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MASTER PLUMBER REVIEW
Plumbing Design and Installation
PowerHouse Review Center
PLUMBING CONCEPTS
Part 1: Fundamentals of Plumbing Design and Installation
Part 2: Process, Design Criteria and Computations
PLUMBING
the art and technique of installing pipes, fixtures, and other apparatuses in buildings for bringing in the supply of liquids, substances and/or ingredients and removing them; and such
water, liquid and other carried-wasteshazardous to health, sanitation, life and property; also the
pipes and fixtures after installationi.e., the plumbing system
PLUMBING
Plumber title of the person who is skilled in plumbing
Plumbarius who worked in the field of sanitation in
ancient Rome
Plumbum means lead, the material the ancient
Rome used in plumbing
C o m p o n e n t s
WATER DISTRIBUTION SYSTEM
FIRE PROTECTION SYSTEM
PLUMBING FIXTURES
SANITARY DRAINAGE SYSTEM
STORM DRAINAGE SYSTEM
FUEL GAS PIPING SYSTEM
PLUMBING SYSTEM
Water Supply PVC, GI, BI, PE, HDPE, Steel,
BI Black Iron
Storm/Drainage System PVC, GI/BI
Vent System PVC
Sewer/Waste System PVC, CI
Fire Protection GI, BI
Co
mp
on
en
ts &
Flo
w in
Wat
er
Syst
em
s:
SUPPLY
Water Mains,Storage Tanks
DISTRIBUTION
Pressure,PipingNetworks
USE
PlumbingFixtures
COLLECTION
Gravity,PipingNetworks
TREATMENT
Sewage Plants,NaturalPurification
SOURCE
Lakes, Rivers,Reservoirs
Treated waterreturned to theoriginal source
DISPOSAL
Sanitary andStorm Sewers
THE PLUMBING CYCLE
NATIONAL PLUMBING CODE OF THE PHILIPPINES
Book of Master Plumbers practicing their profession in the Philippines
22 Basic Principles of the Plumbing Code
7 Code of Ethics
NATIONAL PLUMBING CODE OF THE PHILIPPINES
Board Resolution No. 4, Series of 1999
History of Plumbing Practice
Basic Principles
Master Plumbers Code of Ethics
CHAPTERS:1. Administration
2. Definitions
3. General Regulations
4. Plumbing Fixtures
NATIONAL PLUMBING CODE OF THE PHILIPPINES
5. Inspections and Tests6. Water Supply and Distribution7. Excreta Drainage System8. Indirect Waste Piping, Wet-Vented Systems, and Special
Wastes9. Vents and Venting10. Traps and Interceptors11. Storm Drainage System12. House Drains and House Sewers13. Joints and Connections14. Quality of Weight Materials, Plumbing Materials and
Referenced Standards
NATIONAL PLUMBING CODE OF THE PHILIPPINES
Appendix A: Recommended Rules for Sizing the Water Supply System
Appendix B: Private Sewage Disposal Systems
Tables and Charts
OBJECTIVES OF PLUMBING IN BUILDINGS
1. To supply water to different parts of the building
2. To remove and discharge human wastes and other substances out of the building into the public sewer or septic tank
CONDITIONS FOR AN EFFECTIVE WATER SUPPLY IN BUILDINGS
1. Provide sufficient amount of water to supply each fixture
2. Prevent back flow of used water into the water supply system
WATER DISTRIBUTION IN BUILDINGS
Part 1: Fundamentals of Plumbing Design and Installation
Part 2: Process, Design Criteria and Computations
THINGS TO CONSIDER IN THE PLANNING OF
WATER SYSTEM IN BUILDINGS
1. System must provide adequate supply of water, with adequate pressure up to the extremities of the system
2. System should be provided with sufficient valves and blow-offs to allow repair work without undue interruption of service
3. There should be no unprotected open reservoir, or cross connections with inferior water system to enter the system
4. Water system should be tight against leakage. Branches or connections should not be submerged in surface water or to any source of contamination
5. System design shall afford effective circulation of water with minimum number of dead end mains
6. System shall be guarded against contamination resulting from repair works, replacement or extension of the mains
7. When new are installed, or old mains repaired, they should be filled with strong chlorine solution of 40-60 mg/L for at least 24 hrs., and then flushed with water supplied normally from the main.
