Talk:Settling

Setlling is of two types: 1) unhindered 2) hindered In hindered settling velocity gradients are affected by nearby particles. — Preceding unsigned comment added by 117.239.94.110 (talk) 17:35, 8 April 2013 (UTC)[reply]

213.253.35.226 (talk) 10:55, 18 December 2012 (UTC)[reply]

High quality introduce of the ALTERNATIVE SEDIMENTATION THEORY AND EXAMPLES FOR PRACTICE APPLICATION YOU CAN GET IN THE WEB:

https://www.researchgate.net/profile/Sadyrbek_Djighitekov — Preceding unsigned comment added by Dsadyrbek (talk • contribs) 04:38, 7 October 2016 (UTC) [reply]

                     'RECTANGULAR TANKS DESIGN BASED ON THE ALTERNATIVE SEDIMENTATION THEORY

                                 by Sadyrbek DJIGHITEKOV, ( Saji ), Ph.D                         

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                    INTRODUCTION    
  
Settling Tank (or Sedimentation Basin) is a main construction of any   
Water and Waste Water Treatment Plants. But the traditional Settling   
Tanks design has one lack: there is not analytical formula for definition   
tank' depth. For different over flow rates various agencies and consulting   
firms are recommended side water depth: of 2 to 5 m. However, such   
approach was used in ancient Egypt and Rome before Christian era.   
Since 1904, more than 100 years ago, scientists developed the different   
sedimentation theories but they are devised on basis of Newton's law of   
universal gravitation and Stokes' equation. It was a great mistake, fatal   
error. An accordance with that theories it is impossible to calculate   
the main size of Settling Tanks - depth yet, because the theoretical equations   
do not describe the depth's dependence from the initial and required water   
concentrations, temperature and laminar regime of water flow. For decision   
above problem I am used Newton's Second law and Mesherski's equation /1/ and   
I am devised Alternative Sedimentation Theory. That theory was described in   
the book which has written in Russian in 1991 / 2 /. Thanks to Alternative   
Sedimentation Theory it is possible to calculate accurate sizes of Settling   
Tanks. The new calculation method is more correct and effective than traditional   
approach.   
Now, for English readers author is offering the main formulas for Rectangular Tanks design.
 

                       '1. Definition of the Rectangular Tank’s depth'    
                

a) Definition the value of the sedimentation zone height

                                 ______________________________  
                        Ho = 5,2√ ν t / ln [ Cн /( Cн -Cк ) ]                (1)                                            
  

where, 5,2 - is a constant coefficient of resistance to settling particles in process laminar Italic textflow regime in tank; ν - is a kinematic coefficient of viscosity, мм² / sec; t - is a detention time to reach desired underflow concentration, sec; Cн и Cк - are the initial and desired water concentrations, mg/L.

              b) Definition the value of the sludge zone height:  
                                  _________________________________  
                         Hoc = 2 √ ν t / ln [ Cкo / ( Cкo – Cнo ) ]                                    ( 2 )  
  

where 2 - is a constant coefficient of resistance to settling particles in the inactive water environment; Cнo - is an initial sludge concentrations, mg/L; Cкo is a desired sludge concentrations, mg/L.

              c) Definition the value of the Rectangular Tanks depth:  
  
                          H = Ho + Hoc                                                                   ( 3 )  
    
                       '2.Definition of the Rectangular Tanks width:'  
    
                              W = Q / 3,6 H v                                                              ( 4 ) 

where Q - is a total water inflow, m³ / hr; 
      v - is an average speed of water mass, mm/sec 

 

                       '3. Definition of the Rectangular Tanks length:'  

                 L = H² v ln [ Cн / ( Cн – Cк ) ] /(5,2)² ν                                              ( 5 )  

EXAMPLE. Determine the Rectangular Tank’s sizes if:  

