Necessity analysis for employing preposition aerobic fluidized bed to treat coking wastewater

doi:10.16085/j.issn.1000-6613.2017-0139

Abstract

Abstract: Aiming to solve the problem that coking wastewater was not in proportion for carbon and nitrogen nutrients,abundant in poisonous components and difficult to be anaerobic treatment,self-developed novel biological fluidized bed with three phases was employed as high loading aerobic pretreatment method for the coking wastewater. The investigation mainly focused on the performance of the proposed aerobic reactor. Moreover,variation of critical organic components in aerobic biological process was analyzed by UV-Vis absorption spectrum and GC-MS methods. The main results could be listed as the following. When the influent average COD concentration is 4818.9mg/L, ambient temperature is between 28℃ to 33℃ degree,dissolved oxygen is in the range of 1.0mg/L to 1.5 mg/L and MLSS is about 8.0 g/L,then the organic loading of the reactor is in the range of 3.53 to 3.74kgCOD/(m³·d),and phenol,benzpyrole and phenylamine in wastewater can be efficiently degraded. Average removal ratio of COD,phenols and SCN^-can be over 70%、99% and 80%,respectively. By significantly reducing concentration of poisonous organics such as phenols,SCN^-,CN^-,and so on,the inhibition bottleneck for subsequent anaerobic hydrolysis and aerobic nitrification processes can be relieved. The reason the preposition aerobic fluidized bed can act as a necessary guarantee for high efficient biological treatment for coking wastewater can be attributed to the enhanced mixing and mass transfer and high sludge concentration in the proposed reactor. Therefore,,because aerobic biological fluidized bed has good mixing and mass transfer efficiencies and high sludge concentration,employing it as a pretreatment biological unit process for toxic and refractory organic wastewaters together with high ammonium concentration has some technical advantages,or other,prepositioned aerobic biological fluidized bed is indispensable to guarantee highly efficient treatment of these wastewaters.

Key words: coking, fluidized-bed, wastewater, biological inhibition, degradation

摘要： 针对碳氮比不协调、毒性组分多且厌氧困难的焦化废水，采用自行研制的新型生物三相流化床对其实施前置高负荷好氧处理，重点考察了反应器的好氧处理性能，并结合紫外-可见吸收光谱（UV-Vis）和GC-MS分析研究了好氧处理过程中主要有机成分的变化规律。结果表明，在进水COD平均浓度为4818.9 mg/L、环境温度为28~33℃、溶解氧为1.0~1.5mg/L及污泥浓度为8.0g/L左右的条件下，当有机负荷处于3.53~3.74kgCOD/（m³·d）范围内时，新型生物流化床可实现废水中的苯酚、吲哚及苯胺等化合物的降解，其COD、酚及SCN^-的平均去除率分别达到70%、99%和80%以上，通过大幅度削减酚类化合物、SCN^-和CN^-等毒性物质的浓度而解除后续厌氧水解和好氧硝化过程的抑制瓶颈。因此，好氧生物流化床由于具有良好的混合传质性能和较高的污泥浓度，将其作为前置生物单元工艺处理含高浓度氨氮有毒难降解有机废水具有技术优势，是实现该类废水高效生物处理的必要保障。

关键词: 焦化, 流化床, 废水, 生物抑制, 降解

CLC Number:

X703

ZHANG Tao, WEI Chaohai, REN Yuan, FENG Chunhua, WU Haizhen. Necessity analysis for employing preposition aerobic fluidized bed to treat coking wastewater[J]. Chemical Industry and Engineering Progress, 2017, 36(08): 3108-3115.

张涛, 韦朝海, 任源, 冯春华, 吴海珍. 焦化废水前置好氧流化床处理的必要性解析[J]. 化工进展, 2017, 36(08): 3108-3115.