8. As much as possible water main should be laid above the elevation of concrete sanitary sewers, or crossover points, and at least 3m horizontally from such sanitary sewer when they are parallel. Otherwise, the sewer main must be
encased in concrete
CLASSIFICATION OF PUBLIC WATER DISTRIBUTION SYSTEM
1. DIRECT PRESSURE DISTRIBUTION
2. INDIRECT PRESSURE DISTRIBUTION
DIRECT PRESSURE DISTRIBUTION
Obtain its water supply through a large intake pipe, installed in the lake basin extended down the water;
Water is then drawn from the lake to a receiving well by force of gravity, passing through the filtration plant
The water inside the reservoir is pumped by a centrifugal, or piston pump into the water main with sufficient pressure to serve specific needs
INDIRECT PRESSURE DISTRIBUTION
Water drawn from a drilled distribution is done by indirect pressure using a turbine pump mounted on top of the standpipe extended down the well below the water table
HOUSEHOLD WATER SUPPLY
Water is conveyed from the main to the
household or buildings through:
1. House Service
2. Riser
3. Branches
House Service
pipe connection from the water main to any source of water supply to the building served
Riser
Vertical supply pipe which extend upward from one floor to the next.
Branches
Horizontal pipes that serve the faucets or fixtures
Water Main
Corporation Stop
Stop Box
Curb Stop
Meter Stop
House Service Pipe
Water Meter
Corporation Stop or CockCurb StopMeter Stop
Water Supply
Water Main
refers to the public water connection which are laid underground along the streets where the house service is connected
Corporation Stop
serves as a control of the water service, and a shut-off when service is disconnected
Curb Stop
installed between the curb & the sidewalk line to serve as control stop of the service between the curb and the building
Meter Stop
controlling stop of the entire water supply of the building
Water Meter
device used to measure the amount of water that passes through the water service
TYPES OF COLD WATER SYTEM
1. NORMAL PRESSURE FROM THE PUBLIC MAIN
2. OVERHEAD FEED SYSTEM
3. AIR PRESSURE DISTRIBUTION SYSTEM
Overhead Feed Distribution System
Overhead Feed System
This supplies water to plumbing fixtures by
means of gravity.
Advantages:
1. Water supply distribution is not affected by the peak load hour even if pressure at water main is low.
2. Power interruptions doesnt affect water supply
3. During break down of pumps and their repairs, water supply is not affected.
Disadvantages:
1. Water inside tank is exposed to the natural elements of weather, subject to contamination
2. Water distribution unit has many working parts that require higher maintenance cost
3. Pumping unit and the entire installation throughout the building occupies valuable spaces.
4. Requires stronger foundation and other structures to sustain heavy load of the tank and its water content
Direct Upfeed System
Direct Upfeed System
Used on tall buildings that could not be served by the street main
Operates in sequence according to the volume of demand:
When water demand is small, small (jockey) pump operates;
As water demand increases, the 2nd larger pump starts automatically to replace operation of the small pump
For peak demands, the largest pump operates with full capacity to supply the entire building
Only one pump operates at a time depending on the volume of water demand
Direct Upfeed System
Advantages
1. Eliminate the construction of large house water tank
2. Avoid cost of heavy structures to carry the house tank
3. Eliminate periodic cost
Air Pressured Water Distribution System
Distribution system where compressed air is used as the delivery agent
Advantages:
1. Has compact pumping system requiring limited space
2. Water chamber being air-tight makes the system as sanitary one
3. Oxygen in the CA serves as purifying agent making water more palatable
Air Pressured Water Distribution System
Advantages
4 Economical because it uses small pipe & fitting sizes; less maintenance/construction cost
5 Acceptable to small and tall buildings
Disadvantage:
1 Power interruption cuts water supply
4 Mechanical Devices used in Air Pressurized Water Supply System
1. Storage Tank
2. Single or Duplex centrifugal pump
3. Air compressor
4. Automatic pressure control switch
Friction in Water Supply
the resistance produced by the flowing water with the fittings and interior surface of the pipe
How to minimize friction:1. Pipes should be installed straight and direct2. Use of fittings, stops, turns, offset and traps
should be minimized3. Pipes with plain and smooth surface should be
used4. Fittings and joints must connected properly
Normal Pressure
refers to the pressure range measured over 24 hours
Normal Pressure
30-40 psi
Pressure Lower than Normal Pressure
results to insufficient flow of water
Pressure greater than 50 psi
may cause pipe hammering or even bursting of pipes
Pressure Reducing Valve
valve used to avoid excessive water pressure by keeping pressure constant at 40 psi or can be reset to other pressure desired
Critical Pressure
maximum and minimum pressure at which proper function of the water supply can be maintained
MAXIMUM PROBABLE DEMAND
Refers to the MAXIMUM WATER DISCHARGE OF FIXTURES in terms of Fixture units
THE MAXIMUM DEMAND OF WATER is equal to the TOTAL FIXTURES UNITS in the plumbing system
One unit is valued at 8 gals of water discharge per minute interval
Illustration:
A residential house has 3 water closets, 3
lavatories, 1 kitchen sink, and 3 shower baths.
Determine the maximum demand.
PROBABLE DEMANDOR PEAK LOAD
The fewer the number of fixtures installed,
the higher the percentage of probability of their
simultaneous use;
The greater the number of fixtures installed,
the lower the percentage of probable simultaneous use.
