混凝吸附法处理含油废水的技术研究
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摘要
含油废水是一种常见的工业废水。随着国民经济的迅速发展,石油开采、石油加工、机械加工等诸多行业产生的含油废水量也越来越多。而含油废水对环境造成的危害也越来越大,严重威胁到动植物、甚至人类的生命健康。
根据国内外对含油废水的治理现状和含油废水自身的性质,研制了CAX复合混凝剂,建立了混凝吸附法处理含油废水的技术。采用粉煤灰、烟道灰等工业废弃物和少量工业硫酸铝配制成CAX复合混凝剂。由于粉煤灰和烟道灰本身具有很好的吸附、沉降性能,因此CAX复合混凝剂在含油废水的处理中表现出极大的优越性,混凝反应形成的矾花粒大、易沉降,形成的污泥包水量少,对油的去除率达到99%,对COD的去除率达到80%以上。通过实验室实验总结出CAX复合混凝剂的最佳反应条件:pH范围在6~9;最佳温度在15~55℃;最佳反应时间为4~8min;最佳加药量为0.5g/L。
根据CAX复合混凝剂的特性,研制了集混凝、絮凝、沉降、排泥、出水为一体的混凝沉降综合反应装置,大大缩小了设备的占地面积。实验室实验后进行了小型模拟实验,在混凝处理之后增加了吸附过滤装置。实验结果表明,对油的去除率达到99%,对COD的去除率达到80%以上,对色度、重金属、氨氮等也都有很好的去除效果。
为了进一步验证该技术的可行性,在辽河油田进行了2.5m~3/h废水中试实验。考虑到回收废油和减轻后续处理压力的因素,在混凝反应前增加了粗粒化预处理装置。整套设备占地面积仅10m~2左右,且除了原水由泵提升之外,其余流程均为自流,因此大大节省了占地面积和能源消耗。中试实验结果表明,该项技术对含油废水有极好的处理效果,处理后水质可达到国家规定的排放标准和油田锅炉用生水水质标准。
因此,该项技术处理含油废水不仅是完全可行的,而且具有其它技术所无法比拟的优点,也必将具有广阔的市场应用前景。
Oily wastewater is a kind of familiar industrial sewerage. With the rapid development of national economy, more and more oily wastewater were produced. The harmness of oily wastewater is more serious.
CAX composite coagulator and the method of coagulation and adsorption were developed according to the character of oily wastewater. The main materials of CAX composite coagulator include FA. Flue Ash and Al2(SO4)3. Owing to the capability of adsorption and sedimentation by FA and Flue Ash . CAX composite coagulator show good effect. The floccule is big and easy to go down. The mud has little water, so it is easy to treat. The removal efficiency of oil reach more 99% and the removal efficiency of COD reach more 80%. Experiment result show the best reaction condition: pH6~9, temperature 15-55 degree, coagulator dose: 0.5g/l. reaction time 4-8min.
According to the character of CAX composite coagulator. combined coagulated retort was developed. The area occupied by the equipment is small. After the experiment in laboratory, the small simulant experiment was conducted. The result of small simulant experiment show that the removal efficiency of oil reach more 99% and the removal efficiency of COD reach more 80%. the removal effect of color and heavy metal is good.
For the sake of farther validate the feasibility of this technology, the experiment of 2.5m3/h was conducted in Liaohe Oil Field. Considering reclaim waste oil and reduce press in the last step, pretreatment equipment was developed. The whole equipment occupied 10m". The area be occupied and the energy be consumed were greatly saving. The result of the experiment show that oily wastewater was well disposed. The water quality reached the standard regulated by nation.
So this technology is feasibile to dispose oily vvastewater, and it has the merit that others technology can not reached. It certainly has widely market.
根据国内外对含油废水的治理现状和含油废水自身的性质,研制了CAX复合混凝剂,建立了混凝吸附法处理含油废水的技术。采用粉煤灰、烟道灰等工业废弃物和少量工业硫酸铝配制成CAX复合混凝剂。由于粉煤灰和烟道灰本身具有很好的吸附、沉降性能,因此CAX复合混凝剂在含油废水的处理中表现出极大的优越性,混凝反应形成的矾花粒大、易沉降,形成的污泥包水量少,对油的去除率达到99%,对COD的去除率达到80%以上。通过实验室实验总结出CAX复合混凝剂的最佳反应条件:pH范围在6~9;最佳温度在15~55℃;最佳反应时间为4~8min;最佳加药量为0.5g/L。
根据CAX复合混凝剂的特性,研制了集混凝、絮凝、沉降、排泥、出水为一体的混凝沉降综合反应装置,大大缩小了设备的占地面积。实验室实验后进行了小型模拟实验,在混凝处理之后增加了吸附过滤装置。实验结果表明,对油的去除率达到99%,对COD的去除率达到80%以上,对色度、重金属、氨氮等也都有很好的去除效果。
为了进一步验证该技术的可行性,在辽河油田进行了2.5m~3/h废水中试实验。考虑到回收废油和减轻后续处理压力的因素,在混凝反应前增加了粗粒化预处理装置。整套设备占地面积仅10m~2左右,且除了原水由泵提升之外,其余流程均为自流,因此大大节省了占地面积和能源消耗。中试实验结果表明,该项技术对含油废水有极好的处理效果,处理后水质可达到国家规定的排放标准和油田锅炉用生水水质标准。
因此,该项技术处理含油废水不仅是完全可行的,而且具有其它技术所无法比拟的优点,也必将具有广阔的市场应用前景。
Oily wastewater is a kind of familiar industrial sewerage. With the rapid development of national economy, more and more oily wastewater were produced. The harmness of oily wastewater is more serious.
