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INTRODUCTION
The proposed project is a housing complex located at Sector 108, Gurgaon developed by M/s Chintels India Limitedconsisting of multiple towers within a common project area, to be developed for the client.
Each tower holds a varying number of premium quality apartments, with all necessary services and infrastructural
facilities being provided as per international standards. Additional facilities such as clubhouse, swimming-pool etchas also been catered to.
1.1 LOCATION & CONNECTIVITY
LOCATION:
o Gurgaon is located at 2828N 7702E28.47N 77.03E/28.47; 77.03. It has an average elevationof 220 metres (721 ft) Gurgaon district, comprising four blocks Pataudi, Sohna, Gurgaon andFarrukhnagar, was created on 15 August, 1979.On its north, it is bounded by the district of Rohtak andthe Union Territory of Delhi. Faridabad district lies to its east. On its south, the district sharesboundaries with the district of Mewat. To its west lies the district of Rewari and the State of Rajasthan.
o Gurgaon is situated between the Himalayas and Aravalis mountain ranges. It is surrounded on threesides by Haryana and to the east, across the river Yamuna by Uttar Pradesh. Its greatest length isaround 13 miles and the greatest breadth is 17 miles. Delhi's altitude ranges between 213 to 305meters above sea level.
RAINFALL AND CLIMATE:
o Under the Kppen climate classification, Gurgaon experiences a monsoon-influenced humidsubtropical climate (Cwa). The city experiences four distinct seasons - spring, summer, autumn andwinter, along with the monsoon season setting in towards the latter half of the summer. Summers,from early April to mid October, are typically very hot and humid, with an average daily June hightemperature of 104 F (40 C). The season experiences heat indices easily breaking 110 F (43 C).Winters are very cold and foggy with few sunny days, and with a December daytime average of 37.4
F (3 C). The Western Disturbance brings some rain in winters that further adds to the chill. Springand autumn are mild and pleasant seasons with low humidity. The monsoon season usually starts inthe first week of July and continues till August. Thunderstorms are not uncommon during theMonsoon. The average annual rainfall is approximately 28.1 inches (714 mm).
Climate data for Gurgaon
Month Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Year
Average high F(C)
70
(21.1)
75.6
(24.2)
86
(30.0)
97.2
(36.2)
103.3
(39.6)
102.7
(39.3)
95.2
(35.1)
91.9
(33.3)
93
(33.9)
91.2
(32.9)
82.9
(28.3)
73.4
(23.0)
88.5
(31.4)
Average low F(C)
45.1
(7.3)
50.2
(10.1)
59.7
(15.4)
70.7
(21.5)
78.6
(25.9)
82.9
(28.3)
79.9
(26.6)
78.6
(25.9)
75.9
(24.4)
67.1
(19.5)
55
(12.8)
46.8
(8.2)
65.8
(18.8)
Rainfall inches(mm)
0.799
(20.3)
0.591
(15.0)
0.622
(15.8)
0.264
(6.7)
0.689
(17.5)
2.161
(54.9)
9.114
(231.5)
10.185
(258.7)
5.031
(127.8)
1.429
(36.3)
0.197
(5.0)
0.307
(7.8)
31.389
(797.3)
Avg . rainy days 1.7 1.3 1.2 0.9 1.4 3.6 10.0 11.3 5.4 1.6 0.1 0.6 39.1
Mean
monthly sunshine
hours
213.9 217.5 238.7 261.0 263.5 198.0 167.4 176.7 219.0 269.7 246.0 217.0 2,688.4
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1.2 PROJECT OBJECTIVES
The project objectives include energy efficiency, green eco friendly design, and centralized grouped location ofservices installation to ensure easy maintenance, state of the art technology, fast track installation and compliance toall statutory regulations. The services design shall conform to regulations laid down by various authorities.
1.3 SALIENT FEATURES OF THE PROJECT
Type of the Buildings -- Residential towers consisting of ResidentialApartments/Dwelling Units/Commercial etc
Max. height of Towers -- Category: Above 60 m in height
Categories as per NBC -- Group A - 4 (Residential Apartments)
1.4 LAND USE PATTERN
Total Area under group housing -- 39.375 Acres
Nos of unit & floor in tower
ATHENIA - Phase - 1
S. No. Description Nos. of Floors Nos. of Units
1 TOWER - ( L ) (S+22/18) -
( i ) 3 BED+SQ (RGLR) - 46
( ii ) 3 BED+SQ (S) - 38
2 TOWER - ( M ) (S+22/18) -
( i ) 3 BED+SQ (RGLR) - 46
( ii ) 3 BED+SQ (S) - 38
3 TOWER - ( N ) (S+22/18) -
( i ) 3 BED+SQ (RGLR) - 46
( ii ) 3 BED+SQ (S) - 38
4 TOWER - ( O ) (S+22/18) -
( i ) 3 BED+SQ (RGLR) - 46( ii ) 3 BED+SQ (S) - 38
5 TOWER - ( P ) (S+21/17) -
( i ) 4 BED+SQ (S) - 18
( ii ) 3 BED+SQ (DLX) - 44
6 TOWER - ( Q ) (S+21/17) -
( i ) 4 BED+SQ (S) - 18
( ii ) 3 BED+SQ (DLX) - 44
7 TOWER - ( R ) (S+21/17) -
( i ) 3 BED+SQ (RGLR) - 18
( ii ) 3 BED+SQ (S) - 44
8 TOWER - ( S ) (S+21) -( i ) 4 BED+SQ (RGLR) - 42
9 TOWER - ( T ) (S+18) -
( i ) 4 BED+SQ (DLX) - 36
( ii ) SERVANT - 36
10 TOWER - ( U ) (S+15) -
( i ) 4 BED+SQ (DLX) - 30
( ii ) SERVANT - 30
14 Club (G+1) 8000
15 Shopping (G+1) 3690
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S. No. Description Nos. of Floors Nos. of Units
1 EWS BLOCK -01 - 79
2 EWS BLOCK -02 - 79
3 EWS BLOCK -03 - 79
4 Nursery School -01 (G+2)
5 Nursery School -02 (G+2)6 Primary School (G+2)
AMBROSIA - Phase - 2
S. No. Description Nos. of Floors Nos. of Units
1 TOWER - ( A ) (S+15) -
( i ) 4 BED+SQ (DLX) - 30
( ii ) SERVANT - 30
2 TOWER - ( B ) (S+18) -
( i ) 4 BED+SQ (DLX) - 36
( ii ) SERVANT - 36
3 TOWER - ( C ) (S+21) -
( i ) 4 BED+SQ (RGLR) - 42
4 TOWER - ( D ) (S+21/17) -
( i ) 4 BED+SQ (S) - 18
( ii ) 3 BED+SQ (DLX) - 44
5 TOWER - ( E ) (S+21/17) -
( i ) 4 BED+SQ (S) - 18
( ii ) 3 BED+SQ (DLX) - 44
6 TOWER - ( F ) (S+21/17) -
( i ) 4 BED+SQ (S) - 18
( ii ) 3 BED+SQ (DLX) - 44
7 TOWER - ( G ) (S+22/18) -( i ) 3 BED+SQ (RGLR) - 46
( ii ) 3 BED+SQ (S) - 38
8 TOWER - ( H ) (S+22/18) -
( i ) 3 BED+SQ (RGLR) - 46
( ii ) 3 BED+SQ (S) - 38
9 TOWER - ( J ) (S+22/18) -
( i ) 3 BED+SQ (RGLR) - 46
( ii ) 3 BED+SQ (S) - 38
10 TOWER - ( K ) (S+22/18) -
( i ) 3 BED+SQ (RGLR) - 46
( ii ) 3 BED+SQ (S) - 3811 Club (G+1) 8000
12 Shopping (G+1) 3690
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OLYMPIA - Phase - 3
S. No. Description Nos. of Floors Nos. of Units
1 TOWER - ( V ) (C+S+27) -
( i ) 5 BED - 27
( ii ) SERVANT - 1
2 TOWER - ( W ) (C+S+30) -
( i ) 5 BED - 30( ii ) SERVANT - 1
3 TOWER - ( X ) (C+S+27) -
( i ) 5 BED - 27
( ii ) SERVANT - 1
4 Club (G+1) 9000
5 Shopping (G+1) 820
1.5 BROAD CONCEPT OF SERVICES
The Services Systems for the project have been conceptualized based on the acceptable design standards to
produce a concept which is an integrated whole. Effort shall be made to conceal all services and still provide accessto these for accommodating change in requirement in future. Conservation of energy, optimization of resources inthe design concept to ensure least downtime and reduce maintenance hassles.
Every effort shall be made to design, layout and install equipment in locations which will tend to encourage routinepreventive maintenance by providing easy access for operation personnel. Manual isolation shall be provided toenable servicing, expansion or renovation of any part of the system without interrupting the services in adjacentareas. The changes made by second agency prior to the consultants approval will be causing a redesign.
1.6 CODE & REGULATION
Plumbing/Sanitary systems will be designed and installed conforming to the following codes and standards:
Regulations of the local authority.
National Building Code (NBC) 2005.
Manual on water supply and treatments published by Central Public Health and EnvironmentEngineering Organization Ministry of Urban Development, Govt. of India.
Manual of sewerage and sewage treatment published by Central Public Health and EnvironmentEngineering Organization Ministry of Urban Development, Govt. of India.
Relevant BIS Codes.
Good Engineering Practice.
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WATER SUPPLY SYSTEM
2.1 REFERENCE STANDARDS
2.1.1 National Building Code of India 2005
2.1.2 Code & Design Guidelines :
i. American Society of Plumbing Engineers(ASPE) Design Data Book Volume I to IV
ii. Institute of Plumbing Engineers UK Design Data Book 2002
iii. International Plumbing Code 2003 Edition
iv. Uniform Plumbing Code
2.2 DESIGN BRIEF
2.2.1 BASE OF DESIGN
The Plumbing services for the project shall be designed keeping in view the following:
i) Requirement of adequate and equal pressure of cold water in apartment toilets, public toilets, club,kitchens and other designated areas. Cold water makeup supply to swimming pool & water bodies shallbe ensured.
ii) Adequate storage of raw water/domestic water in underground water tanks (for one day requirement)for both North Zone as well as South Zone. Further static water storage for firefighting requirement shallalso be provided based on NBC requirements and as required by local Chief Fire Officer. Separateunderground fire tanks & fire pumps shall be provided as per local fire officers requirement.
iii) Swimming pool recirculation and filtration system.
iv) Recycling of treated waste water (from sewage treatment plant) for flushing, Cooling Tower makeupand for irrigation water use.
v) Levels of roads/pavements and other services in the area.
vi) Landscape layout.
vii) Soil Investigation report.
2.2.2 CONCEPT OF THE SYSTEM
The following Plumbing Services are envisaged:
i Water treatment plant (WTP) to ensure that the chemical and bacteriological parameters of watersupply in the complex are in accordance with IS:10500 standards. Water shall be available fromHUDA/Tanker water supplier only. WTP system design shall be verified for suitability after obtainingwater analysis report from the above two sources.
ii Sewage and sullage collection system based on applicable guidelines by NBC.
iii Storm/rain water drainage system from the roof terrace and various levels of the buildings, includingbalcony drains, planter drains and fountain drains by means of draining rain water and surface run-offwater to rain water recharge pits, with overflow connection to existing HUDA storm water drains.
