and high retention time, the following parameters apply:
q = 0.12 m/d, L = 375 m, and ho = 0.5 m
Therefore, M1 = 0.027. From Fig. 9-14 in Kadlec and Knight (1996), RATIO = 1.08. The
required head difference is then 4 cm.
Every 125 m in the wetlands, a deep open channel will be incorporated to evenly distribute water
flow across the width of the wetland. The channels will have 1 m water depth and will be 4 m
long. A deep open channel will also be placed at the end of each wetland to collect water before
being discharged into three concrete sumps. Water flow into the sumps will be controlled by
adjustable weirs.
5.0 Tertiary Treatment Wetlands
82
ANNEX IV
Three types of tertiary treatment wetlands will be employed in the project: an emergent plant
wetland, a floating plant wetland using duckweed as the floating plant, and a gravel-based
wetland with reciprocation to promote aerobic treatment. The tertiary emergent plant wetland
will receive water from the high-flow secondary emergent plant wetland. The floating plant
wetland and reciprocating wetland will receive water from the low-flow secondary emergent
plant wetland. The flow of water from the secondary to tertiary wetlands as just described is the
proposed method of operation. This operation mode provides three treatment options that treat
the water to varying degrees (see Annex I). Flexibility will be incorporated to provide options to
direct water from the secondary wetlands to the tertiary wetlands in any combination desired.
Water will be delivered into the tertiary wetlands through a header system spaced over the width
of the wetland. Water will be discharged into a section of limestone rock to help equalize flow
before being released to the wetland cells.
5.1 Emergent Plant Wetland
Table IV-5 shows the preliminary design parameters for the tertiary emergent plant wetland:
Table IV-5. Preliminary design parameters for tertiary
emergent wetland.
Parameter
Units
Value
Flow rate
m3/d 41,000
Hydraulic loading rate
m/d
0.82
Retention time
d
0.6
Outlet water depth
m
0.5
Inlet water depth
m (see below)
0.63
Volume of water
m3 25,000
Surface area
m2 50,000
Length m
375
width m
133
Aspect ratio (length/width)
-
2.8
Berm side slope
-
3.5:1
Bottom slope
%
0
Freeboard m
1
For the emergent wetland the following parameters apply for the modified Manning equation for
wetlands:
q = 0.82 m/d, L = 375 m, and ho = 0.5 m
83
ANNEX IV
Therefore, M1 = 0.184. From Fig. 9-14 in Kadlec and Knight (1996), RATIO = 1.25. The
required head difference is then 13 cm.
5.2 Floating Plant Wetland
Table IV-6 shows the preliminary design parameters for the tertiary floating plant wetland:
Table IV-6. Preliminary design parameters for tertiary floating
plant wetland.
Parameter
Units
Value
Flow rate
m3/d 7,000
Hydraulic loading rate
m/d
0.14
Retention time
d
3.6
Outlet water depth
m
0.5
Inlet water depth
m (see below)
0.55
Volume of water
m3 25,000
Surface area
m2 50,000
Length m
375
Width m
133
Aspect ratio (length/width)
-
2.8
Berm side slope
-
3.5:1
Bottom slope
%
0
Freeboard m
1
For the floating plant wetland the following parameters apply for the modified Manning equation
for wetlands:
q = 0.14 m/d, L = 375 m, and ho = 0.5 m
Therefore, M1 = 0.032. From Fig. 9-14 in Kadlec and Knight (1996), RATIO = 1.1. The
required head difference is then 5 cm.
Duckweed will be used as the floating plant. Because of duckweed's high protein content, the
plant is valuable as a source of fish feed in addition to providing nutrient removal in the
wastewater. To avoid duckweed from accumulating on one side of the wetland or another from
wind action, open water sections will be created with borders of canarygrass or another
clump-forming wetland species. Each section will be approximately 50 m long and 10 m wide.
5.3 Reciprocating Wetland
Reciprocating wetlands will consist of two subsurface flow wetland cells sitting side by side.
Water will flow through gravel placed into the cells with an approximate porosity of 40 percent.
This type of wetland is referred to as reciprocating because water is continuously transferred
from one cell to another via pumps. The periodic movement of water out of the gravel allows for
84
ANNEX IV
the substrate to become easily aerated via oxygen diffusion in air. The oxygenation of the
biofilms on the gravel surface allows for culturing aerobic bacteria which aid in the removal of
BOD and ammonium-N. Because of the continuous reciprocation, the retention volume in the
gravel bed is not equal to the total available porosity volume. The design calculations assume
the retention volume is equal to the porosity volume for one cell in the pair and one-third the
porosity volume in the other cell of the pair.
Table IV-7 shows the preliminary design parameters for the tertiary reciprocating wetland:
Table IV-7. Preliminary design parameters for tertiary reciprocating
wetland.
Parameter
Units
Value
Flow rate
m3/d 2,000
Hydraulic loading rate
m/d
0.2
Retention time
d
2
Outlet water depth
m
1
Inlet water depth
m (see below)
1.11
Volume of water
m3 4,000
Surface area
m2 15,000
Length m
110
Width m
140
Aspect ratio (length/width)
-
0.56
Berm side slope
-
3.5:1
Bottom slope
%
0
Freeboard m
1
For subsurface-flow wetlands, head loss requirement is determined differently from surface-flow
wetlands. The important parameters for determining head loss (Kadlec and Knight, 1996) are:
L = 75 m, gravel porosity (e) = 0.4, detention time (t) = 2 d
The superficial velocity, u, equals L e / t which is 15 m/d. Assuming a gravel hydraulic
conductivity of 10,500 m/d (ke) yields a meter head loss per meter wetland length as:
dH/dx = -u/ke = -15 / 10,500 = -0.00143.
For a 75 m wetland length, the required head loss is 0.00143(75) = 0.11 m or 11 cm.
5.4 Discharge of Water from Tertiary Wetlands
Water released from the reciprocating gravel-bed wetlands will be used to raise fish in an
aquaculture facility. Water will be released to a series of small and large ponds. Water from the
aquaculture ponds, emergent wetland, and floating plant wetland will leave the systems via weirs
so water flow rates can be monitored. Three weirs will be positioned evenly across the widths of
85
ANNEX IV
the tertiary emergent wetland and floating plant wetland to ensure even distribution of water
flow rates at the end of the wetlands. The water will drain into open channels that will direct
water to a common open channel directing water to Lake Manzala or back into Bahr El Baqar
drain.
6.0 Aquaculture Facility
Table IV-8 shows the preliminary design parameters for the aquaculture facility hatchery ponds.
The design is for an individual pond; however, there will be four such ponds in the proposed
hatchery facility, each with independent water inlets and outlets.
Table IV-8. Preliminary design parameters for the hatchery ponds.
Parameter
Units
Value
Flow rate
m3/d 50
Retention time
d
15
Outlet water depth
m
1
Inlet water depth
m (see below)
0.5
Volume of water
m3 750
Surface area
m2 1000
Length m
50
Width m
20
Aspect ratio (length/width)
-
2.5:1
Berm side slope
-
3.5:1
Bottom slope
%
1
Freeboard m
0.5
The head difference requirement between the inlet and outlet is assumed to be negligible. The
inlet water depth is less than the outlet water depth due to a bottom slope of 1 percent.
Table IV-9 shows the preliminary design parameters for the aquaculture facility fingerling
ponds. The design is for an individual pond; however, there will be two such ponds in the
proposed hatchery facility, each with independent water inlets and outlets.
86
ANNEX IV
Table IV-9. Preliminary design parameters for the fingerling ponds.
Parameter
Units
Value
Flow rate
m3/d 900
Retention time
d
10
Outlet water depth
m
1
Inlet water depth
m
0.8
Volume of water
m3 9,000
Surface area
m2 10,000
Length m
200
Width m
50
Aspect ratio (length/width)
-
4.0:1.0
Berm side slope
-
3.5:1
Bottom slope
%
0.1
Freeboard m
0.5
The head difference requirement between the inlet and outlet is assumed to be negligible. The
inlet water depth is less than the outlet water depth due to a bottom slope of 0.1 percent.
The aquaculture facility will be based on labor intensive hatchery technology with the intention
of producing several million Lake Manzala strain tilapia, Oreochromis niloticus, which can be
either sold to the existing aquaculture industry or used for the replenishment of Lake Manzala,
which is heavily fished on an annual basis.
Plans are to install four 0.1 ha breeding ponds, which will be stocked with Lake Manzala stain
tilapia broodstock (200-500 g each ) at a density of 1 fish/m2, and at a sex ratio of 1 male to 1
female (1:1). Fish will be fed at approximately 0.5 to 1.0 of body weight per day using a
combination of prepared fish feed (pellets) and/or duckweed. The import of N via fish feed
pellets is anticipated to result in only a minor increase in NH4-N concentration in the water
(approximately 0.2 mg/L). It is anticipated that under proper management, it should be possible
to produce several million fry per year. Fry collected from the hatchery ponds will be
subsequently stocked into the fingerling production ponds at high density (1-2 million/ha), and
cultured for an additional 30 days prior to harvesting and marketing approximately ten such
cycles per year.