CAX composite coagulator and the method of coagulation and adsorption were developed according to the character of oily wastewater. The main materials of CAX composite coagulator include FA. Flue Ash and Al2(SO4)3. Owing to the capability of adsorption and sedimentation by FA and Flue Ash . CAX composite coagulator show good effect. The floccule is big and easy to go down. The mud has little water, so it is easy to treat. The removal efficiency of oil reach more 99% and the removal efficiency of COD reach more 80%. Experiment result show the best reaction condition: pH6~9, temperature 15-55 degree, coagulator dose: 0.5g/l. reaction time 4-8min.
According to the character of CAX composite coagulator. combined coagulated retort was developed. The area occupied by the equipment is small. After the experiment in laboratory, the small simulant experiment was conducted. The result of small simulant experiment show that the removal efficiency of oil reach more 99% and the removal efficiency of COD reach more 80%. the removal effect of color and heavy metal is good.
For the sake of farther validate the feasibility of this technology, the experiment of 2.5m3/h was conducted in Liaohe Oil Field. Considering reclaim waste oil and reduce press in the last step, pretreatment equipment was developed. The whole equipment occupied 10m". The area be occupied and the energy be consumed were greatly saving. The result of the experiment show that oily wastewater was well disposed. The water quality reached the standard regulated by nation.
So this technology is feasibile to dispose oily vvastewater, and it has the merit that others technology can not reached. It certainly has widely market.
引文
[1] 王良均,吴孟周.石油化工废水处理设计手册[M].北京:中国石化出版社,1996.5
[2] 陈复.水处理技术及药剂大全[M].北京:中国石化出版社,2000.10
[3] 任玉森.含油废水处理技术综述[J].节能与环保,2003(7):26-28
[4] 朱锡恩.机械工业含油废水处理[J].环境工程,1983(4):52-55
[5] 周岳溪.循环间歇式活性污泥法处理漂油废水.1994,14(1):70-72
[6] 江春晓等.含油废水的处理[J].环境污染与防治,1986,8(2):13-16
[7] 赵亚乾等.含油废水的处理[J].水处理技术,1995,21(4):227-230
[8] 李永发.含油废水的超滤法处理[J].水处理技术,1997,21(3):145-148
[9] 王国贵等.含油废水处理技术的应用现状[J].环境科学与技术,1997,78(3):32-33
[10] 胡志安等.含油废水处理的调研和实践[J].上海化工,2001(9):20-21
[11] 沈晓林等.超滤技术处理轧钢含油废水[J].冶金环境保护,2002(2):29-31
[12] 工业废水处理与利用[M].北京,科学出版社,1979
[13] 冯鹏邦.浮选柱用于油田回注水处理的研究[J].油气田环境保护,1994,4 (1):1-7
[14] Rajinder Pal,Jacob Masliyal. Oil Recovery From Oil in Water Emulsions Using a Flotation Column[J]. Chem . Eng. ,1990, 68 (5 : 959
[15] 吴秋林.用膜分相从水中除去油珠的研究[J].环境科学,1986,4(6):1-5
[16] 肖坤林.气浮塔处理含油废水的研究[J].工业水处理,2002,22(1):39-42
[17] Chen Abraham S C, et al. Removal of Oil, Grease and Suspended Solids from Product Water with Ceramic Cross Flow Microfiltration[J]. Spe. Prod. Eng., 1991, 6(2): 131-136
[18] Berne F. Physical-Chemical Methed of Treatment for Oil-contatining Effluents[J]. Water Sci. Techno., 1992, 14(9-11): 195-207
[19] 刘汉利.改性粉煤灰处理含油废水的研究[J].电力环境保护,2001,17(1):16-20
[20] 朱又春.磁分离法处理含油废水的研究[J].广东工业大学学报,1998,15(2):13-18
[21] Clase. Flocculation of Waste Emulsions Using Polyelectrolytes[J]. Prog. Water Techno., 1990, 12(6):371-384
[22] 赵朝成.超临界水氧化技术处理含油污水研究[J].干旱环境监测,2001,15(1):25-28
[23] 陈颖.光催化含油污水的可行性研究[J].大庆石油学院学报,2001,25(2):25-28
[24] King Arthurs. Treater with Self-clearing Electrodes[P]. US 4 236 990. 1993
[25] 田刚.半推流式活性污泥系统工程应用特点分析[J].环境科学,2000,21(4):98-101
[26] Daque R R, et al. Anaerobic activated sludge[J].Water Poll. Control Fed ., 1996, 38 (2):220-226
[27] 李德豪.膜泥法A/O工艺处理炼油污水工艺探讨[J].环境科学与技术,2000,88(1):27-29
[28] 竺建荣.厌-好氧交替工艺处理辽河油田废水的试验[J].环境科学,1999,20(1):62-64
[29] 鲍建国.微孔膜生物反应器处理含油废水[J].中国给水排水,2002,18(2):74-76
[30] 王良均,吴孟周.石油化工废水处理设计手册[Z].北京:中国石化出版社,1996.
