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Revision as of 12:45, 4 June 2021
Contents
- 1 Chapter Nine: Design of Water Structures
- 1.1 SIZING AND LOCATING WATER STRUCTURES
- 1.1.1 Tanks
- 1.1.2 Sedimentation/Settling Tanks
- 1.1.3 Break Pressure Tanks
- 1.1.4 Water Intakes
- 1.1.5 Dams
- 1.1.5.1 Engineering Classification of Dams
- 1.1.5.2 Size classification of dams
- 1.1.5.3 Feasibility investigations
- 1.1.5.4 Hydrological Analysis of the Water Catchment Area
- 1.1.5.5 Geotechnical Investigation
- 1.1.5.6 Design of Dams
- 1.1.5.7 Boreholes
- 1.1.5.8 Groundwater Prospecting
- 1.1.5.9 Structures for Rainwater Harvesting
- 1.1.5.10 Treatment of Harvested Rainwater
- 1.1.5.11 Water Points and Service Connections
- 1.1.5.12 Common Types of Water Points
- 1.1.5.13 Minimum Technical Requirements of Water Points
- 1.1.5.14 Criteria for the Design of Water Point/Kiosks
- 1.1.5.15 Location Considerations for Water Points
- 1.1.5.16 Technical Tips to Improve Water Points
- 1.1.6 STRUCTURAL DESIGN OF CONCRETE
- 1.1 SIZING AND LOCATING WATER STRUCTURES
1 Chapter Nine: Design of Water Structures
The main components of a water project include water intakes, break pressure tanks, water points, valve chambers and storage/sedimentation tanks. The following sections describe the design procedures for various water structures.
1.1 SIZING AND LOCATING WATER STRUCTURES
1.1.1 Tanks
1.1.1.1 Storage tanks
The primary purpose of water storage tank is to balance supply during peak hour demand. It is typical to have two peak times during the day, one in the morning the other in the evening when large amounts of water is collected. Water storage tanks should be positioned on higher ground relative to the supply area so as to command pressure.
The following design points should be considered as procedures when estimating the water tank volume/capacity
- Estimate tank capacity by calculating the water demand at various times of the day and comparing that to the yield of the water supply scheme,
- Establish the demand and supply patterns for a typical day during the assessment phase of the project
- The supply yield pattern of the project depends on the design operation period for pumping systems,
- Consider providing tanks for solar-powered projects as they have limited pumping hours,
- Establish the tank volume based on the amount of water needed from the time when there is more water leaving the tank than entering the tank (demand> supply) until the time when there is more water entering the tank than leaving it (Supply > Demand),
- Size the water tank volume so that it is able to meet the deficit during these hours,
- Calculate the volume of the tank by comparing the supply with demand at incremental time periods and balance to the existing storage,
- The balance should start at zero, then calculated for each time period (iteration) by adding the surplus or deficiency to the balance of previous iteration.
This is represented below, with n representing the iteration.
Balance n = Surplus / Deficiency n + Balance n-1
The necessary tank capacity (V tank) is then calculated as the maximum balance (V max) minus the minimum balance (V min) minus the final volume (V final).
V tank= V max – V min –V final (9.2)
Refer to Appendix C example of the sizing of tanks.
1.1.2 Sedimentation/Settling Tanks
Settling Tanks and clarifiers should be sized based on the settling velocity of the smallest particle to be theoretically 100% removed. Settling velocity of particle may be determined using Stokes law:
Particle characteristics (diameter and density) may be determined in the laboratory through standard methods. Particle settling is governed by the condition that the settling velocity of a particle (Wt) should be less than the settling tank overflow rate (Vo). The settling tank overflow rate (Vo) is defined as:
Overflow rate (Vo) = Flow of water (Q (m3/s)) / (Surface area of settling basin (A)(m2)) (9.4)
Settling tanks and clarifiers may be designed as long rectangles after calculating the surface area, rectangular shapes are hydraulically more stable and easier to control for large volumes. Factors such as flow surges, wind shear, scour, and turbulence may reduce the effectiveness of particle settling. To compensate for these less than ideal conditions, it is recommended to double the area determined from theoretical calculations. It is also important to equalize the water flow distribution at each point across the section of the basin. Poor inlet and outlet designs can produce extremely poor flow characteristics for sedimentation.
Sedimentation efficiency does not depend on the tank depth. If the forward velocity is low enough so that the settled material does not re-suspend from the tank floor, the area is still the main parameter when designing a settling basin or clarifier, taking care that the depth is not too low.
1.1.3 Break Pressure Tanks
Break pressure tank is a structure that is located between a water reservoir and supply point with the aim of reducing the pressure in the system to zero (atmospheric pressure). Conventional break pressure tank is constructed of concrete in rectangular shape with the depth of the tank about 1.2m. The design criteria for the break pressure tank is to find such that the minimum diameter of the outlet pipe can convey the design flow without causing the overflow in the tank.
Example:
Consider:
Free flow in the tank at depth d conveyed to outlet pipe at velocity V_2:
Choose the dimension of the tank at d values ranging from 1.0 m -1.5 m, length and width of the tank between 1 m to 3 m. The sizing of break pressure tank may be calculated based on the following specifications:
1.1.4 Water Intakes
This is a structure built in the body of water to draw water from the water source. The source may be a canal, river, spring, lake or dam usually built as an integral part of the source. The intake consists of an opening, a strainer or grating through which water enters and conduit conveying the water usually by gravity to a well. These structures are masonry or concrete structures and provide relatively clean water, free from pollution by sand and objectionable floating material.
a) Function of Intakes
The main function of an intake is to provide the highest quality of water from the source and to protect pipes and pumps from being damaged or clogged by wave action, floating objects/debris and submerged marine objects or creatures.
b) Consideration for Locating water intake structures
The following general considerations should be taken while designing and locating water intake structures:
- The source of supply should not have wide fluctuation in water level,
- The site selected should be able to admit water even under lowest flow conditions in the river. Generally, it is preferred that intake should be sufficiently below the shoreline,
- The proximity of the intake structure to the treatment plant,
- Good foundation, away from navigation requirements, safe from effect of floods, storms and scouring in the bottom,
- It should be placed at a location that is free from pollution. It is better to provide the intake at a location reasonably far from settlements so that the water is not contaminated,
- Away from locations with a high frequency of floating materials such as ice, vegetation and logging,
- Intake capacity must be large enough to meet the requirement of design discharge,
- It should not interfere with river traffic if any.