In the case where fingerlings will be sold to other aquaculture interests, the fry will be sex-
reversed to all-male populations by feeding the sexually undifferentiated fry a feed additive
(methyltestosterone). This procedure will enable farmers to raise the faster growing males to
market size and eliminate the overpopulation problems that are unavoidable in mixed-sex
populations.
For purposes of restocking to augment Lake Manzala, the fry will not be sex-reversed, so that
normal breeding populations can be sustained.
87
ANNEX IV
7.0 Drying Beds
Drying Beds will be used for drying sediment sludge from sedimentation basin and also the
harvested plants from the wetland channels. The sludge drying beds will be designed in
accordance with standard practices and expected characteristics of the sediment/sludge.
Drainage waters will be collected and directed back to the sedimentation basin. The dried
sediment will be tested for contaminants and, if suitable, used for construction or fill material.
Table IV-10. Preliminary design parameters for sludge drying beds.
Parameter
Units
Value
Estimated amount of sediment sludge
tons/day
4
Number of sediment drying beds
beds
4
Area of each sediment drying bed
m2
1000 (40 x 25 m)
Depth of sediment drying bed
m
0.3
Total volume of harvested plants
tons/day
2
Number of plant drying beds
beds
2
Area of each plant drying bed
m2
400 (40 x 25 m)
Depth of plant drying bed
m
0.3
8.0 Water Distribution Structures
Water collection and distribution channels will be provided for each wetland system component.
Water flow between cells will be accomplished and controlled with portable gravity pipes and
valves.
9.0 Preliminary Cost Estimates
The following sections provide preliminary cost estimates for each component of the wetland
treatment system. The estimates are based on initial assumptions regarding site conditions, unit
costs, and design parameters. All estimates will be upgraded during the design phase, based on
actual site conditions, project design, and current costs.
9.1 Intake and Pumping Station
Based on several large pumping stations constructed in Egypt before 1986, the following cost
equation relates pumping head and pumping flow to the price of all civil , mechanical, and
electrical and intake works, is:
Cost (100 L.E.) = [(3.22 H + 23.8) Q] C1 C2
88
ANNEX IV
Where,
H
= manometric head in meters
Q
= total flow rate in m3/s
C1
= inflation factor
C2
= currency correction factor, which is the ratio of the current U.S.
dollar value to its value in 1986 ( 1986: 1 US$ = 1.3 LE)
For the project pumping station,
Q
= 0.58 m3/s
H
= 6 m
C1
= (1.1)11
C2
= 3.34 (1996 value) =
2.57
1.3 (1986 value)
Estimated Cost
= [(3.22 x 5 + 23.8) 0.58] (2.85) (2.57)
= 183,000 L.E.
An additional 230 percent premium for the small size of pumping station and remote location
results in an estimated total cost of 600,000 L.E. or $ 180,000 U.S.D.
Summary:
Total Estimated Cost = 600,000 L.E.
= $180,000 U.S.D.
9.2 Sedimentation Basin
Bottom Excavation
Surface Area
= 440 m x 114 m
=
50,160 m2
Excavation Depth
= 1.0 m
Volume to be Excavated
= 50,160 m2 x 1.0 m
=
50,160 m3
Estimated Cost (incl. seal)
= 50,160 m3 x 8.0 L.E.
=
400,000 L.E.
Dike Construction
Height
of
Dike =
3.0
m
Cross-section Area
= (10.5 x 3.0) + 3.0 x 3.0
=
40.5 m2
Volume of Fill
= 40.5 m2 x (450 + 124) x 2
=
46,000 m3
Estimated Cost (incl. seal)
= 46,000 m3 x 6.0 L.E.
=
280,000 L.E.
Short Circuiting Barrier
89
ANNEX IV
Length
=
1320
m
Estimated Cost
= 1320 m x 15.0 L.E.
=
20,000 L.E.
Summary
Total Estimated Cost
= 400,000 + 280,000 + 20,000
=
700,000 L.E.
=
$
210,000
U.S.D.
9.3 Secondary Treatment Wetlands
Bottom Cut and Fill
Surface
Area
=
150,000
Depth of Cut and Fill
= 0.2 mm
Volume Cut and Fill
= 0.2 m x 150,000 m2
=
30,000 m3
Estimated Cost (incl. seal)
= 30,000 m3 x 8.0 L.E.
=
240,000 L.E.
Dike Construction
Height
of
Dike =
1.7
m
Cross-section Area
= (1.7 x 6.0) + (3.0 x 1.7)
=
15.3 m2
Volume of Fill
= 15.3 m2 x (343 + 235) x 2
=
18,000 m3
Estimated Cost (incl. seal)
= 18,000 m3 x 6.0 L.E.
=
110,000 L.E.
Reed Bed Planting and Development
Surface
Area
=
150,000
m2
Estimated Cost
= 150,000 m2 x 1.2 L.E.
=
180,000 L.E.
Summary
Total Estimated Cost
= 240,000 + 110,000 + 180,000
=
530,000 L.E.
=
$
160,000
U.S.D
9.4 Tertiary Treatment Wetlands
Bottom Excavation
Surface Area
= (50,000 +50,000 +10,000)
=
110,000 m2
Excavation Depth
= 0.6 m
Volume to be Excavated
= 0.6 m x 110,000 m2
=
66,000 m3
Estimated Cost (incl. seal)
= 66,000 m3 x 7.0 L.E.
=
460,000 L.E.
Dike Construction
90
ANNEX IV
Height
of
Dike =
1.0
m
Cross-section Area
= (3.5 x 1.0) + (3.0 x 1.0)
=
6.5 m2
Volume of Fill
= 6.5 m2 x (343 + 160) x 4 + (77 +160) x 2
= 96,000 m3
Estimated Cost (incl. seal)
= 96,000 m3 x 6.0 L.E.
=
60,000 L.E.
Wetland Planting and Development
Surface Area
= 110,000 m2
Estimated Cost
= 110,000 m2 x 1.2 L.E.
=
130,000 L.E.
Reciprocating System Development
Wetland Gravel Cost
= 10,000 m2 x 1.0 m x 30 L.E.
=
300,000 L.E.
Pump and Appurtenances
Cost
= 50,000 L.E.
Summary
Total Estimated Cost
= 460,000 + 60,000 + 130,000 + 300,000
= 950,000 L.E.
=
$
330,000
U.S.D
9.5 Aquaculture Facility
Bottom Excavation
Surface Area
= (10,000 + 10,000 + 4000)
=
24,000 m2
Average Depth of Cut
= 0.7 m
Volume of Cut
= .7 x 24,000 m2
=
16,800 m3
Estimated Cost (incl. seal)
= 16,800 m3 x 8.0 L.E.
=
130,000 L.E.
Dike Construction
Height
of
Dike =
1.0
m
Cross-section Area
= (3.5 x 1.0) + (3.0 x 1.0)
=
6.5 m2
Volume of Fill
= 6.5 m2 x (160 + 77) x 4 + (35 +35) x 8
= 9800 m3
Estimated Cost (incl. seal)
= 9800 m3 x 6.0 L.E.
=
60,000 L.E.
Miscellaneous Small
Equipment
= 100,000 L.E.
Summary
Total Estimated Cost
= 130,000 + 60,000 + 100,000
=
290,000 L.E.
91
ANNEX IV
=
90,000
U.S.D.
9.6 Support Facilities and Other Costs
Site Fill and Dewatering Contingency
=
900,000 L.E.
Drying Beds (2400 m2 x
21.0
L.E.)
=
140,000
Laboratory and Maintenance Buildings (200 m2 x 1500 L.E.)
=
300,000
Discharge (1500 m x 40 L.E.)
=
60,000
Water
Distribution
Flow
Control
=
500,000
Access
Roads
(on-site) =
400,000
Utilities
(on-site)
=
250,000
Innovative
Technologies
=
100,000
Manual Labor Premium
= 100,000
2,750,000
L.E.
Total Other Costs
$ 820,000 U.S.D.
92
ANNEX IV
9.7 Summary of Cost Estimates
Table IV-9. Summary of preliminary construction costs.
Unit
Estimated
Estimated
Cost
Total Cost Total Cost
Item
Unit
Quantity
(L.E.)
(L.E).
($U.S.)
Intake and Pumping Station
Ea.
1
L.S.