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iv Hot water system comprising of high pressure electrical operated hot water geyser to cater for hot waterrequirement of Apartments toilets & kitchen.
iii. Swimming pool recirculation & filtration system complete with balancing tank, pumps, filters, dosingsystem and other accessories.
2.3 Calculat ions for Dai ly Water Requirement
Phase - 1ATHENIA
S. No. Description Total Water Requirements in LPD
I. DOMESTIC & FLUSHING
(i) Domestic water requirement @ 65% 317012.00
(ii) Flushing water requirement @ 35% 170699.00
Total 487711.00
Say 500 m3/day
II. WATERBODY & SWIMMINGPOOL MAKEUPL.S. 15000
Say 15 m3/day
III. HORTICULTURAL / ROAD WASHING
L.S. 105000
Say 105 m3/day
IV. FILTER BACK WASH
L.S. 28000
Say 30 m3/day
TOTAL WATER REQUIREMENTS FOR ALL PURPOSES 650 m3/day
EWS, Nursery School & Primary School
S. No. Description Total Water Requirements in LPD
I. DOMESTIC & FLUSHING
(i) Domestic water requirement @ 65% 150720.00
(ii) Flushing water requirement @ 35% 56926.00
Total 207646.00
Say 210 m3/dayII. WATERBODY & SWIMMINGPOOL MAKEUP
L.S. 5000
Say 5 m3/dayIII. HORTICULTURAL / ROAD WASHING
L.S. 43750
Say 45 m3/day
IV. FILTER BACK WASH
L.S. 8500
Say 10 m3/day
TOTAL WATER REQUIREMENTS FOR ALL PURPOSES 270 m3/day
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AMBROSIA - Phase - 2
S. No. Description Total Water Requirements in LPD
I. DOMESTIC & FLUSHING
(i) Domestic water requirement @ 65% 312303.00
(ii) Flushing water requirement @ 35% 168163.00
Total 480466.00
Say 480 m3/day
II. WATERBODY & SWIMMINGPOOL MAKEUP
L.S. 15000
Say 15 m3/day
III. HORTICULTURAL / ROAD WASHING
L.S. 132500
Say 135 m3/day
IV. FILTER BACK WASH
L.S. 28000
Say 30 m3/day
TOTAL WATER REQUIREMENTS FOR ALL PURPOSES 660 m3/day
OLYMPIA - Phase - 3
S. No. Description Total Water Requirements in LPD
I. DOMESTIC & FLUSHING
(i) Domestic water requirement @ 65% 89128.00
(ii) Flushing water requirement @ 35% 47992.00
Total 137120.00
Say 140 m3/day
II. WATERBODY & SWIMMINGPOOL MAKEUP
L.S. 15000
Say 15 m3/day
III. HORTICULTURAL / ROAD WASHING
L.S. 40000
Say 40 m3/day
IV. FILTER BACK WASHL.S. 7500
Say 10 m3/day
TOTAL WATER REQUIREMENTS FOR ALL PURPOSES 205 m3/day
2.4 Source
Water will be sourced from the following source:-
o Municipal Supplyo Tanker
The clients may need to furnish information with regard to the availability of water from all the abovetwo sources.
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2.5 Water Treatment System
In order to decide the exact treatment to be adopted, it is essential to know the chemical composition of raw
water as per IS 10500. Efforts should be made by the clients to get the water samples tested from all the
possible sources. If there is no tube well existing at site, sample may be taken from some other tube well
existing in the vicinity of the site.
In general practice following water treatment system will be adopted.
The water from the source will be brought into the underground fire static tank to overflow into the raw
water tank. Water from this tank shall be treated in the water treatment plant, consisting of
chlorination, filtration (DMF - Dual Media Filter) and optional softening units, located in the plant room.
Domestic water shall be supplied after chlorination and filtration. A certain amount of water may also
be softened and blended with the domestic water to reduce the water hardness to permissible levels.
The domestic water shall be stored in the domestic water tank. Municipal connection shall be directly
brought into the domestic water tank.
2.6 Pumping, Overhead Storage & Distribution System
2.6.1 Domestic Water
For pumping and distribution of domestic water to tower, the gravity system is being proposed. The
domestic water from underground domestic water tank shall be transmitted via variable speed
pumping system to all the overhead tanks located at terrace levels of each tower depending upon
heights, and from there the water shall be supplied by gravity to all user points. The system shall be
designed to take care of peak demand of water and a residual pressure at the ground floor users point
shall be minimum 1.5 kg/cm2. Since the pressure in the lower floors shall be high, pressure reducing
valves shall be provided to maintain reasonable pressure. The low rise building club/nursery school
will be feed thru extended by the gravity line from nearby towers with pressure reducing station at
ground floor level or separate pumping system as per requirement. The top four floors will have
separate hydro pneumatic pumping system. (Min 1.5 kg/cm2
)
Each tower shall have an OH tank (Domestic) as per requirement.
Water supply system will be completely automatic through mechanically operated valve with level
controller. The ON/OFF operation of the motorized valve will get signal from level controller placed in
domestic water tank.
2.6.2 Flushing Water
Since the recycled water from STP is to be used for flushing, an independent system of pumps, pipes
and overhead tank in each tower shall be provided. This water shall be used only for flushing and
ablution taps/health faucets shall be connected to domestic water.
Similar pumping system is proposed for flushing water system as described in Domestic water
system.
Each tower shall have an OH tank (Flushing) as per requirement & mechanically operated valve with
level controller. The ON/OFF operation of the motorized valve will get signal from level controller
placed in flushing water tank.
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2.6.3 Water for Irrigation/Horticulture/Road washing
Water to the garden hydrants shall be supplied through a separate garden hydrant pump, which shall
be supply water from treated sewage tank near STP. Another set of pump will be provided near raw
water tank in plant room for fill the treated sewage water tank whenever the sewage flow is low.
Operation of these pumps shall be manually operated system.
2.6.4 Soft water
Soft water shall be provided by separate soft water transfer pumps to the DG Cooling Towers, as perrequirements.
It is proposed to supply soft water from STP treated water tank.
It is proposed that all mechanical equipments shall have 100 % backup to prevent any breakdown inthe system.
2.6.5 Water body & Swimming pool makeup water
For water body & swimming pool separate filtration plant & balancing tank will be proposed and supplymakeup water from there.
2.6.6 Hot water system
Provision of electric operated geyser shall be made in the toilet and kitchen of individual flat.
It is mandatory to provide 20% of total water consumption from solar water heating system to theindividual geysers inlet as required by MOEF.
It is therefore proposed to provide Solar Water Heating system is only for one toilet of each apartmentas supply of preheated water to geyser.
All hot water supply pipe shall be insulated by Nitrile Insulation
2.7 Location & Area requirements for Plant Room & Storages The U.G. water tanks shall be located separately as marked in the drawing by the Architect and the
Plumbing & Fire Fighting plant room shall be adjacent to underground tank. The plant room has fire
pumps, water supply pumps, water treatment plant and all other related equipment located there.
These services shall act as a centralized system for all the towers/buildings.
2.8 Tank Storages
The capacity of all Underground & Overhead Storages shall be as follows:
UNDER GROUND TANK
PHASE - 1
o UG Fire static storage = 350 m3 (2 x 175 m3)
o UG Raw water tank = 150 m3 (2 x 75 m3)
o UG Domestic water tank = 200 m3 (2 x 100 m3)
EWS, NURSERY SCHOOL & PRIMARY
o UG Raw water tank = 100 m3 (2 x 50 m3)
o UG Domestic water tank = 100 m3 (2 x 50 m3)
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PHASE - 2
o UG Fire static storage = 350 m3 (2 x 175 m3)
o UG Raw water tank = 220 m3 (2 x 110 m3)
o UG Domestic water tank = 250 m3 (2 x 125 m3)
PHASE - 3
o UG Fire static storage = 200 m3 (2 x 100 m3)
o UG Raw water tank = 50 m3 (1 x 50 m3)
o UG Domestic water tank = 50 m3 (1 x 50 m3)
OVER HEAD TANK
PHASE 1ATHENIA
S.NO.
BUILDING NAME DOMESTIC FLUSHING FIRE
1 TOWER - ( L ) 18450 9950 250002 TOWER - ( M ) 18450 9950 25000
3 TOWER - ( N ) 18450 9950 25000
4 TOWER - ( O ) 18450 9950 25000
5 TOWER - ( P ) 13650 7350 25000
6 TOWER - ( Q ) 13650 7350 25000
7 TOWER - ( R ) 13650 7350 25000
8 TOWER - ( S ) 9250 5000 25000
9 TOWER - ( T ) 11100 6000 10000
10 TOWER - ( U ) 9250 5000 10000
11 Club & Shopping 9750 5250 10000
EWS, NURSERY SCHOOL & PRIMARY
S.NO.
BUILDING NAME DOMESTIC FLUSHING FIRE
1 EWS BLOCK -01 17350 9500 5000
2 EWS BLOCK -02 17350 9500 5000
3 EWS BLOCK -03 17350 9500 5000
5 Nursery School -01 5000 - 100006 Nursery School -02 5000 - 10000
7 Primary School 12500 - 10000
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PHASE - 2
S.NO.
BUILDING NAME DOMESTIC FLUSHING FIRE
1 TOWER - ( A ) 9250 5000 10000
2 TOWER - ( B ) 11100 6000 10000
3 TOWER - ( C ) 9250 5000 250004 TOWER - ( D ) 13650 7350 25000
5 TOWER - ( E ) 13650 7350 25000
6 TOWER - ( F ) 13650 7350 25000
7 TOWER - ( G ) 18450 9950 25000
8 TOWER - ( H ) 18450 9950 25000
9 TOWER - ( J ) 18450 9950 25000
10 TOWER - ( K ) 18450 9950 25000
15 Club & Shopping 9750 5250 10000
PHASE - 3
S.NO.
BUILDING NAME DOMESTIC FLUSHING FIRE
1 TOWER - ( V ) 8950 4800 25000
2 TOWER - ( W ) 9900 5350 25000
3 TOWER - ( X ) 8950 4800 25000
5 Club 16250 8750 10000
2.9 Area requirement for UGT & Plant roomPHASE - 1
o Area required for UG Tanks = 200 m2 (approx. 20 x 10 meters)
o Area required for Plant Room = 120 m2 (approx. 12 x 10 meters)
PHASE - 2
o Area required for UG Tanks = 235 m2 (approx. 24 x 10 meters)
o Area required for Plant Room = 120 m2 (approx. 12 x 10 meters)
PHASE - 3
o Area required for UG Tanks = 100 m2 (approx. 10 x 10 meters)o Area required for Plant Room = 90 m2 (approx. 9 x 10 meters)
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2.10 Mater ials for Water Supply
The pipes inside shafts/Terrace/Basement ceiling shall be G.I. pipes conforming to IS 1729 andinternal pipes for water supply shall be CPVC (chlorinated poly vinyl chloride) conforming to IS15778 CTS SDR-11 using solvent cement joints.
Fittings shall be G.I. & CPVC.
Valves on branches, main line and pumps shall have ball valve/gate valve/butterfly valve of goodapproved quality, as per requirement.
Internal hot water pipes shall be insulated as per requirements.
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PROJECT: ACROPOLIS GROUP HOUSING, SECTOR-108 , GURGAON, HARYANA.
S.NO.
BUILDING NAMENO. OF
FLOORSUNITS /BLOCK
PERUNITPOP.