References

[1] ZHAO W T,SHEN Y X,XIAO K,et al. Fouling characteristics in a membrane bioreactor coupled with anaerobic-anoxic-oxic process for coke wastewater treatment[J]. Bioresource Technology,2010,101(11):3876-3883.
[2] DONG Y R,ZHANG J T. Testing the genotoxicity of coking wastewater using Vicia faba and Hordeum vulgare bioassays[J]. Ecotoxicology and Environmental Safety,2010,73(5):944-948.
[3] CHEN T,HUANG X,PAN M,et al. Treatment of coking wastewater by using manganese and magnesium ores[J]. Journal of Hazardous Materials,2009,168(2/~3):843-847.
[4] 韦朝海,贺明和,任源,等. 焦化废水污染特征及其控制过程与策略分析[J]. 环境科学学报,2007,27(7):1083-1093. WEI C H,HE M H,REN Y,et al. Pollution characteristics of coking wastewater and control strategies:biological treatment and technology[J]. Acta Scientiae Circumstantiae,2007,27(7):1083-1093.
[5] 杨平,王彬,石炎福,等. 生物流化床A/A/O工艺处理焦化废水中试研究[J]. 化工学报,2002,53(10):1085-1088. YANG P,WANG B,SHI Y F,et al. Pilot study on treatmentof coking plant waste-water in bio-fluidized-bed reactors and A-A-O system[J]. Journal of Chemical Industry and Engineering(China),2002,53(10):1085-1088.
[6] 任源,韦朝海,吴超飞,等. 焦化废水水质组成及其环境学与生物学特性分析[J]. 环境科学学报,2006,26(11):1094-1100. REN Y,Wei C H,WU C F,et al. Environmental and biological characteristics of coking wastewater[J]..Acta Scientiae Circumstantiae,2007,27(7):1094-1100.
[7] 李咏梅,顾国维,仇雁翎,等. 厌氧酸化在焦化废水脱氮和毒性削减中的作用[J]. 环境科学,2001,22(4):86-~90. LI Y M,GU G W,QIUY L,et al. Effect of aAnaerobic acidification treatment on nitrogen removal and toxicity reduction of coke plant wastewater[J]. Environmental Science,2001,22(4):86-90.
[8] ZHAO J L,JIANG Y X,YAN B,et al. Multispecies acute toxicity evaluation of wastewaters from different treatment stages in a coking wastewater-treatment plant[J]. Environmental Toxicology and Chemistry,2014,33:1967-1975.
[9] 郁丹,严群,赵明星,等. 苯酚对厌氧颗粒污泥活性的抑制效应和恢复[J]. 化工学报,2007,58(6):1559-~1564. YU D,YAN Q,ZHAO M X,et al. Inhibitory effect of phenol on activity of anaerobic granular sludge and rejuvenation[J]. Journal of Chemical Industry and Engineering (China),2007,58(6):1559-1563.
[10] AMOR L,EIROA M,KENNES C. Phenol biodegradation and its effect on the nitrification process[J]. Water Research,2005,39(5):2915-2920.
[11] CAMERON S,PAUL L. Thiocyanate degradation during activated sludge treatment of coke-ovens wastewater[J]. Biochemical Engineering Journal,2007,34(2):122-130.
[12] 易欣怡,韦朝海,吴超飞,等. O/H/O生物工艺中焦化废水含氮化合物的识别与转化[J]. 环境科学学报,2014,34(9):2190-2198. YI X Y,WEI C H,WU C F,et al.Identification and transformation of nitrogen compounds in coking wastewater during O/H/O biological treatment process[J]. Acta Scientiae Circumstantiae,2014,34(9):2190-2198.
[13] WEI C H,XIE B,XIE H L. Hydrodynamics in an internal loop airlift reactor with a convergence-divergence draft tube[J]. Chemical Engineering Technology,2000,23(1):38-~45.
[14] 韦朝海,李磊. 底隙设置挡板内循环流化床水力特性分析[J].化工学报,2007,58(10):2480-~2484. WEI C H,LI L. Hydraulic characteristics of internal loop fluidized bed with baffle setting on bottom[J]. Journal of Chemical Industry and Engineering (China),2007,58(10):2480-~2484.