- total water inflow: Q = 2000 m³/ hr;  
- initial water concentration: Cн = 400 mg/L;  
- desired water concentration: Cк = 10 mg/L;  
- initial sludge concentration: Cнo = 6000 mg/L  
- desired sludge concentration: Cкo = 16000 mg/L;  
- detention time to reach desired concentration: t = 2 hr or 7200 sec  
- temperature of the turbid water of 16°C and kinematic  
- coefficient of viscosity: ν = 1,1 mm²/sec;  
- average speed of water mass in settling tank: v = 10 mm/sec 
 

                                'SOLUTION'  

1. Determine the value of the Rectangular Tank’s depth:  
                       _________________________________                      
           a) Ho = 5,2√ 1,1 × 7200/ ln [400/ (400 - 10)] = 2909 mm  
                       ________________________________________
            b) Hoc = 2√ 1,1 × 7200/ ln [ 16000 /( 16000 – 6000)] = 259 mm  

            c) H = Ho + Hoc = 2909 + 259 = 3168 mm or 3,17 m  

              2. Determine the value of the Rectangular Tank’s width:  
  
                   W = 2000/ (3,6 × 10 × 3,168) = 17,58 m  

                 3. Determine the value of the Rectangular Tanks length:  

L = ( 3168 )² × 10 × ln [400/ (400 - 10)]/ (5,2)² × 1.1 = 84829 mm or 85 m  

REFERENCES  

1. Loyzianski, A. M,& Lurye, A. I., 1983. Kurs teoreticheskoi mehaniki. T. 2. Dinamika – M.: Nayka  
2. Djighitekov, S. 1991. Osnovy tehnologicheskogo rascheta otstoinikov. Bishkek: KyrgNIINTI  
  

                    'ALTERNATIVE SEDIMENTATION THEORY FOR SETTLING TANKS DESIGN

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                              ABSTRACT 
              Settling Tanks (Sedimentation basins) are the main construction in the water 
 treatment plants and stations. There are  about 95% of suspended particles sediment from 
 turbid water. But when it is necessary to design the Settling Tanks we do not calculate main 
 parameters, and usually we have used basically experimental data. 
  
 At the present time for Settling Tanks Design Engineers are used traditional (conventional) 
 sedimentation theory. But accordance this theory it is not possible to calculate accurately 
 depth of Settling Tanks. What is the reason? The reason is next: more than 100 years ago 
 Dr. A.Hazen (1904) suggested Newton's gravitational law. It was a fatal mistake because that 
 Newton's law is considering just one external force in the water: gravitation. For decision 
 this problem Dr. T. Camp (1946) suggested artificial approach: "ideal settling tank" for calculate 
 depth theoretically. However, everybody can not believe in ideal things in practice.  As a result 
 specialists in the field of World Water Industry cannot calculate correct sizes of Settling Tanks 
 because all handbooks and manuals are giving traditional sedimentation theory yet.
  
 Correct Settling Tanks Design can be done if specialists will consider three external forces 
 acting to the any elementary volume of water: gravitation and forces of hydrodynamical pressure 
 that normal to both sides of elementary volume and directed to the different sides. It is Newton's 
 Second Law. Based on the Newton's Second Law I devised Alternative Sedimentation Theory. As a result
 everybody: scientist, engineer and even student can calculate correct sizes of Settling Tanks, 
 create models and to choose effective of one.  
 
 
                                          INTRODUCTION 

             Sedimentation is the separation from water, by gravitational settling, 
of suspended particles that are heavier than water. 
It is one of the most widely used unit operations in wastewater treatment. Sedimentation 
basin is a main construction in the water treatment plants and stations. There is sediment 
about 95% of suspended particles from turbid water. But when it is necessary to design the 
sedimentation basins we do not calculate main parameters, and usually we have used basically 
experimental data. For example, in the AWWA handbook / 1 / has written:  "Rectangular basins 
are generally designed to be long and narrow, with width-to-length ratios of 3:1 to 5:1. 
Chain-and-flight collectors are limited to about a 20-ft (6-m) width for single pass, but it 
is possible to cover a wider basin in multiple passes. Traveling bridge collectors can be up 
to 100 ft (30 m) wide, limited only by the economics of bridge design and alignment. In theory, 
asin depth should not be an important parameter either, because settling is based on overflow 
rates. However, in practice, basin depth is important because it affects flow-through velocity. 
Flow-through velocities must be low enough to minimize scouring of the settled floc blanket. 
Velocities of 2 to 4 ft/min (0.6 to 1.2 m/min) usually are acceptable for basin depths of 
7 to 14 ft (2.1 to 4.3 m).... ".  In the latter expression there is the main contradiction of 
modern theories in case of their realization in practice in the field of sedimentation basins 
design. 
   On the other hand above expression leads to other questions: "If we have a great experience 
in the field of sedimentation basins design and there are enough standard dimensions for us why 
we remind ourselves about sedimentation theory? May be this theory is incorrect or the erroneous 
theory?”  The correct theory usually helps to calculate the accurate sizes but not experimentally 
and approximately  like right now. Thanks to correct theory we can evaluate effectiveness the 
kinds of sedimentation basins and to predict economic profits. For finding-out of the reason we 
shall consider the existing theoretical equations.

