郭 骥^1,2， 姬忠礼^1,2*

1. 中国石油大学(北京)机械与储运工程学院，北京1022492. 中国石油大学(北京)过程流体过滤与分离技术北京市重点实验室，北京102249

收稿日期:2019-01-29修回日期:2019-04-03出版日期:2019-12-22发布日期:2019-12-22
通讯作者:姬忠礼

基金资助:天然气净化用气液聚结滤芯过滤分离机理研究

Influence of phenol concentration on coalescence performance of an oleophilic?hydrophobic filter material

Ji GUO^1,2, Zhongli JI^1,2*

1. Department of Mechanical and Transportation Engineering, China University of Petroleum, Beijing 102249, China2. Beijing Key Laboratory of Process Fluid Filtration and Separation, China University of Petroleum, Beijing 102249, China

Received:2019-01-29Revised:2019-04-03Online:2019-12-22Published:2019-12-22
Contact:JI Zhong-li

Supported by:Study on filtration and separation mechanism of gas-liquid coalescing filter element for natural gas purification

摘要/Abstract

摘要： 为探究油品中非烃化合物对滤材聚结性能的影响，在固定含水量1000?10?6(wt)的油水乳状液中添加不同浓度的苯酚，研究亲油疏水滤材的除水效率及过程压降。结果表明，实验过程中滤材的压降有3个阶段：油品对滤材的润湿及水膜初步形成、滤材中水膜形成并稳定、水珠脱落与聚结的动态平衡。随苯酚浓度增加，滤材从疏水态经过渡态逐渐转变为亲水态，苯酚与水摩尔比约为1:3.3时，疏水态向过渡态转变，苯酚与水摩尔比约为1:1.6时，过渡态向亲水态转变，C6H6O(H2O)2是苯酚?水团簇最稳定的结合方式。

引用本文

郭骥 姬忠礼. 苯酚浓度对亲油疏水型滤材聚结性能的影响[J]. 过程工程学报, 2019, 19(6): 1143-1152.
Ji GUO Zhongli JI. Influence of phenol concentration on coalescence performance of an oleophilic?hydrophobic filter material[J]. Chin. J. Process Eng., 2019, 19(6): 1143-1152.

使用本文

0
/ / 推荐
导出引用管理器 EndNote|Ris|BibTeX
链接本文:http://www.jproeng.com/CN/10.12034/j.issn.1009-606X.219127
http://www.jproeng.com/CN/Y2019/V19/I6/1143

