Introduction

The need to clarify water

 Aesthetics and health
 Colloids – impart color and turbidity
to water – aesthetical acceptability
 Microbes are colloids too

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 COAGULATION &
FLOCCULATION
 Removal of colloidal
substances from water

 Potable water requirements

 health, aesthetics, economic
 Colloids
 Size of colloids - light waves
 Brownian motion
 Stability of colloids

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 What is Coagulation?
 Coagulation is the destabilization of colloids by addition of
chemicals that neutralize the negative charges
 The chemicals are known as coagulants, usually higher valence
cationic salts (Al3+, Fe3+ etc.)
 Coagulation is essentially a chemical process

- - - - -
-
-- -- -- --
- - -
--- -- --- ---
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 What is Flocculation?
Flocculation is the agglomeration of destabilized particles into
a large size particles known as flocs which can be effectively removed
by sedimentation or flotation.

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 Coagulation aim

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 Why coagulation and flocculation?
Various sizes of particles in raw water
Particle
Particle diameter
diameter (mm)
(mm) Type
Type Settling
Settling velocity
velocity

GravIty settlIng
10
10 Pebble
Pebble 0.73
0.73 m/s
m/s
11 Course
Course sand
sand 0.23
0.23 m/s
m/s
0.1
0.1 Fine
Fine sand
sand 0.6
0.6 m/min
m/min
0.01
0.01 Silt
Silt 8.6
8.6 m/d
m/d
0.0001
0.0001 (10
(10 micron)
micron) Large
Large colloids
colloids 0.3
0.3 m/y
m/y
0.000001
0.000001 (1
(1 nano)
nano) Small
Small colloids
colloids 33 m/million
m/million yy

Colloids – so small: gravity settling not possible

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 Colloid Stability
Colloid
H 2O

 Colloids have a net negative surface charge

 Electrostatic force prevents them from agglomeration

-
-- -- Repulsion
-
-- --
-
Colloid - A Colloid - B

-
 Brownian motion keeps the colloids in suspension

 Impossible to remove colloids by gravity settling

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 Colloidal interaction

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 Charge reduction

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 Colloid Destabilization
 Colloids can be destabilized by charge
neutralization

 Positively charges ions (Na+, Mg2+, Al3+,

Fe3+ etc.) neutralize the colloidal negative
charges and thus destabilize them.

 With destabilization, colloids aggregate in

size and start to settle

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 Force analysis on colloids

The integral of the

combined forces is
the energy barrier

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 Flocculation aids

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Floc formation with polymers

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 Jar Tests
 The jar test – a laboratory procedure to determine the optimum pH
and the optimum coagulant dose

 A jar test simulates the coagulation and flocculation processes

Determination of optimum pH
 Fill the jars with raw water sample
(500 or 1000 mL) – usually 6 jars
 Adjust pH of the jars while mixing
using H2SO4 or NaOH/lime
(pH: 5.0; 5.5; 6.0; 6.5; 7.0; 7.5)
 Add same dose of the selected
coagulant (alum or iron) to each jar
(Coagulant dose: 5 or 10 mg/L)
Jar Test
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Jar Tests – determining optimum pH
 Rapid mix each jar at 100 to 150 rpm for 1 minute. The rapid mix
helps to disperse the coagulant throughout each container
 Reduce the stirring speed to 25 to 30 rpm Jar Test set-up
and continue mixing for 15 to 20 mins
This slower mixing speed helps
promote floc formation by
enhancing particle collisions,
which lead to larger flocs
 Turn off the mixers and allow
flocs to settle for 30 to 45 mins
 Measure the final residual
turbidity in each jar
 Plot residual turbidity against pH
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Jar Tests – optimum pH

Optimum pH: 6.3

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Optimum coagulant dose
 Repeat all the previous steps
 This time adjust pH of all jars at
optimum (6.3 found from first test)
while mixing using H2SO4 or
NaOH/lime
 Add different doses of the selected
coagulant (alum or iron) to each jar
(Coagulant dose: 5; 7; 10; 12; 15; 20 mg/L)
 Rapid mix each jar at 100 to 150 rpm for 1 minute. The rapid
mix helps to disperse the coagulant throughout each container
 Reduce the stirring speed to 25 to 30 rpm for 15 to 20 mins
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 Optimum coagulant dose
 Turn off the mixers and allow flocs to settle for 30 to 45 mins

 Then measure the final residual turbidity in each jar

 Plot residual turbidity

against coagulant dose
Optimum coagulant dose: 12.5 mg/L

The coagulant dose with

the lowest residual
turbidity will be the
optimum coagulant dose

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Coagulant Dose mg/L
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• Hydraulic Jump: Hydraulic Jump creates turbulence and
thus help better mixing.