TOTALPOP. LPCD
TOTALREQUIREMENT
DOMESTICWATER@65%
OverheadTank
(DOMESTIC)
FLUSHINGWATER@35%
OHT(FLUSHING)
SEWERAGEFLOW
(LITRES)
80
PHASE - 1 (ATHENIA)
1 TOWER - ( L ) (S+23/19) - - 420 135 56700 36855 18450 19845 9950 45360
( i ) 3 BED+SQ (RGLR) - 46 5 230 - - - - - - -
( ii ) 3 BED+SQ (S) - 38 5 190 - - - - - - -
2 TOWER - ( M ) (S+23/19) - - 420 135 56700 36855 18450 19845 9950 45360( i ) 3 BED+SQ (RGLR) - 46 5 230 - - - - - - -
( ii ) 3 BED+SQ (S) - 38 5 190 - - - - - - -
3 TOWER - ( N ) (S+23/19) - - 420 135 56700 36855 18450 19845 9950 45360
( i ) 3 BED+SQ (RGLR) - 46 5 230 - - - - - - -
( ii ) 3 BED+SQ (S) - 38 5 190 - - - - - - -
4 TOWER - ( O ) (S+23/19) - - 420 135 56700 36855 18450 19845 9950 45360( i ) 3 BED+SQ (RGLR) - 46 5 230 - - - - - - -
( ii ) 3 BED+SQ (S) - 38 5 190 - - - - - - -
5 TOWER - ( P ) (S+22/18) - - 310 135 41850 27202.5 13650 14647.5 7350 33480
( i ) 4 BED+SQ (S) - 18 5 90 - - - - - - -
( ii ) 3 BED+SQ (DLX) - 44 5 220 - - - - - - -
6 TOWER - ( Q ) (S+22/18) - - 310 135 41850 27202.5 13650 14647.5 7350 33480
( i ) 4 BED+SQ (S) - 18 5 90 - - - - - - -
( ii ) 3 BED+SQ (DLX) - 44 5 220 - - - - - - -7 TOWER - ( R ) (S+22/18) - - 310 135 41850 27202.5 13650 14647.5 7350 33480
( i ) 3 BED+SQ (RGLR) - 18 5 90 - - - - - - -
( ii ) 3 BED+SQ (S) - 44 5 220 - - - - - - -
8 TOWER - ( S ) (S+21) - - 210 135 28350 18427.5 9250 9922.5 5000 22680
( i ) 4 BED+SQ (RGLR) - 42 5 210 - - - - - - -
9 TOWER - ( T ) (S+18) - - 252 135 34020 22113 11100 11907 6000 27216
( i ) 4 BED+SQ (DLX) - 36 5 180 - - - - - - -
( ii ) SERVANT - 36 2 72 - - - - - - -
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S.NO.
BUILDING NAMENO. OF
FLOORSUNITS /BLOCK
PERUNITPOP.
TOTALPOP. LPCD
TOTALREQUIREMENT
DOMESTICWATER@65%
OverheadTank
(DOMESTIC)
FLUSHINGWATER@35%
OHT(FLUSHING)
SEWERAGEFLOW
(LITRES)
10 TOWER - ( U ) (S+15) - - 210 135 28350 18427.5 9250 9922.5 5000 22680
( i ) 4 BED+SQ (DLX) - 30 5 150 - - - - - - -
( ii ) SERVANT - 30 2 60 - - - - - - -
11Visitors @ 15% ofPopulation
- - - 976 15 14640 9516 - 5124 - 11712
12 Club & Shopping (G+1) Lumpsum 30000 19500 9750 10500 5250 24000.0013 Horticultures 3.2 Acre @ 25000 Ltrs/Acre 80000 - - - - -
14Waterbody & Swimming po olmakeup water
- - - - 15000 - - - - -
15 Road was hin g - - - - - 25000 - - - - -
16 Fi lt er Back Wash - - - - - 28000 - - - - -
630.00 6504.00 635710.00 317012.00 170699.00 390168.00
A) TOTAL DAIL Y WATER DEMANDa) TOTAL DOMESTIC & FLUSHING USE
b) TOTAL DOMESTIC 317012.00 LTRS.
c) TOTAL FLUSHING 170699.00 LTRS.
TOTAL 487711.00 LTRS.
d) WATER BODIES/ SWIMMING POOL 15000.00 LTRS.e) HORTICULTURE/ ROAD WASHING 105000.00 LTRS.
e) Filter Back Wash 28000.00 LTRS.
GRAND TOTAL 635,711.00 LTRS.
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B) SEWAGE FLOW
a) DAILY REQUIREMENT 487,711 LPD
b) RATE OF FLOW TO SEWER 80%
c) FLOW TO SEWER 390,169 LPD
d) SEWAGE FLOW 390.2 KLD
e) CAPACITY OF SEWAGE TREATMENT PLANT 391 KLD
f) WATER AVAILABLE FOR RECYCLING (FLUSHING &GARDENING)
332 KLD
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S.NO.
BUIDING NAMENO. OF
FLOORSUNITS /BLOCK
PERUNITPOP.
TOTALPOP.
LPCDTOTAL
REQUIREMENT
DOMESTICWATER@65%
OverheadTank
(DOMESTIC)
FLUSHINGWATER@35%
OHT(FLUSHING)
SEWERAGEFLOW
(LITRES)
PHASE - 2 (AMBROSIA)1 TOWER - ( A ) (S+15) - - 210 135 28350 18427.5 9250 9922.5 5000 22680
( i ) 4 BED+SQ (DLX) - 30 5 150 - - - - - - -
( ii ) SERVANT - 30 2 60 - - - - - - -
2 TOWER - ( B ) (S+18) - - 252 135 34020 22113 11100 11907 6000 27216
( i ) 4 BED+SQ (DLX) - 36 5 180 - - - - - - -
( ii ) SERVANT - 36 2 72 - - - - - - -3 TOWER - ( C ) (S+21) - - 210 135 28350 18427.5 9250 9922.5 5000 22680
( i ) 4 BED+SQ (RGLR) - 42 5 210 - - - - - - -
4 TOWER - ( D ) (S+22/18) - - 310 135 41850 27202.5 13650 14647.5 7350 33480
( i ) 4 BED+SQ (S) - 18 5 90 - - - - - - -
( ii ) 3 BED+SQ (DLX) - 44 5 220 - - - - - - -
5 TOWER - ( E ) (S+22/18) - - 310 135 41850 27202.5 13650 14647.5 7350 33480
( i ) 4 BED+SQ (S) - 18 5 90 - - - - - - -
( i i ) 3 BED+SQ (DLX) - 44 5 220 - - - - - - -
6 TOWER - ( F ) (S+22/18) - - 310 135 41850 27202.5 13650 14647.5 7350 33480
( i ) 4 BED+SQ (S) - 18 5 90 - - - - - - -( ii ) 3 BED+SQ (DLX) - 44 5 220 - - - - - - -
7 TOWER - ( G ) (S+23/19) - - 420 135 56700 36855 18450 19845 9950 45360( i ) 3 BED+SQ (RGLR) - 46 5 230 - - - - - - -
( i i ) 3 BED+SQ (S) - 38 5 190 - - - - - - -
8 TOWER - ( H ) (S+23/19) - - 420 135 56700 36855 18450 19845 9950 45360( i ) 3 BED+SQ (RGLR) - 46 5 230 - - - - - - -
( i i ) 3 BED+SQ (S) - 38 5 190 - - - - - - -
9 TOWER - ( J ) (S+23/19) - - 420 135 56700 36855 18450 19845 9950 45360
( i ) 3 BED+SQ (RGLR) - 46 5 230 - - - - - - -
( i i ) 3 BED+SQ (S) - 38 5 190 - - - - - - -
10 TOWER - ( K ) (S+23/19) - - 420 135 56700 36855 18450 19845 9950 45360
( i ) 3 BED+SQ (RGLR) - 46 5 230 - - - - - - -
( i i ) 3 BED+SQ (S) - 38 5 190 - - - - - - -
11 Visitors @ 15% of Population - - 493 15 7395 4806.75 - 2588.25 - 5916
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S.NO.
BUIDING NAMENO. OF
FLOORSUNITS /BLOCK
PERUNITPOP.
TOTALPOP.
LPCDTOTAL
REQUIREMENT
DOMESTICWATER@65%
OverheadTank
(DOMESTIC)
FLUSHINGWATER@35%
OHT(FLUSHING)
SEWERAGEFLOW
(LITRES)
12 Club & Shopping (G+1) Lumpsum 30000 19500 9750 10500 5250 24000.00
13 Horticultures 4.1 Acre @ 25000 Ltrs/Acre 102500 - - - - -
14Waterbody & Swimming poolmakeup water
- - - - 15000 - - - - -
15 Road washing - - - - - 30000 - - - - -
16 Fi lt er Back Wash - - - - - 28000 - - - - -
630.00 3282.00 655965.00 312303.00 168163.00 384372.00
A) TOTAL DAIL Y WATER DEMAND
a) TOTAL DOMESTIC & FLUSHING USE
b) TOTAL DOMESTIC 312303.00 LTRS.
c) TOTAL FLUSHING 168163.00 LTRS.
TOTAL 480466.00 LTRS.
d) WATER BODIES/SWIMMING POOL 15000.00 LTRS.
e) HORTICULTURE/ROAD WASHING 132500.00 LTRS.
e) Filter Back Wash 28000.00 LTRS.
GRAND TOTAL 655,966.00 LTRS.
B) SEWAGE FLOW
a) DAILY REQUIREMENT 480,466 LPD
b) RATE OF FLOW TO SEWER 80
c) FLOW TO SEWER 384,373 LPD
d) SEWAGE FLOW 384.4 KLD
e) CAPACITY OF SEWAGE TREATMENT PLANT 385 KLD
f)WATER AVAILABLE FOR RECYCLING (FLUSHING& GARDENING)
327 KLD
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S.NO.
BUIDING NAMENO. OF
FLOORSUNITS /BLOCK
PERUNITPOP.
TOTALPOP.
LPCDTOTAL
REQUIREMENT
DOMESTICWATER@65%
OverheadTank
(DOMESTIC)
FLUSHINGWATER@35%
OHT(FLUSHING)
SEWERAGEFLOW
(LITRES)
PHASE - 3 (OLYMPIA)
1 TOWER - ( V ) (C+S+27) - - 137 200 27400 17810 8950 9590 4800 21920
( i ) 5 BED - 27 5 135 - - - - - - -
( ii ) SERVANT - 1 2 2 - - - - - - -
2 TOWER - ( W ) (C+S+30) - - 152 200 30400 19760 9900 10640 5350 24320
( i ) 5 BED - 30 5 150 - - - - - - -( ii ) SERVANT - 1 2 2 - - - - - - -
3 TOWER - ( X ) (C+S+27) - - 137 200 27400 17810 8950 9590 4800 21920
( i ) 5 BED - 27 5 135 - - - - - - -
( ii ) SERVANT - 1 2 2 - - - - - - -
4 Visitors @ 15% of Population - - 128 15 1920 1248 - 672 - 1536
5 Club (G+1) Lumpsum 50000 32500.00 16250 17500.00 8750 40000.00
6 Horticultures 1.0 Acre @ 25000 Ltrs/Acre 25000 - - - - -
7 Waterbody & Swimming pool makeup water - - - 15000 - - - - -
8 Road washing - - - - - 15000 - - - - -
9 Filter Back Wash - - - - - 7500 - - - - -
84.00 852.00 199620.00 89128.00 47992.00 109696.00
A) TOTAL DAIL Y WATER DEMAND
a) TOTAL DOMESTIC & FLUSHING USE
b) TOTAL DOMESTIC 89128.00 LTRS.
c) TOTAL FLUSHING 47992.00 LTRS.
