Operational Variables affect Sludge Thickening by Centrifugation

Thickening [1]

                 Thickening of sludge is a process to increase its solids concentration and to decrease its volume by removing some of the free water. The resulting material is still fluid. Thickening is employed prior to subsequent sludge-processing steps, such as digestion and dewatering, to reduce the volumetric loading and increase the efficiency of subsequent processes.

                 The most commonly used thickening processes are gravity thickening, dissolved air floatation thickening, gravity belt thickening, and rotary drum thickening. Table 1 presents a comparison of these thickening processes.

              Selection of a particular thickening process sometimes depends on the size of the wastewater treatment plant and the downstream train chosen. The main design variables of any thickening process are:

  • Solids concentration and flow rate of the feed stream
  • Chemical demand and cost if chemicals are used for conditioning
  • Suspended and dissolved solids concentrations and flow rate of the clarified stream
  • Solids concentration and flow rate of the thickened sludge.

Table 1 Comparison of Thickening Methods [1]

Method Advantages Disadvantages
Gravity thickening


Least operation skill required Large space required
Low operating costs Odor potential
Minimum power consumption Erratic and poor solids concentration (2 to 3%) for WAS
Ideal for small treatment plants Floating solids
Good for rapidly settling sludge such as WAS and chemical  
Conditioning chemicals typically not required
Dissolved air flotation thickening Provides better solids concentration (3.5 to 5%) for WAS than that of gravity thickening Operating costs higher than for a gravity thickener
Require less space than a gravity  thickener Relatively high power consump
Will work without chemicals or with low dosages of chemicals Moderate operator attention requir
Relatively simple equipment components Odor potential
  Larger space requirements compared to other mechanical methods
  Has very little storage capacity compared to a gravity thickener
  Not very efficient for primary sludge
  Requires polymer conditioning for higher solids capture or increased loading


Effective for thickening WAS to 4 to 6% solids concentration High capital cost
Control capability for process performance High power consumption
Least odor potential and housekeeping requirements because of contained process Requires moderate operator attention
Less space required Sophisticated maintenance requirements
  Requires polymer conditioning for higher solids capture
Gravity belt thickening Effective for thickening WAS to 0.4 to 6% solids concentration Polymer dependent
Control capability for process performance Housekeeping requirements
High solids capture efficiency Odor potential
Relatively low capital cost Moderate operator attention required
Relatively low power consumption Building commonly required
Rotary drum thickening Effective for thickening WAS to 0.4 to 6% solids concentration Polymer dependent and sensitive to polymer type
Less space required Housekeeping requirements
Low power consumption Odor potential
  Moderate operator attention required
  Building commonly required

Centrifugal Thickening

             Centrifugal thickening is the acceleration of sedimentation through the use of centrifugal force. In a gravity thickener, solids settle by gravity. In a centrifuge, force 500 to 3000 times of gravity is applied; therefore, a centrifuge acts as a highly effective gravity thickener. [2]  

              Centrifuges are commonly used for thickening WAS. Primary sludge is seldom thickened by centrifuges because it commonly contains abrasive material that is detrimental to a centrifuge. In addition to being very effective for thickening WAS, centrifuges have the additional advantages of less space requirement and the least odor potential and housekeeping requirements because of the contained process. However, capital cost and maintenance and power costs can be substantial. Therefore, the process is usually limited to

large treatment plants.

                There are basically three types of centrifuges: disk nozzle, imperforate basket, and solid bowl. Figure 1 shows schematics of all three types of centrifuges. Disk nozzle centrifuges require extensive prescreening and degritting of feed sludge. They can be used on sludges with particle sizes of 400 m or less. Imperforate basket centrifuges can be used for batch operation only and not continuous feed and discharge. They suffer from high bearing wear and require significant maintenance. For these reasons, disk nozzles and imperforate basket centrifuges are being replaced by solid bowl centrifuges.

Solid bowl centrifuges (often referred to as continuous decanter scroll or helical screw conveyor centrifuges) are made in two basic configurations:

  Countercurrent and concurrent. The primary differences between the two are the configuration of the conveyor (scroll) toward the liquid discharge end of the machine, and the location and confi guration of the solids discharge port.

Sludge feed enters the bowl through a concentric tube at one end of the centrifuge.

The liquid depth in the centrifuge is determined by the discharge weir elevation relative to the bowl wall. The weir is typically adjustable. As the sludge particles are exposed to the gravitational field, they start to settle out on the inner surface of the rotating bowl. The lighter liquid (centrate) pools above the sludge layer and flows toward the centrate outlet ports located at the larger end of the machine. The settled sludge particles on the inner surface of the bowl are transported by the rotating conveyor (scroll) toward the opposite end (conical section) of the bowl. The main difference between a thickening and a dewatering centrifuge is in the construction of the conveyor and the conical part of the bowl. The slope of the conical part is less in a thickening centrifuge.

                Performance of a centrifuge is measured by the thickened sludge concentration (sludge cake concentration for a dewatering centrifuge) and the solids recovery (often called solids capture). [3]  


Operational variables [4]  

Operational variables that affect thickening include:

  • Feed flow rate
  • Feed sludge characteristics, such as particle size and shape, particle density, temperature, and sludge volume index
  • Rotational speed of the bowl
  • Differential speed of the conveyor relative to the bowl
  • Depth of the liquid pool in the bowl
  • Polymer conditioning, needed to improve performance

One of most important operational parameters of centrifuges is the factor of separation F, which demonstrates how centrifugal forces are stronger than sedimentation forces by the following equation:

F=a/g  , a=wr   or  F=r (n/g)


F =separation factor

a  =speed of centrifugal force, m/s2

g = speed of sedimentation force, m/ s2

w = angle speed of bowl (rotor), min−1

r = inside radius of bowl, m

n = speed of bowl (rotor) rotation, min−1


         Increasing the speed of bowl (rotor) rotation allows an increase in the factor of separation. However, the high bowl rotation speed can decrease the sludge particle sizes, increase the polymer demand, and decrease the effectiveness of flocculation. Therefore, centrifuges typically operate at speeds between 1500 and 2500 rpm, with the factor of separation between 600 and 1600. At the lower values of factor of separation, thickened sludge concentration and solids recovery values are lower.


Ahmed Ahmed Elserwy

Water & Environmental Consultant

Technical Manager Louts for Water Treatment



[1]   Wastewater sludge processing / Izrail S. Turovskiy, P. K. Mathai, John Wiley & Sons, Inc., Hoboken, New Jersey,2006, p 81.

[2]     L. K. Wang, Y. T. Hung, and N. S. Shammas (eds.), Physicochemical Treatment Processes. Humana Press, Totowa, NJ (2005) ,p 684.

[3]   Metcalf & Eddy, Tchobanoglous, G., Burton, F. L., Stensel, H. D. “Wastewater engineering: treatment and reuse/Metcalf & Eddy, Inc.”, Tata McGraw-Hill, 2003.

[4]   Wastewater sludge processing / Izrail S. Turovskiy, P. K. Mathai, John Wiley & Sons, Inc., Hoboken, New Jersey,2006, p 96.