Sludge granulation and efficiency of phase separator in UASB reactor treating combined industrial effluent 被引量：6

Sludge granulation and efficiency of phase separator in UASB reactor treating combined industrial effluent

下载PDF

导出

摘要 Sludge granulation and the effect of gas-liquid-solid separator （GLSS） design on the efficiency of upflow anaerobic sludge blanket （UASB） and upflow anaerobic sludge filter （UASF） reactors, operating at HRTs ranging from 3 to 12 h was investigated. VSS/TS ratio gradually increased in both the reactors with increasing sludge age （from 0.5 to more than 0.7 for UASB reactor and 0.012 to 0.043 for UASF reactor）. X-Ray diffraction analysis of the UASF sludge showed the presence of expanding clays revealing its additional absorption capability. Fuoraphyllite and albite precipitation related to excellular polymers of the microbial shell structure, showed the extended growth of microorganisms during sludge granulation. A gradual decrease （82%-69%） in COD removal with decreasing HRT was apparent in UASF reactor. In case of UASB reactor, this decrease was marginal because addition of GLSS device significantly improved （14%-20%） the overall efficiency of the UASB reactor. GLSS enhanced the efficiency of the UASB reactor by increasing the settleability of suspended particles and accelerating the coagulation of colloidal particles due to the velocity gradient. Sludge granulation and the effect of gas-liquid-solid separator （GLSS） design on the efficiency of upflow anaerobic sludge blanket （UASB） and upflow anaerobic sludge filter （UASF） reactors, operating at HRTs ranging from 3 to 12 h was investigated. VSS/TS ratio gradually increased in both the reactors with increasing sludge age （from 0.5 to more than 0.7 for UASB reactor and 0.012 to 0.043 for UASF reactor）. X-Ray diffraction analysis of the UASF sludge showed the presence of expanding clays revealing its additional absorption capability. Fuoraphyllite and albite precipitation related to excellular polymers of the microbial shell structure, showed the extended growth of microorganisms during sludge granulation. A gradual decrease （82%-69%） in COD removal with decreasing HRT was apparent in UASF reactor. In case of UASB reactor, this decrease was marginal because addition of GLSS device significantly improved （14%-20%） the overall efficiency of the UASB reactor. GLSS enhanced the efficiency of the UASB reactor by increasing the settleability of suspended particles and accelerating the coagulation of colloidal particles due to the velocity gradient.

作者 Abdullah Yasar Nasir Ahmad Muhammad Nawaz Chaudhry Aamir Amanat Ali Khan

机构地区 Directorate of Research and Development

出处《Journal of Environmental Sciences》 SCIE EI CAS CSCD 2007年第5期553-558,共6页 环境科学学报（英文版）

关键词 sludge granulation gas-liquid-solid （GLS） phase separator UASB microbial growth sludge granulation gas-liquid-solid （GLS） phase separator UASB microbial growth

分类号 X703 [环境科学与工程—环境工程]

引文网络
相关文献

参考文献22

1Amatya P L,1996.Anaerobic treatment of industrial wastewater by upflow anaerobic sludge blanket (UASB) reactor[D].M.Sc.Thesis.Asian Institute of Technology,Bangkok,Thailand.
2APHA,AWWA,WPCF,1998.Standard methods for the examination of water and wastewater[S].American Public Health Association,Washington,DC.
3Baily J E,Ollis D F,1986.Biochemical engineering fundamentals[M].2nd ed.New York:McGaw-Hill.
4Barbosa R A,Sant Anna G L,1989.Treatment of raw domestic sewage in an UASB reactor[J].Water Research,23(12):1483-1490.
5Cavalcanti P F F,2003.Integrated application of the UASB reactor and ponds for domestic sewage treatment in tropical regions[D].Ph.D Thesis.Wageningen University,Wageningen,The Netherlands.
6El-Mamouni R,Leduc R,Guiot S R,1997.Influence of the starting microbial nucleus type on the anaerobic granulation dynamics[J].Applied Microbiology and Biotechnology,47(2):189-194.
7El-mitwalli T A,2000.Anaerobic treatment of domestic sewage at low temperature[D].Ph.D Thesis.Wageningen University,The Netherlands.
8Gonzalez G,Lens P N L,Aelst A V et al.,2001.Cluster structure of anaerobic aggregates of an expanded granular sludge bed reactor[J].Applied and Environ Microbiol,67(8):3683-3692.
9Hulshoff P L W,1989.The phenomenon of granulation of anaerobic sludge[D].Ph D Thesis.Wageningen Agri.Univ.,The Netherlands.
10Kansal,Rajeshwari,Balakrishnan et al.,2003.Anaerobic digestion technologies for energy recovery from industrial wastewater-A study in Indian context[J].TERI Information Monitor on Environmental Science New Dehli,3(2):67-75.