PROBABILITY OF SIMULTANEOUS OF FIXTURES
Number of Fixtures % of Simultaneous Use
1 to 5 50% to 100%
6 to 50 25% to 50%
51 or more 10% to 25%
PROBABLE DEMAND does not exceed 25% of the Maximum Water Demand
Illustration:
Determine the probable demand of the following
Fixtures installed: 2 water closets, 1 lavatory, 1
bathtub, 1 shower valve, 1 kitchen sink.
TYPES OF HOT WATER SYTEM
1. UPFEED AND GRAVITY RETURN SYSTEM
2. DOWNFEED AND GRAVITY RETURN SYSTEM
3. PUMP CIRCUIT SYSTEM
With a continuing network of pipes to provide constant circulation of water
Hot water rises on its own & does not need any pump for circulation
Hot water is immediately drawn form the fixture any time
Provided economical circulating return of unused hot water
Larger pipe is installed at thetop of the riser & the diminishing sizes passes through the lowerfloors of the building
Upfeed and Gravity Return System
Hot water rises on to the highest point of the plumbing system and travels to the fixtures via gravity (closed pipe system)
Water distribution is dependent on the expansion of hot water & gravity.
Larger pipe is installedat the bottom of theriser & the diminishing sizes passesthrough the upperfloors of the building
Downfeed and Gravity Return System
For a more efficient circulation of hot water to the upper floor levels of multi-storey buildings
Pump Circuit System
Water Tanks & Cisterns
Hot Water ConsumptionKIND OFBUILDING
GALLONS PERPERSONS PER HOUR
Office Buildings
School Buildings
Apartment Buildings
Hotels
Factories
Residential
4 to 5
2 to 3
8
8 to 10
4 to 6
10
Working Load of Hot Water Systems
KIND OF BUILDING AVERAGE WORKINGLOAD
School, Office & Industrial types
Apartments & Residences
Hotels & Restaurants
25%
35%
50%
Hot Water Space Heating System
Hot Water Supply System
Water is confined within a system at low temperature
Not a closed system which operate on much higher temperature
Protection of Hot Water Tank:
System Relief Valve
Temperature & Pressure Relief
Used for Hot Water Space Heating System
Used for Hot Water Supply System
TYPES OF WATER HEATING SYSTEM
FLUID COMPUTATIONS
Part 1: Fundamentals of Plumbing Design and Installation
Part 2: Process, Design Criteria and Computations
Water / Wastewater
Conversion
Example:
Convert cubic feet to gallons.
Gallons = Cubic Feet (ft3) x gal/ft3
ProblemHow many gallons of biosolids can be pumped to a digester that has 3600 cubic feet of volume available?
Convert gallons to pounds.
pounds ( lb ) = Gallons (gal) x 8.34 lb/gal
Problem
If 1650 gallons of solids are removed from the primary
settling tank, how many pounds of solids are removed?
Example:
Convert milligrams/liter to pounds.
key point: For plant operations, concentrations in milligrams per liter (mg/L) or parts per million (ppm) determined by laboratory testing must be converted to quantities of pounds, kilograms, pounds per day, or kilograms per day.
Pounds = Concentration (mg/L) x volume (MG)
x 8.34 lb/mg/L/MG
Problem
The solids concentration in an aeration tank is 2580 mg/L. The aeration tank volume is 0.95 MG. How many pounds of solids are
in the tank?
Example:
Convert milligrams per liter to pounds per day.
Pounds/day = Concentration (mg/L) x flow (MGD)
x 8.34 lb/mg/L/MG
Problem
How many pounds of solids are discharged per day when the plant effluent flow rate is 4.75 MGD and the effluent solids concentration is 26 mg/L?
Example:
Convert milligrams per liter to kilograms per day.
kg/day = Concentration (mg/L) x volume (MG)
x 3.785 kg/mg/L/MG
Problem
The effluent contains 26 mg/L of BOD5. How many kilograms per day of BOD5 are discharged when the effluent flow rate is 9.5 MGD?
Example:
Convert million gallons per day (MGD) to gallons per minute (gpm).
Flow = Flow (MGD) x 1,000,000 gal/MG
1440 min/day
Problem
The current flow rate is 5.55 MGD. What is the flow rate in gallons per minute?
Example:
Convert million gallons per day (MGD) to gallons per day (gpd)
Flow = Flow (MGD) x 1,000,000 gal/MG
Problem
The influent meter reads 28.8 MGD. What is the current flow rate in gallons per day?
Example:
Convert million gallons per day (MGD) to cubic feet per second (cfs)
Flow (cfs) = Flow (MGD) x 1.55 cfs/MGD
Problem
The flow rate entering grit channel is 2.89 MGD. What is the flow rate in cubic feet per second?