[31] 张自杰,钱易,章非娟.环境工程手册水污染防治卷[Z].北京:高等教育出版社,1996.
[32] 席炳炬.以废治废与废水净化再用[M].北京:中国环境科学出版社,1992.
[33] 李国鼎.化学工业废水治理 废水卷[Z].北京:中国环境科学出版社,1992.
[34] 徐根良等.含油废水处理技术综述[J].水处理技术,1991,17(1):1
[35] O' Melia C R. Coagulation and Flocculation in Physical Chemical Process of Water Quality Control[M]. New York: Wiley-Interscience, 1972:14-17
[36] 姚金华.混凝剂与絮凝剂[M].北京:中国环境科学出版社,1991.1-53
[37] Kyuichiro kurane. Agr. Biol Chem[J]. 1991,55(4):1127-1129
[38] Mcclune H, Muir J. World, Oil[J]. 1998, 219(7):4-8
[39] 顾夏声,黄铭荣,王占生.水处理工程[M].北京:清华大学出版社,1985.62-81
[40] 曲元辉,雷朋举,栾兆坤.预氧化加复合混凝剂处理高温石油废水[J].环境工程,1997,15(4):3-6
[41] 王彪.原油破乳剂研究新进展[J].油田化学,1994,11(3):256
[42] 关卫省,朱浚黄.PHM-Y混凝剂处理乳化油废水的研究[J].工业水处理,1994,14 (2).20-22
[43] NYER E.K. Groundwater Treatment Technology[M]. Van Nostrand Reinhold Company, 1985.
[44] 刘希波.粉煤灰在废水处理中的应用[J].环境工程,1993,11(6):37-39
[45] 张建平.粉煤灰处理废水机理及应用[J].粉煤灰综合利用,1999,2:32-34
[46] 李亚辉,杨辉,赵红.粉煤灰处理废水的理论与实践[J].工业用水与废水,1999,30(3):1-5
[47] 袁春林.我国火电厂粉煤灰的化学成分特征[J].电力环境保护,1998,14(1):9-14
[48] 刘国光,刘兴旺.侯杰等.粉煤灰吸附性能的研究[J].中国环境科学,1994,7(5):62-64
[49] 邵颖.活性粉煤灰对弱酸性艳绿GS 吸附性能的研究[J].工业水处理,1997,17(1):21-23
[50] 李松田,李灵芝,李汉斌.含油废水处理中混凝剂的选择[J].平顶山师专学抱(自然科学版),1997,11(1):3-6
[51] 杨永哲,王志盈,王晓昌.改进型复合碱式氯化铝在处理含油废水中的应用[J].给水排水,2001,27(12):76-78
[52] 胡勇有,顾国雄.新型混凝剂聚磷氯化铝的研究[J].水处理技术,1993,19(5):281-285
[53] 席炳炬.以废治废与废水净化再用[M].北京:中国环境科学出版社,1992
[54] 林忠胜,文武.CAX 复台混凝剂处理含油废水的研究[J].海洋环境科学,2003,22(1):15-19
[2] 陈复.水处理技术及药剂大全[M].北京:中国石化出版社,2000.10
[3] 任玉森.含油废水处理技术综述[J].节能与环保,2003(7):26-28
[4] 朱锡恩.机械工业含油废水处理[J].环境工程,1983(4):52-55
[5] 周岳溪.循环间歇式活性污泥法处理漂油废水.1994,14(1):70-72
[6] 江春晓等.含油废水的处理[J].环境污染与防治,1986,8(2):13-16
[7] 赵亚乾等.含油废水的处理[J].水处理技术,1995,21(4):227-230
[8] 李永发.含油废水的超滤法处理[J].水处理技术,1997,21(3):145-148
[9] 王国贵等.含油废水处理技术的应用现状[J].环境科学与技术,1997,78(3):32-33
[10] 胡志安等.含油废水处理的调研和实践[J].上海化工,2001(9):20-21
[11] 沈晓林等.超滤技术处理轧钢含油废水[J].冶金环境保护,2002(2):29-31
[12] 工业废水处理与利用[M].北京,科学出版社,1979
[13] 冯鹏邦.浮选柱用于油田回注水处理的研究[J].油气田环境保护,1994,4 (1):1-7
[14] Rajinder Pal,Jacob Masliyal. Oil Recovery From Oil in Water Emulsions Using a Flotation Column[J]. Chem . Eng. ,1990, 68 (5 : 959
[15] 吴秋林.用膜分相从水中除去油珠的研究[J].环境科学,1986,4(6):1-5
