水解—好氧化物处理造纸中段废水工艺的研究
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摘要
本文分析了我国造纸行业的特点及其废水治理的现状。从低投资和降低运行费用的角度,通过动态模拟实验研究了以水解酸化和好氧生化(间歇曝气活性污泥法,以下简称SBR)为主的工艺流程。在水解酸化预处理造纸中段废水时,水解酸化反应器中应增加搅拌设备并悬挂生物填料,废水的停留时间宜大于10小时。造纸中段废水经过水解酸化预处理后,可以提高废水的好氧可生物降解性;废水中不溶解性COD浓度将有一定程度的提高。工程设计中,在水解酸化反应器后应加设沉淀单元。在SBR好氧生物处理系统中,曝气反应时间宜大于6.5小时。当废水初始COD浓度小于1000mg/l时,可以直接应用SBR工艺处理造纸中段废水,而不必采用任何预处理措施。在SBR生物反应器之后必须采用强化固液分离的处理单元,如过滤、混凝沉淀等。当温度低于10℃时,SBR系统出水水质恶化。在SBR工艺中,闲置期对SBR工艺处理造纸中段废水影响不大。在工程设计和运行过程中,可以采用ORP值作为SBR工艺曝气反应的终点指示,其曝气反应终点的ORP值特征是:急速升高后稳定于30mv~50mv之间。
The characteristics of paper industry and problems of paper making wastewater treatment are presented in this paper. In order to decrease both investment and operating expenses, the feasibility to treat the alkali straw pulp making intermediate wastewater by biological hydrolysis (acidification) and sequencing batch reactor (SBR) is studied using laboratory-scale reactor. The results show that the stirrers and biological carriers are needed in the reactor of biological hydrolysis when the wastewater is pretreated. Also, Hydraulic retention time (HRT) is beyond 10 hours. The biodegradability and insoluble chemical oxygen carbon (COD) of the wastewater are enhanced to some extent after biological hydrolysis. Thus, sedimentation unit is followed for removing suspended solid in the wastewater. In the system of SBR following biological hydrolysis reactor, the aeration period should exceed 6.5 hours. The wastewater is treated directly by SBR system without pretreatment on condition that the COD of the feed is less
than 1,000 mg/l. It should be emphasized that SBR reactor must be followed by useful separation process, such as filtration, coagulant sedimentation and so on. The effluent from SBR system does not meet the requirement of discharge standard as the temperature is below 10C,.The same treatment efficiency are achieved using two different aeration methods in SBR operation, such as the restrained aeration and the unrestrained aeration The idle period of SBR system does not affect the removal efficiency. The value of oxidation-reduction potential (ORP) can be employed to reflect the endpoint of aeration period of SBR system in engineering design. The endpoint characteristic of the aeration period in SBR system is that the value of ORP rises sharply and fluctuates between 30mv and 50mv subsequently.
The characteristics of paper industry and problems of paper making wastewater treatment are presented in this paper. In order to decrease both investment and operating expenses, the feasibility to treat the alkali straw pulp making intermediate wastewater by biological hydrolysis (acidification) and sequencing batch reactor (SBR) is studied using laboratory-scale reactor. The results show that the stirrers and biological carriers are needed in the reactor of biological hydrolysis when the wastewater is pretreated. Also, Hydraulic retention time (HRT) is beyond 10 hours. The biodegradability and insoluble chemical oxygen carbon (COD) of the wastewater are enhanced to some extent after biological hydrolysis. Thus, sedimentation unit is followed for removing suspended solid in the wastewater. In the system of SBR following biological hydrolysis reactor, the aeration period should exceed 6.5 hours. The wastewater is treated directly by SBR system without pretreatment on condition that the COD of the feed is less
than 1,000 mg/l. It should be emphasized that SBR reactor must be followed by useful separation process, such as filtration, coagulant sedimentation and so on. The effluent from SBR system does not meet the requirement of discharge standard as the temperature is below 10C,.The same treatment efficiency are achieved using two different aeration methods in SBR operation, such as the restrained aeration and the unrestrained aeration The idle period of SBR system does not affect the removal efficiency. The value of oxidation-reduction potential (ORP) can be employed to reflect the endpoint of aeration period of SBR system in engineering design. The endpoint characteristic of the aeration period in SBR system is that the value of ORP rises sharply and fluctuates between 30mv and 50mv subsequently.
