新型连续式砂滤器的设计与研究
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摘要
人类的生存离不开水。对污水的处理和再利用,不仅能减小污水对环境所造成的危害,同时也是解决水资源短缺的重要途径。连续式砂滤器是在水处理方面应用广泛的设备之一,在过滤领域有着重要的地位。
本文研究了砂滤器发展的状况和趋势,阐述了连续式砂滤器的工作原理、特点和结构形式,针对目前砂滤器存在的问题,改进了连续式砂滤器的提砂系统和洗砂系统,设计了新型波纹提砂管和螺旋洗砂器。利用CFD软件FLUENT对新型波纹提砂管和螺旋洗砂器的功能进行了数值模拟,并在参数分析的基础上对结构进行了优化。通过对新型波纹提砂管与传统提砂管的对比,发现新型波纹提砂管在保证提砂量的情况下,极大的增强了提砂管内的湍流状况,提高了提砂系统初次洗砂的效果;通过对新型螺旋洗砂器和传统洗砂器的对比,发现新型螺旋洗砂器洗砂路径长,悬浮物等杂质与滤料分离效果好,其在多方面性能上均优于传统洗砂器。此外,本文还对螺旋洗砂器的性能进行了实验测试,验证了数值模拟结果。最后,在充分研究的基础上,完成了NCSF新型连续式砂滤器整体设计,并给出了NCSF连续式外循环砂滤器尺寸系列。
Human can not survive without water. By reusing the treated sewage andeffluent, their harmful effects on the environment can be avoided andmeanwhile the shortage of water resource can be solved in some extent.Continuous sand filter plays an important role in the filtration area and widelyused in water treatment fields.
In this thesis, the present state and future trend of the sand filter wereanalyzed and the working principles, characteristics and structures of thecontinuous sand filters were introduced. To solve some problems existed in thepresent sand filters,traditional sand lifting system and sand washing systemwere improved by adopting new structures namely corrugated sand-liftingpipe and spiral sand washer. CFD software FLUENT was used to simulate thefunctions of the corrugated sand-lifting pipe and the spiral sand washer. Byperforming parametric analysis, their structures were optimized. Comparingthe corrugated sand-lifting pipe with the traditional sand-lifting pipe indicatesthat if the amount of sand-lifting is the same,the turbulence of fluid and thesand washing effect were greatly enhanced in the corrugated sand-lifting pipe.Similarly, comparing the spiral sand washer with the traditional sand washer, it is found that the sand washing path of the spiral sand washer is longer and theseparation of the sludge and sand is better, or in other words, the spiral sandwasher is superior to the traditional sand washer in many respects. In addition,on the basis of the numerical simulation, experiments for the performance ofthe spiral sand washer were also conducted. Finally in this thesis, the entireNCSF continuous sand filter is designed and the size of the series of NCSFcontinuous outer loop sand filters was given.
本文研究了砂滤器发展的状况和趋势,阐述了连续式砂滤器的工作原理、特点和结构形式,针对目前砂滤器存在的问题,改进了连续式砂滤器的提砂系统和洗砂系统,设计了新型波纹提砂管和螺旋洗砂器。利用CFD软件FLUENT对新型波纹提砂管和螺旋洗砂器的功能进行了数值模拟,并在参数分析的基础上对结构进行了优化。通过对新型波纹提砂管与传统提砂管的对比,发现新型波纹提砂管在保证提砂量的情况下,极大的增强了提砂管内的湍流状况,提高了提砂系统初次洗砂的效果;通过对新型螺旋洗砂器和传统洗砂器的对比,发现新型螺旋洗砂器洗砂路径长,悬浮物等杂质与滤料分离效果好,其在多方面性能上均优于传统洗砂器。此外,本文还对螺旋洗砂器的性能进行了实验测试,验证了数值模拟结果。最后,在充分研究的基础上,完成了NCSF新型连续式砂滤器整体设计,并给出了NCSF连续式外循环砂滤器尺寸系列。
Human can not survive without water. By reusing the treated sewage andeffluent, their harmful effects on the environment can be avoided andmeanwhile the shortage of water resource can be solved in some extent.Continuous sand filter plays an important role in the filtration area and widelyused in water treatment fields.