- It should be located where good foundation conditions are available,
- It should be located so that it admits relatively pure water free from mud, sand and pollutants.This implies protection from rapid currents,
- It should be created on the erosion side of a river bend and not the deposition side.
c) Considerations for design of various types of water intakes
(i) Reservoir intake
The water in a reservoir is likely to vary in quality at different levels. This feature makes it usually desirable to take water from about 1 m below the surface. Due to fluctuations in water level, it is desirable to have entry ports at various heights with gate valves. These gate valves are used to regulate water supply. When the water level goes down, a gate valve of a lower port is opened. Access to the ports is through an operating room.
(ii) River intakes
A river intake should consist of a port (conduit) provided with a grating and a sump or gravity well. The conduit should be supported on pillars 1-2 m above the bottom to prevent entry of silt. Also it is kept 1 m below the top surface to avoid entry of floating debris. Velocity should be kept at less than 0.15 m/s to prevent the entry of small fish. River intake structure should be constructed upstream the point of sewage disposal or industrial wastewater disposal. River intakes may need screens to exclude large floating matter. The bottom of the river intake must be sufficiently stable.
(iii) Lake intakes
If the lakeshore is inhabited, the intake should be constructed such as to minimize the danger of pollution. The intake opening should be 2.5 m or more above the bottom so that the entry of silt with water is minimized. The water entry velocity must be low to exclude floating matter, sediment, fish or ice. Entering velocity of 0.15 m/s is usually used. Offshore winds tend to stir up sediments which will be carried for long distances. So, intakes must be located at a distance of not less than 600 meters from the shoreline. Such intakes are recommended to be of multiple level intakes to ensure the source can cope with climate change impacts.
(iv) Intake conduit
Intakes located at long distances from the pumps usually deliver their water to the pump well at the shore end by gravity. This requires a large pipe or conduit so that the velocity is low. But velocity should not be too low to allow for the occurrence of sedimentation. The conduit may be a submerged pipe or tunnel. A submerged pipe should be protected by burying it in a trench, surrounding it with rock or held in place with piling.
1.1.5 Dams
A dam is a structure built across a stream, a river, or an estuary to retain water. Dams are built to provide water for human consumption, for irrigating arid and semiarid lands, or for use in industrial processes.
1.1.5.1 Engineering Classification of Dams
Dams are classified according to their function, shape, construction materials and design. This is termed as engineering classification. Figure 9.2 presents a typical dam engineering classification:
Under structural classification, there are several dam type namely; gravity, arch, buttress, earth fill and rock fill. The Ministry of Water has inventoried about 710 dams whose information has been recorded in a database. As per the inventory, more than 99% of these dams are earth fill and rock fill dams and the rest fall into other categories. Due to this fact, the emphasis of this manual is on earth fill and rock fill dams to guide their design, construction and Operation and Maintenance.
1.1.5.2 Size classification of dams
(a) Large dams
According to International Commission on Large Dams (ICOLD), large dams are
those having capacity of 3million cubic meters or more and a height of more than
5 meter as summarized by the expression below:
5<H<15m and V>3Million cubic meters.
Where:
H is height in meters above riverbed level to maximum crest level,
V is storage volume in million at Maximum Operating Level=Full Supply
Level in most cases.
(b) Small Dams
Small dams have height of less than 2.5m and the product of H2√V and should be
less than 200 as indicated here below:
2.5<H<15m and H2√V <200
Note: (*) Minimum dam height can be changed to 2 or 3 m in the case of dams in
residential or very populated areas.
Also, note: For flood retention dams holding no water the storage volume at crest
of spillway level (design storage volume) should be used.
In Figure 9.3, the ICOLD classification (www.icold-cigb.net) of dams based on size
is presented:
The focus of this manual is on large dams. Small and sand dams are covered in the rainwater harvesting guidelines prepared by the Ministry of Water and thus a designer should consult the relevant guidelines as appropriate.
1.1.5.3 Feasibility investigations
During the feasibility study all data and related information of the project should be collected and analysed. The following are the detailed guidelines for conducting feasibility studies and preliminary designs of a dam project. Note that, in this manual, the emphasis is on earth fill dam as the dominant dam type in the country.
(a) Topographical Survey
Once all preliminary investigations have been made and a suitable dam axis has
been selected, the next step is to carry out a detailed survey of the valley and
reservoir area to allow for more accurate estimates of quantities and to provide
the necessary data for appropriate design work to be undertaken. The aim of
such a survey is to present, on paper, contour map of the reservoir up to and
exceeding the maximum flood level, and to provide details for the location of the
embankment, spillway and outlet works. From the contour map, the capacity of
the reservoir can be assessed by varying dam heights.
The topographical survey works can be conducted by using different techniques
depending on the site condition, size of the catchment, availability of resources
and level of accuracy required. Light Detection and Ranging (LiDAR) survey, drone
(Aerial), Differentials GPS (Real Time Kinematics-RTK), Totals station and ordinary
levelling survey may be deployed during the topographical survey. The required
contour map should range from 0.25m to 1.0m contour interval depending on
the topographical characteristics of the area. Note that the contour interval
is directly proportional to accuracy of the estimated volume of reservoir. The
elaboration of the survey techniques used for topographical data collection and
analysis are as provided here below.
(i) Grid survey
This is a simple and straightforward but time-consuming method. It may not be
appropriate if the area is heavily vegetated and/or physically inaccessible.