引文
[1]张珂,俞正千,麦草浆碱回收技术指南,中国轻工业出版社,1999
[2]国家环镜保护局科技标准司,小造纸厂污染防治技术指南,1997
[3]中国环境保护产业协会水污染防治委员会,中国水污染防治技术装备论文集,1998
[4]韦海国,中国造纸工业污染防治的现状和对策,国际造纸,2000,16(1):3-5
[5]俞正千,对我国纸业环保的初步调查及其感受,国际造纸,2000,18(4):12-14
[6]唐运平,范凤申,碱法制浆造纸废水生物膜法达标排放技术,城市环境与城市生态,1999,12(6):16-18
[7]孙先锋,张志杰,崔红军,造纸黑液木质素降解微生物的分离和降解特性研究,环境工程,2002,20(3):78-80
[8]邢书彬,生物物化工艺处理造纸废水实例分析,重庆环境科学,2000,22(3):49-51
[9]尹家贵,造纸中段水上的物化处理研究,工业水处理,1999,(4):19-21
[10]沈耀良,王宝贞,废水生物处理新技术理论与应用,中国环境科学出版社,1999
[11]中国环境保护产业协会水污染防治委员会,中国水污染防治技术装备论文集,1998
[12]娄金生等,水污染治理新工艺与设计,海洋出版社,1999
[13]刘梅英,苏永渤,非化学法制浆造纸废水混凝处理方法研究,安全与环境学报,2002,2(5):33-34
[14]王天利,李士安,SBR-絮凝沉淀法处理造纸废水,环境工程,2002,20(5):68-69
[15]李亚新,李玉瑛,厌氧生物处理新工艺——厌氧序批式反应器,工业用水与废水,2002,33(1):4-6
[16]蓝梅,周琪等,生化法处理难降解混合化工废水的研究,工业用水与废水,2003,34(1),26-29
[17]戴爱临等,稳定塘处理造纸废水的工程设计与净化效果分析,环境工程,2000,18(4):12-14
[18]范懋功,活性污泥法处理造纸废水,给水排水,1996,12(6):29-31
[19]崔延龄,应用活性污泥表面曝气法处理制浆污水,环境工程,1996,14(2):23-25
[20]张希衡,废水厌氧生物处理工程,中国环境科学出版社,1996
[21]马军,邱立平,曝气生物滤池及其研究发展,环境工程,2002,20(3):7-11
[22]纪荣平、邵志,SBR法在扬州啤酒厂废水处理中的应用,环境工程,1996,14(6):8-10
[23]包存宽,李彬,水污染控制模式选择的研究,东北师大学报,1997,(2):110-115
[24]李绍秀,彭勃,SBR法在屠宰废水处理中的应用,给水排水,1997,23(9)34-36
[25]方士等:SBR工艺处理造纸废水试验研究,《水处理技术》,1999,25(2):122-124
[26]罗楠,彭勃,SBR法处理化学药物制剂废水,环境污染与防治,1999,21(2):20-22
[27]胡勤海,管丽莉等,SBR法处理磺胺废水的试验研究,环境污染与防治,2002,24(1):19-20
[28]程凯英,廖戈等,ABR-SBR组合工艺处理食品调料废水,环境工程,2002,20(2):36-38
[29]吕松涛,董军玲等,UASB-SBR工艺处理卫生材料废水的工程实例,环境工程,2002,20(1):36-38
[30]朱淑琴等,序批式活性污泥法处理毛皮废水的研究,环境科学,1997,18(6):66-67
[31]王亚宜,李探微等,序批式生物膜法和SBR的对比研究,工业用水与废水,2002,33(6):4-6
[32]王东海,SBR在难降解有机物处理中的研究和应用,中国给水排水,1999,15(11):29-32
[33]林丰妹,郑平,SBR法的特点及其在生物脱氮中的应用,环境污染与防治,2002,24(2):98-101
[34]杨云龙,陈启斌,SBR工艺的现状与发展,工业用水与废水,2002,33(2):1-3
[35]李健,大型SBR工艺启动特点及活性污泥培训驯化,给水排水,2001,27(5):30-32
[36]胡晓东,何芳,间歇曝气工艺中污泥膨胀问题,环境工程,2002,20(5):18-19
[37]方建章、罗国维,水解—好氧混凝工艺处理啤酒厂废水,环境科学与技术,1997,78(3):23-26
[38]李武,水解-好氧生物处理工艺在制药废水处理上的应用,环境工程,1997,15(4):7-8
[39]陈新宇、陈翼孙等,水解酸化-生物接触氧化处理难降解丁苯橡胶废水的研究,给水排水,1997,23(2):32-35
[40]姜安玺,李德强等,水解酸化—生物接触氧化工艺在抗生素废水处理中的应用,安全与环境学报,2002,2(2):3-6
[41]贺延龄,废水的厌氧生物处理,中国轻工业出版社,1998
[42] Ketchum L.H, Irvine R.: First cost analysis of sequencing batch reactors. J.WPCF, 1987; 59: 288