In this thesis, the present state and future trend of the sand filter wereanalyzed and the working principles, characteristics and structures of thecontinuous sand filters were introduced. To solve some problems existed in thepresent sand filters,traditional sand lifting system and sand washing systemwere improved by adopting new structures namely corrugated sand-liftingpipe and spiral sand washer. CFD software FLUENT was used to simulate thefunctions of the corrugated sand-lifting pipe and the spiral sand washer. Byperforming parametric analysis, their structures were optimized. Comparingthe corrugated sand-lifting pipe with the traditional sand-lifting pipe indicatesthat if the amount of sand-lifting is the same,the turbulence of fluid and thesand washing effect were greatly enhanced in the corrugated sand-lifting pipe.Similarly, comparing the spiral sand washer with the traditional sand washer, it is found that the sand washing path of the spiral sand washer is longer and theseparation of the sludge and sand is better, or in other words, the spiral sandwasher is superior to the traditional sand washer in many respects. In addition,on the basis of the numerical simulation, experiments for the performance ofthe spiral sand washer were also conducted. Finally in this thesis, the entireNCSF continuous sand filter is designed and the size of the series of NCSFcontinuous outer loop sand filters was given.
引文
[1]中投顾问.2012-2016年中国污水处理行业投资分析及前景预测报告[OL].http://www.dragonraja.com.cn/200710/120071031295.html
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[3]赵杰.单元式自清洗过滤器控制系统的研究[D].大连:大连理工大学.2006.
[4]王燕燕.自清洗叠片过滤器的设计与研究[D].北京:北京化工大学化工过程机械,2010
[5]王德英.纤维束屡创深层过滤的研究[D].大连:大连理工大学,2005
[6]肖伟民.粗滤料反粒度过滤技术及其在饮用水处理中的应用研究[D].广州:中国科学院广州地球化学研究所,2004
[7]杨振华.加压转鼓过滤机结构设计与计算[D].北京:北京化工大学化工过程机械,2011
[8]王德英.纤维束屡创深层过滤的研究[D].大连:大连理工大学,2005
[9]唐立夫,王维一,张怀清.过滤机[M].北京:机械工业出版社,1984.6-7
[10]孙启才.分离机械[M].北京:化学工业出版社,1997
[11]盘点过滤技术的发展历史[OL].百度:http://www.e9898.com/blog/blog15464.html
[12]陈楠,覃当麟,陈永利,张健,王鑫宇,韦艳玲.逆流连续砂滤器[P].中国专利,CN202015528U.2011-10-26
[13]李蒙、汪志英.过滤工艺技术研究的最新进展[J/OL].武汉:武汉理工大学,2008
[14]刘元文.砂滤设备的新进展——介绍两种新型连续砂滤器[J].工业水处理,1987,7(6):40-42