(ii) Cross-sections
Cross-section surveys are taken along various lines within the river valley(s) from
benchmarks previously established. Levels are observed at set intervals and
outstanding features (changes of slope in particular) are also noted.
(iii) Spot heights
This is especially suited for larger areas. A circuit of benchmarks is established
and spot height observations with bearing, distance and elevation are made
from each station. For smaller dams, and if a theodolite or electronic instrument
is used, it may be possible to take all the readings from one station. Alternatively,
reasonably accurate GPS surveys can be used to establish a network of elevation
readings across the site.
(iv) Aerial survey
This does not have much difference from the spot heights. However, this
technique deploys plane (LiDAR) and drone to conduct topographical surveys of
the proposed dam catchment area. The major advantage of this technique is that
it is time-saving and the major disadvantage is its high cost compared to other
techniques. Therefore, this technique is more suitable for large projects.
The output of the topographical map is a depth-capacity curve and can then be
drawn up to provide a quick and easy method for the dam designer to choose the
optimum full supply level. Figure 9.4 represents the area capacity depth curve:
1.1.5.4 Hydrological Analysis of the Water Catchment Area
Hydrological analysis is a very important aspect to be considered when designing any hydraulic structure. During a hydrological analysis of a catchment, three design issues should be considered which are:
- Water yield of the catchment,
- Design flood and
- Sediment accumulation in the reservoir.
In Tanzania, some of the rivers are un-gauged which calls for the use of empirical formulae in the estimation of reservoir inflows and spillway capacity of a dam. In the absence of direct measured flows of rivers, the catchment yield is estimated based on rainfall run off models.
Steps to be followed in conducting hydrological analysis of a catchment
Step 1: Determine the amount of data required for the analysis
Rainfall data is required for the probability rainfall analysis, flood analysis and
water availability analysis. For this reason, existing rainfall data from several
sources have to be collected and reviewed, including: daily rainfall, monthly rainfall,
monthly discharges, daily mean discharges and other hydro-meteorological data
which are used as part of the input rainfall runoff modeling.
Step 2: Assessment of Watershed Rainfall Records and gap filling of rainfall
data
In watershed work it is often necessary to know the average depth of rainfall
over an area. The rainfall data used includes daily amounts as measured at rain
gauges. Rainfall data is required for probability rainfall analysis, flood analysis
and water availability analysis. Missing data may be interpolated using several
methods and in this manual Inverse Distance Squared Method is suggested to
be used and compared with other methods available in different references as
indicated below.
Step 3: Estimating Average rainfall depth
Beside other methods, Thiessen is user friendly for estimating watershed Average
rainfall depths using a rain gauge network. In the Thiessen method, the watershed
area is divided in sub areas, using rain gauges as hubs of polygons. This method
and other related approaches are explained in hydrological literature.
Step 4: Assessment of Runoff flow records
Daily river flow records collected within the catchment area and contributing to
the proposed reservoir should be used for runoff estimation.
Step 5: Rating curve
In order to transform the hydrometric levels into flow values, it is necessary to
process a rating curve for each of the stations being considered. The calculation
of the rating curve consists of estimating the parameters of a fitting function on
known pairs of level-flow values. The fitting function is specifically chosen so that
it can mathematically adapt to the experimental points. The look up function in
spread sheet should be deployed to estimate the discharge from the known pair
of level-flow. The following is the basic equation used to estimate the discharge
from water level data measured in the river.
H --> Q Q = a(H – b)c......................................................... (9.9)
1.1.5.5 Geotechnical Investigation
(a) The purpose of geotechnical investigation
The following are the purposes of geotechnical investigation for dam design and
construction:
(i) To evaluate the parameters of soil/rock at the proposed site,
(ii) To assess the engineering parameters and to estimate the safe bearing
capacity of dam foundation,
(iii) Drilling borehole in order to know the stratification and conducting necessary
field tests and to collect samples for laboratory testing,
(iv) Testing soil samples in the laboratory to determine the physical and
engineering properties of the collected samples, and
(v) Analyzing all field and laboratory data to evaluate safe bearing capacity for
given foundation sizes and necessary recommendations for foundation
design and construction materials.
(b) In-situ Tests
The level of geotechnical investigation depends much on the size of the dam
project, surface geological characteristics, topographical and geomorphological
characteristics of the site. The geotechnical investigation mainly is subdivided
into main three categories.
To obtain the geotechnical properties of the foundations of major structures
including dam, spillway and weir, the in-situ tests are carried out in the boreholes
and trench pit field test including standard penetration test and plate load test
in soil and weathered zone dilatometer test to identify strength a different
stratification of the geological formation, as well aswater pressure test in the
bedrock (Hydraulic Conductivity of the Geological formation).
Investigation of the underlying geological formation of the dam site
In order to analyze the formation of the underlying rock of the dam site, different
techniques are deployed. For small scale investigation which is conducted in
soft formation, augering is used while in hard formations deployment of heavy
equipment is highly recommended through coring. The core samples are
analyzed to determine faults and stratification of the underlying geology of the
dam and reservoir sites.
Soil Sampling for Laboratory Test
Soil sampling is conducted in order to determine mechanical and chemical
properties of the geological formation and construction materials collected from
boreholes. Recommended soil tests for design of the embankment dam are
detailed on section 12.4.4.
1.1.5.6 Design of Dams
(a) Design (Spillway Dimensioning) Flood by rainfall runoff model
The aim is to evaluate the extreme floods to be adopted for the design of a dam and
the pertaining hydraulic structures. More in detail, the hydrological elaborations
estimated are expected to satisfactorily assess the flood associated to several
return periods. Two methodologies may be adopted for the hydrological study
for the purpose of constructing hydraulic structure such as dam namely:
- Probable rainfall,
- Rainfall-runoff model.
Different distributions, including two parameters log-normal, three parameters log-normal, Gumbel and Log Pearson type-III have to be compared. It is noteworthy that since the historical runoff time sets are quite limited in some catchments, the prediction of the extreme flood with high return periods with statistical methods can lead to results on significant uncertainties.