600,000
$ 180,000
Sedimentation basin
Bottom Excavation
m3
50,000
8.0
400,000
120,000
Dike Construction
m3
46,500
6.0
280,000
80,000
Short-circuiting Barrier
m
1,320
15.0
20,000
10,000
Subtotal
700,000
210,000
Secondary Treatment Wetlands
Bottom Cut and Fill
m3
30,000
8.0
240,000
70,000
Dike Construction
m3
18,000
6.0
110,000
30,000
Reed Bed Planting and Development
m2
150,000
1.2
180,000
60,000
Subtotal
530,000
160,000
Tertiary Treatment Wetlands
Bottom Excavation
m3
66,000
7.0
460,000
140,000
Dike Construction
m3
9,600
6.0
60,000
20,000
Wetland Planting and Development
m2
110,000
1.2
130,000
40,000
Gravel Bed
m2
10,000
30.0
300,000
90,000
Reciprocating Pump System
Ea.
1
L.S.
50,000
10,000
Subtotal
1,000,000
300,000
Aquaculture Facility
Bottom Excavation
m3
15,600
8.0
130,000
40,000
Dike Construction
m3
9,800
6.0
60,000
20,000
Miscellaneous
L.S.
100,000
30,000
Subtotal
290,000
90,000
Site Preparation/Support Facilities
Fill and Dewatering Contingency
L.S.
900,000
270,000
Drying Beds
m2
6,000
24.0
140,000
40,000
Laboratory Maintenance Building
m2
200
1500.0
300,000
90,000
Discharge
m
1500
40.0
60,000
20,000
Water Distribution and Flow Control
L.S.
500,000
150,000
Access Roads (on-site)
L.S.
400,000
120,000
Utilities (on-site)
L.S.
250,000
70,000
Innovative Technologies
L.S.
100,000
30,000
Manual Labor Premium
L.S.
100,000
30,000
Subtotal
2,750,000
820,000
Total
5,870,000
1,760,000
Contingency
700,000
210,000
Total Construction Cost
6,570,000
$1,970,000
93
ANNEX IV
10.0 Unit Price Estimates
The range of 1996 unit prices for selected project components is given in Table IV-12. Cost
estimates will be revised during the design phase based on site conditions, economic
considerations, and final design requirements.
Table IV-12. Unit price estimates for 1997.
Item
Unit
Unit Price
(L.E.)
Removal and disposal of topsoil (depth 0.3 m)
m2 1.0
Excavation for pond and distribution channel
m3 4.0-6.0
Placing and compacting clay in embankments
m3 5.0-8.0
Placing and compacting borrow material in embankments
m3 5.0
Supply of borrow material to site
m3 6.0-8.0
Excavation and backfill for inlet and outlet works
m3 3.0-6.0
Disposal of excess material (clay)
m3 30-5.0
Pitrun Gravel (0.3 m) for access road including transfer
m2 9.0-15.0
and compaction
Plain concrete
m3 200.0
Reinforced concrete (substructures) including
m3 500.0-600.0
framework
Reinforced concrete (superstructures) including
m3 550-600
framework
Stone pitching (0.4 m thick)
m3 30.0-80.0
Gates (wooden planks in guide rails)
m2 2500-4000
Contractor's insurance, fees, etc.
%
5.0
94
ANNEX IV
blank page
95
ANNEX IV
H y d ra u lic P ro file
4
3
to p o f d ik e
t
,
m
2
w
h
a te r s u rfa ce
e x is tin g
i
g
g r a d e
95
1
He
c u t
s e a le v e l
0
p r im a r y
s e c o n d a r y
te r tia r y
( 1
- )
1
d ra in
0
2 0 0
4 0 0
6 0 0
8 0 0
L e n g th , m
AN
Figure IV-1. Preliminary hydraulic profile of treatment wetlands.
NE
X I
V
blank page
97
ANNEX IV
Figure IV-2. Preliminary layout of sedimentation basin.
Figure IV-3. Preliminary layout of emergent plant wetlands as secondary treatment.
Figure IV-4. Preliminary layout of emergent plant wetland as tertiary treatment.
Figure IV-5. Preliminary layout of floating plant wetland as tertiary treatment.
Figure IV-6. Preliminary layout of reciprocating wetland as tertiary treatment.
Figure IV-7. Preliminary layout of hatchery ponds
Figure IV-8. Preliminary layout of fingerling ponds.
Blank page
ANNEX V. PRELIMINARY MONITORING PLAN
1.0 ENVIRONMENTAL MONITORING
1.1 Preliminary Objectives and Scope
1.2 Sampling Locations
1.3 Field and Laboratory Analyses
2.0 PRELIMINARY ESTIMATE OF MONITORING COSTS
2.1 Environmental Monitoring Program Costs
106
ANNEX V
blank
107
ANNEX V
ANNEX V PRELIMINARY MONITORING PLAN
1.0 Environmental Monitoring
Performance of the wetland system will be monitored during the fourth and fifth year of
the project. Preliminary sampling and analyses will be conducted during the six-month
period prior to year four. A detailed monitoring plan will be developed in draft form by
month 18 of the project. The plan will be finalized by month 30.
A field laboratory and field monitoring equipment will be provided as part of this project.
A monitoring subcontract will be used for field personnel and laboratory analyses that
cannot be conducted in the field. The field personnel will collect all samples, conduct
field analyses and tests, and ship laboratory samples to the contract analytical laboratory.
1.1 Preliminary Objectives and Scope
The basic objectives of the monitoring program are to:
A. Evaluate the performance of the different treatment systems and alternative
methods of operation.
B. Identify operational procedures that will optimize treatment levels and
economic returns.
C. Develop a database for designing similar treatment system for application in
other locations.
The suggested monitoring parameters, frequencies, and analysis location are given in
Table V-1. Where laboratory analytical procedures are required, the reference
methodology will be Standard Methods for the Examination of Water and Wastewater
(Greenberg et al., latest edition). All samples will be collected, handled, and preserved in
accordance with recommended procedures.
As described in Annex I, the wetland system will be operated under two basic flow
regimes. One treatment pathway will involve high flow rates with moderate to low
pollutant removal efficiencies. The second treatment pathway will involve low flow rates
with higher pollutant removal efficiencies. The two flow regimes will be started at the
beginning of year four. The first year of operation will provide data over the period of
wetland plant establishment. Monitoring data from the second year of operation will
provide information on treatment efficiencies after the wetlands have been established.
Pollutant removal efficiencies will be determined during the period of wetland plant
establishment and continual treatment under the two different flow regimes.
1.2 Sampling Locations
The basic monitoring program will sample the flow and quality of waters entering the
wetlands: the water, sediments and plants at various locations in the wetland, and the
flow and quality of water leaving the wetlands. A general description of the monitoring
locations is provided below.
108
ANNEX V
A. Inflow Water Quality--Water quality and hydrometric data will be collected
from the sedimentation basin inflow from the Bahr El Baqar drain and just
upstream of the intake.
B. Water Chemistry Data from the Wetland System--Water samples and
chemical field data will be collected from all influent and effluent stations for
each individual wetland cell so that a detailed mass balance of various water
quality parameters and a water budget can be developed.
C. Sediment and Biological Sample Data from the Wetland System--Sediment,
algae, plants, and benthic invertebrates will be collected near the influent and
effluent of each wetland cell to assess the transfer of pollutants. Fish will also
be sampled in the aquaculture ponds to assess uptake of pollutants in the fish.
These data will be used in evaluating the potential health implications of
recycling biomass products into animal feed and sediments into bricks.
D. Precipitation and EvaporationPrecipitation and evaporation data will be
collected daily to allow a complete water balance for the wetland system.
1.3 Field and Laboratory Analyses
Table V-1 indicates which parameters will be measured in the field and which are to be
conducted in the laboratory. A field laboratory will be constructed and equipped to
accommodate the equipment, instrument calibrations, and field parameter analyses. This
laboratory will include analytical balance and filtration equipment for TSS, turbidity, pH
and BOD measurements. All other parameters will require analytical laboratory support
as shown in Table V-1.
For field sampling and in situ measurements, the equipment and methodology will
provide a practical and reliable method of data collection. The monitoring program will
be designed to include calibration of instruments on a frequent and routine basis using
fresh standards, replicate samples, and distilled water blanks for procedures such as total
suspended solids (TSS). The QA/QC procedures will be documented and the results
presented with the data.
Field equipment requirements are shown in Table V-2. The field team will require a light
durable boat (e.g., aluminum construction) which can be used in the wetland and drain.
A small outboard motor of approximately 5 h.p. will allow access to all sampling areas
and will be light enough to be transported manually. Meters and instruments must be of
robust construction and designed for field use.
109
ANNEX V
Table V-1. Suggested monitoring parameters, frequencies, and analytical location.