[15]李敏贤,戴凌汉,孔晓宁,范德顺,钱才富.连续式砂滤器的结构与研究进展Ⅰ—国外研究[A].见:教育部高等学校机械学科过程装备与控制工程教学指导分委员会.第十二届全国高等学校过程装备与控制工程专业教学改革与学科建设成果校际交流会论文集[C].北京:化学工业出版社,2011,374-377
[16]何绪蕾.流砂过滤器应用研究[D].北京:中国石油大学(华东),2008
[17]陈志强,荣宏伟,吕岩松,吕炳南.滤池工作参数对连续式砂滤器处理效果的影响[J].哈尔滨工业大学学报,2001,33(6):777-784
[18]陆柱,蔡兰坤,从梅.给水与用水处理技术[M].北京:化学工业出版社,2004.115-118
[19]刘凡清,范德顺,黄钟.固液分离与工业水处理[M].北京:中国石化出版社,2001.21-60
[20]丁启圣,王维一等.新型实用过滤技术[M].第三版.北京:冶金工业出版社,2011.22-44
[21]寇光智,裴振洪,于海彬.新型砂滤器[P].中国专利,CN201578891U.2009
[22] Trevisan Saverio. Method and device for backwashing sand bed filtration units[P].European,EP1177825A1.2001-07-31
[23] KAIBARA KAZUTOSHI. Filter apparatus with sand filter bed[P].American, US6471857B1.2001-06-25
[24]胡德金,宋春林,胡立文,王晓兴,李敏,艾军,陈百顺,孙朋,满鑫.一种砂滤器无动力抽吸排污装置和方法[P].中国专利,CN101254367A.2007-12-17
[25] Stephen D. Ward Deep Bed Sand Filter[P].American, US5277829.1992-07-14
[26] Hsiu-Chuan Chang, Mao-Sheng Lin. Deep Bed Sand Filter[P].American, US5746913.1997-02-06
[27] Ken M.Stedman, Redondo Beach. Automated water treatment system and method of use[P].American, US7381336B2.2008-06-03
[28] C. J. Hering, Jr.. Dynamic filtration filter apparatus with level control and deflector plate[P].American, US5543037.1996-08-06
[29] Yasuhiro Saitoh. Particulate Matter Washing Apparatus And Method[P],American,US6273106B1.1999-04-26
[30] Yasuhiro Saitoh. Particulate Matter Washing Method[P].American, US6382221B2.2001-04-10
[31] IEA.Highly efficient filtration for paper mills[J/OL].Energy efficiency
[32] SFFL型高效环保节能砂滤器[OL].精准石油论坛,2010
[33]康泽群,孙忠生,张宏文.波纹流道洗砂移动床砂滤器及其水处理工艺,[P].中国专利,CN102210947A.2011-10-12
[34]陈楠,覃当麟,陈永利,张健,王鑫宇,韦艳玲.逆流连续砂滤器[P].中国专利,CN202015528U.2011-10-26
[35]美国麦王环保能源公司,高效过滤器[OL]
[36]阚琛.连续砂滤器的设计与研究[D].北京:北京化工大学化工过程机械,2011
[37]刘杨. T型管内气液两相泡状与环状流的相分离数值模拟[D].大连:大连理工大学,2011
[38]陈振瑜,李志彪,何利民,何衍军.垂直管气液两相弹状流流动特性研究进展[J].管道技术与设备,2005,4:3-6
[39]王福军.计算流体动力学分析—CFD软件原理与应用[M].北京:清华大学出版社,2004.63-226
[40]于勇,张俊明,姜连田. FLUENT入门与进阶教程[M].北京:北京理工大学出版社,2008.108-187
[41]丁祖荣.流体力学[M].北京:高等教育出版社,2003.249-255
[42]张玉杰.连续流砂过滤器性能实验研究[D].北京:中国石油大学(北京),2007
[43]乔伟,乔惠平.内循环连续式砂滤器微凝絮过滤机理研究[J].黑龙江水利科技,2004,4:84-85
[2]新华网.中国去年城市污水处理率提升至77.4%[OL].http://news.xinhuanet.com/society/2011-06/13/c_121530655.htm
[3]赵杰.单元式自清洗过滤器控制系统的研究[D].大连:大连理工大学.2006.