                                               DISCUSSION 

    So, let's consider the main theoretical equations of the suspended particles in sedimentation process 
that used in the United States. At the present time the AWWA handbook / 2 / recommends flux theory. 
 This theory considers four types of settling for particles:

Type 1. Settling of discrete particles in low concentration, with flocculation and other 
inter particle effects being negligible.

Type 2. Settling of particles in low  concentration but with coalescence or  flocculation. 
As coalescence occurs, particle masses increase and particles settle more rapidly.

Type 3. Hindered, or zone, settling in which particle concentration causes inter particle 
effects which might include  flocculation, to the extent that the rate of settling is a function 
of solids concentration. Zones of different concentrations may develop from segregation of 
particles with different settling velocities. Two regimes exist - "a" and "b" - with the concentration 
being less and greater than that maximum flux, respectively. In the latter case, the concentration 
has reached the point that most particles make regular physical contact with adjustment particles and 
effectively form a loose structure. As the height of this zone develops, this structure tends to form 
layers of different concentration, with the lower layers establishing permanent physical contact, until 
a state of compression is reached in the bottom layer. 

Type 4. Compression settling or subsidence develops under the layers of zone settling. The rate of 
compression is dependent on time and the force caused by weight of solids of solids above

Under the influence of gravity, any particle having a density greater than 1.0 will settle in water 
at an accelerating velocity until the resistance of the liquid equals the effective weight of the particle. 
Thereafter the settling velocity will be essentially constant and will depend upon the size, shape, and 
density of the particle, as well as the density and viscosity of the water. For most theoretical and practical 
computations of settling velocities in sedimentation basins, the shape of the particles is assumed to be 
spherical. Settling velocities of particles of other shapes can be analyzed in relation to spheres. When 
the particle is solid and spherical ( here and in the further the author has accepted some different symbols 
than in handbook / 1 / ):
                       ________________________
                 u =  √ 4g ( ρs - ­ρ) d / 3 ρ CD  ­                  ( 1 )       

where u is the settling velocity of the particle,

          g is the gravity constant, 
          ρs  is the density of the particle, 
          ρ  is the density of the water, 
          d  is diameter of the particle, 
          CD  is a drag coefficient. The drag coefficient is not constant but is dependent upon the Reynolds number.

The value of CD decreases as the value of Re increases. In connection with this there are 4 Reynolds numbers regions are marked. The region 0.0001< Re < 0.2. is the laminar flow region, the equation of relationship approximates to

       CD =  24 / Re                                                                 ( 2 )

when this relationship is inserted in Eq. ( 1 ), it becomes

             _______________________
       u =  √ g ( ρs - ­ρ) d² / 18 μ                                      ( 3 )

which is known as Stokes law / 2 /.

where  µ  is the absolute viscosity of the water and u, d, and ρ are as stated before. 
On basis this law were developed a number theories. The first of them is the "ideal" settling theory / 3 /. 
In accordance with this theory assuming that all particles settle discretely and that those which strike 
the bottom are removed, the absolute velocity path V represents the maximum elevation where particles of 
the smallest settling velocity V which will experience 100 per cent removal may be found. 
That is, a particle with settling velocity u' which enters the the basin at the water surface (at height 
"ho" above the bottom) will travel along the path U and be removed just as water moving at velocity U enters 
the outlet zone. The time t available for a particle to settle is:
   t = L / U                                                                               ( 4 )

and so the critical settling velocity u' is:

          u' = ho U / L                                                                    ( 5 )