[43] Anon,Ontario mill to install North America sfirst anaerobic wastwatersystem, PULP PAPER ,1986,39(33);36-38
[44] Naundorf. Biological treatment of wastwater in the compact reactor. Chem Eng Process, 1985,229-232
[45] HALL E R, Treatability studies of Canadian Pulp and paper wastwater, Environment Canada Report, 1988
[46] M.L.Arora et al. Technology evaluation of sequencing batch reactors. J.WPCF, 1985; 57(8): 867~875
[47] Richard R. Dague, Gouranga C. Bank: Anaerodic sequencing batch reactor treatment of dilute wastewater at psychrophilic temperatures, 《Water Enviroment Research》, P155~160, Vol.70, No.2, 1998
[48] S.M..Stronach, T.Rudd, J.N.Lester, Anaerobic Digestion Processes in Industrial Wastewater Treatment, P7, Springer-Verlag Berlin Heidelberg, 1986
[49] G.F.Nakhla et al., Modeling of sequencing batch reactors treating inhibitory and noninhibitory wastewaters., Water Environ. Res., P6~13, 69(1), 1997
[50] Piero M Armenanate. Anaerobic-aerobic treatment of halogenated phenolic compounds.Water Res., 1999, 33 (3):681-692
[2]国家环镜保护局科技标准司,小造纸厂污染防治技术指南,1997
[3]中国环境保护产业协会水污染防治委员会,中国水污染防治技术装备论文集,1998
[4]韦海国,中国造纸工业污染防治的现状和对策,国际造纸,2000,16(1):3-5
[5]俞正千,对我国纸业环保的初步调查及其感受,国际造纸,2000,18(4):12-14
[6]唐运平,范凤申,碱法制浆造纸废水生物膜法达标排放技术,城市环境与城市生态,1999,12(6):16-18
[7]孙先锋,张志杰,崔红军,造纸黑液木质素降解微生物的分离和降解特性研究,环境工程,2002,20(3):78-80
[8]邢书彬,生物物化工艺处理造纸废水实例分析,重庆环境科学,2000,22(3):49-51
[9]尹家贵,造纸中段水上的物化处理研究,工业水处理,1999,(4):19-21
[10]沈耀良,王宝贞,废水生物处理新技术理论与应用,中国环境科学出版社,1999
[11]中国环境保护产业协会水污染防治委员会,中国水污染防治技术装备论文集,1998
[12]娄金生等,水污染治理新工艺与设计,海洋出版社,1999
[13]刘梅英,苏永渤,非化学法制浆造纸废水混凝处理方法研究,安全与环境学报,2002,2(5):33-34
[14]王天利,李士安,SBR-絮凝沉淀法处理造纸废水,环境工程,2002,20(5):68-69
[15]李亚新,李玉瑛,厌氧生物处理新工艺——厌氧序批式反应器,工业用水与废水,2002,33(1):4-6
[16]蓝梅,周琪等,生化法处理难降解混合化工废水的研究,工业用水与废水,2003,34(1),26-29
[17]戴爱临等,稳定塘处理造纸废水的工程设计与净化效果分析,环境工程,2000,18(4):12-14
[18]范懋功,活性污泥法处理造纸废水,给水排水,1996,12(6):29-31
[19]崔延龄,应用活性污泥表面曝气法处理制浆污水,环境工程,1996,14(2):23-25
[20]张希衡,废水厌氧生物处理工程,中国环境科学出版社,1996
[21]马军,邱立平,曝气生物滤池及其研究发展,环境工程,2002,20(3):7-11
[22]纪荣平、邵志,SBR法在扬州啤酒厂废水处理中的应用,环境工程,1996,14(6):8-10
[23]包存宽,李彬,水污染控制模式选择的研究,东北师大学报,1997,(2):110-115
[24]李绍秀,彭勃,SBR法在屠宰废水处理中的应用,给水排水,1997,23(9)34-36