[4]王燕燕.自清洗叠片过滤器的设计与研究[D].北京:北京化工大学化工过程机械,2010
[5]王德英.纤维束屡创深层过滤的研究[D].大连:大连理工大学,2005
[6]肖伟民.粗滤料反粒度过滤技术及其在饮用水处理中的应用研究[D].广州:中国科学院广州地球化学研究所,2004
[7]杨振华.加压转鼓过滤机结构设计与计算[D].北京:北京化工大学化工过程机械,2011
[8]王德英.纤维束屡创深层过滤的研究[D].大连:大连理工大学,2005
[9]唐立夫,王维一,张怀清.过滤机[M].北京:机械工业出版社,1984.6-7
[10]孙启才.分离机械[M].北京:化学工业出版社,1997
[11]盘点过滤技术的发展历史[OL].百度:http://www.e9898.com/blog/blog15464.html
[12]陈楠,覃当麟,陈永利,张健,王鑫宇,韦艳玲.逆流连续砂滤器[P].中国专利,CN202015528U.2011-10-26
[13]李蒙、汪志英.过滤工艺技术研究的最新进展[J/OL].武汉:武汉理工大学,2008
[14]刘元文.砂滤设备的新进展——介绍两种新型连续砂滤器[J].工业水处理,1987,7(6):40-42
[15]李敏贤,戴凌汉,孔晓宁,范德顺,钱才富.连续式砂滤器的结构与研究进展Ⅰ—国外研究[A].见:教育部高等学校机械学科过程装备与控制工程教学指导分委员会.第十二届全国高等学校过程装备与控制工程专业教学改革与学科建设成果校际交流会论文集[C].北京:化学工业出版社,2011,374-377
[16]何绪蕾.流砂过滤器应用研究[D].北京:中国石油大学(华东),2008
[17]陈志强,荣宏伟,吕岩松,吕炳南.滤池工作参数对连续式砂滤器处理效果的影响[J].哈尔滨工业大学学报,2001,33(6):777-784
[18]陆柱,蔡兰坤,从梅.给水与用水处理技术[M].北京:化学工业出版社,2004.115-118
[19]刘凡清,范德顺,黄钟.固液分离与工业水处理[M].北京:中国石化出版社,2001.21-60
[20]丁启圣,王维一等.新型实用过滤技术[M].第三版.北京:冶金工业出版社,2011.22-44
[21]寇光智,裴振洪,于海彬.新型砂滤器[P].中国专利,CN201578891U.2009
[22] Trevisan Saverio. Method and device for backwashing sand bed filtration units[P].European,EP1177825A1.2001-07-31
[23] KAIBARA KAZUTOSHI. Filter apparatus with sand filter bed[P].American, US6471857B1.2001-06-25
[24]胡德金,宋春林,胡立文,王晓兴,李敏,艾军,陈百顺,孙朋,满鑫.一种砂滤器无动力抽吸排污装置和方法[P].中国专利,CN101254367A.2007-12-17
[25] Stephen D. Ward Deep Bed Sand Filter[P].American, US5277829.1992-07-14
[26] Hsiu-Chuan Chang, Mao-Sheng Lin. Deep Bed Sand Filter[P].American, US5746913.1997-02-06
[27] Ken M.Stedman, Redondo Beach. Automated water treatment system and method of use[P].American, US7381336B2.2008-06-03
[28] C. J. Hering, Jr.. Dynamic filtration filter apparatus with level control and deflector plate[P].American, US5543037.1996-08-06
[29] Yasuhiro Saitoh. Particulate Matter Washing Apparatus And Method[P],American,US6273106B1.1999-04-26
[30] Yasuhiro Saitoh. Particulate Matter Washing Method[P].American, US6382221B2.2001-04-10
[31] IEA.Highly efficient filtration for paper mills[J/OL].Energy efficiency
[32] SFFL型高效环保节能砂滤器[OL].精准石油论坛,2010
[33]康泽群,孙忠生,张宏文.波纹流道洗砂移动床砂滤器及其水处理工艺,[P].中国专利,CN102210947A.2011-10-12
[34]陈楠,覃当麟,陈永利,张健,王鑫宇,韦艳玲.逆流连续砂滤器[P].中国专利,CN202015528U.2011-10-26
[35]美国麦王环保能源公司,高效过滤器[OL]
[36]阚琛.连续砂滤器的设计与研究[D].北京:北京化工大学化工过程机械,2011
[37]刘杨. T型管内气液两相泡状与环状流的相分离数值模拟[D].大连:大连理工大学,2011
[38]陈振瑜,李志彪,何利民,何衍军.垂直管气液两相弹状流流动特性研究进展[J].管道技术与设备,2005,4:3-6
[39]王福军.计算流体动力学分析—CFD软件原理与应用[M].北京:清华大学出版社,2004.63-226
[40]于勇,张俊明,姜连田. FLUENT入门与进阶教程[M].北京:北京理工大学出版社,2008.108-187
[41]丁祖荣.流体力学[M].北京:高等教育出版社,2003.249-255
[42]张玉杰.连续流砂过滤器性能实验研究[D].北京:中国石油大学(北京),2007
[43]乔伟,乔惠平.内循环连续式砂滤器微凝絮过滤机理研究[J].黑龙江水利科技,2004,4:84-85