The transformation of rainfall into runoff to estimate the peak flood and the entire hydrograph at the section of interest should be developed. The hydrological models can allow the estimating of the Probable Maximum Flood (PMF) i.e. the greatest flood physically possible over the catchment of interest.
Probable rainfall by frequency is calculated by statistical analysis on annual extreme series data. The daily maximum rainfall according to various return periods through two parameters log-normal, three parameters log-normal, Gumbel and Log Pearson type-III distribution.More information on statistical approaches can be found in appendix J.
The return period (sometimes called the recurrence interval) is often specified rather than the exceedence probability. For example, the annual maximum flood flow exceeded with a 1 percent probability in any year, or chance of 1 in 100, is called the 100-year flood. In general, Xp in the T-year flood is computed as follows
T = 1/ (1-p) .......................................................................... (9.10)
After geotechnical investigation and soil testing, hydrological analysis, sediment analysis, detailed topographical survey and Environmental and Social Impact Assessment the following stage is to conduct a detailed design and cost estimate of the project. The cost of the project should form a basis for economic analysis of the entire project. During economic analysis of the project the cash flow is prepared which defines the payback period of the project. This chapter is not prepared to guide the users on project economic analysis since the matter is covered in other chapters of the manual.
The design section focuses on earth fill and rock fill dams and other types of dams may be designed using international guidelines.
(b) Reservoirs, Dams and their Spillways
Reservoirs
A reservoir is required when the minimum daily design flow at the intake site plus
any minimum compensation release requirement is less than the average
daily demand. It is a basin constructed in a valley of the stream. For storage of
water, weirs may be constructed if the difference is small but if the difference is
appreciable, an earthen dam, masonry, rock fill, concrete dam may be constructed
across the stream for storage
Site Selection
Site selection criteria have been defined in the pre-feasibility study and more
elaborated in feasibility study section. Therefore, the design section deploys
the information gathered from other studies of the project and are highlighted
below.
The site for an upstream or mainstream Reservoir and its Dam should be selected such that it may command the entire area without pumping. The following main features should be considered for the selection of a site of such an impounding reservoir:
(i) It should be on impermeable strata, i.e. permeability coefficient (k) should
be less than 10-7 m/sec.
(ii) A narrow opening in the valley should be selected to reduce the length of
the dam.
(iii) Objectionable salts and minerals soluble in water should be absent from the
reservoir site so that the water is of acceptable quality.
(iv) The land to be submerged should be relatively unoccupied and cheap, i.e.
involve least compensation and observe laws of environment conservation.
(v) The land should be free of marshy layers and vegetation which could affect
the colour, odour and taste of water.
(vi) The slopes of the basin should be steep so to reduce the surface area per
unit of volume in such a way that both undesirable shallow water and surface
evaporation can be minimized.
(vii) The valley of the stream in which the dam is to be constructed should be
rapidly widening upstream of the dam so that it may afford the greater
average volume per metre height and length of the dam.
(viii) The capacity of the reservoir should be such that it will ensure the total
demand of water for the town to be delivered continuously. The capacity
depends upon the climatic conditions of locality and the period of dry
weather.
(ix) The dam site should not be located over a fault line parallel to the stream
bed.
(x) The storage capacity in regions of dry climate, long droughts and infrequent
rains will be more than that of the regions of moist climate and of frequent
rains, and an initial estimate can be made using Hawksley’s rule.
D = 1600/√F ....................................................................... (9.11)
Where:
D = the number of days for which the supply is to be stored,
F = the mean annual rainfall of three consecutive dry years expressed in cm.
(xi) If the stream brings large quantities of silt, debris, etc., the storing capacity
will be reduced due to considerable accumulation. It should be taken into
account by providing extra storage (called dead storage) which is normally
1/4- 1/5 of the total storage. The actual amount of dead storage depends on
the silt load and design period adopted. As far as practicable, silting should
be controlled. The sediment analysis of the reservoir should be computed
based on the available information from the manual. Details of other design
steps are presented in Appendix K.
1.1.5.7 Boreholes
1.1.5.7.1 Groundwater Analysis
(a) Geology
Geological information is of great value to every hydrogeologist, as it indicates
the extent of water bearing layers and less pervious layers, both in a horizontal
and in vertical direction. A simplified geological map of Tanzania is shown in
Fig. 9.5, together with its key.
Hydrogeologically, rocks may be considered as falling into one of the two groups
as follows:
(i) Sedimentary rocks
These rocks are the result of eroded sediments from source rocks. Sedimentary
rocks are composed of silicate, carbonate and clay minerals. The rocks rarely
occur as single units and younger beds are usually laid down upon older ones.
However, the sequence may be disturbed or extensively folded and faulted.
The occurrence of groundwater in sedimentary formations is generally found in sandstones, carbonates and unconsolidated materials. The sandstone formations are rated as highly productive aquifers due to both their primary and secondary porosity and permeability. The Calcareous formations are also good aquifers due to solution process taking place at later stages (karstification). Unconsolidated formations are regarded as good aquifers due to both weathering and depositional processes resulting in the formation of sand dunes, alluvial fans, floodplains, buried river channels, etc.
(ii) Igneous and metamorphic rocks
Igneous rocks may be classified into two types: extrusive and intrusive. In extrusive
rocks (volcanic) such as tuff, andesite, basalt, etc., water occurs in fractures and
pyroclastic materials. The intrusive and metamorphic rocks termed as hard rocks
are mainly granites and gneisses, respectively. They are solid and non-porous but
can hold water in networks of cracks, joints, fractures or faults or along contacts
between rocks of various types, as in the case of dikes and sills.
Fine grained igneous rocks, e.g. aplites can be good aquifers because they have short and narrowly spaced fractures. While coarse grained rocks like granites, have long and widely spaced fractures forming a mosaic of splinths. The storativity is reasonably good between the splinths. Basic intrusive rocks, e.g. diorites and gabbros have low and tend to be poor aquifers.