Example:
Problem
A liquid chemical with a specific gravity (SG) of 1.22 is pumped at a rate of 40 gpm. How many pounds per day are being delivered by the pump?
Example:
Temperature Conversions
Most water/wastewater operators are familiar with the formulae used for Fahrenheit and Celsius temperature conversions:
oC = 5/9 (oF 32)oF = 9/5 (oC) + 32
The difficulty arises when one tries to recall these formulae from memory. Probably the easiest way to recall these important formulae is to remember three basic steps for both Fahrenheit and Celsius conversions:
Add 40o
Multiply by the appropriate fraction (5/9 or 9/5) Subtract 40o
Suppose that we wish to convert 240oF to Celsius. Using the three-step process, we proceed as follows:
Step 1 : add 40o
240o + 40o = 280o
Step 2 : multiply 280o by either 5/9 or 9/5.
Because the conversion is to the Celsius scale, we will be moving to a
number smaller than 280. Through reason and observation, obviously, if 280 were multiplied by 9/5, the result would be almost the same as multiplying by 2, which would double 280 rather than make it smaller. If we multiply by 5/9, the result will be about he same as multiplying by . Because in this problem we wish to move to a smaller number, we should multiply by 5/9:
(5/9) (280o) = 156.0oC
Example:
Step 3 : now subtract 40o.
156.0o - 40o = 116.0oC
Thus, 240oF = 116.0oC
Convert 22oC to Fahrenheit.
Example:
FLOW
Flow is expressed in many different terms in the English system of measurement. The most commonly used flow terms are as follows:
gpm gallons per minute
cfs cubic feet per second
gpd gallons per day
MGD million gallons per day
In converting flow rates, the most common flow conversions are 1 cfs = 448 gpm and 1 gpm = 1440 gpd. To convert gallons per day to MGD, divide the gpdby 1,000,000. For example, convert 150,000 gallons to MGD:
150,000 gpd = 0.150 MGD
1,000,000
In some instances, flow is given in MGD but is needed in gpm. To make the conversion (MGD to gpm), two steps are required.
Step 1: convert the gpd by multiplying by 1,000,000.
Step 2: convert to gpm by dividing by the number of minutes in
a day (1440 min/day).
Problem
Convert 0.135 MGD to gpm.
Example:
In determining flow through a pipeline, channel, or stream, we use the following equation:
where
Q = cubic feet per second (cfs)
V = velocity in feet per second (ft/second)
A = area in square feet (ft2)
Problem
Find the flow in cubic feet per second (cfs) in an 8-inch line if the velocity is 3
feet per second.
Example:
Problem
Find the flow in gpm when the total flow for the day is 75,000 gpd.
Example:
Problem
Find the flow in gpm when the flow is 0.45 cfs.
Example:
DETENTION TIME
Detention time is the length of time water is retained in a vessel or the period from the time the water enters a settling basin until it flows out the other end. When calculating unit process detention times, we are calculating the length of time it takes the water to flow through that unit process. Detention times are normally calculated for the following basins or tanks:
Flash mix chambers (seconds)
Flocculation basins (minutes)
Sedimentation tanks or clarifiers (hours)
Wastewater ponds (days)
Oxidation ditch (hours)
To calculate the detention period of a basin, the volume of the basin must first be obtained. Using a basin 70 ft long (L), 25 ft wide (W), and 12 ft deep (D), the volume (V) would be:
V = L x W x D
V = 70 ft x 25 ft x 12 ft
V = 21,000 ft3
Gallons = V x 7.48 gal/f2
Gallons = 21,000 x 7.48 = 157,080 gallons
If we assume that the plant filters 300 gpm, then we have 157,080 / 300 = 524 minutes, or roughly 9 hours, of detention time. Stated another way, the detention time is the length of time theoretically required for the coagulated water to flow through the basin.
Key point: If the detention time is desired in minutes, then the flow rate used in the calculation should have the same time frame (cfm or gpm, depending on whether tank volume is expressed as cubic feet or gallons). If detention time is desired in hours, then the flow rate used in the calculation should be cfh or gph.
If chlorine is added to the water as it enters the basin, the chlorine contact time (CT) would be 9 hours. That is, to determine the CT (concentration of free chlorine residual x disinfectant contact time [in minutes] used to determine the effectiveness of chlorine), we must calculate detention time.
Key point: True detention time is the T portion of the CT value.
Detention time, of course, is calculated in units of time. The most common are seconds, minutes, hours, and days. Examples of detention time equations where time and volume units match include:
Detention time (sec) = volume of tank (cu ft)flow rate (cfs)
The simplest way to calculate detention time is to divide the volume of the
container by the flow rate into the container. The theoretical detention time of a container is the same as the amount of time it would take to fill the container if it were empty. For volume, the most common units used are gallons; however, on occasion, cubic feet may also be used. Time units will be in whatever units are used to express the flow. For example, if the flow is in gpm, the detention time will be in days, If, in the final result, the detention time is in the wrong time unit, simply convert to the appropriate units.
