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3. System Components and Design Considerations

3. System Components and Design Considerations. RWH System Components.  Catchment Area/Roof - the surface upon which the rain falls  Gutters and Downpipes - the transport channels from catchment surface to storage  Leaf Screens and Roofwashers

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3. System Components and Design Considerations

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  1. 3. System Components and Design Considerations

  2. RWH System Components Catchment Area/Roof - the surface upon which the rain falls Gutters and Downpipes - the transport channels from catchment surface to storage Leaf Screens and Roofwashers - the systems that remove contaminants and debris Cisterns or Storage Tanks - where collected rainwater is stored  Conveying - the delivery system for the treated rainwater, either by gravity or pump Water Treatment - filters and equipment, and additives to settle, filter, and disinfect

  3. Design considerations for rooftop catchment systems (1)  The material of the catchment surfaces must be non-toxic and not contain substances which impair water quality.  Roof surfaces should be smooth, hard and dense since they are easy to clean and are less likely to be damaged and shed materials into water  Precautions are required to prevent the entry of contaminants into the storage tanks. - No overhanging tree should be left near the roof - The nesting of the birds on the roof should be prevented - A first flush bypass such as detachable downpipe should be installed

  4. Design considerations for rooftop catchment systems (2)  All gutter ends should be fitted with a wire mesh screen to keep out leaves, etc.  The storage tank should have a tight-fitting roof that excludes light, a manhole cover and a flushing pipe at the base of the tank.  The design of the tank should allow for thorough scrubbing of the inner walls and floor or tank bottom. A sloped bottom and a provision of a sump and a drain are useful for collection and discharge of settled grit and sediment.  Taps/faucets should be installed at 10 cm above the base of the tank as this allows any derbis entering the tank to settle on the bottom where it remains undisturbed, will not affect the quality of water.

  5. Factors affecting RWH system design  Rainfall quantity (mm/year)  Rainfall pattern  Collection surface area (m2)  Runoff coefficient of collection (-)  Storage capacity (m3)  Daily consumption rate (litres/capita /day)  Number of users  Cost  Alternative water sources

  6. Feasibility of Rainwater Harvesting  The technical feasibility of roof RWH as a primary source of water is determined by the potential of a rainwater to meet the demand more effectively than other alternatives.  Often the attraction of RWH may be as a supplementary water source to reduce the pressure on a finite primary source or as a backup during the time of drought or breakdown.  The total amount of water that is received in the form of rainfall over an area is called the rainwater endowment of that area.  The collection efficiency accounts for the fact that all the rainwater falling over an area cannot be effectively harvested.

  7. Feasibility of Rainwater Harvesting  The size of supply of rainwater depends on the amount of rainfall (R), the area of the catchment (A) and its runoff coefficient (C).  An estimate of mean annual runoff from a given catchment can be obtained using the equation: S = R * A * C Where S = Rainwater supply per annum R = mean annual rainfall A = Area of the catchment C = Runoff coefficient  The actual amount of rainwater supplied will ultimately depend on the volume of the storage tank or reservoir.

  8. Catchment Area Size  The size of roof catchment is the projected area of the roof or the building’s footprint under the roof.  To calculate the catchment area (A), multiply the length (L) and width (B) of the guttered area. It is not necessary to measure the sloping edge of the roof.  Note that it does not matter whether the roof is flat or peaked. It is the “footprint” of the roof drip line that matters.

  9. Characteristics of Roof Types Source: http://www.eng.warwick.ac.uk/dtu/rwh/components2.html

  10. Example 1: For a building with a flat roof of size 10 m x 12 m in a city with the average annual rainfall of 800 mm Roof Area (A) = 10 x 12 = 120 m2 Average annual rainfall (R) = 800 mm = 0.80 m Total annual volume of rainfall over the roof = A * R = 120 m2 x 0.80 m = 96 m3 = 96,000 litres If 70% of the total rainfall is effectively harvested, Volume of water harvested = 96,000 x 0.7 = 67,200 litres Average water availability = 67,200 / 365 ~ 184 litres/ day

  11. Storage System  There are several options available for the storage of rainwater. A variety of materials and different shapes of the vessels have been used.  In general, there can be two basic types of storage system: - Underground tank or storage vessel -Ground tank or storage vessel  The choice of the system will depend on several technical and economic considerations like, space availability, materials and skill available, costs of buying a new tank or construction on site, ground conditions, local traditions for water storage etc.

  12. Storage System  The storage tank is the most expensive part of any RWH system and the most appropriate capacity for any given locality is affected by its cost and amount of water it is able to supply.  In general, larger tanks are required in area with marked wet and dry seasons, while relatively small tanks may suffice in areas where rainfall is relatively evenly spread throughout the year.  Field experiences show that a universal ideal tank design does not exist. Local materials, skills and costs, personal preference and other external factors may favour one design over another.