Parameters
Frequency
Location of
Method of
Analysis
Analysis
Water Temperature
Daily
Field
thermometer
pH Daily
Field
glass
electrode
Alkalinity Daily
Field
Lab
titration
Dissolved Oxygen
Daily
Field
oxygen electrode
Electrical Conductivity
Daily
Field
salt bridge
Salinity Daily
Field
salt
bridge
Current Velocity
Daily
Field
tbd*
Flow Volumes
Daily
Field
flume height
Precipitation/Evaporation Daily Field rain
guage/
pan evaporator
Turbidity
Weekly
Field Lab
light scattering
TSS Weekly
Field
Lab
filtration
Drain Flow volume, Depth
Weekly Field
tbd
Current Velocity
TSS in the Bahr El Baqar and
Weekly Field filtration
Bashtir Canal
Total Kjeldahl Nitrogen
Weekly
Lab
Kjeldahl
digestion/titration
Total Phosphorus
Weekly
Lab
Kjeldahl
digestion/colorimetry
Ammonium - N
Weekly
Lab
colorimetry
Nitrate - N
Weekly
Lab
Cd reduction/colorimetry
Total Organic Carbon (TOC)
Weekly
Lab
combustion/CO2 analysis
Chlorophyll Weekly
Lab
colorimetry
Fecal Coliform
Weekly
Lab
elevated temp. inoc.
Biological Oxygen Demand
Monthly
Field Lab
5 d incubation/oxygen
(BOD5)
electrode
Chemical Oxygen Demand
Monthly
Lab
digestion/colorimetry
Heavy Metals
Monthly
Lab
atomic absorption
spectroscopy
Selected Priority Pollutants
Monthly
Lab
tbd
Algal Sampling
Monthly
Lab
tbd
Benthic Invertebrates
Bimonthly
Lab
tbd
Plant Tissue Analysis
Once in Three
Lab tbd
Months
Sediment Analysis for Metals
Once in Six Months
Lab
tbd
Fish Samples
Once in Six Months
Lab
tbd
*tbd - to be determined
110
ANNEX V
Table V-2. Equipment and instrumentation requirements for field monitoring.
Parameter/Sample
Equipment/Instrumentation
Sediments
Ekman or Ponar grab sampler, or
equivalent
Water Level Recording
staff gauges
Dissolved Oxygen, pH, Turbidity
Standard Field Monitor
Salinity, Conductivity, Temperature (SCT) similar to YSI or Hydrolab construction
and service
Current Velocity
Aanderaa SD30 Flow Meter or equivalent
Water Sampling
Kemmerer water sampler, bottle sampler,
boat and motor
Dissolved and Particulate Analysis (TSS),
Filtration equipment with various sizes of
Size Fractionation
filters, analytical balance, dessicator
cabinet
In addition to the field measurements, laboratory analysis will be contracted to one or
more laboratories on a competitive tender basis. All laboratory analyses will be
conducted according to Standard Methods for the Examination of Water and Waste
Water, latest edition.
Qualified laboratories will be asked to prepare tenders which can be analyzed on the
basis of adequacy of procedures, analytical time, expertise, and cost. The competitive
tender will be parameter-specific and different laboratories may be used, depending on
expertise, analysis, or cost. The bidding process will be conducted on an annual standing
offer basis. Contracts will cover a specific range of analyses which can be called upon as
needed.
For certain analyses such as the biological parameters, the analytical laboratory will be
asked to supply sample containers, preservatives, and field collection personnel. Other
analyses such as trace metals will only require clean sample containers and charged acid
to be supplied by the analyst. These can be filled in the field by members of the
monitoring team. In either case, the laboratory will be responsible for the delivery of
data which meets QA/QC standards prior to payment for services.
In addition to the routine analyses, Table V-3 lists parameters and the frequency of
specific analyses that will be conducted to obtain information on the fate and pathways of
selected heavy metals and pesticide residues.
Table V-3. Heavy metal and chemical residues.
Parameter
Frequency
Remarks
Hg, Cd, Zn, Cu, Cr,
Monthly
Water, sediment, and
As, Pb, Mn, Fe
aquatic plants
Hydrocarbons and
Once in six
Water, sediment, and
Specific Pesticides
months
aquatic plants
111
ANNEX V
2.0 Preliminary Estimate of Monitoring Costs
2.1 Environmental Monitoring Program Costs
Table V-4 provides a preliminary cost estimate for the base monitoring program to be
funded as part of this project. The base program consists primarily of field and
laboratory equipment, labor for sample collection, and contract laboratory analyses.
Additional NGO funding of approximately $150,000 will be required to support the field
laboratory, data analyses, and reporting required to fully document wetland performance.
In addition to supporting monitoring efforts, these funds would support university
students and others interested in operations of Egyptian wetland systems.
Table V-4. Estimated cost for monitoring program.
ITEM
COST
($ U.S.)
Field Equipment
Water quality monitors (DO, temp, pH, etc.)
$ 5,000
TSS filtration apparatus
(1500)
Cabinet dessicator
(1000)
2,500
Niskin type sampler
(400)
Bottle sampler
(300)
Water sample containers
(1300)
14 Ft Aluminum boat and trailer
(3000)
5 horsepower motor
(3000)
8,000
Sediment sampler (Ekman type)
700
Sample preparation equipment
300
Current meters
3,500
Mooring, floats, etc.
500
Spares and miscellaneous
7,500
Shipping and mobilization
8,000
Field Equipment Subtotal
$ 36,000
Additional Laboratory Equipment
Analytical balance
$ 20,000
Laboratory DO/ pH instruments
2,000
BOD incubator
2,000
UV visible spectrophotometer
20,000
Computers, printers, fax, etc.
10,000
Miscellaneous glassware, stirrers, hotplates, reagents, etc.
10,000
Laboratory Equipment Subtotal
$ 64,000
Monitoring and Analyses
Monitoring and laboratory technicians (27 months)
$ 24,000
Contract laboratory analyses
76,000
Other Cost Subtotal
$100,000
Total Monitoring Cost
$200,000
112
ANNEX V
blank
113
ANNEX VI
ANNEX VI. NATIONAL AND INTERNATIONAL PARTICIPATION
FRAMEWORK AND NATIONAL JOB DESCRIPTIONS
1.0 PROJECT ORGANIZATION
2.0 TERMS OF REFERENCE
2.1 Project Manager
2.2 Senior Project Engineer
2.3 Operations Foreman
114
ANNEX VI
blank
115
ANNEX VI
ANNEX VI NATIONAL AND INTERNATIONAL PARTICIPATION FRAME-
WORK AND NATIONAL JOB DESCRIPTIONS
1.0 Project Organization
The project will be managed within the organizational structure shown in Figure 3
(page 17). The rationale for selecting EEAA as the Executing Agency is given in Section
B.4.
Construction and operation of the engineered wetland will be executed by Egyptians,
including project management, engineering (civil, mechanical, and electrical sub-
disciplines), construction, monitoring, botany, environmental law, geotechnical,
hydrogeology, land surveys, laboratory analysis, and human resource development.
International inputs for the engineered wetland are restricted and relate to four senior
professionals labeled as technical advisors in Figure 3 (page 17). An International
Coordinator will be responsible for coordinating international inputs, ensuring technical
oversight and evaluation. The International Field Manager will assist in monitoring
design, data analysis and evaluation, and the QA/QC program.
Technical, socioeconomic, and scientific disciplines for the wetland will be staffed from
Egyptian professionals. Expertise on construction and operation of large engineered
wetlands is not well developed in Egypt. The International Wetland Designer and
International Wetland Advisor will provide this expertise over the full five years of the
project. These professionals will be selected so that one can substitute for the other as
needed.
The Terms of Reference for the national experts are given below. Terms of Reference for
the international project personnel and additional details on the international contract are
given in Annex VII.
2.0 Terms of Reference
2.1 Project Manager
Background
Egypt has deteriorating surface water resources. Municipal wastewater, agricultural
runoff, and industrial effluent are threatening the health and welfare of millions of
people. At the same time Egypt's ability to pay for the treatment infrastructure is
declining. A successful wetland demonstration project will be of interest to governments
around the world that are searching for affordable solutions to wastewater treatment.
The development objective of the engineered wetland project is to improve global
environmental management by upgrading national to global linkages and by reducing
international water pollution, climate gases, and the decline in biodiversity. This will be
accomplished by the transfer of an appropriate, cost-effective wastewater treatment
technology to Egypt. This will also address a serious impediment to national and
regional development, namely, poor water quality.
116
ANNEX VI
Qualifications
The Project Manager will have the following qualifications:
A. Ph.D. in engineering, science, or business management or equivalent
expertise.
B. Ten years of experience at a high level in project management and
government service.