Detention time (days) = volume of tank (gal)flow rate (gph)
Problem
The reservoir for the community holds 110,000 gallons. The well will produce 60 gpm. What is the detention time in the reservoir in hours?
Example:
Problem
Find the detention time in a 55,000-gallon reservoir if the flow rate is 75 gpm.
Example:
HORSEPOWER AND ENERGY COSTS
In water/wastewater treatment and ancillaries, horsepower is a common expression for power. One horsepower is equal to 33,000 foot pounds (ft-lb) of work per minute. This value is determined, for example, for selecting the pump or combination of pumps to ensure an adequate pumping capacity (a major use of calculating horsepower in water/wastewater treatment). Pumping capacity depends upon the flow rate desired and the feet of head against which the pump must pump (also referred to as effective height).
Calculations of horsepower are made in conjunction with many treatment plant operations. The basic concept from which the horsepower calculation is derived is the concept of work, which involves the operation of a force (lb) over a specific distance (ft). The amount of work accomplished is measured in foot-pounds:
ft x lb = ft-lb
The rate of doing work (power) involves a time factor. Originally, the rate of doing work or power compared the power of a horse to that of a steam engine. The rate at which a horse could work was determined to be about 550 ft-lb/sec (or 33,000 ft-lb/min). This rate has become the definition of the standard unit called horsepower.
Horsepower (hp)
Horsepower (hp) = power (ft-lb/min)
33,000 ft-lb/min/hp
As mentioned, in water/wastewater treatment the major use of horsepower calculation is in pumping stations. When used for this purpose, the horsepower calculation can be modified as shown below.
Water Horsepower (whp)
The amount of power required to move a given volume of water a specified total head is known as water horsepower.
whp = pump rate (gpm) x total head (ft) x 8.34 lb/gal
33,000 ft-lb/min/hp
Problem
A pump must deliver 1210 gpm to a total head of 130 feet. What is the required water horsepower?
Example:
Brake Horsepower (bhp)
Brake horsepower (bhp) refers to the horsepower supplied to the pump from the motor. As power moves through the pump, additional horsepower is lost from slippage and friction of the shaft and other factors; thus, pump efficiencies range from about 50% to 85%, and pump efficiency must be taken into account.
bhp = whp
pump efficiency (%)
Problem
Under the specified conditions, the pump efficiency is 73%. If the required water horsepower is 40 hp, what is the required brake horsepower?
Example:
Motor Horsepower (mhp)
Motor horsepower (mhp) is the horsepower the motor must generate to produce the desired brake and water horsepower.
mhp = brake horsepower
motor efficiency (%)
Problem
The motor is 93% efficient. What is the required motor horsepower when the required brake horsepower is 49.0 bhp?
Example:
ELECTRICAL POWER
On occasion, water/wastewater operators (especially senior
operators) must make electrical power calculations especially regarding electrical energy required/consumed during a period of time. To accomplish this, horsepower is converted to electrical energy (kilowatts), then multiplied by the hours of operation to obtain kilowatt-hours.
Kilowatt-hours = hp x 0.746 kW/hp x operating time (hr)
Problem
A 60-horsepower motor operates at full load 12 hours per day, 7 days a week. How many kilowatts of energy does it consume per day?
Given the cost per kilowatt-hour, the operator (or anyone else) may calculate the cost of power for any given period of operation.
Cost = power required/day x kW-hr/day x days/period x cost/kW-hr
Example:
PD 856 Chapter 17 - Sewage Collection and
Disposal, Excreta Disposal and Drainage
Part 1: Fundamentals of Plumbing Design and Installation
Part 2: Process, Design Criteria and Computations
Section 3: Individual Excreta and Sewage Disposal System
3.1 Individual Excreta Disposal System Every plan and specifications for excreta disposal
system approved by the local health authority prior to construction.
The City/Municipal Building Official shall refer all applications for Sanitary (Plumbing) Permit to the Local Health Authority prior to issuance of building permit.
The privy recommended for use is the sanitary privy.
The sanitary privy shall be atleast one (1) meter square.
Section 3: Individual Excreta and Sewage Disposal System
3.2 Individual Sewage Disposal System3.2.1 Installation Requirements When a public sanitary sewer is not available,
wastewater piping shall be provided with individual sewage disposal system of approve type and design.
The public sanitary sewer may be considered as not being available when such public sanitary sewer is located more than 100 meters from any proposed building on any lot or premises.