(b) Hydrogeological considerations
The water resources study of the hydro-geological conditions of the project area will
indicate the viable sites for well exploration in terms of supply capacity and
water quality. Hydro-geological studies should be conducted by knowledgeable
professionals or drillers, who assess available information on existing wells.
Professionals should examine well data such as
- water quality,
- well yield,
- seasonal fluctuations,
- water table depth, and
- well drilling logs showing geologic layers.
A geo-resistivity survey of the areas being considered for possible well sites will indicate the depth and thickness of aquifers.
Wells can be designed and constructed in a number of ways depending on the geological condition, budget for the construction and the desired capacity of the well. The following are the types of wells that can be identified based on the construction methods employed.
(i) Dug wells
Dug wells are holes or pits dug manually into the ground to tap the water table.
The dug well may be up to 15 meters deep, with diameter usually ranging from
1 meter to 1.5 meters. The well is usually lined with concrete masonry, bricks,
stones, or reinforced concrete to prevent the wall from caving in. At depths of the
aquifer layer, the wall is embedded with slots; or prefabricated concrete caisson
rings are installed for the passage of groundwater into the dug well. Dug wells
are normally circular in shape (Figure 9.6). This type of well is sometimes capable
of drawing sufficient supplies of water from shallow sources but is easily polluted
by surface water.
(ii) Driven wells
Driven wells are like dug wells, in the sense that they tap the shallow portion of the
unconfined aquifers (Figure 9.7). They are easy and relatively inexpensive to
construct in locations with unconsolidated formations that are relatively free
of cobbles or boulders. The wells are constructed by driving to the ground an
assembly of Galvanized Iron (G.I) pipe and a pointed metal tube called a “well
point”. The pointed end of the well point, which is the penetrating end, has
screens or holes to allow the passage of water.
(iii) Bored wells Bored wells are constructed with hand or power augers, usually into soft cohesive or non-caving formations that contain enough clay to support the boreholes. The depth of bored wells could be up to 15 metres. Bored wells are very prone to surface contamination. The well construction method is not applicable on hard consolidated materials and is not advisable on predominantly boulder formations. Figure 9.8 shows a properly bore well.
(iv) Deep drilled wells
Deep Wells drilled by professional drillers with the appropriate experience and
equipment can extract groundwater from a much deeper level than the other
types of wells. Various well drilling methods have been developed because
geological conditions range from hard rock such as granite and dolomite to
completely unconsolidated sediments such as alluvial sand and gravel. Particular
drilling methods have become dominant in certain areas because they are most
effective in penetrating the local aquifers, thus offer cost advantages.
1.1.5.8 Groundwater Prospecting
(a) Required data
Prior to carrying out hydrogeological and geophysical investigation a thorough
analysis of previous work should be carried out at the survey area. The activities
will include the use and interpretation of available data of the survey area.
Available data can be present in the form of maps, aerial photographs, satellite
imagery and drilled boreholes.
(i) Topographical maps
Topographical maps are used to show the physical features of the land.
(ii) Geological maps
This is an important tool normally used to give in some representative vertical
sections an indication about the lithology of the layers present. It is of great help
for the hydrogeological investigation.
(iii) Hydrogeological maps
These maps should show all the hydrogeological features of the area concerned.
(iv) Archived Satellite Imagery
Archived satellite imagery, much of which is increasingly available at little or no
cost is another important source of useful information. There are other maps
such as Soil Maps, Aerial Photographs as well as some others with special features
which may give valuable hydrogeological information.
Other data
(v) Water quality data
Information regarding the quality of the groundwater should be collected.
(vi) Data on different hydrological parameters
Records on discharges of rivers and streams, others on meteorological data such
as rainfall, evaporation, etc., as far as they could be of help for the hydrogeological
investigations envisaged, should be collected.
(vii) Information on wells and springs
Information about any previous drilled boreholes is of great help in knowing
groundwater potential areas. Also springs in the area should be measured and
the records be kept in an archive.
(viii) Data on borings
Information about the composition of the ground and water obtained from
samples taken from a borehole should be collected.
(b) Reconnaissance survey
The hydrogeologists should check geological structures and extent of the
catchment areas. These evidences are the key elements focus on while selecting
the best site recommended for drilling.
(i) Geological survey
Geological survey aims at identifying the visible surface geology of the area and
its surrounding, including identification of topography, physical features, soil
type, vegetation and drainage, rock outcrops, strike/dip of rocks etc. Geological
survey helps to provide a model of historical development of an area with respect
to geological time.
(ii) Hydrogeological survey
Generally, the occurrence of groundwater in hard rocks i.e. igneous and
metamorphic formation is largely limited to secondary features such as fractured
/ weathered/shear zones or faults. The potentiality of weathered zones depends
on the degree and depth of saturation and associated fracturing are normally
the groundwater controls. Recharge in this formation is by rain water infiltration
through the superficial formation, shear or weathered rocks and fractures.
Shear/ weathered or fractured zones are the expected aquifer points in the
surveyed area.
(c) Geophysical methods
Geophysical surveys are a relatively cheaper and faster way in groundwater
investigation compared to drilling of exploratory wells. This is the reason why
geophysical surveys are applied in the preliminary stages of investigations.
However, geophysical surveys require specialized professionals (Geophysists
or Hydrogeologists) to execute the surveys and to interpret the results. Several
methods are used in hydrogeology depending on the geological formation as
described below:
(i) Geo-electrical resistivity soundings
With the resistivity method normally an electrical current, generated by an artificial
source, is sent through the ground by means of two current electrodes at the land
surface. The resulting electrical potentials are measured with two other electrodes,
also at the land surface. Since rock types have different electrical properties
depending on their density, pore fluids, porosity etc., the strength of the current
applied gives a measure of the apparent resistivity of the rock. By varying the
distances between either the current electrodes (Schlumberger arrangement,), or
both types of electrodes (Wenner arrangement) apparent resistivity at different
depths and layer thicknesses are obtained. The wider the spacing distance, the
deeper the layers involved in transmitting the electrical current.