C. Proven record in interdisciplinary project management skills.
D. Good communication skills in Arabic and English.
E. Working knowledge of government organization and decision making in
Egypt.
F. Capabilities in evaluating of project and team performance.
G. Excellent personnel and financial management skills.
H. Ability to provide oversight to the local cooperatives enabling them to
develop sound businesses with the wetland products.
Tasks
The Project Manager will serve as a liaison for the Project Management Board, Technical
Advisors, and Technical Focal Points. The Project Manager will recruit and evaluate
project personnel, prepare detailed workplans, tender subcontracts, prepare work
schedules and milestones, and generally direct and coordinate implementation and
completion of the project The Project Manager will have overall responsibility for the
project, including reporting and financial accountability to the Project Management
Committee, EEAA, and the UNDP. The Project Manager will also serve as Rapporteur
of the Project Management Committee, He/she will be based in Cairo with frequent
visits to the project site. The Cairo base is essential because of the liaison needed with
the government personnel.
The Project Manager will be required to participate in and contribute to the following
tasks (numbered according to the objective outputs):
1.1 Community Participation
1.2 Capacity Building
1.3 Technology Transfer
2.1 Preconstruction Work
2.2 Wetland Construction
2.3 Socioeconomic Opportunities
2.4 Operation and Monitoring
117
ANNEX VI
Reporting Requirements
The Project Manager will participate in the preparation and submission of the following
reports:
Tender
documents
Annual
reports
Project Performance Evaluation Reports (PPER)
Terminal
Report
118
ANNEX VI
2.2 Senior Project Engineer
Background
Egypt has deteriorating surface water resources. Municipal wastewater, agricultural
runoff, and industrial effluent are threatening the health and welfare of millions of
people. At the same time Egypt's ability to pay for the treatment infrastructure is
declining. A successful wetland demonstration project will be of interest to governments
around the world that are searching for affordable solutions to wastewater treatment.
The development objective of the engineered wetland project is to improve global
environmental management by upgrading national to global linkages and by reducing
international water pollution, climate gases, and the decline in biodiversity. This will be
accomplished by the transfer of an appropriate, cost-effective wastewater treatment
technology to Egypt. This will also address a serious impediment to national and
regional development, namely, poor water quality.
Qualifications
The Senior Project Engineer will be an experienced professional in project
implementation with a broad background in consensus building and local participation.
Minimum qualifications include:
A. A professional engineer with a B.A. or B.S. degree in civil engineering or
equivalent expertise.
B. Proven record in interdisciplinary project management.
C. Ten years of experience in the design and construction of large-scale public
works projects having hydraulic components.
D. Familiarity with the environmental problems of Egypt's coastal lakes and
drains.
E. Excellent project and business management skills.
F. Fluent in Arabic and English.
G. Experience integrating inputs of local and national participants.
H. Working knowledge of local governmental organizations and decision
making.
I. Ability to work constructively with local residents in developing project
support and business opportunities.
Tasks
The Senior Project Engineer will be responsible for coordinating day-to-day construction
and operation of the engineered wetland and will be located at the project site. He/she
will be responsible for local administration of the project, preparation of detailed
workplans, recruitment of project personnel, establishment of project offices and field
station, tendering of subcontracts, liaison with interested parties, project and personnel
performance evaluation, and general reporting and accountability. He/she is responsible
for the inspection and verification of the construction supervisor's and subcontractor's
work quality and quantity; for promoting local business development associated with the
119
ANNEX VI
project; for gaining local cooperation and support; and for promoting wider use of the
wetland technologies and aquaculture among local residents.
The Senior Project Engineer will be required to participate in and contribute to the
following tasks (numbered according to the objective outputs):
1.1 Community Participation
1.2 Human Resource Development
1.3 Technology Transfer
2.1 Preconstruction Work
2.2 Wetland Construction
2.3 Socioeconomic Opportunities
2.4 Operation and Monitoring
Reporting Requirements
The Senior Project Engineer will be involved in preparing all project reports. The reports
requiring the greatest involvement and written contributions include:
Tender documents
Annual reports
Project Performance Evaluation Reports (PPER)
120
ANNEX VI
2.3 Operations Foreman
Background
Egypt has deteriorating surface water resources. Municipal wastewater, agricultural
runoff, and industrial effluent are threatening the health and welfare of millions of
people. At the same time, Egypt's ability to pay for the treatment infrastructure is
declining. A successful wetland demonstration project will be of interest to governments
around the world that are searching for affordable solutions to wastewater treatment.
The development objective of the engineered wetland project is to improve global
environmental management by upgrading national to global linkages and by reducing
international water pollution, climate gases, and the decline in biodiversity. This will be
accomplished by the transfer of an appropriate, cost-effective wastewater treatment
technology to Egypt. This will also address a serious impediment to national and
regional development, namely, poor water quality.
Qualifications
The Operations Foreman will have the following minimum qualifications:
A. Ten years of supervisory management experience in construction, operations
and maintenance of water related projects.
B. Good communication skills in English and Arabic.
C. Knowledge of pumps, hydrology, and aquatic biota.
D. Extensive experience in equipment operations and maintenance.
E. Knowledge of sampling techniques of water, plants, and sediments.
F. Ability to supervise personnel.
G. Familiarity with the project area and awareness of its local social, political,
and economic sensitivities.
H. Familiarity with potential business opportunities with by-products produced
from wetland treatment system.
Tasks
The Operations Foreman will be responsible for the day-to-day operation of the wetlands
and for data and sample collection. Overseeing wetland operation will involve checking
water levels and flows throughout the system. Data collection will involve analyzing
water for pH, dissolved oxygen (DO), and salinity on a daily basis. The Operations
Foreman will also be responsible in overseeing the potential business opportunities
developed from collecting plant biomass in the wetlands and fish in the aquaculture
ponds. The Operations Foreman will supervise three to eight people.
121
ANNEX VI
The Operations Foreman will be required to participate in and contribute to the following
tasks (numbered according to the objective outputs):
1.2 Technology Transfer
2.3 Socioeconomic Opportunities
2.4 Operation and Monitoring
Reporting Requirements
The Operations Foreman will be required to provide input to the following reports:
Socioeconomic monitoring plan
Educational brochures and booklets
Public participation guidelines
Annual reports
Project Performance Evaluation Reports (PPER)
122
ANNEX VI
blank
123
ANNEX VII
ANNEX VII. INTERNATIONAL CONTRACT AND INTERNATIONAL JOB
DESCRIPTIONS
1.0 INTERNATIONAL CONTRACT
2.0 TERMS OF REFERENCE
2.1 International Coordinator
2.2 International Wetland Designer
2.3 International Wetland Advisor
2.4 International Field Manager
124
ANNEX VII
blank
125
ANNEX VII
ANNEX VII
INTERNATIONAL CONTRACT AND INTERNATIONAL JOB
DESCRIPTIONS
1.0 International Contract
A single international contract will provide technical assistance and expertise, including
an International Coordinator, Wetland Designer, Wetland Advisor, and Field Manager.
The international contract will provide expertise that is not available in Egypt.
The budget for the international contract is given in Table VII-1. Annual budgets are
given in Table 2 of Section J. The international contract will be organized with a
15 percent mobilization payment and semiannual reimbursable payments up to 90 percent
of the contract amount. The last payment (10 percent of the contract amount) will be
retained until the final report and responsibilities of the international team are completed.
Terms of Reference for the international experts are given below.
Table VII-1. International contract budget estimate - Egyptian Wetland Project.
Estimated
Unit Cost
Total Cost
Item
Unit
Quantity
($)
($)
Personnel
Professionals
pers/mo
14
$17,000
$238,000
Technical and Clerical Support
pers/mo
10
6,000
60,000
Subtotal
$298,000
Travel
Airfare
rend
20
5,000
$100,000
trip
Per Diem
day
150
200
30,000
Local Transportation
day
150
60
9,000
Subtotal
$139,000
Miscellaneous
Reproduction, Supplies, Equipment
$ 13,000
TOTAL
$450,000
126
ANNEX VII
2.0 Terms of Reference
2.1 International Coordinator
Background
Egypt has deteriorating surface water resources. Municipal wastewater, agricultural
runoff, and industrial effluent are threatening the health and welfare of millions of
people. At the same time Egypt's ability to pay for the treatment infrastructure is
declining. A successful wetland demonstration project will be of interest to governments
around the world that are searching for affordable solutions to wastewater treatment.
The development objective of the engineered wetland project is to improve global
environmental management by upgrading national to global linkages and by reducing
international water pollution, climate gases, and the decline in biodiversity. This will be
accomplished by the transfer of an appropriate, cost-effective wastewater treatment
technology to Egypt. This will also address a serious impediment to national and
regional development, namely, poor water quality.
