L 11 screen chamber
jshrikant
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30 slides
Mar 11, 2015
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About This Presentation
Lecture notes of Environmental Engineering-II as per Solapur university syllabus of TE CIVIL.
Prepared by
Prof S S Jahagirdar,
Associate Professor,
N K Orchid college of Engg and Technology,
Solapur
Slide Content
LL--1111
Screen Chamber Screen Chamber Screen Chamber Screen Chamber
Environmental Engineering-II
Unit-II
Screen Chamber Screen Chamber Screen Chamber Screen Chamber
Environmental Engineering-II
Unit-II
Screening, Screening,
Definition:
Screening is a unit operation that
separates large floating materials in
and/or on water (found in different and/or on water (found in different sizes) from water and from entering
water treatment/ Wastewater
treatment facilities and mains.
The unit involved is called a screen.
Definition:
Screening is a unit operation that
separates large floating materials in
and/or on water (found in different and/or on water (found in different sizes) from water and from entering
water treatment/ Wastewater
treatment facilities and mains.
The unit involved is called a screen.
Objective of providing screens Objective of providing screens
Screens are provided to protect:
i.
Pumps
ii.
Valves
ii.
Valves
iii.
Pipe line and other appurtenances
from damage or clogging by rags
and other large objects
Screens are provided to protect:
i.
Pumps
ii.
Valves
ii.
Valves
iii.
Pipe line and other appurtenances
from damage or clogging by rags
and other large objects
Bar Screen Bar Screen
Vendor Vendor--Provided Equipment Provided Equipment
Purpose: to remove large objects (sticks,
cans, etc) which may cause flow
obstructions.
Depending on the size of the plant, bar
Depending on the size of the plant, bar screens are either hand or mechanically
cleaned.
Hand cleaned: used primarily at small
plants.
Vendor Vendor--Provided Equipment Provided Equipment
Purpose: to remove large objects (sticks,
cans, etc) which may cause flow
obstructions.
Depending on the size of the plant, bar
Depending on the size of the plant, bar screens are either hand or mechanically
cleaned.
Hand cleaned: used primarily at small
plants.
Bar Screen Bar Screen
Mechanically Cleaned Mechanically Cleaned
More frequently used because labor and
overflowing are greatly reduced.
A by-pass channel with a hand cleaned bar
screen must also be provided. A second
mechanically cleaned bar screen can also be mechanically cleaned bar screen can also be provided.
The purpose of the by-pass channel is to
provide treatment in case of a mechanical
failure.
Screens are either front or back cleaned.
Mechanically Cleaned Mechanically Cleaned
More frequently used because labor and
overflowing are greatly reduced.
A by-pass channel with a hand cleaned bar
screen must also be provided. A second
mechanically cleaned bar screen can also be mechanically cleaned bar screen can also be provided.
The purpose of the by-pass channel is to
provide treatment in case of a mechanical
failure.
Screens are either front or back cleaned.
Bar Screen Bar Screen
13
Bar Screen Bar Screen
13
Bar Screen Bar Screen
Classification of Screens Classification of Screens
Point of
Comparison
Coarse
screen
Medium
screen
Fine
screen
Angle of
Inclination
@ 45
0
30
0
to 60
0
30
0
to
60
0
Openings 50 mm
or more
6-40mm1.5 to 3
mm
Cleaning
Mechanically or
manually cleaned
Comparison
Coarse
screen
Medium
screen
Fine
screen
Angle of
Inclination
@ 45
0
30
0
to 60
0
30
0
to
60
0
Openings 50 mm
or more
6-40mm1.5 to 3
mm
Cleaning
Mechanically or
manually cleaned
Disposalof
screenings
By Burialor dumping or
incineration
Screenings
collection
6 lit of solids/
30 to 90 lit solids/
mLd
20% of SS from
collection
solids/ mLd
solids/
mLd
SS from sewage
Frequency
ofclogging
less moderateOften or
more
screenings
By Burialor dumping or
incineration
Screenings
collection
6 lit of solids/
30 to 90 lit solids/
mLd
20% of SS from
collection
solids/ mLd
solids/
mLd
SS from sewage
Frequency
ofclogging
less moderateOften or
more
Velocity Velocity
The velocity of flow ahead of and through the screen varies and affects its operation.
The lower the velocity through the screen, the greater is the amount of screenings that would be removed from sewage. that would be removed from sewage.
However, the lower the velocity, the
greater would be the amount of solids
deposited in the channel.
The velocity of flow ahead of and through the screen varies and affects its operation.
The lower the velocity through the screen, the greater is the amount of screenings that would be removed from sewage. that would be removed from sewage.
However, the lower the velocity, the
greater would be the amount of solids
deposited in the channel.
Hence, the design velocity should be such
as to permit 100% removal of material of
certain size without undue depositions.
Velocities of 0.6 to 1.2 m/s through the
open area for the peak flows have been
used satisfactorily. used satisfactorily.
Further, the velocity at low flows in the
approach channel should not be less than
0.3 m/s to avoid deposition of solids.
Hence, the design velocity should be such
as to permit 100% removal of material of
certain size without undue depositions.
Velocities of 0.6 to 1.2 m/s through the
open area for the peak flows have been
used satisfactorily. used satisfactorily.
Further, the velocity at low flows in the
approach channel should not be less than
0.3 m/s to avoid deposition of solids.
Head loss Head loss
Head loss varies with the quantity and
nature of screenings allowed to
accumulate between cleanings.