Coagulant

• In-line flash mixing

• Mechanical mixing
Back mix impeller flat-blade impeller

Inflow
Chemical
feeding
Chemical
feeding Inflow
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 Chemical
feeding

Inflow

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 Relative coagulating power

Na+ = 1; Mg2+ = 30
Al3+ > 1000; Fe3+ > 1000

 Typical coagulants

Aluminum sulfate: Al2(SO4)3.14 H2O

Iron salt- Ferric sulfate: Fe2(SO4)3

Iron salt- Ferric chloride: Fe2Cl3

Polyaluminum chloride (PAC): Al2(OH)3Cl3

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 Aluminum Chemistry
With alum addition, what happens to water pH?

Al2(SO4)3.14 H2O ⇔ 2Al(OH)3↓+ 8H2O + 3H2SO4-2

1 mole of alum consumes 6 moles of bicarbonate (HCO3-)

Al2(SO4)3.14 H2O + 6HCO3- ⇔ 2Al(OH)3↓+ 6CO2 + 14H2O + 3SO4-2

If alkalinity is not enough, pH will reduce greatly

Lime or sodium carbonate may be needed to neutralize the acid.

(Optimum pH: 5.5 – 6.5)

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 Alkalinity calculation
If 200 mg/L of alum to be added to achieve complete coagulation.
How much alkalinity is consumed in mg/L as CaCO3?

Al2(SO4)3.14 H2O + 6HCO3- ⇔ 2Al(OH)3↓+ 6CO2 + 14H2O + 3SO4-2

594 mg 366 mg
594 mg alum consumes 366 mg HCO3-
200 mg alum will consume (366/594) x 200 mg HCO3-

= 123 mg HCO3-

Alkalinity in mg/L as CaCO3 = 123 x (50/61)

= 101 mg/L as CaCO3
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 COAGULANT AIDS
Other substances than
coagulants used:
- Clay minerals
- Silicates
- Polymers

Polymers are often

either anionic or
cationic to aid
coagulation.
Polymers also
reinforce flocs
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 FLOCCULATION

Flocculation - agglomeration of colloids by collisions to form separable flocs

Examples - milk, blood, seawater
Mechanisms - perikinetic, collisions from Brownian motion
- orthokinetic, induced collisions through stirring

Orthokinetic flocculation
Velocity gradient, relative movement between colloids in a fluid body
RMS velocity gradient

Camp No. Gt Typical 2x 104 - 105

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 Typical layout of a water treatment plant

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 Slide 13 of 27

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 Design of Flocculator (Slow & Gentle mixing)
Flocculators are designed mainly to provide enough interparticle
contacts to achieve particles agglomeration so that they can be
effectively removed by sedimentation or flotation
Transport Mechanisms
• Brownian motion: for relatively small particles
which follow random motion and collide with
other particles (perikinetic motion)
• Differential settling: Particles with different
settling velocities in the vertical alignment collide
when one overtakes the other (orthokinetic motion)

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 Mechanical Flocculator
L

H
Transverse paddle

Cross flow Flocculator (sectional view)

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Plan (top view)
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 Hydraulic Flocculation

• Horizontally baffled tank L

The water flows horizontally.
The baffle walls help to create W
turbulence and thus facilitate mixing
Plan view (horizontal flow)
• Vertically baffled tank
The water flows vertically. The baffle
walls help to create turbulence and thus
facilitate mixing
H

L
Isometric View (vertical flow)
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 Hydraulic Flocculation

http://www.environmental-center.com/magazine/iwa/jws/art4.pdf
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 Hydraulic flocculators

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Hydraulic flocculators: simple technology

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 Hydraulic Flocculation: Pipe

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 Hydraulic Flocculation: Pipe

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Hydraulic Flocculation:Large stirrers

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 Mechanical flocculators

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 Mecahnical flocculators

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 Mechanical flocculators

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 Another mechanical
flocculator

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 Differential settling flocculation

Slide 26 of 27

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Flocculators integrated with settling

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Flocculators integrated with settling

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Flocculators both sides of settling

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Flocculator perforated wall (in background)

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