ENVIRONMENTAL ENGINEERING : Treatment of Sewage Notes

 Treatment of Sewage

 Sedimentation Tank

Settling Velocity

(i) 

  for d < 0.1 mm

 Where,

  The velocity of the settlement of particle or settling velocity in m/sec.

 d= The diameter of the particle in the meter.

 G= Specific gravity of the particle.

 v= Kinematic viscosity of water in m²/sec.

  Dynamic viscosity

  Density

(ii)

where, 

 → For laminar flow

  Reynolds number   

  for transition flow.

(when flow is transition)

  for turbulent flow.

(when flow is turbulent)

(iii)

(iv) Newtons Equation for Turbulent Settling

(v) Modified Hazen’s Equation for Transition Zone

 (a)  

 Where T = Temperature in ^oC.

 (b) Putting G = 2.65 for Inorganic Solids

 (c) Putting G = 1.2 for Organic Solids

Critical Scour Velocity in Constant Velocity Horizontal Flow Grit Chamber  

PROPORTIONAL FLOW WEIR

 Where,

  B= Width of the channel.

V_h = Horizontal flow velocity.

 C_D =Coefficient of discharge.

 x and y are coordinates on weir profile.

Parabolically or V-Shaped Grit Chamber Provided with a Parshall Flume

(i) Parshall Flume

 Where,

  W=Width of the throat in the meter.

  Q=Flow in (m³/sec) through Parshall flume.

H_a=  Depth of flow in the upstream leg of a flume of one-third portion in the meter.

(ii) Parabolic Grit Channel

 Where,

 n = Discharge coefficients of the control section.

 = 1.5 for partial flume.

 = 1 for proportional flow weir.

• Aerated Grit Channels

• Detritus Tank

Skimming Tank

 (i) Detention Period = 3 to 5 minutes.

 (ii) Amount of compressed air required = 300 to 6000 m³ per million liters of sewage.

 (iii) Surface Area,

 Where,

  Rate of flow of sewage in m³/day.

  Min. rising velocity of greasy material to be removed in m/min

 = 0.25 m/min mostly.

Vacuators

 Vacuum Pressure = 0 to 25 cm of Hg

 For 10 to 15 minutes.

• Sedimentation Tank

 (i) Overflow rate

 = 40000 to 50000 lit/m² day for plain sedimentation.

 = 50000 to 60000 lit/m² day for sedimentation with coagulation.

 = 25000 to 35000 lit/m² day for secondary sedimentation tank

 (ii) Depth ~ 2.4 to 3.6 m.

 (iii) Detention time = 1 to 2 hour.

 (iv) width = 6.0 m

 (v) Length = 4 to 5 times width.

 (vi) Velocity of flow V_f = 0.3 m/min.

 (vii) 

 Where,

 V = Flow velocity

 B = Width of the Basin

 H = Depth of sewage in the tank.

 (viii)  

 (ix)  

• Detention Time

(a)  For rectangular Tank

(b)  for circular tank

Where

d = Dia of the tank

H = Vertical depth of wall or side depth

• Displacement Efficiency

Trickling Filter

 (a) Conventional Trickling Filter or Low Rate Trickling Filter

 Where,

  The efficiency of the filter and its secondary clarifier, in terms of % of applied BOD

  Organic loading in kg/ha-m/day applied to the filter (called unit organic loading)

 (b) High Rate Trickling Filter

 (i)  

 Where, F = Recirculation factor

 Recirculation ratio

 (ii)  

 Where,

 Y = Total organic loading in kg/day applied to the filter i.e. the total BOD in kg.

  Unit organic loading in kg/Ha-m/day

 V = Filter volume in Ha-m.

 % efficiency of single-stage high rate trickling filter.

 (iii) 

 Where,

  Final efficiency in the two-stage filter.

  Total BOD in the effluent from the first stage in kg/day.

  Recirculation factor for second stage filter

  Volume in second stage filter in ha-m.

 Dunbar Filter

 Surface loading = 25000 MI/m²/day.

 BOD removed = 85%

 Sludge and its Moisture Content

 The volume of sludge at moisture content P₁%

 The volume of sludge at moisture content P%

Sludge Digestion Tank

(i) When the change during digestion is linear.

 (a)  

 Where,

  The volume of digestion in m³.

  Raw sludge added per day (m³/day)

Equivalent digested sludge produced per day on completion of digestion, m³/day.

Digestion period in the day.