The velocity U is:

   U  = Q / ho W                                                                     ( 6 )

where W is width of basin After the combination of this relationship with the previous two yields:

   u' = ho U / L = ho Q / ho W L = Q / WL                                 ( 7 )

The quantity WL is the surface (bottom) area A of the basin, and

   u' = Q / A                                                                               ( 8 )
Usually, in accordance with the theory of ideal settling u' = 0.048 cm/sec.with the surface loading Q/A 
of 1,000 gpd/sq ft.
Equation ( 7 ) shows that settling efficiency for the ideal condition is independent of depth H and 
dependent only the tank plan area. This principle is sometimes referred to as Hazen's law. In contrast, 

retention time, t is dependent on water depth, H, as given by

     t = AH / Q                                                                             ( 9 )
in reality, depth is important because it can affect flow stability if it is large and scouring if it is 
small / 2 /.
But sedimentation basins seldom perform in accordance with ideal settling theory. Two factors are predominant 
in the departure of basin performance from ideality: currents and particle interactions. One approach for 
estimating the effect of currents is that devised by Hazen / 4 /:
              y / yo = 1 - [ 1 + u' / a ( Q / A ) ]‾ ª                                        ( 10 )

where yo is the initial quantity of particles in a suspension possessing a settling velocity of u'

     y  is the quantity of  such particles which will be removed in the basin, 
     a  is the number of (hypothetical) basins in series. For a = 1 in Hazen's theory, 
only 50% of the particles with settling velocity u' (equal to the surface loading Q/A) will be removed,  
whereas 100% of such particles would be removed in accordance with ideal theory. 
Particle interactions manifest themselves in three ways, one of which accelerates settling whereas the others  
retard it. Settling is accelerated by the occurrence of flocculation within the sedimentation basin itself.  
In addition to flocculation, particle interactions may produce an effect known as hindered settling ( Type 3 ).  
The simplest and most widely used equation 

for estimating the extent to which settling is hindered is that devised by Richardson and Zaki / 5 /:

   Us = U' ( 1 - Ф )ⁿ                                                                    ( 11 )

where Us is the hindered settling velocity of the suspension,

       U'  is the unhindered settling velocity [ as calculated by Eq. ( 1 ) or ( 3 ) ],
       Ф  is the volume concentration of particles in the suspension (volume fraction), and
       n is an exponent which, for spheres settling at Reynolds numbers less than 0.2, has a value of 4.65.

Another simplest and most convenient relationship is represented by general equation / 2 / :

   Us = Uo exp ( - q Ф )                                                                       ( 12 )
where  q is constant representative of the suspension
           Uo is settling velocity of suspension for concentration extrapolated to zero.

         RESULTS OF DISCUSSION

  1.   At the present time the traditional (conventional) sedimentation theory are based on the effect 
 of gravity on particles suspended in a liquid of lesser density. The settling velocity of the particle 
 determined on the basis of Stokes equation as the  main calculation formula that inserted in the different 
 theoretical equations. But this physical formula does not definite the sedimentation basin's geometrical 
 sizes accurately. Especially, main of them it is a depth of basin. 
 2.  In connection with above sedimentation basin design has contradiction : " In theory, basin depth should 
 not be an important parameter either, because settling is based on overflow rates. However, in practice, 
 basin's depth is important because it affects flow-through velocity" / 1 / . But in practice basin's depth 
 is assumed approximately.  This incorrect approach is used in the water global industry more than 100 years. 
 
                                   PROBLEM   

    Why we have such contradiction between theory and practice? 
The matter is that scientists have taken a great interest to the private law for a special case: 
settling of particles in water. And the main question: what degree of water treating as a whole on an 
output from sedimentation basin became minor. As a result scientists have chosen Newton gravitational 
law and Stokes equation. 
It was the fatal choice from their party. They have absolutely forgotten, that it was necessary to consider 
the general case: degree of water treatment before and after sedimentation basins. In connection with above 
we have a question. The question is: " How we can calculate basin's depth as an important parameter in theory 
for application in practice?