Qualifications
The International Coordinator should have the following qualifications: at least 15 years
of experience in a related engineering or scientific discipline and:
A. A Ph.D. with at least 15 years experience in a related engineering or scientific
discipline.
B. A proven record in interdisciplinary project management.
C. Substantial experience in applied scientific programs dealing with
environmental impact assessment, environmental management, and
rehabilitation.
D. Substantial experience in water resource management and international projects.
E. Familiarity with the environmental problems of Egypt's coastal lakes and
previous experience in Egypt.
F. Excellent project management skills.
G. Good communication skills in English.
H. Experience integrating inputs of national and international experts.
I. Working knowledge of the organization and procedures of the UNDP.
J. Excellent international network of contacts needed for the project.
K. Experience in the principles and design of wastewater treatment systems and
engineered wetlands.
L. Experience in project performance evaluation and monitoring.
Tasks
The International Coordinator will provide oversight to the project, assist the Project
Manager with technical and administrative issues, troubleshoot potential problems,
oversee monitoring results, coordinate the input of the international team, review
expenditures and milestone accomplishments, and assist in the preparation of
127
ANNEX VII
international reports, meetings, and information dissemination. The International
Coordinator will provide liaison with the UNDP and the Executing Agency.
The International Coordinator will review and provide technical advice to the Project
Manager and Project Management Board as requested on the following tasks:
1.1 Community
Participation
1.3 Technology
Transfer
2.1 Preconstruction
Work
2.2 Wetland
Construction
2.3 Socioeconomic
Opportunities
2.4 Operation and Monitoring
Reporting Requirements
The International Coordinator will prepare and submit the following reports:
Independent Annual Review Reports
128
ANNEX VII
2.2 International Wetland Designer
Background
Egypt has deteriorating surface water resources. Municipal wastewater, agricultural
runoff, and industrial effluent are threatening the health and welfare of millions of
people. At the same time Egypt's ability to pay for the treatment infrastructure is
declining. A successful wetland demonstration project will be of interest to governments
around the world that are searching for affordable solutions to wastewater treatment.
The development objective of the engineered wetland project is to improve global
environmental management by upgrading national to global linkages and by reducing
international water pollution, climate gases, and the decline in biodiversity. This will be
accomplished by the transfer of an appropriate, cost-effective wastewater treatment
technology to Egypt. This will also address a serious impediment to national and
regional development, namely, poor water quality.
Qualifications
The International Wetland Designer will have the following qualifications:
A. A Ph.D. with at least ten years of wetland design experience or equivalent
expertise.
B. Prior recognized experience in wetland design.
C. Evaluation of wetland performance requirements for water and sediment quality.
D. Experience in international project development.
E. Good communication skills in English.
F. Ability to produce academic and general public reports.
Tasks
The International Wetland Designer will review and provide technical advice to the
International Coordinator and Project Manager as requested on wetland design criteria
and tender documents. The Wetland Designer will review performance of the wetland to
assure water and sediment quality objectives are being achieved; provide design
modification suggestions as required; and assist with the biomass harvesting and
manufacturing programs. The Wetland Designer will also provide guidance in
establishing the local business cooperatives for marketing wetland and aquaculture
products.
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ANNEX VII
The Wetland Designer will assist with the following tasks:
1.3 Technology
Transfer
2.1 Preconstruction
Work
2.2 Wetlands
Construction
2.3 Socioeconomic
Opportunities
2.4 Operation and Monitoring
Reporting Requirements
The Wetland Designer will provide input and advice for the following reports:
Construction design drawings and specifications
Tender documents
Scientific study and monitoring workplan
Annual reports
Project Performance Evaluation Reports (PPER)
Scientific papers
130
ANNEX VII
2.3 International Wetland Advisor
Background
Egypt has deteriorating surface water resources. Municipal wastewater, agricultural
runoff, and industrial effluent are threatening the health and welfare of millions of
people. At the same time, Egypt's ability to pay for the treatment infrastructure is
declining. A successful wetland demonstration project will be of interest to governments
around the world that are searching for affordable solutions to wastewater treatment.
The development objective of the engineered wetland project is to improve global
environmental management by upgrading national to global linkages and by reducing
international water pollution, climate gases, and the decline in biodiversity. This will be
accomplished by the transfer of an appropriate, cost-effective wastewater treatment
technology to Egypt. This will also address a serious impediment to national and
regional development, namely, poor water quality.
Qualifications
The International Wetland Advisor will have the following qualifications:
A. A Ph.D. with at least ten years experience in environmental management.
B. Extensive and internationally recognized experience in wetland design.
C. Experience with the construction and operation of large scale wetlands.
Tasks
The International Wetland Advisor will be involved throughout the project period and
will act as a resource person. The International Wetland Advisor will be able to
substitute as required for the International Wetland Designer.
The Wetland Advisor will assist with the following tasks:
1.3 Technology Transfer
2.1 Preconstruction Work
2.2 Wetlands Construction
2.3 Socioeconomic Opportunities
2.4 Operation and Monitoring
Reporting Requirements
The Wetland Advisor will provide input and advice for the following reports:
Construction design drawings and specifications
Tender documents
Scientific study and monitoring workplan
Annual reports
Scientific papers
131
ANNEX VII
2.4 International Field Manager
Background
Egypt has deteriorating surface water resources. Municipal wastewater, agricultural
runoff, and industrial effluent are threatening the health and welfare of millions of
people. At the same time, Egypt's ability to pay for the treatment infrastructure is
declining. A successful wetland demonstration project will be of interest to governments
around the world that are searching for affordable solutions to wastewater treatment.
The development objective of the engineered wetland project is to improve global
environmental management by upgrading national to global linkages and by reducing
international water pollution, climate gases, and the decline in biodiversity. This will be
accomplished by the transfer of an appropriate, cost-effective wastewater treatment
technology to Egypt. This will also address a serious impediment to national and
regional development, namely, poor water quality.
Qualifications
The International Field Manager should have the following qualifications:
A. A proven track record in managing and implementing multidisciplinary field
programs.
B. Extensive experience in developing and evaluating contracts and proposals.
C. Experience in data collection and laboratory analysis of water and sediment
quality programs.
D. Knowledge of local conditions, regulations, and support facilities.
E. Successful experience in applied science programs dealing with environmental
impact assessment, environmental management, and rehabilitation.
F. Good communication skills in English.
G. Competence in the design and execution of QA/QC programs.
Tasks
The Field Manager will review and provide technical advice to the Project Manager as
requested on the mobilization and coordination of the field surveys, monitoring,
construction, and operation; the preparation of contracts with Egyptian laboratories for
data analyses; the supervision of field and laboratory studies; and the preparation of data
reports to relevant team members.
The International Field Manager will assist with the following tasks:
1.3 Technology Transfer
2.1 Preconstruction Work
2.2 Wetlands Construction
2.3 Socioeconomic Opportunities
2.4 Operation and Monitoring
132
ANNEX VII
Reporting Requirements
The International Field Manager will assist in preparing the following reports:
Scientific study and monitoring workplan
Annual reports
Scientific papers
133
ANNEX VII
ANNEX VIII. EQUIPMENT REQUIREMENTS
1.0 CONSTRUCTION
2.0 OFFICE EQUIPMENT
3.0 FIELD MONITORING AND LABORATORY EQUIPMENT
4.0 MONITORING EQUIPMENT SUPPLIED BY ANALYTICAL SUBCONTRACTORS
5.0 PLANTING AND HARVESTING EQUIPMENT
6.0 VEHICLES
134
ANNEX VIII
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135
ANNEX VIII
ANNEX VIII EQUIPMENT REQUIREMENTS
The following is a preliminary list of equipment for the project. A more detailed
appraisal and specific list of project requirements will be developed by the subcontractor
and project consultants as soon as possible after project initiation.
1.0 Construction
Pumps, electrical transformers, piping, couplers, valves, sumps, and ancillary
equipment
Supplied by subcontractor:
Excavators, draglines, trucks, bulldozers, front-end loaders, compactors, concrete
mixers, vessels, survey instruments, miscellaneous implements, and tools
2.0 Office Equipment
Nonexpendable:
Office furniture
Personal computers, printers
Photocopier
Telephones
Fax machines
Expendable:
Stationery, data sheets, and miscellaneous office supplies
Maps and charts of area
3.0 Field Monitoring and Laboratory Equipment
14-foot boat and trailer
temperature controlled BOD incubator
5 horsepower motor
Niskin type sampler
35 mm camera
bottle sampler
binoculars
field sample bottles
insitu water quality monitors
Ekman type sediment sampler
total suspended solids filtration
trays, pails, and containers (sediment
apparatus
collection)
analytical balance (5 decimal)
moored current meter
cabinet dessicator
mooring, floats, etc.
ultraviolet--visible
spares and miscellaneous field items
spectrophotometer for
computers, monitors, software, printers,
colorimetric analyses
miscellaneous laboratory glassware,
laboratory DO and pH instruments
stirrers, hotplates, reagents, etc.
