Journal of Korean Society of Water and Wastewater (상하수도학회지)

The Korean Society of Water and Wastewater (대한상하수도학회)
권호 표지

Characteristics of Micro Floc in a Rapid Mixing Step at Different Coagulant Dose

급속혼화공정에서 응집제 주입률에 따른 미세입자의 성장특성

  • Received : 2007.02.12
  • Accepted : 2007.03.16
  • Published : 2007.04.15
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Abstract

Effects of alum dosage on the particle growth were investigated by monitoring particle counts in a rapid mixing process. Kaolin was used for turbid water sample and several other chemicals were added to adjust pH and ionic strength. The range of velocity gradient and mixing time applied for rapid mixing were $200{\sim}300sec^{-1}$ and 30~180 sec, respectively. Particle distribution in the synthetic water sample was close to the natural water where their turbidity was same. The number of particles in the range of $10.0{\sim}12.0{\mu}m$ increased rapidly with rapid mixing time at alum dose of 20mg/L, however, the number of $8.0{\sim}9.0{\mu}m$ particles increased at alum dose of 50mg/L. The number of $14.0{\sim}25.0{\mu}m$ particles at alum dose of 20mg/L was 10 times higher than them at alum dose of 50mg/L. Dominant particle growth was monitored at the lower alum dose than the optimum dose from a jar test at an extended rapid mixing time(about 120 sec). The number of $8.0{\sim}14.0{\mu}m$ particles was lower both at a higher alum doses and higher G values. At G value of $200sec^{-1}$ and at alum dose of 10-20mg/L, residual turbidity was lower as the mixing time increased. But at alum dose above 40mg/L and at same G value, lower residual turbidity occurred in a short rapid mixing time. Low residual turbidity at G value of $300sec^{-1}$ occurred both at lower alum doses and at shorter mixing time comparing to the results at G value of $200sec^{-1}$.

Keywords

Acknowledgement

Supported by : 충북대학교

References

  1. Park, S.M., Jun, H.B., Jung, M.S., Koo, H.M. (2006) Effects of velocity gradient and mixing time on particle growth in a rapid mixing tank, Water Science & Technology, 53(7), pp 95-102
  2. Amirtharajah, A., Clark, M.M. and Trussell, R.R. (1991) Mixing in coagulation and flocculation, American Water Works Association Research Foundation, pp. 256-281
  3. Amirtharajah, A. and O'Melia, C.R. (1990) Coagulation process: Destabilization, mixing and flocculation, Water Quality and treatment, McGraw-Hill
  4. Benefield DL, Judkins JF, Weand BL, Process chemistry for water and wastewater treatment, Prentice-Hall, Inc., NJ, USA, 1982
  5. Amirtharajah, A. and Mills, K.M. (1982), Rapid Mix Design for mechanisms of Alum Coagulation, J. AWWA, 74, pp. 210-216 https://doi.org/10.1002/j.1551-8833.1982.tb04890.x
  6. Bratby JR. (1981), Interpreting laboratory results for the design of rapid mixing and flocculation systems. J. AWWA, 73, pp. 318-325 https://doi.org/10.1002/j.1551-8833.1981.tb04721.x
  7. Kawamura S. (1976) Consideration in improving flocculation, J. AWWA, 68, pp. 328-336 https://doi.org/10.1002/j.1551-8833.1976.tb02421.x
  8. Letterman, R.D., Quon, J.E. and Gemmell, R.S. (1973) Influence of rapid-mix parameters on flocculation, J. AWWA
  9. Vrale L. and Jorden R.N. (1971) Rapid mixing in water treatment, J. AWWA, 63, pp. 52-58 https://doi.org/10.1002/j.1551-8833.1971.tb04027.x
  10. Camp T. R. (1968), Floc volume concentration, J. AWWA, 60, pp. 656-673 https://doi.org/10.1002/j.1551-8833.1968.tb03592.x
  11. Hudson, H.E., Jr., and Wolfner, JP. (1967) Design of Mixing and Flocculation Basins, J. AWWA, 59, 1257