ON-LINE MONITORING AND QUANTITATIVE ANALYSIS OF BIOFOULING IN LOW-VELOCITY COOLING WATER SYSTEM

Lee HJ; Han DG; Lee SH; Yoo JW; Baek SH; Lee EK

Korean Journal of Chemical Engineering, Vol.15, No.1, 71-77, January, 1998

Lee HJ, Han DG, Lee SH, Yoo JW, Baek SH, Lee EK

To monitor and analyze the biofouling phenomenon caused primarily by microbial suspended solids (MSS), a ’biofouling tube’ apparatus consisting of a carbon steel tube, a differential pressure transmitter, a corrator, and a cooling water circulation device was designed and fabricated. By measuring continuously the pressure drop across the biofouling tube and using the correlation between the fluid’s friction factor and surface roughness, we quantitatively analyzed the influence of MSS concentration, temperature, and fluid velocity on the rate of biofilm growth on the metal surface. The result indicated that the fluid velocity had the most profound impact, e.g., lowering the linear velocity from 0.3 to 0.15 m/sec resulted in about a four times higher biofouling rate. Up to 50 ppm MSS, the biofouling rate was proportional to the MSS concentration. The biofouling rate at 35℃ was about 1.75 times higher than that of 45℃, probably due to the diminishing effect of thermolabile microorganisms exposed at 45℃. It was also demonstrated that the biofouling could be significantly reduced by incorporating cooling water treatment programs such as protective prefilming and adding corrosion inhibitors. This apparatus, if installed on-site at a sidestream of a cooling water system, could be used to monitor the biofouling tendency on-line and to suggest timely preventive maintenance actions.

Keywords:Biofouling;Microbial Suspended Solids;Pitting;Corrosion;Cooling Water Treatment;Biofouling Monitoring

[References]

Busscher HJ, Weerkamp AH, Fems Microbiol. Rev., 46, 165 (1987)
Cheremisinoff PN, "Handbook of Water and Wastewater Treatment Technology," Marcel Dekker, New York, 539 (1995)
Colturi TF, Kozelski KJ, Mater. Performance, 23(8), 43 (1984)
Coulson JM, Richardson JF, Sinnott RK, "Chemical Engineering," Pergamon Press, New York, 6, 511 (1989)
Epstein N, Heat Transf. Eng., 4, 43 (1983)
Geesey GG, Lewandowski Z, Flemming HC, "Biofouling and Biocorrosion in Industrial Water Systems," CRC Press, Florida (1994)
Hamilton WA, Ann. Rev. Microbiol., 39, 195 (1985)
Marcus P, Oudar J, "Corrosion Mechanisms in Theory and Practice," Marcel Dekker Inc., 457 (1995)
Nevers ND, "Fluid Mechanics for Chemical Engineers," 2nd ed., McGraw-Hill, 178 (1991)
Pope DH, Duquette DJ, Johannes AH, Wayner PC, Mater. Performance, 23(4), 14 (1984)
Sanatgar H, Somerscales EFC, Chem. Eng. Prog., 53 (1991)
Taborek J, Aoki T, Ritter RB, Palem JW, Knudsen JG, Chem. Eng. Prog., 68, 56 (1972)
Tatnall RE, Mater. Performance, 20(9), 32 (1981)
Tatnall RE, Mater. Performance, 20(8), 41 (1981)
Thierry D, Mater. Performance, 26(5), 35 (1987)
Uchida T, Nishiyama T, Kawamura T, "Up-to-data Problems in Alkaline Cooling Water Treatment Program," Corrosion/90, NACE, Paper No. 349 (1990)
Wakamatsu Y, Ono Y, Yoshihara K, Kawamura F, "New Real-time Monitoring System for Improvement of Cooling Water Treatment Performance-Case History," Corrosion/91, Paper No. 481, NACE (1991)
Walker CK, Maddux GC, Mater. Performance, 28(5), 64 (1989)
Welty JR, Wicks CE, Wilson RE, "Fundamentals of Momentum, Heat, and Mass Transfer," 3rd ed., Oregon, 202 (1984)

[Referenced By]

[1] Busscher HJ, Weerkamp AH, Fems Microbiol. Rev., 46, 165 (1987)

[2] Cheremisinoff PN, "Handbook of Water and Wastewater Treatment Technology," Marcel Dekker, New York, 539 (1995)

[3] Colturi TF, Kozelski KJ, Mater. Performance, 23(8), 43 (1984)

[4] Coulson JM, Richardson JF, Sinnott RK, "Chemical Engineering," Pergamon Press, New York, 6, 511 (1989)

[5] Epstein N, Heat Transf. Eng., 4, 43 (1983)

[6] Geesey GG, Lewandowski Z, Flemming HC, "Biofouling and Biocorrosion in Industrial Water Systems," CRC Press, Florida (1994)

[7] Hamilton WA, Ann. Rev. Microbiol., 39, 195 (1985)

[8] Marcus P, Oudar J, "Corrosion Mechanisms in Theory and Practice," Marcel Dekker Inc., 457 (1995)

[9] Nevers ND, "Fluid Mechanics for Chemical Engineers," 2nd ed., McGraw-Hill, 178 (1991)

[10] Pope DH, Duquette DJ, Johannes AH, Wayner PC, Mater. Performance, 23(4), 14 (1984)

[11] Sanatgar H, Somerscales EFC, Chem. Eng. Prog., 53 (1991)

[12] Taborek J, Aoki T, Ritter RB, Palem JW, Knudsen JG, Chem. Eng. Prog., 68, 56 (1972)

[13] Tatnall RE, Mater. Performance, 20(9), 32 (1981)

[14] Tatnall RE, Mater. Performance, 20(8), 41 (1981)

[15] Thierry D, Mater. Performance, 26(5), 35 (1987)

[16] Uchida T, Nishiyama T, Kawamura T, "Up-to-data Problems in Alkaline Cooling Water Treatment Program," Corrosion/90, NACE, Paper No. 349 (1990)

[17] Wakamatsu Y, Ono Y, Yoshihara K, Kawamura F, "New Real-time Monitoring System for Improvement of Cooling Water Treatment Performance-Case History," Corrosion/91, Paper No. 481, NACE (1991)

[18] Walker CK, Maddux GC, Mater. Performance, 28(5), 64 (1989)

[19] Welty JR, Wicks CE, Wilson RE, "Fundamentals of Momentum, Heat, and Mass Transfer," 3rd ed., Oregon, 202 (1984)