UNDER THE GUIDANCE OF
Dr. B. Nagamalleswara RaoProfessor & Head
DESIGN AND IMPLEMENTATION OF ROOFTOP RAINWATER HARVESTING SYSTEM(RRHS)
FOR D-BLOCK OF VNRVJIET CAMPUS By• G.Sandhya Rani (10071A0174)
• J.Sai Kiran (10071A0176) • K.Sravan kumar (10071A0185)
Department of Civil Engineering VNR Vignana Jyothi Institute of Engineering &Technology,
Bachupally, Nizampet (S.O), Hyderabad-500090, AP
• B.Rani (11075A0117)• M.Mahesh (11075A0124)
CONTENTS
1. INTRODUCTION2. OBJECTIVES 3. LITERATURE REVIEW4. METHODOLOGY5. TIME SCHEDULE6. APPLICATIONS7. REFERENCES
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1.INTRODUCTION Water is the most common or major substance on earth, covering more than 70% of the planets surface. The total amount of water on earth remains constant.
The rapid growth in population together with industrial development, are putting stress on the natural ecosystems.
Water supply mainly depends on the natural water bodies likes lakes and artificial water bodies like reservoirs etc.
Due to the Urbanisation and rapid growth in the population many lakes has been lost and the majority of the present were polluted .
This results in the imbalance of demand and supply of water.
To overcome supply shortages, many households, businesses and industries fall back on groundwater reserves. The number of bore wells increased.
1.INTRODUCTION
This is leading to the fall in the ground water table.
One possible strategy could be the usage of rainwater in order to overcome the shortage of water.
Rain water harvesting means to make optimum use of rain water at the place where it falls i.e. conserve it and not allowing it to drain away.
The water can be used as drinking water, water for livestock, water for irrigation or to refill aquifers in a process called ground water recharge.
The rainwater falling on roof of residential buildings and institutions can be an important contribution to the availability of water.
Hydrological cycle
2.OBJECTIVES
Design of rain water harvesting system components.
Implementation of rain water harvesting system in D Block of
VNRVJIET campus
Cost benefit analysis
3. LITERATURE REVIEW
ANIL AGARWAL (2013): Manual on Urban Rainwater Harvesting “Catch Water Where it Falls”
KIRAN. A, NIKHIL. T, R HARISH, J KULKARNI (2012): Harvested Rain Water for Drinking- Research Paper.
ROHITASHW KUMAR, THAMAN S, AGRAWAL G. and SHARMA POONAM(2011): Rain Water Harvesting and Ground Water Recharging in North Western Himalayan Region for Sustainable Agricultural Productivity- Research Paper.
M. DINESH KUMAR, ANKIT PATEL(2005) : Rainwater Harvesting in the Water-scarce Regions of India potential and Pitfalls-Research paper
ACHAYRA, B. P. (2004). Managing Water Sector Institution - HMWSSB Experience (Presentation). Hyderabad Metropolitan Water Supply and Sewerage Board, Hyderabad.
SIVARAMAN , K.R. & THILLAI GOVINDARAJAN S.. (2003), Manual on Rainwater Harvesting. Chennai, Akash Ganga.
ARIYABANDU R. D. S. (2003). Very-Low-Cost Domestic Roof Water Harvesting in the Humid Tropics: Its Role in Water Policy. Sri Lanka Domestic Roofwater Harvesting Research Programme.
4. METHODOLOGY
Collection of the building data.
Collection of rainfall data of past 10 years.
Design of RWHS components
Implementation
COMPONENTS OF RWHS
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• Roof Catchment• Drain pipes• Down pipes• First Flush Pipe• Storage Tank• Recharge Pit
Drain Pipe
Storage tank
Down pipe
First Flush Pipe
DESIGN OF RWHS COMPONENTS
1.Roof catchment 2.Calculation of Volume of Runoff 3.Design of Rectangular Storage Tank 4.Design of Conduits 5.Design of Recharge Pit
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DESIGN OF RWHS1.Roof catchment: • The area of the roof from which the rain water is
collected.• The total roof area of D block = 2351 m2
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12ALL DIMENSIONS ARE IN MM
ROOF PLAN
DESIGN OF RWHS
Area of catchment = 2351 m2
Annual average rainfall = 887 mm = 0.887mRunoff co-efficient = 0.85
Volume of runoff = area of catchment x annual average rainfall x runoff co-efficient = 2351 x 0.887 x 0.85 = 1773 m3/yr
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2.Calculation of Volume of Runoff:
DESIGN OF RWHS
Average value of highest rainfall in rainy days = 94mm =0.094m