TOTAL 137120.00 LTRS.
d) WATER BODIES/ SWIMMING POOL 15000.00 LTRS.
e) HORTICULTURE/ ROAD WASHING 40000.00 LTRS.
e) Filter Back Wash 7500.00 LTRS.
GRAND TOTAL 199,620.00 LTRS.
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B) SEWAGE FLOW
a) DAILY REQUIREMENT 137,120 LPD
b) RATE OF FLOW TO SEWER 80
c) FLOW TO SEWER 109,696 LPD
d) SEWAGE FLOW 109.7 KLD
e) CAPACITY OF SEWAGE TREATMENT PLANT 110 KLD
f)WATER AVAILABLE FOR RECYCLING (FLUSHING &
GARDENING)94 KLD
S.NO.
BUIDING NAMENO. OF
FLOORSUNITS /BLOCK
PERUNITPOP.
TOTALPOP.
LPCDTOTAL
REQUIREMENT
DOMESTICWATER@65
OverheadTank
(DOMESTIC)
FLUSHINGWATER@35%
OHT(FLUSHING)
SEWERAGEFLOW
(LITRES)
EWS & OTHERS
1 EWS BLOCK -01 - 79 5 395 135 53325 34661.25 17350 18663.75 9500 42660
2 EWS BLOCK -02 - 79 5 395 135 53325 34661.25 17350 18663.75 9500 42660
3 EWS BLOCK -03 - 79 5 395 135 53325 34661.25 17350 18663.75 9500 42660
4Visitors @ 15% ofPopulation
- - - 178 15 2670 1735.5 - 934.5 - 2136
5 Nursery School -01 (G+2) - Lumpsum 10000 10000.00 5000 - - 8000.00
6 Nursery School -02 (G+2) - Lumpsum 10000 10000.00 5000 - - 8000.00
7 Primary School (G+2) - Lumpsum 25000 25000 12500 0 20000.008 Horticultures - - 0.75 Acre @ 25000 Ltrs/Acre 18750 - - - - -
9Waterbody & Swimming po olmakeup water
- - - - 5000 - - - - -
10 Road washing - - - - - 25000 - - - - -
11 Fi lt er Back Wash - - - - - 8500 - - - - -
171.0 1185.0 264895.0 150720.0 56926.0 166116.0
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A) TOTAL DAIL Y WATER DEMAND
a) TOTAL DOMESTIC & FLUSHING USE
b) TOTAL DOMESTIC 150720.00 LTRS.
c) TOTAL FLUSHING 56926.00 LTRS.
TOTAL 207646.00 LTRS.
d) WATER BODIES/SWIMMING POOL 5000.00 LTRS.
e) HORTICULTURE/ROAD WASHING 43750.00 LTRS.
e) Filter Back Wash 8500.00 LTRS.GRAND TOTAL 264,896.00 LTRS.
B) SEWAGE FLOW
a) DAILY REQUIREMENT 207,646 LPD
b) RATE OF FLOW TO SEWER 80%
c) FLOW TO SEWER 166,117 LPD
d) SEWAGE FLOW 166.1 KLD
e) CAPACITY OF SEWAGE TREATMENT PLANT 167 KLD
f)WATER AVAILABLE FOR RECYCLING (FLUSHING &GARDENING)
142 KLD
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SEWERAGE SYSTEM
3.1 As per MOEF requirement it is mandatory to provide STP and same shall be done for this project.
3.2 It is proposed that the sewage generated from the entire tower shall be treated in a sewage treatment plant,so that the treated effluent can be recycled for horticulture, flushing & soft water requirements of the site &balance treated water can be sold to outside agencies. So that site will be ZERO discharge site.
Design Conditi ons
a. Termination of vent cowl at terrace level.
b. Provision of adequate slope for horizontal header pipes in the ceiling level of the floor for achievingself-cleaning velocity in the pipes.
c. Provision of cleanout plugs.
d. Provision of the system services maintenance.
3.3 System Designed
The sewerage system will be based on conventional water carriage system, in which soil anddomestic waste generated by individual buildings/units will be collected into a collection chamber,through soil and waste piping system.
The sanitary, waste & vent system shall be water tight and gas tight designed to prevent escape offoul gas and odour from various fixtures.
Provision of ASP vertical vent shall be made for hygiene, safety considerations, and to avoid entry offoul smell into occupied areas.
Vent system shall be designed to facilitate escape of gases and odour from all parts of sanitary andwaste system to the atmosphere at a point above the building and to allow admittance of air to allpart of the system, so that siphonage, aspiration or back pressure conditions do not cause loss of
seal at traps.
It is proposed to use uPVC SWR pipe for soil/waste application. The soil & waste piping from toiletshall be connected vertical stack located inside the pipe shaft which shall be coordinated with otherservices and in consultation with the Architect.
The collection chamber from all units shall be connected to the nearest manhole on the externalsewer line planned along the periphery of the building and as per site conditions.
It is recommended that the domestic sewage shall finally be carried due to gravity to one disposalpoint for further treatment in the Sewage Treatment Plant.
Phase - 1,As per calculation total domestic water consumption, is about 488 m3/day. For designingthe STP it is considered that 80% of water consumed gets converted in to sewage. Based on thisfundamental the capacity of STP shall be 391 m3/day. But for working point, we are proposing STPcapacity 460 KLD as per EIA requirement.
Phase - 2,As per calculation total domestic water consumption, is about 481 m3/day. For designingthe STP it is considered that 80% of water consumed gets converted in to sewage. Based on thisfundamental the capacity of STP shall be 385 m3/day. But for working point, we are proposing STPcapacity 460 KLD as per EIA requirement.
3
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Phase - 3,As per calculation total domestic water consumption, is about 137 m3/day. For designingthe STP it is considered that 80% of water consumed gets converted in to sewage. Based on thisfundamental the capacity of STP shall be 110 m3/day. But for working point, we are proposing STPcapacity 140 KLD as per EIA requirement.
EWS, Nursery & Primary Schools,As per calculation total domestic water consumption, is about208 m3/day. For designing the STP it is considered that 80% of water consumed gets converted in
to sewage. Based on this fundamental the capacity of STP shall be 170 m3/day. But for workingpoint, we are proposing STP capacity 210 KLD as per EIA requirement.
Treated effluent shall be filtered through Dual Media Filter (DMF) & Activated Carbon filter (ACF)and stored in an UG tank for use in flushing and Horticulture.
Further filtered water will be softened and used for DG Cooling tower.
3.4 Basic characteristic of incoming and outgoing parameter are as follows:
Parameter Raw Sewage Treated Sewage (Incoming) (SAFF treatment)
Ph 7.5 - 8.5 6.5 8.0BOD 5 @200 C 200 - 250 mg/l Less than 10 mg/l (Less than 10 mg/l) as per EIASuspended 200 - 400 mg/l Less than 10 mglCOD 400 - 500 mg/l Less than 60mg/lOil & Grease 30 mg/l Less than 5 mg/l
3.5 Material Specifications for the Sewerage System
SW Pipes: For dia. 100mm, 150mm and 200mm Grade A as per IS:651 depending on siteconditions with laying, jointing and bedding as per IS:4127-1983
RCC Pipes Class NP3: For dia 250mm and above as per IS: 458, for normal slopes and generalsite conditions.
3.6 Manholes
The manholes shall be constructed of brick masonry as per standard specifications of NationalBuilding Code and shall be having details as follows:-
o Rectangular of size 900x800mm up to 900mm depth.
o Circular of size 910mm dia from 900mm up to 1670mm depth.
o Circular of size 1220mm dia from 1668mm up to 2290mm depth.
o Circular of size 1520mm dia from 2290mm up to 4180mm depth.
Manhole Covers
Steel fiber reinforced concrete (SFRC) Manhole cover with frame conforming to IS: 12592 shall beprovided.
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Design Parameters for 2 x 230 KLD STP on MBBR Technology
S. No. Description
1 Sewage generated 460 m3/day
2 Sewage to be treated 460 m3/daySay 460 m3/day
3 BOD in influent 300 mg/l
4 Total BOD load on plant 138 kg/day
5 Suspended solid influent 450 mg/l
6 SS load on plant 207 kg/day
Tertiary Treatment
7 Desired effluent standard Before After
8 BOD 30
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11.3 Settling Tank
Nos. of tank 2.0
Total Flow Rate 460.0 m3/day
Flow Rate 153.3 m3/hr
Surface Loading Rate 3.0 m3/hr/m2
Operation Time 20.0 hr
Retention Time 4.5 hr
Area Required 2.6 m2
Length 3.6 mWidth 2.4 m
Straight Height 2.0 m
Total height 4.0 m
11.4 Sludge Holding Tank
Nos. of tank 1.0
Total Flow 460.0 m3/day
Inlet BOD 300.0 mg/l
Outlet BOD 20.0 mg/l
Suspended Solid 450.0 mg/lBOD to be removed per Day 128.8 Kg/day
Excess sludge generation rate 38.6 Kg/day
Suspended Solid to be removed 207.0 Kg/day
Total Sludge to be removed 335.8 Kg/day
Considering Sludge density as 5% thickening 0.05
Total Sludge to be removed per day 6.716 m3/day
Volume of tank for 20 days 134.3 m3
Length 6.4 m
Width 5.3 m
Height (Water depth 3.5) 4.0 m
Volume 135.7 m3
11.5 Clarified Water Tank (CWT)
Nos. of tank 1.0
Total Flow 460.0 m3/day
Average flow 23.0 m3/hr
Hydraulic Retention time 4.0 hr
Volume required 92.0 m3
Length 5.4 m 93
Width 4.3 mHeight 4.0 m
11.6 Final Effluent Tank
Nos. of tank 2.0Total Flow 460.0 m3/dayAverage flow 23.0 m3/hr
Hydraulic Retention time 10.0 hr
Volume required 230.0 m3
Length 6.2 m
Width 4.7 m
Height 4.0 m
Volume 233.1 m3
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12 AIR REQUIREMENT FOR THE PLANT
Ai r Requi rement for SAFF TankTotal Flow 460 m3/day
BOD to be removed 138 kg/day
Oxygen required per kgs of BOD to be removed 1.4 kgs/kg/day
Total Oxygen required to remove BOD 193.2 kg/day
Consider oxygen transfer rate12% 0.1221% oxygen content in atmospheric air 0.21
1.18 density 1.18 kg/m3
Total Oxygen required to remove BOD 270.72 m3/hr
Say 280.00 m3/hr
Ai r Requirement for Equal isation Tank
Air transfer for Equalisation Tank 70% 0.7
Total Air Requirement for Equalisation tank 89.44444444 m3/hr
Say 90.00 m3/hr
Ai r Requi rement for Sludge Hold ing Tank
Air transfer for Sludge Holding Tank 75% 0.75Total Air Requirement for Sludge Holding tank 100.74 m3/hr
Say 110.00 m3/hr
TOTAL AIR REQUIREMENT 480 m3/hr
Say 480 m3/hr
13 Raw Sewerage Pumps
Flow 460 m3/day
Operational hours 18 hrs.
Average flow 25.56 m3/hr
Provide (2 working + 1 standby) 12.78 m3/hr
Pump Flow rate 220.0 LPM
Head 10 to 12 m
14 Filter Feed Pump
Flow 460 m3/day
Operational hours 15 hrs.