The major advantage with the resistivity method as far as ground water
investigations are concerned is that it gives direct indications of the presence of
water as resistivity is a function of water content of the rocks. Other geophysical
methods tend to provide indirect indications.
(ii) Electromagnetic (EM) methods
This method is cheap and fast, as it does not involve extended walking with
electrodes as for the case of resistivity. The methods rely on the measurement of
secondary magnetic fields generated by conducting bodies in the ground when
subjected to primary signal. The principle is that a time varying low frequency
electromagnetic field is generated by a transmitter at the land surface, which
later is transformed by an electrical conductor underground. The method is
useful in detecting buried conducting bodies such as fractured fault zones, dikes
etc. This method may also be used in detecting polluted groundwater or, fresh
water/brackish water interface.
(iii) Magnetic method
Magnetc profiling is used to measure the variation of the total magnetic field in
relation to geology along the profiles. The magnetic field of fractures/features,
dykes system and deeply weathered zone differs considerably from surrounding
rocks. The changes are increase or decrease in the normal field of the area.
(iv) Seismic methods
The method has limited direct use in groundwater exploration. However, it is
useful in determining the depth to the bed rock. The methods makes use of the
elastic property of rocks. The seismic waves are generated on the ground by
explosion or any other instantaneous release of energy into the earth.
1.1.5.8.1 Drilling
After the survey, the drilling work in areas that look promising follows. It is the duty of the hydrogeologist to supervise all drilling activities and provide technical advice in the course of drilling. Another responsibility is the analysis of rock cuttings, identification of the productive zones and recommending the borehole depth. During drilling, drillers must keep a detailed log of the drill cuttings obtained from the advancing borehole. In addition, after the drilling has been completed but before the well is installed, it is often desirable to obtain more detailed data on the subsurface geology by taking geophysical measurements in the borehole.
(a) Drilling Methods
There are several different types of rigs available for drilling water boreholes.
They vary in size, capacity and capability depending on the type of formation
expected and the depth required. There are rigs which do not perform well in
hard rock formations and there are those that are multipurpose. Percussion and
rotary-percussion drilling methods are generally the most applicable techniques
for drilling in igneous and metamorphic rocks. If a significant thickness of granular
or other overburden materials is present, a combination of methods can be
effective, although not very practical. Cable-tool, hydraulic-rotary percussion and
air-rotary percussion (down-the-hole air hammer) and foam drilling modifications
are the most common types of equipment in use today for such rock types
(Referred to web: resvol.design).
(b) Borehole Logging
(i) Rock sampling
Rock cuttings are collected, normally at a 2 meters interval while drilling is in
progress and a proper borehole log is kept. The samples are analysed to identify
the water bearing zones, and the driller keeps a record of penetration rate to
assist in identifying the hard formations and their thickness as well as recording
the water struck levels.
(ii) Down-hole logging
For accurate description of the penetrated strata, application of geophysical
logging methods assist in the determination of thickness of formations, the zones
of highest porosity and water quality.
1.1.5.8.2 Siting of Well/Borehole
The borehole siting methodology should be adjusted to the hydrogeological conditions and the local experience and should be done by an experienced hydrogeologist. It should include the following steps:
- Identification of fracture zone on aerial photographs, satellite images and maps;
- Identification of fracture zones in the field using resistivity profiling, Electrical profiling, and
- Vertical Electrical Sounding (VES).
1.1.5.8.3 Well Design
Well design is done in two stages, the preliminary design and the final well design.
Designing consists primarily of deciding the well depth, casing diameter, screen
type and slot size and its position in the well. Once the well site is determined,
a preliminary well design is prepared by an experienced hydrogeologist or
driller based on hydro-geologic information gathered before the drilling. This
preliminary design is the basis of the well drilling contract and the cost estimates.
During the drilling period, the preliminary well design will be adjusted based on
actual observations and findings on the specific site. This adjusted design will
then become the final well design. During this stage, the design assumptions
used are verified and become actual design parameters, such as water table
level, drawdown, depth and thickness of the geologic layers, types of material of
each geologic layer encountered, and other relevant information.
The main objective of the design is to construct a well that:
(a) Is structurally stable;
(b) Is able to extract groundwater at the desired volume and quality;
(c) Has the proper and correctly placed screens or slots to tap the productive
aquifers as well as to allow effortless flow of ground water into the well;
(d) Has enough space to house pumps;
(e) Has appropriate gravel packing that minimizes entry of sediments and sand
particles.
1.1.5.9 Structures for Rainwater Harvesting
1.1.5.9.1 Roof Catchment
Following details are available:
Catchment: Rooftop
Area of the catchment (A) = 100 sq. m.
Average annual rainfall (R) = 611 mm (0.61 m)
Runoff coefficient (K) = 0.85
Family size = 5
Per capita household water requirement = 25 litre/person/day
a) Calculate the maximum amount of rainfall that can be harvested from the
rooftop:
Annual water harvesting potential, S = 0.85 x 100 x 0.61 = 51 cu. m (51,000 litres)
b) Determine the tank capacity: This is based on the dry period, i.e., the period
between the two consecutive rainy seasons. For example, with a rain period
extending over four months, the dry season is of 245 days.
c) Calculate drinking water requirement for the family for the dry season,
C = 5 x 25 x 245 = 30,625 litres
As a safety factor, the tank should be built 20 per cent larger than required,
i.e., 36,750 litres. This tank can meet the basic drinking water requirement of a
5-member family for the dry period. A typical size of a rectangular tank constructed
in the basement will be about 5.0 m x 5.0 m x 1.5 m.
Note that in this case the analysis of the water availability/harvested against
satisfaction of the demand need to be done. Alternatively, other detailed analysis
such as the cumulative mass curve should be carried out for storage determination.
