Wednesday, 9 October 2019

SIZE OF SEWAGE TREATMENT PLANT / CAPACITY OF SEWAGE


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SIZE OF SEWAGE TREATMENT PLANT / CAPACITY  OF SEWAGE 


Before Calculating the size of STP calculate Total Domestic  Water Demand Required

Total domestic water demand  =  TWD 
Estimated Sewage X = 90 % of TWD
Estimate Sewerage X  = 90/100 * TWD

For  If TWD = 1600 KLD( Kilo  liter per day)

Capacity of S.T.P           = 90 / 100 * 1600 KLD
                                                      = 1440 KLD

 Space Requirement For 1440 Cum STP = 

Consider Total Depth 3.00 (Standard Depth )

Liquid Depth  L = 3.0 Mtr

 Size Of STP = 1440/3 = 480
                        =480/15 (Breadth Assumed) = 32 (Width )

Total Space =15*32*3= 1440 CUM 

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Tuesday, 8 October 2019

Thumb rules for designing a Column layout


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Thumb rules for designing a Column layout


Three thumb rules to be followed are as follows:

  1. Size of the Columns
  2. Distance between Columns
  3. Alignment of columns

1.Minimum Size of RCC columns

The size of the columns depends on the total load on the columns. There are axial loads and lateral loads. Large beam spans induce bending moment not only in the beams, but also in columns which are pulled by the stresses in the beams. It is important to use advanced structural design software like ETabs or Staad pro. I highly recommend every structural designer learn these software. The thumb rules are for general designing in very small projects.
For this general thumb rule, we will assume a structure of G+1 floors high, using standard 6″ walls.
Minimum size of an RCC column should not be less than 9” x 12” (225mm x 300mm) with 4 bars of 12 MM Fe415 Steel.
These days the minimum I use in my projects is 9″ x 12″ (225 mm x 300mm) with 6 bars of 12 MM Fe500 steel. You can never go wrong with strong columns. I also recommend use of M20 grade concrete for the structure (ratio 1 part Cement : 1.5 parts Sand : 3 parts Aggregate with 0.5 parts water by volume). I recommend use of 8 MM stirrups at a distance of 150 MM center to center throughout the length of column.
This setup of 9″ x 12″ RCC columns is safe for G+1 Floors. There are a lot of other considerations, but this is just a thumb rule.

2.Span (distance) between two columns

For the above column setup, a span of up to 5 meters is quite safe. One can use beams of size 9″ X 12″ (225 MM x 300MM) with a slab thickness of 5″ (125 MM) cast in M20 concrete for spans up to 5m. There are other considerations like secondary and tertiary spans, point loads and wall loads which have to be considered. It is complicated, but thumb rules can work if the structure is simple. It is always recommended to use structural design software like ETabs or Staad pro for design.
In a beam of up to 5 meters length, secondary spans of up to 4 meters, wall loads of up to 8 kN per running meter, I can use steel as below.
  • Top Steel – 2 bars of 12 MM
  • Crank bars – 2 bars of 12 MM, cranked at an angle of 45° at a distance of L/4 at both ends of a simply supported beam
  • Bottom Steel – 3 bars of 12 MM.
This configuration can change depending on a lot of factors.

3.Alignment of Columns

Placing of columns depend completely on the plan. A planner has a very important job. A grid column placement is always preferred in order to reduce point loads and unnecessary complications while construction. This reduces the cost of construction as well as time required for construction. Beams which have continuity with other simply supported beams have reduced bending moments, and thus require less steel and concrete depth to be safe.

Columns have to be connected with each other for smooth transfer of loads. An experienced planner will keep such things in mind when planning the structure.

Monday, 7 October 2019


Understanding Grades of Concrete
Grades of concrete are defined by the strength and composition of the concrete, and the minimum strength the concrete should have following 28 days of initial construction. The grade of concrete is understood in measurements of MPa, where M stands for mix and the MPa denotes the overall strength.
 
Concrete mixes are defined in ascending numbers of 5, starting at 10, and show the compressive strength of the concrete after 28 days. For instance, C10 has the strength of 10 newtons, C15 has the strength of 15 newtons, C20 has 20 newtons strength and so on.
 
Different mixes (M) come in various mix proportions of the various ingredients of cement, sand and coarse aggregates. For instance, M20 comes in the respective ratio of 1:1:5:3. You can see other examples below in the table.
 
Concrete GradeMix Ratio (cement : sand : aggregates)Compressive Strength
MPa (N/mm2)psi

Grades of Concrete
M51 : 5 : 105 MPa725 psi
M7.51 : 4 : 87.5 MPa1087 psi
M101 : 3 : 610 MPa1450 psi
M151 : 2 : 415 MPa2175 psi
M201 : 1.5 : 320 MPa2900 psi

Standard Grade of Concrete
M251 : 1 : 225 MPa3625 psi
M30Design Mix30 MPa4350 psi
M35Design Mix35 MPa5075 psi
M40Design Mix40 MPa5800 psi
M45Design Mix45 MPa6525 psi


High Strength Concrete Grades
M50Design Mix50 MPa7250 psi
M55Design Mix55 MPa7975 psi
M60Design Mix60 MPa8700 psi
M65Design Mix65 MPa9425 psi
M70Design Mix70 MPa10150 psi
 

Sunday, 6 October 2019

How deep is a sump pit?

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How deep is a sump pit?
The typical pit is 30 inches in depth and 18 to 24 inches across. The standard sump pit insert available in home improvement centers is 26 gallons and 18 inches diameter. In many cases the pit needs to be a minimum of 24 inches and up to a depth of 36 inches. But some builders just use a common 5-gallon bucket.
A small pit fills up with water very quickly and the sump pump has to turn on and off frequently, which shortens the life of the pump and of its check valve. Installing a store-sold backup pump in a small basin is impractical because of the risk of its float getting stuck and basement flooding.
In case the sump pit is still too small or crowded, you may need to dig through the bottom of the pail to place the main pump deeper or to cut the concrete and install a full-size sump pit. But many pumps have set turn-on level of 6 to 8" and turn-off at 3" level. Then, making the pit deeper would not affect the short-cycling of the pump. A larger diameter pit will take longer to fill, or install a pump with a switch that turns the pump on at a much higher level.
When the sump pump short-cycles, its thermal overload protection kicks in and shuts the pump down – the basement floods even though the sump pump is not broken and will return back to normal after it cools down.
The Hi & Dry backup pumps will not trip! They are placed well above the pit or the normal water level. Inside the pit, they only need enough space for the suction pipe and a float. And Hi & Dry battery pumps feature a slim-line vertical switch to avoid the risk of entanglement.