Section 3: Individual Excreta and Sewage Disposal System
3.2 Individual Sewage Disposal System
3.2.2 Approval
The Local Health Authority may require any or all of the following information before Sanitary (Plumbing) Permit is issued.
Plot plan drawn to scale completely dimensioned, showing direction and approx slope of surface
Location of all present and proposed retaining walls, drainage channels, water supply lines and wells
Number of plumbing fixtures
Location of building sanitary sewer and individual sewage disposal system
A log of soil formations and ground water levels, together with a statement of water absorption characteristics of the soil
Section 3: Individual Excreta and Sewage Disposal System
3.2 Individual Sewage Disposal System3.2.2 Disposal of Sewage Individual sewage disposal system utilizing leaching fields,
leaching beds, or leaching wells shall not be permitted where the depth to normal ground water or rock strata is less than 1.20 meters
A leaching system shall not be installed in an area where the texture, structure, and porosity of soil are not suitable as determined by a percolation test performed by a registered Civil/Sanitary Engineer.
No leaching tile file or bed shall be installed where percolation rate is less than 2.54 cm fall in water level in test holes in 60 minutes.
No seepage pit or leaching well shall be installed where percolation rate is less than 2.54 cm fall in water level in test holes in 30 minutes.
Section 4: Design and Construction of Septic Tanks, Leaching Tile Field and House Sewers
4.1 Septic Tank4.1.1 Design Capacity May be determined from the quantities of Sewage
Flow, based on adequate detention time interval resulting in efficient sedimentation.
For building with occupants, the number of persons to be served shall be computed based on the number of rooms and considering each room as occupied by two persons or on basis of the actual number of persons served by the tank, whichever is greater.
Section 4: Design and Construction of Septic Tanks, Leaching Tile Field and House Sewers
4.1 Septic Tank4.1.2 Inlet and Outlet The invert level of the inlet shall not be less than 5 cm
above the liquid level of the septic tank. A vented inlet baffle or sanitary tee shall be provided to
divert the incoming sewage downward. The baffle or tee shall penetrate at least 15 cm below the liquid level, but the penetration shall not be greater than that allowed for the outlets baffle or sanitary tee.
The outlet baffle or sanitary device shall extend through the scum layer above the liquid level of the tank to approximately 2.5 cm from the inside top of the tank.
The invert of the inlet pipes shall be at a level not less than 5 cm above the invert of the outlet pipe
Section 4: Design and Construction of Septic Tanks, Leaching Tile Field and House Sewers
4.1 Septic Tank
4.1.3 Tank Proportions
If two or more compartments are used, the first compartment shall have the capacity from one-half to two-thirds of the total volume of the tank.
The septic tank shall have a liquid drawing depth not less than 1.20 meters (4 feet).
The vertical distance from the liquid level to the inside top of the tank shall be at least 20 cm (8in).
Section 4: Design and Construction of Septic Tanks, Leaching Tile Field and House Sewers
4.1 Septic Tank4.1.4 Inspection Manholes Shall be provided with an inspection manhole 0.36
sq.m. (4 sq.ft.) in minimum area or by equivalent removable cover slab to provide access to the inlet and outlet devices and to the compartment of the tank for inspection and cleaning.
Septic tanks installed under concrete or block top paving shall have the required manholes accessible by extending the manhole openings to grade.
Section 4: Design and Construction of Septic Tanks, Leaching Tile Field and House Sewers
4.1 Septic Tank
4.1.5 Construction of Septic Tank
4.1.6 Location
Shall be located not less than 25 metersfrom any well, spring, cistern, or other sources of drinking water supply; not less than 1.5 m from any water service line; and not less than 3.0 meters away from water main.
Shall not be located under the building.
Section 4: Design and Construction of Septic Tanks, Leaching Tile Field and House Sewers
4.1 Septic Tank
4.1.7 Maintenance
Shall be inspected at least once a year and be cleaned when the bottom of the scum mat is within 3 inches of the bottom of the outlet device or the sludge and scum has reduced the liquid capacity by 50%.
Tanks shall not be washed or disinfected after cleaning. A small residual of sludge shall be left in the tank for seeding.
Section 4: Design and Construction of Septic Tanks, Leaching Tile Field and House Sewers
4.2 Leaching Tile Field
4.2.1 Design
A leaching tile system utilizing trenches 0.45-0.90 m wide is considered to be a leaching tile field.
A leaching tile system utilizing trenches more than 0.90 m wide is considered to be a leaching bed.
Section 4: Design and Construction of Septic Tanks, Leaching Tile Field and House Sewers
4.2 Leaching Tile Field
4.2.2 Construction
The leaching tile field or leaching bed shall be located not less than 25 meters from any well, spring, cistern, or other source of drinking water supply; not less than 3 meters from an occupied building; and not less than 1.5 meters from any lot line.