Volume of Runoff = 2351 x 0.094 x 0.85 = 188 m3/dayFor economical design considering half of the discharge
as volume of tankVolume of tank = 94 m3
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DESIGN OF RWHS
Assume depth of tank = 2mArea of tank = volume of the tank/depth = 94/2 = 47m2 = 50m2(approx.)Taking Length: Breadth ratio as 2:1 L = 2B 2B x B = 50 B = 5m L = 10m
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3.Design of Rectangular Storage Tank:
ALL DIMENSIONS ARE IN METERS
Storage Tank
EXISTING PIPE DETAILS
S.No Diameter(mm)
No of Pipes Length of Pipe(m)
1 110 4 22.00
2 110 2 21.77
3 140 1 21.34
4 150 1 21.40
5 150 1 21.37
6 150 1 14.64
7 150 1 11.00
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DESIGN OF RWHS
Taking diameter of pipe = 110mm = 0.11m Average value of highest rainfall in rainy days = 94mm =0.094m Taking number of pipes = 10 Volume of water that can be discharged through 10 pipes = 2351×0.094×0.85 = 188 m3/day Volume of water that can be discharged through each pipe = 188/10 = 18.8m3/day = 2.17×10-4 m3/sec
4.Design of Conduits:
DESIGN OF RWHS
The recharge pit is designed for one third of discharge Volume of recharge pit = 62m3
Assuming depth of recharge pit = 3m Area of the recharge pit = 62/3 = 20 m2
Taking Length: Breadth ratio as 2:1 L = 2B 2B x B = 20 B = 3.2m L = 6.4m
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5.Design of Recharge Pit:
ALL DIMENSIONS ARE IN MM
RAINFALL DATA
Jan Feb Mar Apr May June July Aug Sep Oct Nov Dec2003 0 10.7 11.7 27.3 0 65.5 265 144 54.9 168 0 0
2004 38.9 0.6 32.4 59 41.9 29.4 221 68.7 118.2 72.8 0.2 0
2005 39.7 10.3 18.7 24.8 21.8 88.9 369 115 220 221 0 0
2006 0 0 41.8 67.9 100 83.8 192 237 206 15.7 52.2 0
2007 0 0 0 23 11.5 113.3 92.8 214 266 18.1 21 0
2008 0 69.2 166 13.8 20.8 40.2 96 464 199 48 48 0
2009 0 0 2.1 23 17.3 69 55.5 353 145 69.6 28 4.4
2010 6.3 2.7 0 0.6 17.4 150.8 339 216 231 55.5 46.8 15.2
2011 0 25.2 1.7 6.9 1.7 35.6 185 234 76.9 70 8.4 0
2012 0.3 0 0 18.3 4.8 132 232 143 114 78.1 39.5 0
2013 0.3 17 0 74.5 10.2 203.2 197 124 155 239 14 0
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5.TIME SCHEDULE
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S.NO ACTIVITY DURATION DATES
RESCHEDULED DATES STATUS
1. LITERATURE REVIEW
6 WEEKS 23.09.2013 -
02.11.2013
23.09.2013 -
02.11.2013COMPLETED
2. DATA COLLECTION 4 WEEKS 04.11.2013 -
30.11.2013
04.11.2013 -
30.11.2013COMPLETED
3. DESIGNING 9 WEEKS 02.12.2013 -
03.02.2014
02.12.2013 -
03.02.2014COMPLETED
4. COST BENEFIT ANALYSIS AND
DOCUMENTATION
4 WEEKS 04.02.2014 -
04.03.2014
04.02.2014 -
31.03.2014UNDER
PROGRESS
5 IMPLEMENTATION 4 WEEKS 05.03.2014 1.04.2014 ONWARDS
WORKS TO BE COMPLETED
Estimation and Costing
Cost Benefit Analysis
Documentation
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6. APPLICATIONS To overcome the inadequacy of water to meet our
demands. To arrest decline in ground water levels. To increase availability of ground water at specific place
and time and utilize rainwater for sustainable development.
To increase infiltration of rainwater in the subsoil which has decreased drastically in urban areas.
To reduce the expenditure spent on water.
7. REFERENCES
ANIL AGARWAL (2013): Manual on Urban Rainwater Harvesting “Catch Water Where it Falls”
KIRAN. A, NIKHIL. T, R HARISH, J KULKARNI (2012): Harvested Rain Water for Drinking- Research Paper.
ROHITASHW KUMAR, THAMAN S, AGRAWAL G. and SHARMA POONAM(2011): Rain Water Harvesting and Ground Water Recharging in North Western Himalayan Region for Sustainable Agricultural Productivity- Research Paper.
RAMACHANDRAIAH, C. (2007). Hyderabad’s Water Issues and the Musi River, Need for Integrated Solutions. Draft version of the Paper presented in the International Water Confe-rence, Berlin during 12-14 September 2007.
ACHAYRA, B. P. (2004). Managing Water Sector Institution - HMWSSB Experience (Presen-tation). Hyderabad Metropolitan Water Supply and Sewerage Board, Hyderabad.
SIVARAMAN , K.R. & THILLAIGOVINDARAJAN S.. (2003), Manual on Rainwater Har-vesting. Chennai, Akash Ganga.
ARIYABANDU R. D. S. (2003). Very-Low-Cost Domestic Roof Water Harvesting in theHu-mid Tropics: Its Role in Water Policy.Sri Lanka Domestic Roofwater Harvesting Research Pro-gramme.
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THANK YOU