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ANNEX VIII
4.0 Monitoring Equipment Supplied by Analytical Subcontractors
Chemical reagents
Analytical equipment
5.0 Planting and Harvesting Equipment
Sickles, mesh-buckets, nets, shovels, rakes, containers
6.0 Vehicles
Car
Pick-up truck and trailer
137
ANNEX VIII
ANNEX IX. BUDGET DETAILS
1.0 GOVERNMENT OF EGYPT CONTRIBUTIONS
1.1 Personnel
1.2 Land
2.0 UNDP CONTRIBUTIONS
2.1 Personnel
2.2 Duty Travel
2.3 Cairo Office
2.4 Project Equipment
2.5 Project Operations
2.6 Subcontracts
2.7 Miscellaneous
138
ANNEX IX
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139
ANNEX IX
ANNEX IX BUDGET DETAILS
1.0 Government of Egypt Contribution
1.1 Personnel
EEAA Representative
2 mth/yr (Y1, Y2, Y5); 1 mth/yr (Y3, Y4);
9500 LE/mth in Y1 with escalation factor
of 1.03/yr
Project Management Board (7)
4 mth/yr (Y1-Y2); 2 mth/yr (Y3-Y4);
3 mth/yr (Y5); 12,000 LE/mth in Y1 with
escalation factor of 1.03/yr
Technical Focal Points (14)
4 mth/yr (Y1-Y2); 2 mth/yr (Y3-Y4;
3 mth/y (Y5): 7000 LE/mth in Y1 with
escalation factor of 1.03/yr
1.2 Land
Project Site
8000 LE/feddans; 200 feddans; This is the
cost of land for the wetland site. The land
will be provided before project implemen-
tation as a prior obligation.
2.0 UNDP Contribution
2.1 Personnel
Project Manager
12 mth/yr (Y1-Y5)
$3300/mth in Y1 with escalation factor of
1.03/yr
Senior Project Engineer
12 mth/yr (Y1-Y5)
$2700/mth in Y1 with escalation factor of
1.03/yr
Secretary
12 mth/yr (Y1-Y5)
$752/mth in Y1 with escalation factor of
1.03/yr
Assistant/Driver
12 mth/yr (Y1-Y5)
$940/mth in Y1 with escalation factor of
1.03/yr
Legal Counsel
3 mth in Y1
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ANNEX IX
$3000/mth in Y1
Operations Foreman
6 mth/yr (Y3); 12 mth/yr (Y4-Y5);
$380/mth in Y3 with escalation factor of
1.03/yr
Unskilled Labor
24 mth/yr (Y3); 48 mth/yr (Y4-Y5);
$190/mth in Y3 with escalation factor of
1.03/yr
2.2 Duty Travel
National Personnel
$8000/yr (Y1-Y5); based
- on an estimate of 20 round-trips between
Cairo and Port Said per year at $130 per
round-trip; and
- an estimate of 20 per diems per year in
Cairo at $160 per day and 20 per diems
per year in Port Said at $110 per day.
2.3 Cairo Office
Office Space
$12,000/yr (Y1-Y5)
Office Furnishings
5,000 (Y1)
Office Equipment
15,000 (Y1)
Office Car
20,000 (Y1)
Office Utilities/Supplies
8,400/yr (Y1-Y5)
2.4 Project Equipment
Truck and Trailer
$ 30,000 (Y3)
Maintenance Equipment
15,000 (Y3)
Monitoring/Lab Equipment
100,000 (Y3) See Annex VIII for details
2.5 Project Operations
Electricity
6 mth/yr (Y3); 12 mth/yr (Y4-Y5)
$1775/mth in Y1 with escalation factor of
1.03/yr based on pumping 50,000 m3/d,
4 m of head, 70 percent efficiency, and
$0.075/kWh electricity cost
141
ANNEX IX
Expendable Materials
6 mth/yr (Y3); 12 mth/yr (Y4-Y5);
$1600/mth
Maintenance, Repair, and Replacement
1 mth (Y3); 12 mth/yr (Y4-Y5);
$2480/mth
2.6 Subcontracts
International Wetland Consultant
$110,000 (Y1); $90,000/yr (Y2-Y3); and
$80,000/yr (Y4-Y5)
See Table VII-1 for details
Design and Construction Supervisor
$190,000 in Y1; $70,000 in Y2, and
$30,000 in Y3 based on $80,000 for site
surveys, 9 percent of construction for
design, and 4 percent of construction cost
for supervision
Construction
$1,300,000 in Y2; and $670,000 in Y3.
See Annex IV for details.
Design Modifications
$30,000 in Y3
Monitoring
$10,000 in Y3; $35,000 in Y4; and $55,000
in Y5. See Annex V for details.
2.7 Miscellaneous
UNDP Administration
$24,000/yr (Y1-Y5) based on 3 percent of
project total of $4,000,000.
142
ANNEX IX
blank
143
ANNEX X
ANNEX X.
FINANCIAL AND ACCOUNTING ARRANGEMENTS
1.0 GENERAL
2.0 ADVANCE OF FUNDS
3.0 DIRECT PAYMENTS BY UNDP
4.0 PERIODIC FINANCIAL STATEMENTS
5.0 GOVERNMENT ANNUAL AUDITED FINANCIAL STATEMENTS
6.0 GOVERNMENT FINAL FINANCIAL STATEMENTS
7.0 AUDIT BY UNDP
144
ANNEX X
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145
ANNEX X
ANNEX X FINANCIAL AND ACCOUNTING ARRANGEMENTS
1.0 General
1. The Executing Agency named on cover page of the project document, hereinafter
referred to as "the Government," is responsible to the Administrator of UNDP for the
custody and proper use of funds advanced to it by UNDP.
2. The Government will maintain separate accounts (including a separate bank account)
for UNDP resources. It will use the funds provided to it only for inputs financed by
UNDP, in accordance with the project budget covering UNDP's contribution. (See
PPM Part III, section 30305, subsection 3.0).
3. Advances of funds to and payments by UNDP on behalf of Governments are
governed by the applicable UNDP Financial Regulations and Rules and directives
regarding the utilization of currencies.
4. The Government will provide UNDP with financial statements of UNDP funds
received and spent, prepared in accordance with the UNDP financial year (1 January
to 31 December) in English. The periodicity and content of such statements are set
out below. Annual financial statements will be audited by the legally-recognized
auditors of the Government's own accounts. To the extent feasible, the audit
principles and procedures prescribed for the United Nations will be applied by the
auditors, who will provide audit reports annually together with the reports set out
below.
5. For the purpose of reporting to UNDP, US dollar equivalents will be calculated at the
United Nations operational rates of exchange. The resident representative of UNDP
will inform the Government of such United Nations rates of exchange and of changes
thereto when they occur.
2.0 Advance of Funds
6. Advances will be made by the resident representative at the request of the
Government in accordance with the project document and in the required currencies
subject to the conditions set out below.
7. The Government will indicate its cash requirements from UNDP funds for each
period of the schedule of advances included in the project document at least two
weeks before payment is due (Attachment 1 of this annex, Request for Advance of
Funds). Advances will be made by UNDP at the time indicated in the schedule of
advances, in the amounts and currencies requested by the Government. (See also
paragraph 9, below for requests for cash advances in currencies not available to the
UNDP field office).
146
ANNEX X
8. If the schedule of advances included in the project document no longer reflects actual
requirements for funds, a new schedule will be prepared by the Government in
consultation with the resident representative, in accordance with the format indicated
in Attachment 5 of this annex, Schedule of Advances. Advances should normally be
sufficient to cover anticipated cash requirements for a maximum of three months.
9. Local currency advances to the Government will normally be made by the resident
representative.
10. Advances to the Government in US dollars will be made by the resident
representative if this currency is available to him or her. The resident representative
will arrange for advances in currencies not available to him or her to be made by
UNDP headquarters or other field offices, as deemed appropriate.
3.0 Direct Payments by UNDP
11.
At the request of the Government, UNDP will, after verification of the supporting
documentation, make payments directly to individuals or firms providing
UNDP-financed services or goods. The requests will be addressed to the resident
representative who will either arrange for the payments to be made by his or her
office or by UNDP headquarters. The requests will indicate payee, amounts and
currencies required, justification for the request and payment instructions
reflecting payee's bank, its address, and the account number.
12.
The resident representative will provide the Government with statements of direct
payments made by UNDP within 15 days following 30 April, 31 August, and 31
December, for incorporation in the project delivery report in accordance with
paragraph 13 (b), below.