二级参考文献28

1[1]American Public Health Association, AWWA, WPCF, 1995. Standard methods for the examination of water and wastewater[S]. 19th edition, WashingtonDC, USA.
2[2]Ciftci T, Ozturk, 1993. Anaerobic treatment of the high strength wastes from the yeast industry[J]. Wat Sci Tech, 28(2): 199-209.
3[3]Craveiro A M, Soares H M, Schmidell W, 1986. Technical aspects and eost estimations for anaerobic systems treating vinasse and brewery/soft drink wastewaters[J]. Wat Sci Tech, 18(12): 123-134.
4[4]Fang H H P, Chui H K, 1993. Maximum COD loading capacity in UASB reactors at 37 ℃ [ J ]. ASCE Journal of Environmental Engineering, 119 ( 1 ): 103-119.
5[5]Fang H H P, Chui H K, Li Y Y, 1995. Anaerobic degradation of butyrate in a UASB reactor[J]. Bioresource Technology, 51: 75-81.
6[6]Habets L H A, Vegt A L de, 1991. Anaerobic treatment of bleached TMP and CTMP effluent in the biopaq UASB system[J]. Wat Sci Tech, 24(3-4): 331-345.
7[7]Herbert H P, Fang, Zhou G M, 1997. Anaerobic degradation of benzoate andcresol isomers in sulfate-rich waste water[J]. Wat Sci Tech, 36(6-7): 7-14.
8[8]Herbert H P, Fang et al., 1995. Performance and sludge characteristics of UASB process propionate-rich wastewater[J]. Wat Res, 29(3): 895-898.
9[9]He Y L, Gong X L, Yang S H, 1995. Sludge granulation in a UASB reactor for the treatment of soda anthraquinone chemical wheat-straw pulp black liquor [J]. Bioresource Technology, 51: 213-215.
10[10]Hideki Harada, Shigeki Vemura, Ann-Cheng Chen et al., 1996. Anaerobictreatment of a recalcitrant distillery wastewater by a thermophilic UASB reactor[J]. Bioresource Technology, 55: 215-221.

共引文献6

1王汉林,刘康怀,郑玉.UASB反应器处理木薯淀粉废水影响因素分析[J].贵州环保科技,2006,12(3):13-16. 被引量：2
2刘只欣.气相色谱法测沼气成分方法改进[J].西南给排水,2012,34(3):74-76.
3邱祺.水解酸化-好氧工艺处理制浆造纸中段废水[J].广东化工,2012,39(6):155-156. 被引量：2
4李江,何强,Henri Spanjers.UASB反应器处理造纸废水不同高度的污泥特性[J].环境科学学报,2012,32(12):2929-2934. 被引量：6
5郭建国,孙野青.造纸工业污染源对周边土壤细菌群落的影响[J].大连海事大学学报,2015,41(4):127-132.
6杨春,吕锡武.农村生活污水处理ABR工艺的启动与污泥微生物特性[J].净水技术,2017,36(5):79-85. 被引量：12

同被引文献57

1刘永红,贺延龄,李耀中,杨树成.UASB反应器中颗粒污泥的沉降性能与终端沉降速度[J].环境科学学报,2005,25(2):176-179. 被引量：26
2杨景亮,左剑恶,胡纪萃.两相厌氧工艺处理含硫酸盐有机废水的研究[J].环境科学,1995,16(3):8-11. 被引量：61
3杨世关,赵青玲,张杰,张百良.两种厌氧反应器培养颗粒污泥的对比试验[J].农业工程学报,2007,23(1):183-187. 被引量：9
4常晓雷,康勇,李峰,姚心.水力学条件对硫酸盐还原菌生物膜传质的影响[J].环境化学,2007,26(4):464-467. 被引量：2
5李梅,刘艳菊,张兆海.UASB+接触氧化+SBR工艺在酒精废水处理中的应用[J].水处理技术,2007,33(8):82-84. 被引量：12
6Cazarez O, Montoya D, Vital A G, et al. Modeling of three-phase heavy oil-water-gas bubbly flow in upward vertical pipes [ J ]. International Journal of Muhiphase Flow, 2010, 36 (6) : 439 - 448.
7Hashemian S J, James A. Gas-solid-liquid separator in anaerobic treatment of wastewater [ J]. Water Research, 1990, 2(3): 381 -382.
8Narnoli S K, Indu Mehrotra. Sludge blanket of UASB reactor: mathematical simulation[ J]. Water Research, 1997, 31 (4) : 715 -726.
9Claudia E T Caixeta, Magali C Cammarota, Aleina M F Xavier. Slaughter house wastewater treatment: evaluation of a new three-phase separation system in a UASB reactor [ J]. Bioresource Technology, 2002, 81 ( 1 ) : 61 - 69.
10Ranganathan PanneerseNam, Sivarama Savithri, Gerald Devasagayam Surender. CFD modeling of gas-liquid-solid mechanically agitated contactor [ J]. Chemical Engineering Research and Design, 2008, 86 (12) : 1 331 -1 344.