Average flow 30.67 m3/hr
Say 30.67 m3/hr
Provide (2 working + 1 standby) 15.33333333 m3/hr
Pump Flow rate 260.0 LPM
Head 35 m
15 Sludge Disposal PumpFlow 460 m3/day
40% of total flow 184 m3/day
Operational hours 10 hrs.
Average flow 18.40 m3/hr
Provide (2 working + 1 standby) 9.20 m3/hr
Pump Flow rate 160.0 LPM
Head 15 m
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17 Pressure Sand Filter
Flow 460 m3/day
Operational hours 15 hrs.
Capacity 30.67 m3/hr
Say 30.67 m3/hr
Filtration Rate 16 m3/hr/m2
Dia of Vessel 1.56 m
Say 1600 mm
Height of Straight 1500 mm
18 Ac tivated Carbon Fil ter
Flow 460 m3/day
Operational hours 15 hrs.
Capacity 30.67 m3/hr
Say 30.67 m3/hr
Filtration Rate 14 m3/hr/m2
Dia of Vesel 1.67 m
Say 1700 mm
Height of Straight 1500 mm
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Design Parameters for 140 KLD STP on MBBR Technology
S. No. Description
1 Sewage generated 140 m3/day
2 Sewage to be treated 140 m3/day
Say 140 m3/day
3 BOD in influent 300 mg/l4 Total BOD load on plant 42 kg/day
5 Suspended solid influent 450 mg/l
6 SS load on plant 63 kg/day
Tertiary Treatment
7 Desired effluent standard Before After
8 BOD 30
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11.3 Settling Tank
Nos. of tank 1.0
Total Flow Rate 140.0 m3/day
Flow Rate 140.0 m3/hr
Surface Loading Rate 3.0 m3/hr/m2
Operation Time 20.0 hr
Retention Time 4.5 hr
Area Required 2.3 m2
Length 2.2 m
Width 2.2 m
Straight Height 2.0 m
Total height 4.0 m
11.4 Sludge Holding Tank
Nos. of tank 1.0
Total Flow 140.0 m3/day
Inlet BOD 300.0 mg/l
Outlet BOD 20.0 mg/l
Suspended Solid 450.0 mg/l
BOD to be removed per Day 39.2 Kg/day
Excess sludge generation rate 11.8 Kg/day
Suspended Solid to be removed 63.0 Kg/day
Total Sludge to be removed 102.2 Kg/dayConsidering Sludge density as 5% thickening 0.05
Total Sludge to be removed per day 2.044 m3/day
Volume of tank for 20 days 40.9 m3
Length 3.6 m
Width 2.9 m
Height (Water depth 3.5) 4.0 m
Volume 41.8 m3
11.5 Clarified Water Tank (CWT)
Nos. of tank 1.0Total Flow 140.0 m3/day
Average flow 7.0 m3/hr
Hydraulic Retention time 4.0 hr
Volume required 28.0 m3
Length 3.0 m 29
Width 2.4 mHeight 4.0 m
11.6 Final Effluent Tank
Nos. of tank 1.0Total Flow 140.0 m3/dayAverage flow 7.0 m3/hr
Hydraulic Retention time 10.0 hr
Volume required 70.0 m3
Length 4.8 m
Width 3.7 m
Height 4.0 m
Volume 71.0 m3
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12 AIR REQUIREMENT FOR THE PLANT
Ai r Requi rement for SAFF Tank
Total Flow 140 m3/day
BOD to be removed 42 kg/day
Oxygen required per kgs of BOD to be removed 1.4 kgs/kg/day
Total Oxygen required to remove BOD 58.8 kg/day
Consider oxygen transfer rate12% 0.1221% oxygen content in atmospheric air 0.21
1.18 density 1.18 kg/m3
Total Oxygen required to remove BOD 82.39 m3/hr
Say 90.00 m3/hr
Ai r Requi rement for Equal isation Tank
Air transfer for Equalisation Tank 70% 0.7
Total Air Requirement for Equalisation tank 27.2222 m3/hr
Say 30.00 m3/hr
Ai r Requi rement for Sludge Hold ing Tank
Air transfer for Sludge Holding Tank 75% 0.75
Total Air Requirement for Sludge Holding tank 30.66 m3
/hrSay 40.00 m3/hr
TOTAL AIR REQUIREMENT 160 m3/hr
Say 160 m3/hr
13 Raw Sewerage Pumps
Flow 140 m3/day
Operational hours 18 hrs.
Average flow 7.78 m3/hr
Provide (1 working + 1 standby) 7.78 m3/hr
Pump Flow rate 130.0 LPMHead 10 to 12 m
14 Filter Feed Pump
Flow 140 m3/day
Operational hours 15 hrs.
Average flow 9.3 m3/hr
Say 9.3 m3/hr
Provide (1 working + 1 standby) 9.3 m3/hr
Pump Flow rate 160.0 LPM
Head 35 m
15 Sludge Disposal Pump
Flow 140 m3/day
40% of total flow 56 m3/day
Operational hours 10 hrs.
Average flow 5.6 m3/hr
Provide (1 working + 1 standby) 5.6 m3/hr
Pump Flow rate 100.0 LPM
Head 15 m
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17 Pressure Sand Filter
Flow 140 m3/day
Operational hours 15 hrs.
Capacity 9.3 m3/hr
Say 9.3 m3/hr
Filtration Rate 16 m3/hr/m2
Dia of Vessel 0.86 m
Say 900 mm
Height of Straight 1200 mm
18 Activated Carbon Fi lter
Flow 140 m3/day
Operational hours 15 hrs.
Capacity 9.33 m3/hr
Say 9.33 m3/hr
Filtration Rate 14 m3/hr/m2
Dia of Vessel 0.92 m
Say 1000 mm
Height of Straight 1200 mm
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Design Parameters for 2 x 105 KLD STP on MBBR Technology
S. No. Description
1 Sewage generated 210 m3/day
2 Sewage to be treated 210 m3/day
Say 210 m3/day
3 BOD in influent 300 mg/l4 Total BOD load on plant 63 kg/day
5 Suspended solid influent 450 mg/l
6 SS load on plant 94.5 kg/day
Tertiary Treatment
7 Desired effluent standard Before After
8 BOD 30
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11.3 Settling Tank
Nos. of tank 2.0
Total Flow Rate 210.0 m3/day
Flow Rate 105.0 m3/hr
Surface Loading Rate 3.0 m3/hr/m2
Operation Time 20.0 hr
Retention Time 4.5 hr Area Required 1.8 m2
Length 3.6 m
Width 2.2 m
Straight Height 2.4 m
Total height 4.0 m
11.4 Sludge Holding Tank
Nos. of tank 1.0
Total Flow 210.0 m3/day
Inlet BOD 300.0 mg/l
Outlet BOD 20.0 mg/l
Suspended Solid 450.0 mg/lBOD to be removed per Day 58.8 Kg/day
Excess sludge generation rate 17.6 Kg/day
Suspended Solid to be removed 94.5 Kg/day
Total Sludge to be removed 153.3 Kg/dayConsidering Sludge density as 5% thickening 0.05
Total Sludge to be removed per day 3.066 m3/day
Volume of tank for 20 days 61.3 m3
Length 4.8 m
Width 3.2 m
Height (Water depth 3.5) 4.0 m
Volume 61.4 m3
11.5 Clarified Water Tank (CWT)
Nos. of tank 1.0
Total Flow 210.0 m3/day
Average flow 10.5 m3/hr
Hydraulic Retention time 4.0 hr
Volume required 42.0 m3
Length 7.3 m 43
Width 5.9 m
Height 4.0 m
11.6 Final Effluent Tank
Nos. of tank 2.0Total Flow 210.0 m3/day
Average flow 10.5 m3/hr
Hydraulic Retention time 10.0 hr
Volume required 105.0 m3
Length 4.0 m
Width 3.3 m
Height 4.0 m
Volume 105.6 m3
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12 AIR REQUIREMENT FOR THE PLANT
Ai r Requi rement for SAFF Tank
Total Flow 210 m3/day
BOD to be removed 63 kg/day
Oxygen required per kgs of BOD to be removed 1.4 kgs/kg/day
Total Oxygen required to remove BOD 88.2 kg/day
Consider oxygen transfer rate12% 0.12
21% oxygen content in atmospheric air 0.21
1.18 density 1.18 kg/m3
Total Oxygen required to remove BOD 123.59 m3/hr
Say 130.00 m3/hr
Ai r Requi rement for Equal isation Tank
Air transfer for Equalisation Tank 70% 0.7
Total Air Requirement for Equalisation tank 40.833333 m3/hr
Say 50.00 m3/hr
Ai r Requi rement for Sludge Hold ing Tank
Air transfer for Sludge Holding Tank 75% 0.75
Total Air Requirement for Sludge Holding tank 45.99 m3/hrSay 50.00 m3/hr
TOTAL AIR REQUIREMENT 230 m3/hr
Say 230 m3/hr
13 Raw Sewerage Pumps
Flow 210 m3/day
Operational hours 18 hrs.
Average flow 11.67 m3/hr
Provide (2 working + 1 standby) 5.83 m3/hr
Pump Flow rate 100.0 LPM
Head 10 to 12 m
14 Filter Feed Pump
Flow 210 m3/day
Operational hours 15 hrs.
Average flow 14.00 m3/hr
Say 14.00 m3/hr
Provide (2 working + 1 standby) 7 m3/hr
Pump Flow rate 120.0 LPMHead 35 m
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15 Sludge Disposal Pump
Flow 210 m3/day
40% of total flow 84 m3/day
Operational hours 10 hrs.
Average flow 8.40 m3/hr
Provide (2 working + 1 standby) 4.20 m3/hr
Pump Flow rate 70.0 LPMHead 15 m
17 Pressure Sand Filter
Flow 210 m3/day
Operational hours 15 hrs.
Capacity 14.00 m3/hr
Say 14.00 m3/hr
Filtration Rate 16 m3/hr/m2
Dia of Vessel 1.06 m
Say 1100 mm
Height of Straight 1500 mm
17 Activated Carbon Fi lter
Flow 210 m3/day
Operational hours 15 hrs.
Capacity 14.00 m3/hr
Say 14.00 m3/hr
Filtration Rate 14 m3/hr/m2
Dia of Vessel 1.13 m
Say 1200 mm
Height of Straight 1500 mm
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DRAINAGE & RAINWATER HARVESTING SYSTEM
4.1 Introduction
Due to urbanization of the land and sharp growth in population and thus increase in water demand forvarious uses, the fresh water is becoming scarce in most regions of the area. In certain areas due to almosttotal dependency on the underground water, the wells and bore-wells are getting deeper and deeper. Also
due to increase in paved surface/roof areas, the amount of natural/percolation of rainfall is reducing verydrastically.
Therefore, it has become very necessary to harvest the rain water as maximum as possible. The drainagesystem needs to be planned with a view to incorporate rainwater harvesting principles.
Separate and independent rain water drainage system shall be provided for collecting rain water fromterrace, paved area, lawns and roads. Independent rain water down takes of appropriate size and numbershall be provided in apartment toilet shafts & other dedicated shafts. The final disposal shall be in rain waterharvesting pit with overflow connection to the municipal storm water mains for the site. Perforated pipedrainage system shall be provided for open-to-sky courtyards/lawns.