4.0 Periodic Financial Statements
13. The Government will furnish the resident representative with certified financial
statements within 30 days following 30 April and 31 August and within 60 days
following 31 December. The statements will include the following:
a) Status of Funds Advanced by UNDP (Attachment 2 of this annex). The
statement will be submitted for each period indicated above and will be
prepared in the currency of the advance. Separate statements will be issued
where different currencies have been advanced. Each statement will reflect
cumulatively for the year the amount of funds available at the beginning of the
year, funds advanced by UNDP, funds expended by the Government during the
reporting period, and the resulting balance at the end of that period. The
statement will also detail expenditure incurred by month in local currency and
the US dollar equivalent calculated at the applicable United Nations
operational rate of exchange.
147
ANNEX X
b) Project Delivery Report (Attachment 3 of this annex). The report will be
submitted for each period indicated above and will reflect cumulative
current-year expenditure classified according to the items listed in the
approved project budget. It will incorporate the expenditure incurred by the
Government and, where appropriate, the expenditure statement of the
cooperating agency, if any, and the statement of direct payments made by
UNDP.
c) Annual Report of UNDP-Financed Nonexpendable Equipment (Attachment 4
of this annex). The Government will furnish the resident representative, for the
year to 31 December, within 60 days following that date and together with
other financial statements due at that date, with an annual report of
nonexpendable equipment. The report will include all UNDP-financed
nonexpendable equipment furnished to the project during the year.
Nonexpendable equipment purchased by the cooperating agency, if any, and
furnished to the project will also be included. The report will describe each
item in detail, list the identification number given by the Government and the
serial or registration number assigned by the maker and reflect the cost at the
US dollar equivalent at the time of purchase calculated at the United Nations
operational rate of exchange.
d) Expenditure Statement for Jointly Financed Project. In the case of joint
financing of project activities by the Government and UNDP and, as the case
may be, other sources of assistance, the certified financial statements referred
to above shall be accompanied by a separate statement reflecting expenditure
for the full project covering the same period as the certified financial
statements. To this expenditure statement should be added an indication of the
apportionment by the Government of the reported expenditure to UNDP's
contribution and other available funds.
14. If the Government cannot submit the financial statements on the date on which they
are due, it will inform the resident representative of the reasons and indicate the
planned submission date.
5.0 Government Annual Audited Financial Statements
15.
A certified and audited annual financial statement of the status of funds advanced
by UNDP, as described in paragraph 13 (a), above, will be made available by the
Government to the resident representative within 120 days after the end of the
calendar year.
16.
The financial statement will be audited and attested to by the entity specified in
paragraph 4, above.
148
ANNEX X
6.0 Government Final Financial Statements
17.
Upon financial completion of UNDP assistance to a project, the Government will
provide final financial statements to cover the period 1 January to the date of
either financial completion or refund of the unspent balance of UNDP funds, if
any (see paragraph 18, below). The financial statements will be audited so as to
conform to the requirements set out in section E above. The format given in
Attachments 2 and 3 of this annex should be used. The statements will be
provided within 120 days from the date of financial completion to the Director of
Finance with copies to the UNDP resident representative.
18.
If there is an unspent cash balance of UNDP funds held by the Government, that
balance will be refunded by the Government in the currency of the advance not
later than 30 days after the date of financial completion.
7.0 Audit by UNDP
19.
All accounts maintained by the Government for UNDP resources may be audited
by the UNDP internal auditors and/or the United Nations Board of Auditors or by
public accountants designated by the United Nations Board of Auditors.
149
ANNEX X
Attachment 1
GOVERNMENT OF ______________________________________________________
REQUEST FOR ADVANCEMENT OF FUNDS FROM UNDP
FOR PROJECT __________________________________________ NO: /
For the period from __________________ 19 ____ to _____________________ 19 ____
Currency
Cash in
Estimated
Net
Payment Details
hand at
disbursements advance
Bank
Account
Number
beginning to end of
required
Name &
Title
of period
period
Address
Certified
by:
______________________________
Name
(typed)
Title
Government agency (department)
150
ANNEX X
blank
151
ANNEX X
Attachment 2
Page 1 of 2
GOVERNMENT OF ______________________________________________________
STATUS OF FUNDS ADVANCED BY UNDPa
FOR PROJECT __________________________________________ NO: __/__/__
For the period of 1 January ________ 19 ___
(In [currency] )
Amount
A. Summary of funds received and expended (currency of advance)
Balance at 1 January 19 ___
XXX XXX
Add: Advances received from UNDP
XXX XXX
Total funds available for project purposes
XXX XXX
YYY YYYb
Deduct: Total expenditure for year-to-date
Balance at ................. 19 ___
XXX XXX
Represented by:
Cash in bank
XXX XXX
Cash on hand
XXX XXX
Balance at ................. 19 ___
XXX XXX
a A separate statement is required for each currency advanced by UNDP.
b
ount should be the sam
This am
e as the total expenditure (in currency of advance)
in Table B.
152
ANNEX X
Page 2 of 2
B. Summary of expenditure by month
Expenditure
(In currency
UN operational
Expenditure
of advance)
rate of exchange
(in US $ equivalent)
January
XX XXX
XX.XX
XX XXX
February
XX XXX
XX.XX
XX XXX
March
XX XXX
XX.XX
XX XXX
April
XX XXX
XX.XX
XX XXX
May
XX XXX
XX.XX
XX XXX
June
XX XXX
XX.XX
XX XXX
July
XX XXX
XX.XX
XX XXX
August
XX XXX
XX.XX
XX XXX
September
XX XXX
XX.XX
XX XXX
October
XX XXX
XX.XX
XX XXX
November
XX XXX
XX.XX
XX XXX
December XX
XXX
XX.XX
XX XXX
Total YYY
YYYa XXX
XXX
Certified correct by:
Approved by:
___________________________ ___________________________
Name (typed)
Name (typed)
Chief Accountant
Title
Government agency (department)
Government agency (department)
AUDIT CERTIFICATE
(As issued and signed by the Auditors)
REQUIRED ONLY FOR ANNUAL AUDITED
AND FINAL AUDITED FINANCIAL STATEMENTS
______
a
ount should be the sam
This am
e as the total expenditure for year-to-date in Table A.
Attachment 3
153
ANNEX X
GOVERNMENT OF ______________________________________________________
PROJECT TITLE _______________________ UNDP PROJECT NO. (____/____/___)
Project delivery report for funds provided by
United Nations Development Program (UNDP)
for the period 1 January to 19
(prepared in US dollars)
Budget Description Expenditure
Line
Budget
Government UNDP
Cooperating Total
of Year
Direct
Agency
Payments
(1) (2) (3) (4) (5) (6) (7)
99.00 Total
a
Certified by:
Approved by:
______________________________ __________________________
Name (typed)
Name (typed)
Chief Accountant
Chief Accountant
Government Agency (department)
Government Agency (department)
Audit Certificate
(as issued and signed by the Auditors)
REQUIRED ONLY FOR ANNUAL AUDITED
AND FINAL AUDITED FINANCIAL STATEMENTS
________________________
aTotal of US dollars equivalent shown in each Attachment 2.
Attachment 4
154
ANNEX X
GOVERNMENT OF ______________________________________________________
Annual Report of UNDP-financed nonexpendable equipmenta
For Project No:
For the year ending 31 December 19___
Description
Government
Maker's serial or
Cost in US
Identification
registration number
dollarsb
number
Total
Certified
by:
___________________________
Name
(typed)
Title
Government agency (department)
_______________________
a Includes those items of equipment valued at $400 or more, and with serviceable life of
at least five years, and those items of equipment, although valued at less than $4000, which
are office furniture, filing cabinets, office machines, attractive items (such as cameras,
projectors, stop watches, briefcases) or other similar items as determined by the
Government.
b US dollars equivalent at time of purchase calculated at the United Nations operational
rate of exchange.
155
ANNEX X
Attachment 5
[PROJECT NUMBER AND TITLE]
SCHEDULE OF ADVANCESa
US $
A. Funds advanced to date
XXX
XXX
B. Funds to be advanced in forthcoming 12 monthsb
i. To Government
Date
Amount
_________________________ _______________________
_________________________ _______________________
_________________________ _______________________
_________________________ _______________________
_________________________ _______________________
Total
XXX
XXX
ii. To cooperating agency
XX XXX
C. Funds to be advanced in subsequent periods
XXX XXX
TOTAL ALLOCATION PER PROJECT BUDGET (LINE 99)
X XXX XXX
________________________
aTo be included in the project document immediately following the budget for UNDP's
contribution (part IV). Advances should only cover anticipated cash requirements for a
maximum of three months.
bThe period to be covered should be the 12 months following the date of approval of the
project revision.
156
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157
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ANNEX XI. BIBLIOGRAPHY
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159
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