中英文文獻檢索報告《BMED在廢水處理中的應(yīng)用》

1、BMED在廢水處理中的應(yīng)用² 中文文獻一、 文獻檢索范圍及檢索策略(一) 檢索范圍：中國學(xué)術(shù)期刊網(wǎng)全文數(shù)據(jù)庫：中國期刊全文數(shù)據(jù)庫 2010.1.1-2015.6.9中國優(yōu)秀博碩士學(xué)位論文全文數(shù)據(jù)庫 2010.1.1-2015.6.9中國重要會議論文集全文數(shù)據(jù)庫 2010.1.1-2015.6.9(二) 關(guān)鍵詞：電滲析雙極膜雙極膜電滲析離子交換膜丙烯酸(三) 檢索策略：條件： 發(fā)表時間 between (2010-01-01,2015-6-9 and 摘要=雙極膜 and 摘要=電滲析 and 全文=廢水 ) (精確匹配)二、 檢索結(jié)果1. 付麗麗. 雙極膜電滲析生產(chǎn)琥珀酸的研究. 碩

2、士, 中國海洋大學(xué), 2014.2. 任洪艷; 王倩; 吳霞; 楊鵬波; 叢威, 鈣鹽和氨基酸對味精等電母液模擬料雙極膜電滲析過程膜污染的影響. 過程工程學(xué)報 2011, (04), 627-632.3. 余杰. 雙極膜電滲析技術(shù)制備季銨堿過程的研究. 碩士, 浙江工業(yè)大學(xué), 2013.4. 劉洪濤; 袁俊生; 劉杰, 雙極膜法軟化海水制備酸堿的研究. 鹽業(yè)與化工 2012, (06), 15-18.5. 衛(wèi)艷新. 雙極膜電滲析法處理典型化工廢水研究. 博士, 中國科學(xué)技術(shù)大學(xué), 2012.6. 周鵬飛. 地表水脫鹽副產(chǎn)濃鹽水的資源化研究. 碩士, 中國海洋大學(xué), 2013.7. 婁玉峰; 張

3、偉華 In 均相離子荷電膜分離技術(shù)在濕法冶金行業(yè)中的應(yīng)用, 第四屆全國膜分離技術(shù)在冶金工業(yè)中應(yīng)用研討會, 中國四川都江堰, 2014; 中國四川都江堰, 2014; p 4.8. 宋麗莎. 多相體系中稀土和銨離子的遷移及其應(yīng)用. 碩士, 南昌大學(xué), 2014.9. 宋永會; 魏健; 馬印臣; 曾萍; 朱鵬, 中和-絡(luò)合萃取-雙極膜電滲析處理金剛烷胺制藥廢水. 環(huán)境科學(xué)學(xué)報 2015, (01), 200-206.10. 張凱. 雙極膜電滲析生產(chǎn)酒石酸的研究. 博士, 中國海洋大學(xué), 2012.11. 徐靜. 離子交換去除丙烯酸丁酯廢水中多價離子的研究. 碩士, 河北工程大學(xué), 2012.12.

4、 李鑫. 雙極膜電滲析法從丙烯酸丁酯廢水中回收有機酸的研究. 碩士, 河北工程大學(xué), 2011.13. 李鑫; 宋玉棟; 周岳溪; 李福勤; 康瑩瑩; 許吉現(xiàn), 雙極膜電滲析法回收丙烯酸丁酯廢水中的有機酸. 化工環(huán)保 2011, (03), 197-201.14. 楊洋. 利用雙極膜電滲析以濃海水制備酸堿的研究. 碩士, 中國海洋大學(xué), 2014.15. 樊杰. 金剛烷胺制藥廢水Fenton-超聲氧化處理及溴化氫雙極膜電滲析回收. 碩士, 北京林業(yè)大學(xué), 2013.16. 汪耀明. 雙極膜電滲析法生產(chǎn)有機酸過程的幾個關(guān)鍵科學(xué)問題研究. 博士, 中國科學(xué)技術(shù)大學(xué), 2011.17. 汪耀明; 吳

5、亮; 徐銅文, 新型通用離子交換膜的研究與實踐. 中國工程科學(xué) 2014, (12), 76-86.18. 汪耀明; 吳亮; 李傳潤 In 黃金冶煉廢水雙極膜法處理示范工程建設(shè), 第四屆全國膜分離技術(shù)在冶金工業(yè)中應(yīng)用研討會, 中國四川都江堰, 2014; 中國四川都江堰, 2014; p 3.19. 王曉林. 電滲析技術(shù)在有機酸生產(chǎn)和剩余污泥氮磷資源化中的應(yīng)用研究. 博士, 中國科學(xué)技術(shù)大學(xué), 2014.20. 王欣欣. 雙極膜電滲析法資源化草甘膦生產(chǎn)廢水的研究. 碩士, 中國海洋大學(xué), 2013.21. 祁曉靜. 鄰甲苯胺重氮化法制備鄰甲酚的工藝優(yōu)化研究. 碩士, 中北大學(xué), 2010.22