Figure 9.21 shows a typical rooftop water harvesting configuration.
Storage tanks should be located as close to supply and demand points as possible and should be protected from direct sunlight. Storage tanks can be elevated, on the ground or underground. They can be made of plastic materials, concrete or galvanised steel. Configuration depends on the size of the tank. For large catchment, underground tanks fitted with a pump to draw water to elevated distribution tank are preferable. Underground tanks can be rectangular or cylindrical, reinforced or plain concrete. Overflow pipes must be installed in the top of the tank to allow the safe disposal of excess rainwater. The size of the overflow pipe should be the same as that of the inlet pipe, with mesh at the bottom to prevent rats, squirrels, cockroaches, and other pests from entering.
The most common materials for gutters and downspouts are half-round PVC, vinyl, pipe, seamless aluminium, and galvanized, steel. Regardless of material, other necessary components in addition to horizontal gutters are drop outlets, which route water from the gutters downward, and at least two 45-degree elbows, which allow the downspout pipe to sit snugly against the side of the house. Additional components include the hardware, brackets, and straps to fasten the gutters and downspout to the fascia and the wall. First flush system separates first rainwater contaminants namely debris, dirt, and dust that collect on roofs during dry periods and prevent it from entering the storage tank.
1.1.5.9.2 Surface Runoff Harvesting
Surface runoff water harvesting is the collection, accumulation, treatment or purification, and storing of storm water for its eventual reuse. It can also include other catchment areas from man-made surfaces, such as roads, or other urban environments such as parks, gardens and playing fields. The harvested surface runoff water is an excellent alternative to replace treated water for use in other purposes. If properly designed, surface runoff catchment systems can collect large quantities of rainwater.
1.1.5.10 Treatment of Harvested Rainwater
Effective and reliable water treatment is essential in protecting public health and promoting consumers’ confidence in the water they receive. Rainwater collection systems had historically been thought to provide safe drinking water without treatment, because its collection surfaces (roofs) are isolated from typical contamination sources (e.g. soil materials, rocks and sanitation systems). However, contamination of waters from such sources may originate from materials used to manufacture the roofing sheets and drainpipes (gutters). Other sources of contaminants may include domestic and industrial dust, leaves and other debris blown onto roofs. In addition, birds and climbing animals defecate upon such roofs and gutters presenting risks associated with bacteriological and metal contamination.
These are among the potential sources of rainwater contaminants and thus
preventing them from entering the storage tanks can significantly enhance the
quality of rainwater collected. The reduction of contaminants in rainwater tanks
may be brought about through different ways including:
(a) Takinginto consideration several environmental conditions to improve
rainwater quality, such as proper design, operation, and periodic maintenance
of collection systems,cleanliness of the catchment area and water storage
tank, and protection of collection systems from pollutants,
(b) Discarding the first spill of rain (for at least 15 minutes) before collecting the
water,
(c) Installation of screeners in drainpipe inlets or gutters,
(d) Avoiding roof painting with materials likely to present health risks,
(e) Adopting closed tanks option rather than open tanks which are prone to
contamination emanating from atmospheric deposition,
(f) Disinfecting the harvested rainwater with appropriate water disinfectants
such as chlorine.
1.1.5.11 Water Points and Service Connections
To achieve the Water Sector Sustainable Development Goals (SDGs), Water Points (WPs), or community taps, are essential components of any new or expanded water supply schemes. In peri - urban or informal urban housing areas, this predominant service should as far as possible be water points. In rural areas the decision on whether to install a community tap or water point (WP) should be taken by the community but only after they have been fully informed on what this means. In either case, water should be charged for on some volumetric basis. Individuals who wish to have yard or in-house connection should be allowed in return for higher payment.
Because WPs play a key role in the supply of water in rural areas and to the urban poor and will continue to do so for many years to come, the most appropriate guidelines should not, therefore, be rigidly followed but should be used as a basis from which designers can start.
Regardless of the detail, involving the community in finding proper sites for the water points has proven to be an efficient way to improve psychological ownership, prevent vandalism and make treated water accessible. As the design of water point is vital for its sustainability; therefore, it has to be well adapted to the local context and the requirements of operators and customers. The water point design has also a significant implication on the required funds for construction. The user community should be consulted before deciding on where to locate WPs. Use of the criteria of time to walk to WPs should be adopted with an indicative time of 30 minutes (maximum).
1.1.5.12 Common Types of Water Points
- Water taps
- Public standpipe with super structure/kiosk
- Public standpipe without superstructure but has a simple shade with one or two tap points
1.1.5.13 Minimum Technical Requirements of Water Points
The utilities must ensure that the following minimum requirement for technical
aspects must be adhered to in order to guarantee the ergonomic and hygienic
aspects of water supply outlets as well as their user-friendliness in terms of
the movements and practices of outlet users (and of women and children in
particular) and operators:
(a) No one should have to carry the water for more than 20 m in an urban area
and 400 m in rural areas whilst the time spent on collecting water should not
exceed 30 minutes elsewhere in Tanzania,
(b) Users should be able to fill their container safely,
(c) For water points with long operating hours, a shade, roof or shelter for sun
protection should be provided;
(d) A solid slab should be installed to ensure a hygienic and safe water collection
(e) Sufficient slope to allow natural drainage and efficient cleaning;
(f) An elevated fetching bucket bay as lifting aid;
(g) A soak away into the ground should be provided at the water point site to
ensure that the water point site is adequately drained;
(h) A water meter for an accurate measurement of the water delivered and sold
at the water point site
(i) High quality water taps to be used
(j) Where water is only available intermittently or supply pressures are low,
provision of storage should be considered.
1.1.5.14 Criteria for the Design of Water Point/Kiosks
(a) Water point should be designed for a water consumption of 25 l/p/d,
(b) Design periods to be adopted: short term - 5 years; medium term - 10 years,
(c) Satisfactory pressure at the WP/water points should be provided for: The
minimum static head should be not less than 6m and the maximum 25m.