[16] 肖坤林.气浮塔处理含油废水的研究[J].工业水处理,2002,22(1):39-42
[17] Chen Abraham S C, et al. Removal of Oil, Grease and Suspended Solids from Product Water with Ceramic Cross Flow Microfiltration[J]. Spe. Prod. Eng., 1991, 6(2): 131-136
[18] Berne F. Physical-Chemical Methed of Treatment for Oil-contatining Effluents[J]. Water Sci. Techno., 1992, 14(9-11): 195-207
[19] 刘汉利.改性粉煤灰处理含油废水的研究[J].电力环境保护,2001,17(1):16-20
[20] 朱又春.磁分离法处理含油废水的研究[J].广东工业大学学报,1998,15(2):13-18
[21] Clase. Flocculation of Waste Emulsions Using Polyelectrolytes[J]. Prog. Water Techno., 1990, 12(6):371-384
[22] 赵朝成.超临界水氧化技术处理含油污水研究[J].干旱环境监测,2001,15(1):25-28
[23] 陈颖.光催化含油污水的可行性研究[J].大庆石油学院学报,2001,25(2):25-28
[24] King Arthurs. Treater with Self-clearing Electrodes[P]. US 4 236 990. 1993
[25] 田刚.半推流式活性污泥系统工程应用特点分析[J].环境科学,2000,21(4):98-101
[26] Daque R R, et al. Anaerobic activated sludge[J].Water Poll. Control Fed ., 1996, 38 (2):220-226
[27] 李德豪.膜泥法A/O工艺处理炼油污水工艺探讨[J].环境科学与技术,2000,88(1):27-29
[28] 竺建荣.厌-好氧交替工艺处理辽河油田废水的试验[J].环境科学,1999,20(1):62-64
[29] 鲍建国.微孔膜生物反应器处理含油废水[J].中国给水排水,2002,18(2):74-76
[30] 王良均,吴孟周.石油化工废水处理设计手册[Z].北京:中国石化出版社,1996.
[31] 张自杰,钱易,章非娟.环境工程手册水污染防治卷[Z].北京:高等教育出版社,1996.
[32] 席炳炬.以废治废与废水净化再用[M].北京:中国环境科学出版社,1992.
[33] 李国鼎.化学工业废水治理 废水卷[Z].北京:中国环境科学出版社,1992.
[34] 徐根良等.含油废水处理技术综述[J].水处理技术,1991,17(1):1
[35] O' Melia C R. Coagulation and Flocculation in Physical Chemical Process of Water Quality Control[M]. New York: Wiley-Interscience, 1972:14-17
[36] 姚金华.混凝剂与絮凝剂[M].北京:中国环境科学出版社,1991.1-53
[37] Kyuichiro kurane. Agr. Biol Chem[J]. 1991,55(4):1127-1129
[38] Mcclune H, Muir J. World, Oil[J]. 1998, 219(7):4-8
[39] 顾夏声,黄铭荣,王占生.水处理工程[M].北京:清华大学出版社,1985.62-81
[40] 曲元辉,雷朋举,栾兆坤.预氧化加复合混凝剂处理高温石油废水[J].环境工程,1997,15(4):3-6
[41] 王彪.原油破乳剂研究新进展[J].油田化学,1994,11(3):256
[42] 关卫省,朱浚黄.PHM-Y混凝剂处理乳化油废水的研究[J].工业水处理,1994,14 (2).20-22
[43] NYER E.K. Groundwater Treatment Technology[M]. Van Nostrand Reinhold Company, 1985.
[44] 刘希波.粉煤灰在废水处理中的应用[J].环境工程,1993,11(6):37-39
[45] 张建平.粉煤灰处理废水机理及应用[J].粉煤灰综合利用,1999,2:32-34
[46] 李亚辉,杨辉,赵红.粉煤灰处理废水的理论与实践[J].工业用水与废水,1999,30(3):1-5
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