6、. 胡田. 丙烯酸丁酯廢水電滲析雙極膜電滲析回收酸堿工藝中試研究. 碩士, 蘭州交通大學(xué), 2014.23. 董恒; 王建友; 盧會霞, 雙極膜電滲析技術(shù)的研究進展. 化工進展 2010, (02), 217-222.24. 謝鴻芳; 肖艷春; 鄭林祿; 鄭淑英; 陳震, 雙極膜技術(shù)在環(huán)境工程中的應(yīng)用與展望. 廣州化學(xué) 2012, (01), 56-62.25. 鄭淑英, 雙極膜電滲析的理論研究進展與應(yīng)用. 化學(xué)工程與裝備 2011, (10), 161-164+175.26. 金可勇; 胡鑒耿; 金水玉; 高從堦, 中水回用RO濃水的零排放工藝比較及優(yōu)化研究. 水處理技術(shù) 2015, (01

7、), 103-106.27. 陳葉. 丙烯酸丁酯廢水濁度去除組合工藝研究. 碩士, 河北工程大學(xué), 2014.28. 陳慶; 張偉明, 基于膜分離的電極箔行業(yè)減排降耗過程研究. 水處理技術(shù) 2014, (03), 44-48.29. 陳靜. 丙烯酸在離子交換膜中的傳質(zhì)特性及其對雙極膜電滲析的影響研究. 碩士, 蘭州交通大學(xué), 2013.30. 馬洪運; 吳旭冉; 王保國, 雙極膜分離技術(shù)及應(yīng)用進展. 化工進展 2013, (10), 2274-2278+2301.² 英文文獻一、 文獻檢索范圍及檢索策略檢索范圍：Web of Science Core Collection檢索策略：主

8、題: (bipolar membrane electrodialysis) 精煉依據(jù): 出版年: ( 2014 OR 2012 OR 2013 OR 2011 OR 2010 OR 2015 ) AND Web of Science 類別: ( ENVIRONMENTAL SCIENCES OR ENGINEERING ENVIRONMENTAL )二、 檢索結(jié)果1. Eisaman, M. D.; Alvarado, L.; Larner, D.; Wang, P.; Garg, B.; Littau, K. A., CO2 separation using bipolar membrane

9、 electrodialysis. Energy & Environmental Science 2011, 4, (4), 1319-1328.2. Ghyselbrecht, K.; Silva, A.; Van der Bruggen, B.; Boussu, K.; Meesschaert, B.; Pinoy, L., Desalination feasibility study of an industrial NaCl stream by bipolar membrane electrodialysis. Journal of Environmental Manageme

10、nt 2014, 140, 69-75.3. Shen, J. N.; Huang, J.; Liu, L. F.; Ye, W. Y.; Lin, J. Y.; Van der Bruggen, B., The use of BMED for glyphosate recovery from glyphosate neutralization liquor in view of zero discharge. Journal of Hazardous Materials 2013, 260, 660-667.4. Shen, J. N.; Yu, J.; Huang, J.; Van der

11、 Bruggen, B., Preparation of highly pure tetrapropyl ammonium hydroxide using continuous bipolar membrane electrodialysis. Chemical Engineering Journal 2013, 220, 311-319.5. Venugopal, K.; Dharmalingam, S., Utilization of Bipolar Membrane Electrodialysis for Salt Water Treatment. Water Environment R

12、esearch 2013, 85, (7), 663-670.三、 文獻分析（摘要翻譯）1. Eisaman, M. D.; Alvarado, L.; Larner, D.; Wang, P.; Garg, B.; Littau, K. A., CO2 separation using bipolar membrane electrodialysis. Energy & Environmental Science 2011, 4, (4), 1319-1328.Abstract:Caustic solvents such as sodium or potassium hydroxid

13、es, converted via CO2 capture to aqueous carbonates or bicarbonates, are a likely candidate for atmospheric CO2 separation. We have performed a comprehensive experimental investigation of CO2 gas regeneration from aqueous potassium carbonate and bicarbonate solutions using bipolar membrane electrodi

14、alysis (BPMED). This system allows the regeneration of pure CO2 gas, suitable for subsequent sequestration or reaction to synthetic hydrocarbons and their products, from aqueous carbonate/bicarbonate solutions. Our results indicate that the energy consumption required to regenerate CO2 gas from aque

15、ous bicarbonate (carbonate) solutions using this method can be as low as 100 kJ (200 kJ) per mol of CO2 in the small-current-density limit.摘要：像氫氧化鉀和氫氧化鈉這樣的腐蝕性的化學(xué)溶劑，能夠吸收二氧化碳，轉(zhuǎn)變成為水溶液中的碳酸根離子和碳酸氫根離子，這是一種很好的分離大氣中二氧化碳的辦法。我們做了一個利用碳酸鉀溶液和碳酸氫鉀溶液的雙極膜電滲析法重建二氧化碳氣體的綜合性的實驗研究。2. Ghyselbrecht, K.; Silva, A.; Van der