                                  SOLUTION

    We live in a space age. And in our space age it is impossible to keep only by one law and to pray as 
on Maria's icon of the virgin. 
If scientists in the field of spacecrafts have been applied Stokes equation and studied speed of fuel 
particles from engines, in this case rockets would not take off for space. As is known, spacecrafts have 
a number engines supplied by fuel tanks. Engines are serially separated after full combustion of fuel and 
a spacecraft's mass is decreased. But a mass of the clarified effluent is decreased after sedimentation 
basin too, because the particles settled in basin and sludge is removed from the bottom. Essence of the 
phenomenon in both cases identical: it is loss of mass in both cases. What have made scientists in the 
field of spacecrafts design? They have used equation that devised by Ivan Mesherski in 1904 on the basis 
of  Newton's second law: 
  
     v dm / dt = F                                                                           ( 13 )
 
 where F  is the sum of external forces
           m - is mass of the body that is changed depending on time t
           v - is average speed of body
   In order to show applicability of Mesherski's equation to еffluent of water from sedimentation basin 
 and calculate basin depth in the first let we shall consider sedimentation process in the motionless 
 settling column. In accordance with flux theory there are four settling regions / 6 /. But in practice 
 we can not see these settling regions. We can see just two zones: settling and sludge. Now let's allocate 
 in the settling column with the polluted water some the elementary volume of a liquid of the rectangular 
 form. After that we shall set to themselves the task: to define depth of the elementary volume.

'Task # 1. Definition of section's depth of the elementary volume that has the rectangular form.'

Let consider the case when the water movement is uniform and has some corner upwards.  
As a result of settling of particles is accepted, there is a change of water mass in the elementary volume.  
Here particles as though play a role of engine fuel in process of mass loss in the elementary volume of water.  
It is known from mechanics law / 7 /, that to the moving mass of any body the external forces are acting.  
For this case the Eq. (13 ) has: 
v - velocity of water mass movement  
t - time of water movement  
F - projection of external forces on the direction of water movement. 
Let's consider at the first external forces acting to the any  elementary volume of water / 11 /.  
There next forces are acting: 
- Equally effective gravity of the water volume, directed vertically downwards: 

 G = γωℓ                                                                              (14)                                                                                 
where γ - relative density of water; ω - the section square of elementary volume; ℓ - length of the  
elementary volume. 
- Forces of hydrodynamical pressure that normal to both sides of elementary volume  and directed to  
the different sides 
  
   P1 = p1ω;  P2 = p2 ω;                                           ( 15 ) 
 
The sum of projections of equally effective external forces on an axis of the liquid movement gives: 
  
    v dm / dt = P1 – P2  –  G cos α                                            ( 16 ) 
 
Substitution yields ( 14 ) and ( 15 ), and  
  
   cos α = ( Z2  –  Z1 ) / ℓ 
 
where Z1 - is co-ordinate of the bottom section of elementary volume; Z2 - is co-ordinate of the top  
section of elementary volume 
in the Eq. ( 16 ) gives 
 
    v dm / dt = p1ω – p2 ω – γ ω ℓ ( Z2  –  Z1 ) / ℓ                 ( 17 ) 
 
Having increased and having divided the right part of the Eq. ( 17 ) on the gravity of the water stream,  
we shall receive 
 
    v dm / dt = G [ ( p1 / γ ) – (p2 / γ) – Z2 + Z1 ] 1 / ℓ           ( 18 ) 
 
It is known from the basic equation of water uniform movement: 
 
    { [( p2 / γ ) + Z2] – [ ( p1 / γ ) + Z1]}1 / ℓ = i                ( 19 ) 
 
where i - hydraulic slope 
 
Then the Eq. ( 18 ) can be written down: 
 
    v dm / dt = – G i                                                                           ( 20 ) 
 
On the other hand: 
 