Drain channel shall be provided in the car parking and pump room areas within the floor-fill. Drain channelsshall be provided with adequate slope to effect self cleaning velocity and shall terminate in sumps. For eachsumps, 2 nos submersible pumps (1 working + 1 standby) shall be provided for disposal of collected run-off.Pumps shall be installed in identified sumps and shall be operated by Hi-Lo level switches with automaticchangeover between both pumps. Provision of water detector/alarm shall be made in each lift pit. Portablepumps shall be lowered in the lift pit when water logging is detected, to enable disposal of surface runoffwater.
4.2 Systems of Rainwater Harvesting:- The sub-soil met the course of investigation consist of predominantlygravelly silty fine sands up to termination depths of 25.45M & silt layer between 6.0 & 7.5 M depth. The subsoil to have gravel /Kankar at all depths but beyond between 9.0 M & 18 M appreciable percentage.
The Sub Soil is alluvial deposit. The stratification at site indicated layered deposits caused by sedimentdeposition by streams in non marine fluvial condition. The deposit is known as alluvium. The sub soil islayered deposit consisting of fine sand with gravel/kankar. The sub-soil is cohesion less deposit. They areinorganic and non- plastic. The standard penetration values observed at site indicate the deposit to bemedium dense up to 21.0 M below which they are dense. The field penetration value increases with depth,indicating they are normally consolidated deposit. The N values observed at site are influenced due topresence of gravel/kankar.
As the sub soil is cohesion less deposit, any long-term settlements are unlikely. Most settlement if any arelikely to take place during construction period itself except for creep. Water table varies between 10.5M to11.15M in the month of Nov/Dec, 2012. The raise in water table may not be more than a meter duringmonsoon.
The layered deposit encountered in all bore hole are similar. The deposit appear to be homogeneous andisotropic, as N value at similar depth in various bore hole are same.
4.2 Systems of Rainwater Harvesting
Out of the various techniques adopted in India, and approved of by the Central Ground Water Authority, thefollowing are the three main classes of rainwater harvesting systems:
o System that collect direct roof runoff for storage and then reusing for various purposes.o Systems that use in-field or adjoining surface catchments to collect run-off and then impounded for
irrigation, horticultural, recreational & domestic purposes, after treatment.
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o Systems that utilize the rainwater run-off from various surfaces including Terrace and Roads andgreen areas etc. for re-charging of the underground aquifer, through various measures.
In this system, the catchments from roof/terrace areas are further segregated for directrecharging of aquifer through filter media.
The catchment from surfaces of road/paved/park/lawns etc. is segregated and then taken to
underground, through desilting chamber/oil and grease separator etc.
4.3 Therefore as per prevailing practice and from a practical point of view in North India, it is morefeasible and recommended to use rainwater to recharge groundwater aquifers than for directstorage. Therefore, it is proposed to implement the system as explained in Point-C above, so as tomaximize the rain water utilization efficiency for recharging the underground aquifer.
The entire rainfall is received over a period of 27 days, 80% of which falls in the period between July toSeptember. The rainwater therefore has to be harvested during this short period.
4.4 Parameters/Data/Calculations
(i) Areasa) Total Area of the Site /Plot -- . m2
b) Terrace/Roof area -- . m2
c) Paved/Pavement/Road area -- . m2
d) Green/Playground/Loose Area -- . m2
(ii) Co-efficient and factors adopted
a) Harvesting efficiency factor for terraces & rooftops -- 0.85b) Harvesting efficiency factor for roads and paved surfaces -- 0.70c) Harvesting efficiency factor for soft landscaped areas, gardens, parks etc. -- 0.20
(iii) Coefficient for Calculation for Capacity for Collection Wells for Harvesting
a) Peak Hourly rainfall as per HUDA rule -- 35 mm/hrb) Retention time for capacity of Recharge Tank -- 30 Minutes
(iv) For Roof Drainage
100mm dia. vertical stack -- For 70 - 80 m2
150 MM dia. vertical Stack -- For 120 - 140 m2
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(A) Calculations for Infi l tration Wells
Rainfall Intensity 0.0400 m/hr
a) Plot Area 152515.90 m2
b) Ground Coverage/Terrace Area 53380.56 m2
c) Road Area/Paved Area 81252.34 m2
d) Proposed Greens Area 17883.00 m2
1 For Roof /Ter race o nl y
(i) Average Runoff co-efficient for terraces and other built-up areas. 0.85
(ii) Area-1 considered (For Terrace/Roof only) 53380.56 m2
(iii) Theoretical Volume of Infiltration Wells required. Approximately (Total Area x 0.80 x 0.040)1814.94 m3/hr
2 For landscaped, green and other open areas.
(i) Average Runoff co-efficient for landscaped, green and other open areas. 0.25
(ii) Area - 2 considered 17883.00 m2
(ii i) Theoretical Volume of Infil tration Wells required. Approximately (Total Area x 0.2 x 0.040) 178.83 m3/hr
3 For road & paved areas :
(i) Average Runoff co-efficient for landscaped, green and other open areas. 0.70
(ii) Area-3 considered 81252.34 m2
(vi) Theoretical Volume of Infil tration Wells required. Approximately (Total Area x 0.65 x 0.040) 2275.07 m3
(vii) Total Volume Generated per hour 4268.83 m3/hr
For 15 minute holding capacity 1067.21 m3
(vi ii ) Size of the Wel ls
Dia of Recharge well 3.30 m
Depth of Recharge well 2.50 m
(ix) Volume of 1 Infil tration well 21.37 m3
(x) Absorption capacity of Recharge pit @ 60% of yield capacity of borewell
(xi) Yield capacity of borewell 18.00 m3/hr
(xii) Absorption 0.60 10.8
(xiii) Absorption capacity in 1/2 hr 5.40 m3
(xiv) Total capacity of Recharge Pit 26.77 m3
(xv) Number of Infiltration Wells Provided 40.00
(xvi) Total Rainwater holding/Absorbing capacity 1070.87 m3
(xvii) Surplus Rainwater Disposal to HUDA Drain -3.66 m3
4.4 References
o Manual on Rain Water Harvesting & Conservation by Govt. of India, Central Public WorksDepartment (CPWD), New Delhi, June 2002.
o Guidelines from Central Water Board - Ministry of Water Resources, Govt. of India.
o A Water Harvesting manual for Urban Areas Case Studies from Delhi by Centre for Science &Environment.
o Part a National Building Code of India 2005
4.5 Proposed Storm Water Drainage System
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In general the rain water from terraces and other open areas shall be collected through Rain water downtake pipes and connected to catch basins. The Rain water from hard courts and landscaped area shall becollected by catch basins through a RCC NP2 pipe network with perforated gratings and connected to therain water harvesting pits in the complex and finally over flow from rain water harvesting will be led out tomain Municipal Drainage. But we will have to design our system to achieve zero discharge site. As perCGWB norms, we are proposing one recharging pit per acre basis.
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INTERNAL PLUMBING SYSTEMS
5.1 Details of System
1. System Designed Two pipe (stack) system as recommended in code ofpractice for soil and waste pipes above ground (IS : 5329 1964)
2. Minimum dia adopted(a) All main soil & waste pipes and branches 110mm OD/90mm OD
(b) All Main soil & waste vertical stacks 110 and 160mm OD as per requirementFor kitchens dedicated stack to be provided.
(c) Vent pipes (if required) 63mm OD or 90 mm OD
(d) Wash Basin waste connection to floortraps.
40mm OD
(e) Floor Drain 63mm OD
3. Vertical Pipe (Exposed & approachable) All soil, waste, and vent pipes shall be running vertically invertical shafts as per architectural drawing.
4. Access door junctions for cleaningpurpose
Each connection from the fixtures.
5. Clean out Plugs Where two or three fixtures are connected to a singlehorizontal pipe leading to a vertical stack (in toilets),provided at starting point. The cleanout plugs shall haveaccess from the ceiling or shall be flush with the finishedfloor level.
6. Water seal for all traps Minimum 50mm
7. Methodology of conveying horizontal soil &waste pipes/Sinking of Slab(Option 1) - Most preferred
At ceiling level below, by hanging the pipes with MSstructural supports/dash fasteners and proper clamping etc.with proper slope (1:60). All structural Beams at ceilinglevel should be inverted.
App. 100mm sunken area required for connection of Wash
Basin & Floor Drain etc.(Option 2) At floor level below, by laying the pipes on floor with properslope (1:60). All structural Beams at floor level should bedownwards preferably.
App. 350 mm sunken area required for connection of W.C.,Wash Basin & Floor Drain, traps etc. However incase ofIndian W.C. the sunken area required is 450 mm.
8. Material
(a) All soil, waste and vent pipes and fittings. uPVC (SWR) pipes conforming to IS : 13592
(b)Waste pipe from sinks, wash basins andurinals etc
uPVC pipe conforming to IS : 4985
(c) Rain water pipe uPVC pipe conforming to IS : 4985
5.2 Fixtures and Fittings
o Sanitary fixtures shall be off-white vitreous china and of standard quality and make, as perrequirement.
o C.P. fittings shall be as per requirement and of good quality (medium range).
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Generally Following Type of Fixtures/Accessories shall be provided:
Water Closet
o Generally, either wall hung European W.C with cistern or floor mounted with P- trap & cistern shall beprovided in main apartment toilets.
o Combination of IWC and floor mounted wash down WC for lower end apartments.
o Health faucet & ablution tap with two way bib cock for E.W.C.
Wash Basins
o Circular/Oval table top and flat back wash basins with mirror, single lever hot & cold water mixtures asper requirement, liquid soap containers and towel rings.
o Flat back wash basin for toilets as per requirements.
Geysers
o Instant geysers of one liter capacity have been considered as per commitment.
Sinks
o Stainless steel sinks with drain board with mixtures in kitchen/utility and pantry areas, as perrequirements.
Urinals (If required for clubhouse/ any specifi c common areas)
o Flat back semi-stall urinal of size 610x400x380mm with automatic electrical sensor operated flushsystem shall be provided as per requirements.
o Flush fixtures(Urinal/EWC) 6/3 (LPF)o Flow fixtures(Faucet/Shower/Basin mixer/Taps) at 3bar 12 (LPM)
Note:- Low water consumption sanitary fixture to be considered.
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FIRE FIGHTING SYSTEM
6.1 Introduction
Type of the Building -- Group A - 4 (Residential Apartments)
Max. height of building -- Category: Above 60m in height
The entire fire safety installation shall be compliant with the most stringent codes / standard for theentire Township to ensure the highest safety standard and uniformity of system
References & Design Guideline Sources
o National Building Code of India - (Latest Edition, November 2005 - Part - IV, Fire & Life Safety)
o IS: 3844-1989 (Amended to Date) - Code of practice for installation and maintenance ofinternal fire hydrants and hose reels on premises.
o IS: 13039-1991 (Amended to Date) - Code of practice for external hydrant system provision
and maintenance.
o IS: 2190-1992 (Amended to Date) - Code of practice for selection, and maintenance of first aidfire extinguishers.
o IS: 15105:2002 (Amended to Date) - Design & Installation of Fixed Automatic Sprinkler FireExtinguishing Systems
o Consultation with Local Chief Fire Officer
6.2 SYSTEM
Following functional system shall be provided; strictly in compliance with the listed reference standards:
a. Piping System : Piping system as per NBC confirming to IS:1239 MS heavyclass.
b. Fire water staticStorage
: Fire water static storage shall be provided in accordance to theNBC/Local bye-lows.
c. Fire Pumping system : Pumping system comprising of independent pumps for hydrant &jockey application shall be provided.
d. Fire Fighting system : Wet Riser pipe with hose reel.
e. Trolley mounted CO2 system : For Transformer Room/LT Panel Room, all as per local bye-laws.Gas flooding system over LT/HT panel.
f. Hand held fire extinguishers : Strategically placed at designated areas.