[25]方士等:SBR工艺处理造纸废水试验研究,《水处理技术》,1999,25(2):122-124
[26]罗楠,彭勃,SBR法处理化学药物制剂废水,环境污染与防治,1999,21(2):20-22
[27]胡勤海,管丽莉等,SBR法处理磺胺废水的试验研究,环境污染与防治,2002,24(1):19-20
[28]程凯英,廖戈等,ABR-SBR组合工艺处理食品调料废水,环境工程,2002,20(2):36-38
[29]吕松涛,董军玲等,UASB-SBR工艺处理卫生材料废水的工程实例,环境工程,2002,20(1):36-38
[30]朱淑琴等,序批式活性污泥法处理毛皮废水的研究,环境科学,1997,18(6):66-67
[31]王亚宜,李探微等,序批式生物膜法和SBR的对比研究,工业用水与废水,2002,33(6):4-6
[32]王东海,SBR在难降解有机物处理中的研究和应用,中国给水排水,1999,15(11):29-32
[33]林丰妹,郑平,SBR法的特点及其在生物脱氮中的应用,环境污染与防治,2002,24(2):98-101
[34]杨云龙,陈启斌,SBR工艺的现状与发展,工业用水与废水,2002,33(2):1-3
[35]李健,大型SBR工艺启动特点及活性污泥培训驯化,给水排水,2001,27(5):30-32
[36]胡晓东,何芳,间歇曝气工艺中污泥膨胀问题,环境工程,2002,20(5):18-19
[37]方建章、罗国维,水解—好氧混凝工艺处理啤酒厂废水,环境科学与技术,1997,78(3):23-26
[38]李武,水解-好氧生物处理工艺在制药废水处理上的应用,环境工程,1997,15(4):7-8
[39]陈新宇、陈翼孙等,水解酸化-生物接触氧化处理难降解丁苯橡胶废水的研究,给水排水,1997,23(2):32-35
[40]姜安玺,李德强等,水解酸化—生物接触氧化工艺在抗生素废水处理中的应用,安全与环境学报,2002,2(2):3-6
[41]贺延龄,废水的厌氧生物处理,中国轻工业出版社,1998
[42] Ketchum L.H, Irvine R.: First cost analysis of sequencing batch reactors. J.WPCF, 1987; 59: 288
[43] Anon,Ontario mill to install North America sfirst anaerobic wastwatersystem, PULP PAPER ,1986,39(33);36-38
[44] Naundorf. Biological treatment of wastwater in the compact reactor. Chem Eng Process, 1985,229-232
[45] HALL E R, Treatability studies of Canadian Pulp and paper wastwater, Environment Canada Report, 1988
[46] M.L.Arora et al. Technology evaluation of sequencing batch reactors. J.WPCF, 1985; 57(8): 867~875
[47] Richard R. Dague, Gouranga C. Bank: Anaerodic sequencing batch reactor treatment of dilute wastewater at psychrophilic temperatures, 《Water Enviroment Research》, P155~160, Vol.70, No.2, 1998
[48] S.M..Stronach, T.Rudd, J.N.Lester, Anaerobic Digestion Processes in Industrial Wastewater Treatment, P7, Springer-Verlag Berlin Heidelberg, 1986
[49] G.F.Nakhla et al., Modeling of sequencing batch reactors treating inhibitory and noninhibitory wastewaters., Water Environ. Res., P6~13, 69(1), 1997
[50] Piero M Armenanate. Anaerobic-aerobic treatment of halogenated phenolic compounds.Water Res., 1999, 33 (3):681-692
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