The head loss created by a clean screen
The head loss created by a clean screen may be calculated by considering the flow and the effective areas of screen
openings, the latter being the sum of the
vertical projections of the openings.
Head loss varies with the quantity and
nature of screenings allowed to
accumulate between cleanings.
The head loss created by a clean screen
The head loss created by a clean screen may be calculated by considering the flow and the effective areas of screen
openings, the latter being the sum of the
vertical projections of the openings.
The head loss through clean flat bar
screens is calculated from the following
formula:
h = 0.0729 (V
2
-v
2
)
where, h = head loss in m
where, h = head loss in m
V = velocity through the screen in m/s
v = velocity before the screen in m/s
The head loss through clean flat bar
screens is calculated from the following
formula:
h = 0.0729 (V
2
-v
2
)
where, h = head loss in m
where, h = head loss in m
V = velocity through the screen in m/s
v = velocity before the screen in m/s
Another formula often used to
determine the head loss
through a bar rack is
Kirschmer'sequation:
h =β(W/b)
4/3
h
vsin θ
where h = head loss,m
Another formula often used to
determine the head loss
through a bar rack is
Kirschmer'sequation:
h =β(W/b)
4/3
h
vsin θ
where h = head loss,m
β= bar shape factor (2.42 for sharp edge
rectangular bar, 1.83 for rectangular bar with
semicircle upstream, 1.79 for circular bar and
1.67 for rectangular bar with both u/s and d/s
face as semicircular).
W = maximum width of bar u/s of flow, m
W = maximum width of bar u/s of flow, m
b = minimum clear spacing between bars, m
h
v= velocity head of flow approaching rack,
m = V
2
/2g
θ = angle of inclination of rack with horizontal
β= bar shape factor (2.42 for sharp edge
rectangular bar, 1.83 for rectangular bar with
semicircle upstream, 1.79 for circular bar and
1.67 for rectangular bar with both u/s and d/s
face as semicircular).
W = maximum width of bar u/s of flow, m
W = maximum width of bar u/s of flow, m
b = minimum clear spacing between bars, m
h
v= velocity head of flow approaching rack,
m = V
2
/2g
θ = angle of inclination of rack with horizontal
Number of bars in screen Number of bars in screen
chamber chamber
[clear spacing x (n+1)] +[size of bar x n]
=B
Where, Where, N= number of bars
B= width of screen chamber or channel
Clear spacing and size of bars is expressed in
m
chamber chamber
[clear spacing x (n+1)] +[size of bar x n]
=B
Where, Where, N= number of bars
B= width of screen chamber or channel
Clear spacing and size of bars is expressed in
m
Other formulae used Other formulae used
Gross area
A
g= A
netx (c/c spacing/ clear
spacing) spacing)
Velocity of flow above screen
v = Velocity through the screen
(V) x (clear spacing/c/c spacing)
Gross area
A
g= A
netx (c/c spacing/ clear
spacing) spacing)
Velocity of flow above screen
v = Velocity through the screen
(V) x (clear spacing/c/c spacing)
Disposal of Screenings Disposal of Screenings
Screenings is the waste materials collected
from screens. Screenings should be properly
disposed.
Various methods of screening disposal were
used such as:
-
burning,
-
burning,
-burying,
-digestion,
-dumping into large bodies of water,
-
and shredding and returning it to
wastewater collection or treatment
system
.
Screenings is the waste materials collected
from screens. Screenings should be properly
disposed.
Various methods of screening disposal were
used such as:
-
burning,
-
burning,
-burying,
-digestion,
-dumping into large bodies of water,
-
and shredding and returning it to
wastewater collection or treatment
system
.
Inland burying is efficient in small
treatment plants, while burning is best
for medium and large treatment plants.
Other methods cause problems and may need subsequent treatment. may need subsequent treatment.
Digestion is used for large systems and
in combination with the treatment of
the organic portion of municipal solid
waste.
Inland burying is efficient in small
treatment plants, while burning is best
for medium and large treatment plants.
Other methods cause problems and may need subsequent treatment. may need subsequent treatment.
Digestion is used for large systems and
in combination with the treatment of
the organic portion of municipal solid
waste.
A Must Visit Site A Must Visit Site
http://techalive.mtu.edu/meec/m
odule21/title.htm
http://techalive.mtu.edu/meec/m
odule21/title.htm
Video: Mechanical bar screen Video: Mechanical bar screen
Objective Questions Objective Questions
1.
Screens can not remove
___________.(Paper/plastic/tree leaves/silt) 2.
Design of screens mainly depends upon
_________. 3.
Suggest suitable type of screen for 80
-
100 mm
3.
Suggest suitable type of screen for 80
-
100 mm
sized floating particles. __________________
1.
Screens can not remove
___________.(Paper/plastic/tree leaves/silt) 2.
Design of screens mainly depends upon
_________. 3.
Suggest suitable type of screen for 80
-
100 mm
3.
Suggest suitable type of screen for 80
-
100 mm
sized floating particles. __________________
Theory Questions Theory Questions
Q1. Draw a general flow sheet of Domestic
Wastewater treatment plant and write
function of each and every unit.
Q2. Write short note on Q2. Write short note on i.
Types of screen
ii.
Design of screen chamber
iii.
Disposal of screenings
Q3. Draw a neat sketch of screen chamber.
Q1. Draw a general flow sheet of Domestic
Wastewater treatment plant and write
function of each and every unit.
Q2. Write short note on Q2. Write short note on i.
Types of screen
ii.
Design of screen chamber
iii.
Disposal of screenings
Q3. Draw a neat sketch of screen chamber.
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