The flow from each tap at a WP should not be less than 10 l/min, and where
appropriate, a constant flow valve should be installed,
(d) A single WP/Water point should in general not supply more than 40-50
households, or 200 to 250 persons, which number is likely to be the minimum
if the supply is to be financially viable for an operator or a community,
(e) The water quality must comply with the latest edition of Tanzanian Standards
(TBS) and contamination at the source should be avoided,
(f) Acceptability: The design of the water point should be user friendly and
according to the minimum technical standards specified in Figures 5.4, 5.5
and 5.6,
(g) Water points structures (pre-paid taps, yard taps, etc.) should be designed to
be vandalism proof, e.g. by putting a concrete slab on top of the iron roofing
sheets or even a concrete roof,
(h) Water at the source should be provided in sufficient quantity and the supply
should be regular and continuous,
(i) Design of a water point should take into a consideration upgrading to yard
and house connection later,
(j) Design should consider the most appropriate technology, which can serve a
high number of poor people in urban settlements at low per capita cost and
takes shorter time to construct,
(k) Potential users should participate in planning and designing of the water
source and access to information must be guaranteed,
(l) A water point with a superstructure is often a more convenient place to
fetch water since it is more hygienic; gender sensitive and allows customers
to interact at the water point.
1.1.5.15 Location Considerations for Water Points
(a) The water points should be accessible to all users. It is easier to guarantee
free and non-discriminatory access to water points for all customers if the
water points are placed on public land, such as a municipal land or on a
land that belongs to a water utility. Private landowners are potentially in a
position to deny access to water points which are placed on their premises,
(b) Public participation in decisions about a water point location is an important
requirement. Potential water point customers know their own surrounding
areas best and can easily locate appropriate water point sites. This, in turn,
will develop a sense of ownership for the water point,
(c) The placement of WPs must take the preferences of the operator or attendant
and of future customers into account, as well as the technical and commercial
constraints and objectives identified by the designer. In other words, a water
point should be placed in such a way that it can serve a maximum number
of customers in an efficient and customer friendly manner,
(d) The location of water points in relation to one another should ensure
adequate coverage,
(e) Water points shall be constructed on public places or private owned land
with written permission from the landowner, witnessed by the LGA (Street
Leadership),
(f) The water point should be located strategically starting with densely
populated areas to less populated areas,
(g) Notwithstanding criteria (a) to (f), the location of a water point should be
confirmed by the communities to be served through their Government,
(h) The potential beneficiaries of water point services should be involved in the
selection of the water point location. If the location is not conducive to its
customers, they might consider other sources and thus abandon the water
point.
1.1.5.16 Technical Tips to Improve Water Points
The following are practical tips concerning the design and construction of water points:
- The soak-away: This should have a pit filled with stones to avoid breeding of infectious insects. Also, the drains should have a slope that allows for regular cleaning and unblocking,
- Paintwork: Only washable paints should be used; for the exterior and the interior walls of the water point,
- The water meter: The water meter should be placed inside the water point. A vertical meter should be installed vertically and a horizontal meter horizontally,
- Door, window and locks: it is important that water point doors and windows(and frames) are made of steel; strong enough to withstand vandalism or attempts of theft. Water point windows should be installed in such a way that if they are fully opened, they are parallel to the front wall of the water point. This allows for the full use of the lifting slabs,
- Cement works: It is important that the Utility’s supervisor is present during the mixing of cement.
- This is important in order to have the right mix and to prevent “sandy water points”,
- Making the roof water-proof: In order to make the roof water proof, it should be tarred with a sufficient quantity of Roof Compound. Experience shows that many water point roofs are often leaking,
- Quality Water taps: Only high quality taps and valves should be used. Do not forget that a water point tap is used hundreds of times each day. The quality requirements of a water point tap, therefore, are much higher than of a normal domestic tap,
- The siting of WPs: should be so that the area can be kept clean with minimum effort and there must be sufficient scope for natural drainage of wastewater. Where cloth washing slab is provided this should be not more than 20 metres from the water point,
- Water taps: Install the high water taps to avoid wastage of water caused by leaking taps and unhygienic conditions around the water point surroundings,
- The operator: or attendant should be made responsible for keeping the area clean and drained without altering any stagnant water pools,
- A charge: should be made for the supply of water from a WP. This should preferably be based on a coin still in wide circulation per container of 20 litres (e.g. 50/- or 100/-),
- In urban areas: the operator should be selected or appointed by the household representatives and the street executive officer. In urban areas,the supply is best provided through a formal structure/water point, and the operator should be encouraged to sell other non-contaminant dry goods items both to augment income and extend operating hours.
1.1.6 STRUCTURAL DESIGN OF CONCRETE
1.1.6.1 Structural Requirements
Concrete members used in water structures range from walls, slabs, roofs and floors. Design of Reinforced Concrete (RC) should ensure these structures have sufficient resistance to cracking, adequate strength and does not allow leakage.
1.1.6.2 Methods
Three methods or approaches are available for structural design of concrete, these are listed below:
1.1.6.2.1 Working Stress Method
- Produces uneconomical section,
- Produces stable section
1.1.6.2.2 Ultimate Load Method
- Produces cheaper section,
- Produces unstable section.
1.1.6.2.3 Limit State Method
- Produces economical section,
- Produces stable section.
Detailed design steps for concrete structures are presented in Appendix D to this manual.
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BS 8110 (1997): Structural Use of concrete, Part1: Code of Practice for design and
construction, British Standards Institution, London 1997.
Harter, T. (2016 (University of California, Davis) Retrieved from UC Groundwater
Cooperative Extension Program Web Site: http://groundwater.ucdavis.edu
Manual for Rooftop Rainwater Harvesting Systems in the Republic of Yemen. November,
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Nibedita Sahoo (2008): Design of Water Tank, National Institute of Technology Rourkela,
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Conference (pp. 390-400). Springer, Cham
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