16、 Bruggen, B.; Boussu, K.; Meesschaert, B.; Pinoy, L., Desalination feasibility study of an industrial NaCl stream by bipolar membrane electrodialysis. Journal of Environmental Management 2014, 140, 69-75. Abstract: The industrial implementation of alternative technologies in the processing of saline

17、 effluent streams is a topic of growing importance. In this technical feasibility study, the desalination of an industrial saline stream containing about 75 g L-1 NaCl contaminated with some organic matter using bipolar membrane electrodialysis (EDBM) was investigated on lab-scale. Bipolar membranes

18、 of two different manufacturers (PCA - PolymerChemie Altmeier GmbH and FuMA-Tech GmbH) were tested and compared in terms of electrical resistance, current efficiency and purity of the produced acid and base stream. In both cases, almost complete desalination (>99%) was achieved and simultaneously

19、 HCl and NaOH were produced with a concentration between 1.5 and 2 M with a relatively good purity. The Fumasep bipolar membranes scored slightly better for electrical resistance and current efficiency. On the other hand, slightly higher current densities were achieved with PCA bipolar membranes. Si

20、multaneously, some information was obtained on the transport behavior of the organic matter present in the saline stream. It was observed that a transport competition occurred between the organic matter and the accompanying chlorides. From this lab-scale study it was concluded that EDBM is a promisi

21、ng and attractive technology in the area of saline effluent reclamation and reuse. (C) 2014 Elsevier Ltd. All rights reserved.摘要：3. Shen, J. N.; Huang, J.; Liu, L. F.; Ye, W. Y.; Lin, J. Y.; Van der Bruggen, B., The use of BMED for glyphosate recovery from glyphosate neutralization liquor in view of

22、 zero discharge. Journal of Hazardous Materials 2013, 260, 660-667.Abstract: Conventional methods of tetrapropyl ammonium hydroxide (TPAOH) production via electrolysis, reaction of tetrapropyl ammonium halide with silver oxide, and ion-exchange suffer from high production costs, low quality, and env

23、ironmental pollution. In this work, continuous bipolar membrane electrodialysis (BMED) is employed for the preparation of TPAOH from its halide as a sustainable alternative process. Novel ion-exchange membranes were developed for lab and pilot scale experiments, which indicate an acceptable current

24、efficiency and energy consumption. The results indicate that a cell configuration with four compartments yielded the best results when the salt concentration was 0.3 mol L-1 and the current density was 200 A m(-2). The highest conversion in electrodialysis was 91.6%, with a high purity of trace alka

25、li metal ions and low Br- content (176 ppm) at a TPAOH concentration of 25%. The energy consumption is 1.897 kW h kg(-1). Continuous pilot experiments demonstrate the feasibility of manufacturing TPAOH by direct splitting its halide for industrial application. Crown Copyright (C) 2013 Published by E

26、lsevier B.V. All rights reserved.摘要：4. Shen, J. N.; Yu, J.; Huang, J.; Van der Bruggen, B., Preparation of highly pure tetrapropyl ammonium hydroxide using continuous bipolar membrane electrodialysis. Chemical Engineering Journal 2013, 220, 311-319. Abstract: Alkaline glyphosate neutralization liquo

27、rs containing a high salinity pose a severe environmental pollution problem by the pesticide industry. However, there is a high potential for glyphosate recovery due to the high concentration of glyphosate in the neutralization liquors. In the study, a three-compartment bipolar membrane electrodialy

28、sis (BMED) process was applied on pilot scale for the recovery of glyphosate and the production of base/acid with high concentration in view of zero discharge of wastewater. The experimental results demonstrate that BMED can remove 99.0% of NaCl from the feed solution and transform this fraction int

29、o HCl and NaOH with high concentration and purity. This is recycled for the hydrolysis reaction of the intermediate product generated by the means of the Mannich reaction of paraformaldehyde, glycine and dimethylphosphite catalyzed by triethylamine in the presence of HCl and reclamation of the triet

30、hylamine catalyst during the production process of glyphosate. The recovery of glyphosate in the feed solution was over 96%, which is acceptable for industrial production. The current efficiency for producing NaOH with a concentration of 2.0 mol L-1 is above 67% and the corresponding energy consumpt

31、ion is 2.97 kWh kg(-1) at a current density of 60 mA cm(-2). The current efficiency increases and energy consumption decreases as the current density decreases, to 87.13% and 2.37 kWh kg(-1), respectively, at a current density of 30 mA cm(-2). Thus, BMED has a high potential for desalination of glyp

32、hosate neutralization liquor and glyphosate recovery, aiming at zero discharge and resource recycling in industrial application. (C) 2013 Elsevier B.V. All rights reserved.摘要：5. Venugopal, K.; Dharmalingam, S., Utilization of Bipolar Membrane Electrodialysis for Salt Water Treatment. Water Environment Research 2013, 85, (7), 663-670.Abstract: Bipolar ion-exchange membranes, using polystyren