Research progress on respiratory measurement technology in biological wastewater treatment system
CHEN Gang1, CHEN Si-yuan1, DONG Shan-yan1,2, LI Xin-dong1,2, LIU Zu-wen1,2
1. School of Architectural and Surveying & Mapping Engineering, Jiangxi University of Science and Technology, Ganzhou 341000, China; 2. Research Center for Water Quality Security Technology at Ganjiang River Basin, Jiangxi University of Science and Technology, Ganzhou 341000, China
Abstract: As the continuous improvement of water quality monitoring requirements in biological wastewater treatment system,research on respiratory measurement technology with good performance and high reliability has got more and more attention.Through summarizing the research development of respiratory measurement technology in biological wastewater treatment in recent years,this paper describes three respiratory measurement technologies and introduces their principles,characteristics,advantages and disadvantages,applications,respectively.Finally,the main problems of current respiratory measurement technologies are proposed and the outlook of their development in the field of biological wastewater treatment is prospected,which aims at providing a reference for the further research on respiratory measurement technology.
[1] Zerdazi R,Boutraa M,Melizi A,et al.Use of continuous aeration respirometry method for the prediction of slightly saline waste water biodegradation[J].Energy Procedia,2012,18:1361-1371. [2] Junker T,Paatzsch C,Knacker T.A water-sediment screening tool for measuring biodegradation of organic chemicals[J].Science of the Total Environment,2010,408:3803-3810. [3] Young J C,Cowan R M.Respirometry for enviromental science and engineering[M].Arkansas USA:SJ Enterprises Springdale,2004:7. [4] Zhang J,Yang M,Qiao Y S,et al.Biodegradation of nonylphenoxy carboxylates mixtures in two microcosms[J].Science of theTotal Environment,2007,388:392-397. [5] Organisation for Economic Cooperation and Development.OECD guidelines for testing of chemicals.OECD 301B.CO2 evolution test[S].Paris:Organisation for Economic Cooperation and Development,France,1993. [6] He M,Mei C F,Sun G P,et al.The effects of molecular properties on ready biodegradation of aromatic compounds in the OECD 301B CO2 evolution test[J].Arch Environ Contam Toxicol,2016,71:133-145. [7] 宋佳秀,任南琪,钱东旭,等.醌呼吸影响厌氧消化产CO2/CH4及转化有毒物质的研究[J].中国环境科学,2014,34(5):1236-1241. [8] Montgomery H A C.The determination of biochemical oxygen demand by respirometric methods[J].Water Research,1967,1:631-662. [9] 胡琼玲,高秋实,胡纪革,等.利用瓦勃氏呼吸仪研究废水生物处理中的问题[J].化工环保,1985,5:138-144. [10] Cai B J,Xie L,Yang D H,et al.Toxicity evaluation and prediction of toxic chemicals on activated sludge system[J].Journal of Hazardous Materials,2010,177:414-419. [11] Cristovao R,Rinto V M S,Martins R J E,et al.Assessing the influence of oil and grease and salt content on fish canning wastewater biodegradation respirometric tests[J].Journal of Cleaner Production,2016,127:343-351. [12] Karube I,Matsunaga T,Mitsuda S,et al.Microbial electrode BOD sensors[J].Biotechnology and Bioengineering,1977,19(10):1535-1547. [13] Ponomareva O N,Arlyapov V A,Alferov V A,et al.Microbial biosensors for detection of biological oxygen demand(a review)[J].Applied Biochemistry and Microbiology,2011,47(1):1-11. [14] 陈长茵.微生物传感器快速测定水中BOD的分析研究[J].环境与可持续发展,2017,42(3):117-118. [15] 赵磊,金若芸,何利,等.胶原纤维固定酿酒酵母BOD传感器性能及应用[J].环境工程学报,2015,9(7):3558-3564. [16] Jouanneau S,Recoules L,Durand M J,et al.Methods for assessing biochemical oxygen demand (BOD):A review[J].Water Research,2014,49:62-82. [17] Borys A,Hake J M,Gabb D M D.Evaluation of an online biochemical oxygen demand analyzer for oxygen production control[J].Proceedings of the Water Environment Federation,2002,11(20):378-396. [18] Liu J,Olsson G,Mattiasson B.Short-term BOD (BODst) as a parameter for on-line monitoring of biological treatment process[J].Biosensors and Bioelectronics,2004,20(3):562-570. [19] 张虎军,江岚,刘长宇,等.基于微生物膜反应器的在线BOD测量仪及应用[J].分析化学(FENXI HUAXUE)仪器装置与实验技术,2016,44(10):1619-1624. [20] Lawrence A J,Moores G R.Conductimetry in enzyme studies[J].European Journal of Biochemistry,1972,24:538-546. [21] Ginkel S W V,Hassan S H A,Ok Y S,et al.Detecting oxidized contaminants in water using sulfur-oxidizing bacteria[J].Environ Sci Technol,2011,45:3739-3745. [22] Ginkel S W V,Hassan S H A,Oh S E,et al.Detecting endocrine disrupting compounds in water using sulfur-oxidizing bacteria[J].Chemosphere,2010,81:294-297. [23] Gurung A,Hassan S H A,Oh S E.Assessing acute toxicity of effluent from a textile industry and nearby river waters using sulfur-oxidizing bacteria in continuous mode[J].Environ Technol,2011,32:1597-1604. [24] Grzebyk M,Pozniak G.Microbial fuel cells (MFCs) with interpolymer cation exchange membranes[J].Separat Purif Technol,2005,41(3):321-328. [25] Rabaey K,Verstraete W.Microbial fuel cells:Novel biotechnology for energy generation[J].Trends in Biotechnology,2005,23(6):291-298. [26] Yoshida N,Nakamura H,Karube I,et al.A mediator-type biosensor as a new approach to biochemical oxygen demand estimation[J].The Analyst,2000,125(12):2280-2284. [27] 徐筑君,徐颖超,常晓杰,等.以表面处理大肠杆菌为模型的电化学微生物传感器在毒性检测领域的应用[J].环境化学,2015,34(5):897-903. [28] Yang Y J,Fang D Y,Liu Y R,et al.Problems analysis and new fabrication strategies of mediated electrochemical biosensors for wastewater toxicity assessment[J].Biosensors and Bioelectronics,2018,108:82-88. [29] 杨冰,高海军,张自强.微生物燃料电池研究进展[J].生命科学仪器,2007,5:3-12. [30] Kim B H,Chang I S,Gil G C,et al.Novel BOD(biological oxygen demand)sensor using mediator-less microbial fuel cell[J].Biotechnol Lett,2003,25(7):541-545. [31] Tront J M,Fortner J D,Plotze M,et al.Microbial fuel cell biosensor for in situ assessment of microbial activity[J].Biosensors and Bioelectronics,2008,24:586-590. [32] 贾辉,杨光,房宏艳,等.进水COD浓度对基于MFC的UASB生物传感器反馈性能的影响[J].天津工业大学学报,2016,35(6):55-60. [33] Hassan S H A,Gadel S M F,Rahimnejad M,et al.Electricity generation from rice straw using a microbial fuel cell[J].International Journal of Hydrogen Energy,2014,39:9490-9496. [34] 张宏伟,郑雅文,王捷,等.微生物燃料电池生物传感器在环境监测中的应用及其研究进展[J].天津工业大学学报,2015,34(1):44-49.