参考文献

[1]钟宇峰.焦化汽油加氢装置长周期运行探讨[J].广东化工, 2012, 39(5):177-180 [2]陈宇联.油水聚结分离技术的理论与实验研究 [D]. 北京：北京化工大学., 2006, :4-6 [3]张哲.聚结法脱除油品中的乳化水 [D]. 天津：天津大学., 2013, :6-7 [4]赵悦，李飞，宫红等.焦化汽柴油中苯酚、苯硫酚类化合物对比分析及其来源探讨[J].石油炼制与化工, 2017, 48(5):15-20 [5]陈飞洋，李飞，姜恒等.延迟焦化分馏塔顶油水分离器中酸碱性有机物分布[J].化工科技, 2017, 25(5):8-13 [6]Hajra M G, Mehta K, Chase G G.Effects of Humidity,Temperature,and Nanofibers on Drop Coalescence in Glass Fiber Media[J].Separation and Purification Technology, 2003, 30(1):79-88 [7]刘丽艳，侯立飞，谭蔚等.油水乳状液中水滴在疏水纤维丝上的聚结实验研究[J].天津大学学报(自然科学与工程技术版), 2018, 15(3):271-277 [8]Agarwal S, Arnim V V, Stegmaier T, et al.Effect of Fibrous Coalescer Geometry and Operating Conditions on Emulsion Separation [J].Industrial & Engineering Chemistry Research., 2013, 52(36):13164-13170 [9]Shin C, Chase G G.The effect of wettability on drop attachment to glass rods[J].Journal of Colloid & Interface Science, 2004, 272(1):186-190 [10]Patel S U, Kulkarni P S, Chase G G.The effect of surface energy of woven drainage channels in coalescing filters[J].Separation and Purification Technology, 2012, 87(87):54-61 [11]Podgórska W.Influence of Dispersed Phase Viscosity on Drop Coalescence in Turbulent Flow[J].Chemical Engineering Research & Design, 2007, 85(5):721-729 [12]Piroird K, Clanet C, Lorenceau é, et al.Drops impacting inclined fibers[J].Journal of colloid and Interface Science, 2009, 334(1):70-74 [13]Shin C, Chase G G.Water-in-Oil Coalescence in Micro- Nanofiber Composite Filters[J].AIChE Journal, 2010, 50(2):343-350 [14]Shin C, Chase G G, Reneker D.The Effect of Nanofibers on Liquid–Liquid Coalescence Filter Performance[J].Aiche Journal, 2010, 51(12):3109-3113 [15]Rebelein F, Blass E.Separation of micro-dispersions in fibre-beds[J].Filtration & Separation, 1990, 27(5):360-363 [16]Viswanadam G, Chase G G.Water–diesel secondary dispersion separation using superhydrophobic tubes of nanofibers[J].Separation and Purification Technology, 2013, 104(104):81-88 [17]Krasinski A.Filter media: Multilayer PP filters for the separation of O/W emulsions[J].Filtration Separation, 2014, 51(6):22-28 [18]SareenSS, RosePM, GudesenRC, et al.Coalescence in fibrous beds[J][J].AIChEJ, 1966, 12(6):1045-1050 [19]HazlettRN.Fibrous bed coalescence of water[J][J].Ind Engng Chem Fundam, 1969, 8(4):625-632 [20] Jr MCS, Bonner JS, Ernest ANS, Page CA, AutenriethRL.Chemical dispersant effectiveness testing influenceof droplet coalescence[J].Marine Pollution Bulletin, 2004, 48(9-10):969-977 [21] Shenwen Fang, Ting Chen, Bin Chen, et al.Graphene oxide at oil-water interfaces: Adsorption, assembly & demulsification[J].Colloids and Surfaces, 2016, 511(6):47-54 [22]文利雄，赵旻，程靖等.乳状液膜系统稳定性的显微研究及离子分离效率分析[J].过程工程学报, 2006, 6(3):369-373 [23] Aderangi N, WasanD.T.Coalescent of single drops at a liquid-liquid interface in the presence of surfactants/polymers[J].Chemical Engineering Communiciations, 1995, 32(1):207-222 [24]夏立新，曹国英，陆世维.无机盐对乳状液破乳效果的影响[J].石油学报, 2003, 19(4):94-97 [25] Shin C.Filtration application from recycled expanded polystyrene[J].Journal of Colloid and Interface Science, 2006, 302(1):267-271 [26] BROWN R C.Air Filtration: an Integrated Approach to the Theory and Applications of Fibrous Filters[M].New York: Pergamon Press, 1993, :- [27] Congfei Yao, Yucui Hou, Shuhang Ren, et al.Sulfonate based zwitterions: A new class of extractants for separating phenols from oils with high efficiency via forming deep eutectic solvents [J].Fuel Processing Technology, 2018, 178(9):206-212 [28] Tiantian Jiao, Xulei Zhuang, Hongyan He, et al.Separation of Phenolic Compounds from Coal Tar via Liquid-Liquid Extraction Using Amide Compounds[J].Industrial & Engineering Chemistry Research, 2015, 54(9):2573-2579 [29] Jiajun Gao, Yafen Dai, Wenyan Ma, et al.Efficient separation of phenol from oil by acid–base complexing adsorption[J].Chemical Engineering Journal, 2015, 281(6):749-758 [30]杨建虎，林本才，孙霞等.基于氢键作用的超分子聚合物的研究进展[J].化学世界, 2009, 15(8):498-502 [31]LJ.Prins,David Reinhoudt,P.Timmerman. Noncovalent synthesis using hydrogen bonding [J].Angewandte Chemie International Edition, 2001, 40(13):2382-2426 [32]李晓明，张来斌，郑萌萌等.苯酚-水团簇=-结构与电子性质的密度泛函理论研究[J].原子与分子物理学报, 2019, 36(2):184-192

相关文章 2

[1]	隋元伟 贾广如 许高洁 董强 宁朋歌 曹宏斌. 水力旋流器研究现状及其在煤化工废水处理中的应用前景[J]. 过程工程学报, 2019, 19(2): 235-245.
[2]	胡坤 艾志久 付必伟 李杰 李振北. T型管油水分离特性数值模拟 [J]. , 2017, 17(1): 29-34.

PDF全文下载地址:

http://www.jproeng.com/CN/article/downloadArticleFile.do?attachType=PDF&id=3363