[15] 韦朝海,李磊,吴锦华,等. 漏斗型导流内构件对内循环三相流化床流体力学与传质特性的影响[J]. 化工学报,2007,58(3):591-~595. WEI C H,LI L,WU J H,et al. Influence of funnel-shape internals on hydrodynamics and mass transfer in internal loop three-phase fluidized bed[J]. Journal of Chemical Industry and Engineering (China),2007,58(3):591-595.
[16] 潘霞霞,李媛媛,黄会静,等. 焦化废水中硫氰化物的生物降解及其与苯酚、氨氮的交互影响[J]. 化工学报,2009,60(12):3089-3096. PAN X X,LI LY Y,HUANG H J,et al. Biodegradation of thiocyanate and inhibitory interaction with phenol,ammonia in coking wastewater[J]. CIESC Journal of Chemical Industry and Engineering (China),2009,60(12):3089-3096.
[17] 张伟,韦朝海,彭平安,等. A/O/O生物流化床处理焦化废水中酚类组成及降解特性分析[J].环境工程学报,2010,4(2):253-258. ZHANG W,WEI C H,PENG P A,et al. Components and degradation characteristics analysis of phenols in coking wastewater in biological fluidized bed A/O/O process[J]. Chinese Journal of Environmental Engineering,2010,4(2):253-258.
[18] 韦朝海,谢波,吴超飞,等. 三重环流生物流化床的流体力学与传质特性[J]. 化学反应工程与工艺,1999,15(2):166-173. WEI C H,XIE B,WU C F,et al.Hydrodynamics and mass transfer of triplet loop biological fluidized bed[J].Chemical Reaction Engineering and Technolog y,1999,15(2):166-173.
[19] MARANON E,VAZQUEZ I,RODRIGUEZ J,et al. Treatment of coke wastewater in a sequential batch reactor (SBR) at pilot plant scale[J]. Bioresource Technology,2008,99(10):4192-4198.
[20] YOUNGM K,DONGHEE P,DAE S L,et al. Inhibitory effects of toxic compounds on nitrification process for cokes wastewater treatment[J]. Journal of Hazardous Materials,2008,152(3):915-921.
[21] YONG S J,JONG S C. Simultaneous removal of COD,thiocyanate,cyanide and nitrogen from coal process wastewater using fluidized biofilm process[J]. Process Biochemistry,2006,41(5):1141-1147.
[22] KIM Y M,PARK D,JEON C O,et al. Effect of HRT on the biological pre-denitrification process for the simultaneous removal of toxic pollutants from cokes wastewater[J]. Bioresource Technology,2008,99(18):8824-8832.
[23] BOUCABEILLE C,BORIES A,OLLIVIER P. Degradation of thiocyanate by a bacterial cocultue[J]. Biotechnology Letters,1994,16(4):425-~430.
[24] 胡记杰,肖俊霞,任源,等. 焦化废水原水中有机污染物的活性炭吸附过程解析[J]. 环境科学,2008,29(6):1567-1571. HU J J,XIAO J X,REN Y,et al. Adsorption process of organic contaminant in untreated coking wastewater by powdered activated carbon[J]. Environmental Science,2008,29(6):1567-1571.
[25] 朱顺妮,刘冬启,樊丽,等. 喹啉降解菌Rhodococcus sp. QL2的分离鉴定及降解特性[J]. 环境科学,2008,29(2):488-493. ZHU S N,LIU D Q,FAN L,et al. Isolation,identification and degradation characteristics of a quinoline-degrading bacterium Rhodococcus sp.QL2[J]. Environmental Science,2008,29(2):488-493.
[26] 姚珺,何苗. 焦化废水中有机污染物经厌氧酸化后对好氧生物降解性能的影响[J]. 中国环境科学,1998,18(3):34-38. YAO J,HE M. Effect on the aerobic biodegradability after anaerobic acidification of organic pollutants in coke-plant wastewater[J]. China Environmental Science,1998,18(3):34276-38279.