(b) with monsoon storage

Where,

T = Number of days for which digested sludge  is stored (monsoon) storage)

(ii) When the change during digestion is parabolic

(a) without monsoon storage

 (b)  without monsoon storage

 Destruction and Removal Efficiency (DRE)

 Where,

  The mass fill rate of one POHC (Principal organic Hazardous constituent) in the waste stream.

  Mass emission rate of the same POHC present in the exhaust emission prior to release to the atmosphere.

Aeration Tank (ASP)

(i) Detention period,  

 Where

 V = Volume of the tank in m³.

 Q = Quantity of wastewater flow into the aeration tank excluding the quantity of recycled sludge (m³/day)

(ii) Volumetric BOD Loading or Organic Loading, (U)  

 Where,

  Mass of BOD applied per day to the aeration tank through influent sewage in gm.

  The volume of the aeration tank in m3.

 Q= Sewage flows into the aeration tank in m³.

  BOD₅ in mg/lit (or gm/m3) of the influent sewage.

(iii)  

 Where,

 (F/M) Food (F) to Microorganism (M) ratio

 Daily BOD applied to the aeration system in gm.

 5 day BOD of the influent sewage in mg/lit.

 Q=The flow of influent sewage in m³/day.

X_t = MLSS (Mixed liquor suspended solids) in mg/lit.

 V=The volume of the Aeration Tank (lit).

 Total microbial mass in the system in gm.

(iv) Sludge Age  

 (a)  

 (b)  

 Where,

 The concentration of solids in the influent of the Aeration Tank called the MLSS i.e. mixed liquor suspended solids in mg/lit.

V = Volume of Aerator

 =The volume of waste sludge per day

 The concentration of solids in the returned sludge or in the wasted sludge (both being equal) in mg/lit.

 Q=Sewage inflow per day.

 The concentration of solids in the effluent in mg/lit.

(v) Sludge Volume Index (S.V.I)

 Where,

 Concentration of suspended solids in the mixed liquor in mg/lit.

 Settled sludge volume in ml/lit.

S.V.I= Sludge volume index in ml/gm.

(vi) Sludge Recycle and Rate of Return Sludge

 Where,

 Sludge recirculation rate in m³/day.

 MLSS in the aeration tank in mg/lit.

 MLSS in the returned or wasted sludge in mg/lit.

 S.V.I = Sludge volume index in ml/gm.

• Specific substrate utilization rate

  for MLSS and 0.6 for MLVSS,  

• Oxygen Requirement of the Aeration Tank

 Where,

• Oxygen Transfer Capacity (N)

 Where,

  N=Oxygen transferred under field conditions in kg O₂/k.wh (Or MJ)

 N_s= Oxygen transfer capacity under standard conditions in kg O₂/kwh (or MJ)

  Ds =Dissolved oxygen-saturation value for sewage at operating temperature.

  Operation D.O level in Areation tank usually 1 to 2 mg/lit.

 T= Temperature in ^oC

  Correction factor for oxygen transfer for sewage usually 0.8 to 0.85.

Oxidation Ponds

• Depth → 1.0 to 1.8 m.
• Detention period → 2 to 6 weeks.
• Organic loading → 150 to 300 kg/ha/day.

 Under hot condition → 60 to 90 kg/ha/day.

 Under cold conditions.

• Length to width ratio = 2
• Sludge Accumulation = 2 to 5 cm/year
• Minimum depth to be kept = 0.3 m.

For Inlet Pipe Design

 Assume V = 0.9 m/s

 Assume flow for 8 hrs.

For Outlet Pipe Design

 Dia of outlet = 1.5 dia of the inlet pipe

Septic Tank

• Detention time = 12 to 36 hr.
• Sludge accumulation rate = 30 lit/cap/year.
• Sewage flow = 90 to 150 lit/capita/day.
• Cleaning period = 6 to 12 months
• Length to width ratio = 2 to 3 m.
• Depth = 1.2 to 1.8 m
• Width ≮ 0.9 m.
• Free board = 0.3 m.  
•               

If you are preparing for ESE/ GATE or other PSU Exams (Civil Engineering), then avail Online Classroom Program for ESE and GATE CE:

Online Classroom Program for ESE/GATE CE(20+ Courses and 180+ Mock Tests)

You can avail of BYJU'S Exam Prep Test Series specially designed for all AE & JE Exams:

BYJU'S Exam Prep Test Series AE & JE (160+ Mock Tests)

You can avail of BYJU'S Exam Prep Test Series specially designed for all Civil Engineering Exams:

BYJU'S Exam Prep Test Series ESE/GATE CE (180+ Mock Tests)

Thanks

Sahi Prep Hai To Life Set Hai.