  13. Requirements for Storage System  A solid secure cover to keep out insects, dirt and sunshine  A coarse inlet filter to catch leaves etc.  A overflow pipe  A manhole, sump and drain for cleaning  An extraction system that does not contaminate the water e.g. tap/pump  A soakaway to prevent split water forming puddles near the tank.  Additionally features - sediment trap or other foul flush mechanism - device to inside water level in the tank

  14. RWH Brick Jars - Uganda Source: Rees and Whitehead (2000), DTU, University of Warwick, UK

  15. Rainwater Harvesting - Kenya Source: John Gould (Waterlines, January 2000)

  16. Ferro-cement jar for rainwater collection - Uganda Source: DTU, University of Warwick (September 2000)

  17. Underground lime and bricks cistern

  18. Rainwater Harvesting – Sri Lanka

  19. http://www.greenhouse.gov.au/yourhome/technical/pdf/fs22.pdf

  20. A wooden water tank in Hawaii, USA Source: Rainwater Harvesting And Utilisation. An Environmentally Sound Approach for Sustainable Urban Water Management: An Introductory Guide for Decision-Makers. ITEC, UNEP, Japan

  21. http://www.arcsa-usa.org/

  22. Rainwater Tanks Source: http://www.greenhouse.gov.au

  23. Storage capacity  When using rainwater, it is important to recognize that the rainfall is not constant through out the year; therefore, planning the storage system with an adequate capacity is required for constant use of rainwater, even during the dry period.  Knowledge of the rainfall quantity and seasonality, the area of the catchment surface and volume of the storage tank, and quantity and period of use required for water supply purposes is critical.  There are two commonly used method to estimate storage requirements.

  24. Storage capacity Method 1 – Storage required for dry period  A rough estimate of the maximum storage requirement can be made based on the (i) per capita consumption (ii) no of users and (iii) length of the longest dry period  For a household with a 5 people, assuming water use of 20 lpcd and if longest dry period is 30 days and rainwater is the only water source, storage required = 5 x 20 x 30 = 3000 litres

  25. Storage capacity Method 1 – Storage required for dry period  This simple method assumes sufficient rainfall and catchment area which is adequate, and is therefore only applicable in areas where this is the situation.  It is a method for acquiring rough estimates of tank size.

  26. Storage capacity Method 2 – Based on rainfall and water demand pattern  A better estimate of storage requirement can be made using the mass curve technique based on rainfall and water demand pattern.  Cumulative rainfall runoff and cumulative water demand in year is calculated and plotted on the same curve.  The sum of the maximum differences, on the either side, between the rainfall curve and water demand curve gives the size of the storage required

  27. Storage capacity Example 2: Calculate the size of the storage tank required for a school with 65 students and 5 staff, assuming average water consumption of 5 litres/day. Roof area = 200 m2. Assume runoff coefficient of 0.9. The rainfall pattern in the area is given in the table below Average daily demand = 70 x 5 = 350 litres Yearly demand = 350 * 365 = 127750 litres = 127.75 m3 Average monthly demand = 127.75/12 ~ 10.65 m3

  28. Storage capacity calculations (a) Rainfall pattern - 1

  29. Calculation of required storage capacity (1) Required storage capacity = 29.4 m3 say 30 m3

  30. Mass curve for calculation of required storage capacity

  31. Mass curve for calculation of required storage capacity

  32. Storage capacity calculations (b) Rainfall pattern - 2

  33. Calculation of required storage capacity (2) Required storage capacity = 35.7 + 18.3 = 54 m3

  34. Gutters  Gutters are channels all around the edge of a sloping roof to collect and transport rainwater to the storage tank.  A carefully designed and constructed gutter system is essential for any roof catchment system to operate effectively.  When the gutters are too small considerable quantities of runoff may be lost due to overflow during storms.  The size of the gutter should be according to the flow during the highest intensity rain. It is advisable to make them 10 to 15 per cent oversize.

  35. Gutters (2)  A general rule of thumb is that 1 cm2 of guttering is required for every m2 of roof area.  Gutters can be semi-circular or rectangular and could be made using a variety of materials: - Locally available material such as plain galvanised iron sheet (20 to 22 gauge), folded to required shapes. - Semi-circular gutters of PVC material can be readily prepared by cutting those pipes into two equal semi-circular channels. - Bamboo or betel trunks cut vertically in half. - Wood or plastic

  36. Gutters (3)  Gutters need to be supported so they do not sag or fall off when loaded with water.  The way in which gutters are fixed depends on the construction of the house; - it is possible to fix iron or timber brackets into the walls, but for houses having wider eaves, some method of attachment to the rafters is necessary.  A properly fitted and maintained gutter-downpipe system is capable of diverting more than 80% of all runoff into the storage tank, the remainder being lost through evaporation, leakage, rain splash and overflow.

  37. Gutters - Shapes and Configurations Gutter configurations

  38. Gutters - Shapes and Configurations

  39. Gutters and Hangers

  40. Shade cloth guttering Source: Peter Morgan (1998) http://aquamor.tripod.com/RAINWATER.htm

  41. Plastic sheet guttering http://www.eng.warwick.ac.uk/DTU/pubs/wp/wp55/8gutter.html

  42. Gutter sizing Recommended gutter widths for use in humid tropics Source: (Still and Thomas, 2002)

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