Section 4: Design and Construction of Septic Tanks, Leaching Tile Field and House Sewers
4.3 House Sewers
4.3.1 Design
Minimum size shall not be less than 100mm (4 inches) in diameter
Section 5: Public Sewerage System
5.2 Provision of Sewerage System
5.2.2 Operation of Sewage Treatment Plants
a. The sewage treatment plant shall be capable of treating the flow of sewage discharged by the community in the area.
b. The type of sewage treatment plant shall be approved by the Secretary or his duly authorized representative and the effluent from such treatment plants shall meet the standards formulated by the Department of Environment and Natural Resources.
c. The sewage treatment plant shall provide laboratory facilities for control tests and other examinations needed.
Section 5: Public Sewerage System
5.2 Provision of Sewerage System5.2.2 Operation of Sewage Treatment Plantsd. Operating data, control tests and such other
records as may be required shall be forwarded to the local health authority.
e. The local health authority shall be informed in case of breakdown or improper functioning of the treatment works.
f. Where sewage treatment plant is provided, no sewage shall be allowed to by-pass the plant.
g. The sewage treatment plant shall be managed by a registered sanitary engineer.
Section 6: Damage to Public Sewer or Sewage Disposal System
6.1 It is unlawful for any person to discharge anything which would cause damage to the public sewage disposal system, whether the system is government or privately-owned.
Effectivity
IRR of the Chapter 17 of PD 856 was approved on December 21, 1995
Date of Publication: February 22, 1996
Private Sewage Disposal Systems
Definition: (SEPTIC TANK)
A watertight covered receptacle designed and constructed to
receive the discharge of sewage from a building sewer, separate solids from the liquid, digest organic matter and store digested solids through a period of detention, and allow the clarified liquids to discharge for final disposal
SLUDGE- solid organic matter that are denser than water and settle at the bottom of the septic tank
SCUM- lighter organic material that rise to the surface of the water
EFFLUENT- liquid content of sewage
DISPOSAL PHASE- the final stage of the plumbing process; where used water and water-carried wastes are brought to various disposal outlets
Bacteria in septic tankto encourage decomposition:
Aerobic bacteria- relies on oxygen to survive
Anaerobic bacteria- can survive in places without oxygen
SEPTIC TANK
MinimumDimensions:L= 1500mmW=900mmD=1200mm
SEPTIC TANK
SINGLE CHAMBER SEPTIC TANK:
SEPTIC TANK
should show all dimensions, reinforcing, structural calculations, and such other pertinent data as needed.
DESIGN CRITERIA:
PLANS:
shall be such as to produce a clarified effluent of acceptable standards and shall provide adequate space for sludge and scum accumulations.
QUALITY OF DESIGN:
constructed of durable materials, not subject to excessive corrosion or decay, shall be watertight.
MATERIALS:
Material: cement (most common) or pre-fabricated cast iron
SEPTIC TANK
have a minimum of 2 compartments:First compartment: not less than 2/3 capacity of the total capacity of tank; not less than 2 cum liquid capacity; shall be at least 0.9 m width and 1.5 m long; Liquid depth not less than 0.6 m nor more than 1.8 m.Secondary compartment: maximum capacity of 1/3 total capacity of tank; minimum of 1 cum liquid capacity
COMPARTMENTS:
In septic tanks having over 6 cum capacity, the secondary compartment should be not less than 1.5 m in length.
with at least two (2) manholes, 508 mm in min dimension; one over inlet, other over outlet. Wherever first compartment exceeds 3.7 m in length, an additional manhole required over the baffle wall.
MANHOLES:
maintain a slope of 1:10 at the bottom of the digestion chamber to collect the sludge and make it easily accessible from the manhole
SEPTIC TANK
Inlet and Outlet pipes diameter size not less than the sewer pipe
SIZES OF PIPE INLET & OUTLET & THEIR VERTICAL LEGS:
Vertical legs of inlet and outlet pipes diameter size not less than the sewer pipe nor less than 104.6 mm.
Shall extend 101.6 mm above and at least 304.8 mm below the water surface
LENGTH AND LOCATION OF INLET & OUTLET:
Invert of the inlet pipe shall be at a level not less than 50.8 mm above the invert of the outlet pipe.
equal to the cross sectional area of the house sewer.
VENT DIAMETER:
SEPTIC TANK
Side walls shall extend 228.6 mm above liquid depth.
AIR SPACE:
Cover of septic tank shall be at least 50.8 mm above the back vent openings.
PARTITION (between compartments):
An inverted fitting equivalent in size to the tank inlet, but in no case less than 104.6 mm in diameter, shall be installed in the inlet compartment side of the baffle with the bottom of the fitting placed midway in the depth of the liquid. Wooden baffles are prohibited.