    G = m g 
 
and finally the Eq. ( 20 ) can be written down: 
 
    v dm / dt = – m g i                                                                        ( 21 ) 
 
The hydraulic slope for pipes of rectangular section is defined under the formula given in work / 8 /: 
 
i = λ v² / 8 R g                                                                              ( 22)                           
 
where R - hydraulic radius which is defined for the pipes of rectangular section under the formula: 
 
R = h / 2                                                                                       ( 23 ) 
 
λ - dimensionless coefficient of friction in the pipes, depending in the first from of water movement rejim.  
In our case we have the regime of laminar flow,  therefore it is possible to write down: 
 
    λ = 64 / Re 
 
Reynolds number for the rectangular pipe and the channel is written in the form of: 
 
    Re = v max 4 R / ν                                                                      ( 24 ) 
 
where ν - kinematic coefficient of viscosity 
 
    v max = 2 v                                                                            ( 25 ) 
 
After substitution yields (23) and (25) the formula (24) can be written down: 
 
    Re = 4 v h / ν                                                                                ( 26 ) 
 
As a result we shall receive: 
 
    λ = 16 v / ν h                                                                                 ( 27 ) 
 
After substitution Eq. ( 23 ) and Eq. ( 27 ) in Eq. ( 22 ) we shall receive: 
 
    i = 4 v ν / h² g                                                                                ( 28 ) 
 
After substitution yield (28) in eq. (21) we shall receive 
 
          dm / dt = – 4 m ν / h²                                                                ( 29 ) 
 
Now we can integrate the Eq. (29) by method of variables division. For this purpose we can write down Eq. (29)  
in the form of: 
  
 
    ∫ dm / m  = –(4 ν / h² )∫ dt 
  
After integration we can receive  
 
 
  ln m = ln C –  4 ν t / h²                                                                     ( 30 ) 
 
  
where C - a constant of integration which is defined from a condition: 
 
when t = 0; m = mн 
where mн - initial mass of the elementary volume of water 
Hence:                
 
    ln C = ln mн, or C = mн   
 
At the end of  t we have the result: 
 
     ln mк = ln mн – 4 ν t / h²                                                       ( 31 )  
 
where mк - final mass of elementary volume of water after time t. 
 
From Eq. ( 31 ) it follows that: 
          _____________________           
    h = 2√ ν t / ln ( mн / mк )                                                       ( 32 ) 
 
But we should leave from a micro level to a macro level: from definition of depth of the rectangular section  
to definition of depth of settling column ( Ho ). 
 
'Task # 2.  Definition of sedimentation zone depth of the settling column in which water with initial concentration'  
 
Сн is converted up to final Ск .  
    For this purpose at first we shall express mass of water through their density.  
L. Prandtl / 9 / offered for the mixed liquids with various density following equation for definition of mass: 
 
    m = ( ρ2 – ρ1) V                                                                    ( 33 ) 
 
where ρ2 и ρ1 - densities of heavy and easy liquids;  V - volume of the mixed liquid. 
For our case: 
 
    mн = ( ρн – ρ) V      
    mк = ( ρн – ρк )V 
 
where ρн и ρк - initial and final densities of water, ρ - density of pure water.  It is known: 
  
 
    ρн = ρ  + Cн    
    ρк = ρ  + Cк  
 
Hence: 
 
    mн = ( ρ  + Cн ) V – ρ V = Cн V 
    mк = [( ρ  + Cн ) – ( ρ  + Cк )] V = ( Cн – Cк ) V 
 
Thus we have the result: 
           _______________________________ 
    Ho = 2√ ν t / ln [ Cн  / ( Cн – Cк ) ]                                                  ( 34 ) 
 
The resulted formula is fair only for the motionless vessel that filled by polluted water. But in the  
sedimentation basin the water's movement is uniform. How to account the influence of water movement rejim  
for definition of sedimentation zone depth ( height ) in basin? 
  
Task # 3. Definition of sedimentation zone depth in the basin.  
  