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6.3 SYSTEM DESCRIPTION
Fire Pumping System:
The fire pumping system shall comprise of independent electrical pump, independent electrical pump fordown corner/hose reel and independent electrical pumps for sprinkler in basement. Electrical pump shallprovide adequate flow for catering requirement of hydrant system. Diesel engine driven fire pumps shall beprovided for ensuring operation & performance of the system in case of electrical power failure. Jockeypumps are proposed to compensate for pressure drop and line leakage in the hydrant and sprinklerinstallation.
Individual suction lines shall be drawn from the fire tanks at the terrace level and connected to independentfire suction header.
Delivery lines from various pumps shall also be connected to a common down comer header. The sprinklerpump shall be isolated from the hose reel by a non return valve so that the hydrant pump can also act asstandby for the sprinkler system. Automation required to make the system fully functional shall be provided.
Water Curtain System:
Water Curtains: Sprinklers in water curtains shall be hydraulically designed to provide three gpmper lineal foot of water curtain, with no sprinkler discharging less than 15 gpm. The number ofsprinklers calculated in the water curtain shall be the number in the length corresponding to thelength parallel to the branch lines in the area determined by Sections11.3.3.2 and 11.3.3.3 of NFPA-13. If a single fire can be expected to operate sprinklers within the water curtain and within thedesign area of a hydraulically calculated system, the water supply to the water curtain shall beadded to the water demand of the hydraulic calculations and shall be balanced to the calculatedarea demand. Hydraulic design calculations shall include a design area selected to include ceilingsprinklers adjacent to the water curtain. When the water curtain is located in an otherwise un-sprinklered area, the design shall include all the sprinklers located in each fire separation area beingprotected i.e. the portion bounded by fire area separation or occupancy separation walls.
Sprinkler Type: Sprinklers used for water curtain shall be ordinary temperature, standard or quick-response commercial-type sprinklers. However, in light hazard areas (as defined by NFPA 13),commercial quick-response type sprinklers shall be used. Also, in residential occupancies,commercial quick-response or residential type sprinklers shall be used.
Sprinkler Spacing: Sprinklers shall be spaced no more than 6-feet apart along the opening and 6"to 12" inches from the draft stop on the inside of the building. The distance between the edge of theopening and the nearest sprinkler head shall be a maximum of 3' feet. Where sprinklers are placedcloser than 6' for commercial-type sprinklers or 8' for residential-type sprinklers, cross baffles shallbe provided in accordance with section 8.6.3.4.2 of NFPA 13, 2010 edition.
6.2 Wet Riser ,Hydrants & Sprink ler System
The fire fighting system shall be provided mainly as per latest National Building Code of India (November2005) (Part IV) and other relevant I.S codes and it shall be consisting of:-
For Phase 1 : Static Underground storage fire tank of 350 m3 capacity (Minimum 2 hr storage ofpumping system) and terrace tanks of 10/25 m3 capacity as per requirement.
For Phase 2 : Static Underground storage fire tank of 350 m3 capacity (Minimum 2 hr storage ofpumping system) and terrace tanks of 10/25 m3 capacity as per requirement.
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For Phase 3 : Static Underground storage fire tank of 200 m3 capacity (Minimum 2 hr storage ofpumping system) and terrace tanks of 10/25 m3 capacity as per requirement.
Fire main of 150 mm dia. connected to external yard hydrants placed @ 45m c/c distance.
Each tower will have sprinkler system in each & every apartment.
Wet - riser system with landing hydrant valves and fire hose cabinet @ 900m2 area minimum, and asper staircases/landing details of final architectural layouts. (As per recommendations of IS:3844:1989,
Code of practice for installation of Internal Hydrants)
Sprinkler system will be provided at all Apartments/floors in all buildings above 45m in heights, and asper final architectural layouts. (As per recommendations of IS:15105-2002, Code of practice forDesign & installation of fixed sprinkler fire extinguishing systems)
Each Fire Hose Cabinet shall be consisting of:
2 Nos., 63mm dia and 15m long rubberized fabric lined hose pipe as per IS: 636 (Amended toDate) type - II.
SS male and female instantaneous type coupling as per I.S:903 (Amended to Date) with I.S.specifications.
SS branch pipe with nozzle as per I.S:903 (Amended to Date)
First-aid fire hose reels with 20mm dia 36.5m long with 5mm bore SS nozzle as per IS:884 1969 (Amended to Date).
Firemans axe.
6.3 Fire Pumps - In each Phase
Following Fire Pumps shall be provided:
o Multi stage split casing Main Electrical fire pump of 2280 LPM capacity (to give a minimumpressure of 3.5 kg/cm2 at the farthest point)
o Multi stage split casing Main Electrical Sprinkler pump of 2280 LPM capacity (to give aminimum pressure of 3.5 kg/cm2 at the farthest point)
o Multi stage split casing Electrical Jockey pump of 180 LPM capacity
o Multi stage split casing Diesel operated fire pump of 4500 LPM capacity
o Multi stage split casing water curtain pump of 2280 LPM capacity
All fire pumps shall be with positive suction arrangements.
All the fire pumps shall cut-in automatically based on the pressure settings, so as to ensure that theentire fire main line, risers etc. are pressurized on a continuous basis.
The jockey pump shall automatically cut-out based on the pressure settings. However, theremaining fire pumps shall off only in the manual mode.
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6.4 Fire Extinguishers
The following type of portable fire extinguishers shall be provided at all levels of the towers, at strategiclocations as per requirements, generally to follow IS - 2190: 1992 (Amended to Date).
o Two 9 liter water expelling type for every 600 m2 area with minimum of 1 extinguisher per floor.-- IS : 15683 - 2012
o Dry powder type of 10 kg capacity -- IS : 15683 - 2012
o One nos. 4.5 kg, CO2 type for every 100 m2 of area. -- IS : 15683 - 2012
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SPACE REQUIREMENTS
(i) App. space for underground tank (considering the maximum depthof 3.0m) See details above
(ii) Space for Plant room(for water supply and fire fighting pumps) (Adjacent to UG tanks) See details above
(iii) Space for STP of Capacity 460 m3/day - Phase - 1 App. 400 m2.
(iii) Space for STP of Capacity 460 m3/day - Phase - 2 App. 400 m2.
(iv) Space for STP of Capacity 110 m3/day - Phase 3 App. 100 m2.
(v) Space for STP of Capacity 210 m3/day - EWS & Nursery schools App. 170 m2.
(v) Details/sizes for various shafts
a) Main Plumbing Shaft for water supply pipes/fire fighting line risersto terrace level (Originating from plant room and continues toterrace)
b) Plumbing shafts for Apartment Toilets Minimum(i) 750 x 750, mm for one toilet(ii) 1150 x 700mm for combination
of two nos. toilets
c) Fire Hose Cabinets To be placed in consultation witharchitect and co-ordination withinterior planning.
(v) Plant Room for Swimming Pool 4m x 6m x 3.5 m
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APPROVALS AND CLEARANCES
E.I.A. / other Statutory Approval :-
o As per the latest govt. notifications, it has become mandatory to get the E.I.A. clearances for aproject like this from local pollution control board authorities and Ministry of Environment andForests (MOEF).
o It is therefore suggested that from this stage only, an expert agency should be hired to start thenecessary formalities for obtaining these clearances.
o This report provides all necessary information related to our services, however E.I.A. agency mustbe informed to coordinate with our office before finalizing the submission of documents.
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(Head Loss Calculation)TOWER "L"
A= From O.H.T. to d esir ed fl oor
Floors PipeNo.
Load onpipe (fixunits)
Probabledemand
(lps)
cum/hr Assumedpipe dia.
(mm)
Headloss
(m/m)
Pipelength
(m)
Eq.Lengthfitts (%)
Eq.Length (m)
Totallength
(m)
headloss line
(m)
Head lossprog (m)
Vel(m/sec)
HeadAvai lable
StaticHead
Avai lable
PRVRati
(Shaft - 01) Domestic (DOUBLE TOILET) IN1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
A 1 96 2.650 9.54 65 0.022 10.00 5 0.50 10.50 0.227 0.227 0.439 3.77 4.00