Shall be capable of supporting an earth load of not less than 14.4 kPa
STRUCTURE:
SEPTIC TANK
The capacity of septic tanks is determined by the number of bedrooms or apartment units in dwelling occupancies; by the estimated waste/sewage design flow rate for various building occupancies; or by the number of fixture units of all plumbing fixtures; whichever is greater.
CAPACITY:
The capacity of any one septic tank and its drainage system shall also be limited by the soil structure classification in its drainage field.
Should not be located underneath the house
LOCATION:
At least 15 meters from the water distribution system
SEPTIC TANK
Isometric Viewof a Typical Drainage System with Septic Tank System
Private sewage disposal system common in rural areas for structures with large adjacent open fields
DISPOSAL FIELD
No excavation for leach bed shall extend within 1.5 m of the water table.
DISTANCE FROM WATER TABLE:
WITH SEEPAGE PIT:
Filter material in the trenches shall terminate 1.5 m from pit excavation and the pipe extending from such points to the seepage pit shall be watertight.
dependent on the required septic tank capacity or estimated sewage flow rate, whichever is greater, and;the type of soil found in the excavation.
AREA:
DISPOSAL FIELD
based on the quantity of liquid waste and on the character and porosity of the surrounding soil.
CAPACITY:
Circular in shape with excavated diameter of not less than 2.2 m and to be lined with clay or concrete brick.
SIZE OF SEEPAGE PIT:
a loosely lined excavation in the ground, which receives the discharge of a septic tank; designed to permit effluent to seep through pit bottom and sides
SEEPAGE PITS
Brick lining shall have a minimum compressive strength of 17225 kPa.
STRENGTH:
served through a distribution box or shall be connected in series by means of a watertight connection. The outlet shall have a vented leg fitting extending 304.8 mm below the inlet fitting.
MULTIPLE SEEPAGE PITS:
SEEPAGE PITS
a non-watertight linedexcavation in the groundwhich receives the dischargeof a sanitary drainage system,designed to retain the organicmatter but permitting the liquidto seep through the pit bottomand sides
CEESPOOLS
Temporary expedient pending the construction of a public sewer, so long as it is established that a public sewer will be available in less than 2 years and the soil and ground water conditions are favorable;
TEMPORARY PERMITS:
As an overflow facility when installed in conjunction with an existing cesspool;
As a means of sewage disposal for limited, minor, or temporary uses.
CEESPOOLS
Outside Privy- oldest form of disposal of organic waste. Consists of a vault constructed of concrete for the collection of raw sewage and a wooden shelter
PRIVIES
When liquid wastes containing excessive amounts of grease, garbage, flammable wastes, sand, or other ingredients which may affect the operation of a private sewage disposal system, an interceptor for such waste shall be installed.
REQUIREMENTS:
Waste from interceptors may be discharged to a septic tank or other primary system or into a separate disposal system.
DISPOSAL:
COMMERCIAL/INDUSTRIAL SPECIAL LIQUID WASTE DISPOSAL
GENERAL GUIDELINES FOR PRIVATE SEWAGE DISPOSAL SYSTEMS
Location of Sewage Disposal System
MIN. HORIZONTALDISTANCE IN CLEARREQUIRED FROM
BLDGSEWER
SEEPAGEPIT OR
CESSPOOL
SEPTICTANK
1Buildings or
structures*
0.6 m1.5 m 2.4 m 2.4 m
2
Property line
Adjoining private
Property
Clear** 1.5 m 1.5 m 2.4 m
3Water supply
wells15.2 m 15.2 m 30.5 m 45.7 m
4 Streams15.2 m 15.2 m
15.2 m 30.5 m
5 Trees - 3 m - 3 m
Private Sewage Disposal Systems
DISPOSALFIELD
Location of Sewage Disposal System
MIN. HORIZONTALDISTANCE IN CLEARREQUIRED FROM
BLDGSEWER
DISPOSALFIELD
SEEPAGEPIT OR
CESSPOOL
SEPTICTANK
6Seepage pits or
Cesspools- 1.5 m 1.5 m 3.7 m
7 Disposal field 1.5 m 1.2 m 1.5 m
8On site domestic
Water service line0.3 m 1.5 m 1.5 m 1.5 m
9Pressure public
Water main3 m 3 m 3 m 3 m
Private Sewage Disposal Systems
GENERAL GUIDELINES FOR PRIVATE SEWAGE DISPOSAL SYSTEMS
Sewage Treatment Plan (STP)
An aeration system within the tank;
Some features of STP:
A submersible mixer to mix the waste;A sludge waste pump that aids in clarifying;A decanter;Blowers;A fully electronic control system, etc.
DESIGN OF GREASE TRAP
Part 1: Fundamentals of Plumbing Design and Installation
Part 2: Process, Design Criteria and Computations
MASTER PLUMBER REVIEW
Plumbing Design and Installation
Thank You.