It is known: 
  
   t = L / v 
 
Substitution of this in Eq. ( 34 ) gives: 
            _______________________________ 
    Ho = 2 √ ν L / v ln [ Cн  / ( Cн – Cк )]                                              (35) 
                                                                                                                                                                               In Eq. ( 35 ) we have yield:                                                                
      ________ 
    2√ ν L / v                                                                            ( 36 ) 
 
this looks like formula that defines thickness of the boundary layer at the laminar flow and its movement  
around of the thin motionless plate / 10/: 
                        ________ 
               δ = 5,2 √ ν L / v                                                           ( 37 ) 
 
Eq.( 36 ) and Eq.( 37 ) just have different coefficients. It is explained that in the motionless vessel there  
is poorly expressed boundary layer on the border of phases: sludge - settling zone. In case of water movement  
in the sedimentation basin, thickness of the boundary layer on that phases is increased in 2,6 times, than in  
the motionless settling column. Therefore, it is necessary to adhere at calculations of sedimentation's basins  
already established coefficient - 5,2. And equation for definition of the sedimentation zone height of basin  
( H ) will be: 
               _________________________________ 
      Ho = 5,2√ ν L / v ln [ Cн  / ( Cн – Cк ) ]                                          ( 38 ) 
 
The settling time usually is known and is always set and in connection with this the formula (38) is more  
convenient for writing down in the form of: 
             ________________________________ 
    Ho = 5,2√ ν t /  ln [ Cн  / ( Cн – Cк ) ]                                               ( 39 ) 

Definition the value of the sludge zone height:  
              _________________________________  
     Hoc = 2 √ ν t / ln [ Cкo / ( Cкo – Cнo ) ]  

       Cкo - desired sludge concentration
       Cнo - initial sludge concentration

Definition the value of the Rectangular Tanks depth:

                          H = Ho + Hoc 

Definition of the Rectangular Tanks width:

           W = Q / 3,6 H v                                                              
    Q - total water inflow, m³ / hr;
    v - is average speed of water mass in settling tank, mm/sec. 

On the other hand we can use Eq. ( 34 ) for definition the depth ( height ) sludge оn the bottom of the basin(Hoc ).  
For research aims and analysis it is better Eq. ( 38 ) to write down in the form:                     
    
 L = H² v ln [ Cн  / ( Cн – Cк ) ] / 27,04 ν                                            ( 40 ) 
 
CONCLUSIONS: 
   
   1. On the basis of the body mass change law and bases of hydraulics analytical equations received  
for settling and sludge zones depths calculation.   
    2. These equations show an impact of suspended particles concentration,  
temperature and regime of water flow to the sizes of sedimentation basin and they are very important  
for research and practice design.  
    3. On the basis of above equations it is possible to develop mathematical models of Settling Tanks  
and to choose effective one. 

REFERENCES

1. American Water Works Association.2005. Water Treatment Plant Design, 4th ed. New York: McGraw-Hill.

2. American Water Works Association. 1999. Water Quality and Treatment, 5th ed. New York: McGraw-Hill.

3. Camp, T. R. 1946. Sedimentation and the Design of Settling Tanks. Transactions of ASCE 3 (2285): 895.

4. Hazen, A. 1904. On Sedimentation. Transactions of ASCE 53:63.

5. Richardson, J. F. and W. N Zaki. 1954. Sedimentation and Fluidization. Trans. Instn. Chem. Engrs. 32:35.

6. Tchobanoglous, G. 1991. Wastewater engineering: treatment, disposal, and reuse. 3rd.ed. New York: Metcalf & Eddy, Inc.

7. Loyzianski L. G and Lurie A. I. 1983. Kyrs teoreticheskoi mehaniki. t. 2. Dinamika - M.: Nayka.

8. Latushenkov A. M. and Lobachev V. G. 1956. Hydraulic - M.: Gosstroizdat.

9. Prandtl L. 1949. Gidroairomehanika. - M.: IL.

10. Shlihting G. 1969. Teoria pogranichnogo sloya. - M.: Nayka.

11. Djighitekov, S. 1991. Osnovy tehnologicheskogo rascheta otstoinikov. Bishkek: KyrgNIINTI