23th 2 96 2.650 9.54 65 0.022 3.00 5 0.15 3.15 0.068 0.294 0.439 6.71 7.0022th 3 92 2.587 9.31 50 0.224 3.00 5 0.15 3.15 0.706 1.000 1.317 9.00 10.00
21th 4 88 2.523 9.08 50 0.214 3.00 5 0.15 3.15 0.674 1.674 1.284 11.33 13.0020th 5 84 2.460 8.86 50 0.204 3.00 5 0.15 3.15 0.643 2.317 1.252 13.68 16.00
19th 6 80 2.397 8.63 50 0.194 3.00 5 0.15 3.15 0.613 2.930 1.220 16.07 19.0018th 7 76 2.321 8.36 50 0.183 3.00 5 0.15 3.15 0.577 3.507 1.181 18.49 22.00
17th 8 72 2.245 8.08 50 0.172 3.00 5 0.15 3.15 0.543 4.050 1.143 20.95 25.0016th 9 68 2.170 7.81 50 0.162 3.00 5 0.15 3.15 0.510 4.559 1.104 23.44 28.00 2.3
15th 10 64 2.094 7.54 50 0.151 3.00 5 0.15 3.15 0.477 5.036 1.066 25.96 31.00 2.614th 11 60 2.018 7.27 50 0.141 3.00 5 0.15 3.15 0.446 5.482 1.027 28.52 34.00 2.913th 12 56 1.930 6.95 50 0.130 3.00 5 0.15 3.15 0.410 5.892 0.982 31.11 37.00 3.1
12th 13 52 1.842 6.63 50 0.119 3.00 5 0.15 3.15 0.376 6.268 0.937 33.73 40.00 3.4
11th 14 48 1.753 6.31 40 0.323 3.00 5 0.15 3.15 1.018 7.286 1.394 35.71 43.00 3.610th 15 44 1.665 5.99 40 0.294 3.00 5 0.15 3.15 0.925 8.212 1.324 37.79 46.00 3.8
9th 16 40 1.577 5.68 40 0.266 3.00 5 0.15 3.15 0.836 9.048 1.254 39.95 49.00 4.0
8th 17 36 1.450 5.22 40 0.227 3.00 5 0.15 3.15 0.716 9.764 1.153 42.24 52.00 4.27th 18 32 1.323 4.76 40 0.192 3.00 5 0.15 3.15 0.605 10.369 1.052 44.63 55.00 4.5
6th 19 28 1.197 4.31 40 0.159 3.00 5 0.15 3.15 0.502 10.871 0.952 47.13 58.00 4.75th 20 24 1.070 3.85 40 0.130 3.00 5 0.15 3.15 0.408 11.279 0.851 49.72 61.00 5.0
4th 21 20 0.943 3.40 40 0.103 3.00 5 0.15 3.15 0.323 11.602 0.750 52.40 64.00 5.23rd 22 16 0.817 2.94 32 0.233 3.00 5 0.15 3.15 0.733 12.335 1.015 54.66 67.00 5.52nd 23 12 0.690 2.48 32 0.170 3.00 5 0.15 3.15 0.537 12.872 0.857 57.13 70.00 5.71st 24 8 0.563 2.03 32 0.117 3.00 5 0.15 3.15 0.369 13.241 0.700 59.76 73.00 6.0
GF 25 4 0.437 1.57 25 0.243 3.00 5 0.15 3.15 0.766 14.006 0.889 61.99 76.00 6.2
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(Shaft - 01) Flushing (DOUBLE TOILET) IN1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
A 1 48 1.753 6.31 50 0.109 10.00 5 0.50 10.50 1.145 1.145 0.892 2.86 4.00
23th 2 48 1.753 6.31 50 0.109 3.00 5 0.15 3.15 0.343 1.488 0.892 5.51 7.0022th 3 46 1.709 6.15 50 0.104 3.00 5 0.15 3.15 0.328 1.816 0.870 8.18 10.00
21th 4 44 1.665 5.99 50 0.099 3.00 5 0.15 3.15 0.312 2.128 0.848 10.87 13.0020th 5 42 1.621 5.84 40 0.279 3.00 5 0.15 3.15 0.880 3.008 1.289 12.99 16.00
19th 6 40 1.577 5.68 40 0.266 3.00 5 0.15 3.15 0.836 3.844 1.254 15.16 19.0018th 7 38 1.513 5.45 40 0.246 3.00 5 0.15 3.15 0.775 4.620 1.204 17.38 22.00
17th 8 36 1.450 5.22 40 0.227 3.00 5 0.15 3.15 0.716 5.336 1.153 19.66 25.0016th 9 34 1.387 4.99 40 0.209 3.00 5 0.15 3.15 0.659 5.995 1.103 22.00 28.00 2.2
15th 10 32 1.323 4.76 40 0.192 3.00 5 0.15 3.15 0.605 6.600 1.052 24.40 31.00 2.414th 11 30 1.260 4.54 40 0.175 3.00 5 0.15 3.15 0.552 7.152 1.002 26.85 34.00 2.713th 12 28 1.197 4.31 40 0.159 3.00 5 0.15 3.15 0.502 7.654 0.952 29.35 37.00 2.9
12th 13 26 1.133 4.08 32 0.427 3.00 5 0.15 3.15 1.345 8.999 1.408 31.00 40.00 3.111th 14 24 1.070 3.85 32 0.384 3.00 5 0.15 3.15 1.209 10.209 1.330 32.79 43.00 3.3
10th 15 22 1.007 3.62 32 0.343 3.00 5 0.15 3.15 1.080 11.289 1.251 34.71 46.00 3.59th 16 20 0.943 3.40 32 0.304 3.00 5 0.15 3.15 0.958 12.247 1.172 36.75 49.00 3.7
8th 17 18 0.880 3.17 32 0.267 3.00 5 0.15 3.15 0.842 13.089 1.094 38.91 52.00 3.97th 18 16 0.817 2.94 32 0.233 3.00 5 0.15 3.15 0.733 13.822 1.015 41.18 55.00 4.1
6th 19 14 0.753 2.71 32 0.200 3.00 5 0.15 3.15 0.632 14.454 0.936 43.55 58.00 4.45th 20 12 0.690 2.48 25 0.567 3.00 5 0.15 3.15 1.786 16.240 1.405 44.76 61.00 4.5
4th 21 10 0.627 2.26 20 1.407 3.00 5 0.15 3.15 4.431 20.670 1.994 43.33 64.00 4.33rd 22 8 0.563 2.03 20 1.155 3.00 5 0.15 3.15 3.637 24.308 1.792 42.69 67.00 4.3
2nd 23 6 0.500 1.80 20 0.926 3.00 5 0.15 3.15 2.917 27.224 1.591 42.78 70.00 4.31st 24 4 0.437 1.57 20 0.720 3.00 5 0.15 3.15 2.270 29.494 1.389 43.51 73.00 4.4
GF 25 2 0.373 1.34 20 0.539 3.00 5 0.15 3.15 1.698 31.192 1.188 44.81 76.00 4.5
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(Shaft - 03) Domestic (SINGLE TOILET) IN
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16A 1 48 1.753 6.31 50 0.109 10.00 5 0.50 10.50 1.145 1.145 0.892 2.86 4.00
23th 2 48 1.753 6.31 50 0.109 3.00 5 0.15 3.15 0.343 1.488 0.892 5.51 7.0022th 3 46 1.709 6.15 50 0.104 3.00 5 0.15 3.15 0.328 1.816 0.870 8.18 10.0021th 4 44 1.665 5.99 50 0.099 3.00 5 0.15 3.15 0.312 2.128 0.848 10.87 13.00
20th 5 42 1.621 5.84 40 0.279 3.00 5 0.15 3.15 0.880 3.008 1.289 12.99 16.0019th 6 40 1.577 5.68 40 0.266 3.00 5 0.15 3.15 0.836 3.844 1.254 15.16 19.00
18th 7 38 1.513 5.45 40 0.246 3.00 5 0.15 3.15 0.775 4.620 1.204 17.38 22.00
17th 8 36 1.450 5.22 40 0.227 3.00 5 0.15 3.15 0.716 5.336 1.153 19.66 25.0016th 9 34 1.387 4.99 40 0.209 3.00 5 0.15 3.15 0.659 5.995 1.103 22.00 28.00 2.2
15th 10 32 1.323 4.76 40 0.192 3.00 5 0.15 3.15 0.605 6.600 1.052 24.40 31.00 2.414th 11 30 1.260 4.54 40 0.175 3.00 5 0.15 3.15 0.552 7.152 1.002 26.85 34.00 2.7
13th 12 28 1.197 4.31 40 0.159 3.00 5 0.15 3.15 0.502 7.654 0.952 29.35 37.00 2.912th 13 26 1.133 4.08 32 0.427 3.00 5 0.15 3.15 1.345 8.999 1.408 31.00 40.00 3.1
11th 14 24 1.070 3.85 32 0.384 3.00 5 0.15 3.15 1.209 10.209 1.330 32.79 43.00 3.310th 15 22 1.007 3.62 32 0.343 3.00 5 0.15 3.15 1.080 11.289 1.251 34.71 46.00 3.59th 16 20 0.943 3.40 32 0.304 3.00 5 0.15 3.15 0.958 12.247 1.172 36.75 49.00 3.7
8th 17 18 0.880 3.17 32 0.267 3.00 5 0.15 3.15 0.842 13.089 1.094 38.91 52.00 3.97th 18 16 0.817 2.94 32 0.233 3.00 5 0.15 3.15 0.733 13.822 1.015 41.18 55.00 4.1
6th 19 14 0.753 2.71 32 0.200 3.00 5 0.15 3.15 0.632 14.454 0.936 43.55 58.00 4.4
5th 20 12 0.690 2.48 25 0.567 3.00 5 0.15 3.15 1.786 16.240 1.405 44.76 61.00 4.54th 21 10 0.627 2.26 20 1.407 3.00 5 0.15 3.15 4.431 20.670 1.994 43.33 64.00 4.3
3rd 22 8 0.563 2.03 20 1.155 3.00 5 0.15 3.15 3.637 24.308 1.792 42.69 67.00 4.32nd 23 6 0.500 1.80 20 0.926 3.00 5 0.15 3.15 2.917 27.224 1.591 42.78 70.00 4.3
1st 24 4 0.437 1.57 20 0.720 3.00 5 0.15 3.15 2.270 29.494 1.389 43.51 73.00 4.4
GF 25 2 0.373 1.34 20 0.539 3.00 5 0.15 3.15 1.698 31.192 1.188 44.81 76.00 4.5
(Shaft - 03) Flushing (SINGLE TOILET) IN1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
A 1 24 1.070 3.85 50 0.044 10.00 5 0.50 10.50 0.459 0.459 0.545 3.54 4.0023th 2 24 1.070 3.85 50 0.044 3.00 5 0.15 3.15 0.138 0.596 0.545 6.40 7.0022th 3 23 1.038 3.74 50 0.041 3.00 5 0.15 3.15 0.130 0.726 0.529 9.27 10.00
21th 4 22 1.007 3.62 50 0.039 3.00 5 0.15 3.15 0.123 0.849 0.512 12.15 13.00
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20th 5 21 0.975 3.51 40 0.109 3.00 5 0.15 3.15 0.343 1.193 0.775 14.81 16.0019 h 6 20 0.943 3.40 40 0.103 3.00 5 0.15 3.15 0.323 1.516 0.750 17.48 19.0018th 7 19 0.912 3.28 40 0.096 3.00 5 0.15 3.15 0.303 1.819 0.725 20.18 22.00
17th 8 18 0.880 3.17 40 0.090 3.00 5 0.15 3.15 0.284 2.103 0.700 22.90 25.0016th 9 17 0.848 3.05 40 0.084 3.00 5 0.15 3.15 0.265 2.369 0.675 25.63 28.00 2.6
15th 10 16 0.817 2.94 32 0.233 3.00 5 0.15 3.15 0.733 3.102 1.015 27.90 31.00 2.814th 11 15 0.785 2.83 32 0.216 3.00 5 0.15 3.15 0.682 3.783 0.976 30.22 34.00 3.0
13th 12 14 0.753 2.71 32 0.200 3.00 5 0.15 3.15 0.632 4.415 0.936 32.59 37.00 3.312th 13 13 0.722 2.60 32 0.185 3.00 5 0.15 3.15 0.583 4.998 0.897 35.00 40.00 3.5
11th 14 12 0.690 2.48 32 0.170 3.00 5 0.15 3.15 0.537 5.535 0.857 37.47 43.00 3.710th 15 11 0.658 2.37 32 0.156 3.00 5 0.15 3.15 0.492 6.027 0.818 39.97 46.00 4.0
9th 16 10 0.627 2.26 32 0.143 3.00 5 0.15 3.15 0.449 6.476 0.779 42.52 49.00 4.38th 17 9 0.595 2.14 25 0.431 3.00 5 0.15 3.15 1.358 7.834 1.211 44.17 52.00 4.47th 18 8 0.563 2.03 25 0.389 3.00 5 0.15 3.15 1.227 9.060 1.147 45.94 55.00 4.6
6th 19 7 0.532 1.91 25 0.350 3.00 5 0.15 3.15 1.102 10.163 1.083 47.84 58.00 4.85th 20 6 0.500 1.80 25 0.312 3.00 5 0.15 3.15 0.984 11.146 1.018 49.85 61.00 5.0
4th 21 5 0.468 1.69 20 0.820 3.00 5 0.15 3.15 2.584 13.730 1.490 50.27 64.00 5.03rd 22 4 0.437 1.57 20 0.720 3.00 5 0.15 3.15 2.270 16.000 1.389 51.00 67.00 5.1
2nd 23 3 0.405 1.46 20 0.627 3.00 5 0.15 3.15 1.974 17.974 1.288 52.03 70.00 5.21st 24 2 0.373 1.34 20 0.539 3.00 5 0.15 3.15 1.698 19.672 1.188 53.33 73.00 5.3
GF 25 1 0.342 1.23 15 1.857 3.00 5 0.15 3.15 5.850 25.521 1.932 50.48 76.00 5.0
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PROJECT : ACROPOLIS GROUP HOUSING, SECTOR-108 , GURGAON, HARYANA.
SOLAR HOT WATER CALCULATION FOR PHASE - II (ATHENIA)
2 BHK apartment hot water requirement