油气排放及回收的研究进展
|
摘要
在分析油气排放及回收领域面临的新形势和新挑战后,提出了油气排放及回收领域研发的新理念及应对策略。分别从油品蒸发及油气扩散的基础物性参数、油罐蒸发排放内在的油气传质规律、基于模块设计与积木式组合的油气回收成套技术等方面,总结了油气排放及回收领域的研究进展;尤其创新性地构建出油气传质因子和油气-空气间集中归一化的拟对流扩散系数的测算方法,揭示了油气排放及回收的内在规律,指出今后的研究方向和研究重点。建议多方面协同合作来研究油气污染全过程的控制,分离净化及资源化利用的基础理论、关键技术、成套装备,从而及时地满足社会科技和经济发展的重大需求。
Based on the analysis of new situation and challenges for oil vapor emission and recovery, the new research concept and strategies were proposed. The research progress in the area of oil vapor emission and recovery was summarized in different areas including fundamental physical parameters of oil vaporization and vapor diffusion, vapor-air mass transfer, and the concept of the modular design and combination for the vapor recovery technology. Vapor mass transfer factor was applied in this study. Especially, according to the centralized unification concept, the evaluation method for the quasi turbulent diffusion coefficient of vapor-air was established. Therefore, based on the above studies, the fundamentals of vapor emission and recovery were thoroughly understood, and the future research strategies were proposed. For oil vapor emission and recovery, it was suggested to perform an integrated research from fundamentals, technologies to equipment in the areas of vapor pollution, separation and purification, and resources utilization to meet the current various challenges.
Based on the analysis of new situation and challenges for oil vapor emission and recovery, the new research concept and strategies were proposed. The research progress in the area of oil vapor emission and recovery was summarized in different areas including fundamental physical parameters of oil vaporization and vapor diffusion, vapor-air mass transfer, and the concept of the modular design and combination for the vapor recovery technology. Vapor mass transfer factor was applied in this study. Especially, according to the centralized unification concept, the evaluation method for the quasi turbulent diffusion coefficient of vapor-air was established. Therefore, based on the above studies, the fundamentals of vapor emission and recovery were thoroughly understood, and the future research strategies were proposed. For oil vapor emission and recovery, it was suggested to perform an integrated research from fundamentals, technologies to equipment in the areas of vapor pollution, separation and purification, and resources utilization to meet the current various challenges.
引文
[1]黄维秋.油气回收基础理论及其应用[M].北京:中国石化出版社,2011.
[2]MU?OZ R,SOUZA T S O,GLITTMANN L,et al.Biological anoxic treatment of O2-free VOC emissions from the petrochemical industry:A proof of concept study[J].Journal of Hazardous Materials,2013,260(6):442-450.
[3]方文政.大气氧化及光氧化挥发性有机物生成二次有机气溶胶的研究[D].合肥:中国科学技术大学,2012.
[4]YUAN B,SHAO M,LU S H,et al.Source profiles of volatile organic compounds associated with solvent use in Beijing,China[J].Atmospheric Environment,2010,44(15):1919-1926.
[5]CAIC J,GENGF H,TIEX X,et al.Characteristics and source apportionment of VOCs measured in Shanghai,China[J].Atmos Environ,2010,44(38):5005-5014.
[6]LEUCHNER M,RAPPENGLCK B.VOC sourcereceptor relationships in Houston during TexAQS-II[J].Atmospheric Environment,2010,44(33):4056-4067.
[7]中华人民共和国环境保护部.“十三五”挥发性有机物污染防治工作方案[EB/OL].(2017-09-13).http://www.zhb.gov.cn/gkml/hbb/bwj/201709/t20170919_421835.htm.
[8]中华人民共和国环境保护部.大气环境保护标准(汇总)[EB/OL].(2017-01-26).http://kjs.mep.gov.cn/hjbhbz/bzwb/dqhjbh/.
[9]张加成,刘艺,胡乃科,等.轻质油品罐区油气密闭收集系统的设计及安保措施[J].油气储运,2016,35(2):167-172.(ZHANG Jiacheng,LIU Yi,HUNaike,et al.Design and safety measures of oil/gas sealed collection system in the light oil tank farm[J].Oil&Gas Storage and Transportation,2016,35(2):167-172.)
[10]焦国凤,周祥,孟繁磊,等.分子水平预测汽油馏分的蒸气压[J].石油学报(石油加工),2017,33(4):662-666.(JIAO Guofeng,ZHOU Xiang,MENG Fanlei,et al.Prediction of the vapor pressure of gasoline at a molecular level[J].Acta Petrolei Sinica(Petroleum Processing Section),2017,33(4):662-666.)
[11]黄维秋,钟秦.非稳态油品蒸发的数值分析Ⅱ数值分析及应用实例[J].石油学报(石油加工),2004,20(1):52-57.(HUANG Weiqiu,ZHONG Qin.Numerical analysis of petroleum products evaporation under unsteady conditionsⅡNumerical analysis and application examples[J].Acta Petrolei Sinica(Petroleum Processing Section),2004,20(1):52-57.)
[12]黄维秋.油品蒸发损耗及其控制技术的评价体系[J].石油学报(石油加工),2005,21(4):79-85.(HUANGWeiqiu.Appraisement system of petroleum evaporation loss and its control measurements[J].Acta Petrolei Sinica(Petroleum Processing Section),2005,21(4):79-85.)
[13]王英霞,黄维秋,郑京禾,等.油品参数测定在油气排放评估中的应用[J].环境工程,2014,32(8):143-146.(WANG Yingxia,HUANG Weiqiu,ZHENGJinghe,et al.Determination of physical parameters of petroleum products and their applications in the evaluation of vapor emissions[J].Environmental Engineering,2014,32(8):143-146.)
[14]李丽,黄维秋,纪妍妍,等.气体扩散系数测试装置研制及应用[J].实验技术与管理,2016,33(2):77-86.(LI Li,HUANG Weiqiu,JI Yanyan,et al.Development and application of gas diffusion coefficient test device[J].Experimental Technology and Management,2016,33(2):77-86.)
[15]李丽,黄维秋,吕爱华,等.有机蒸气-空气分子扩散系数测定的影响因素分析[J].环境工程学报,2017,11(3):1633-1638.(LI Li,HUANG Weiqiu,LAihua,et al.Effect factors analysis of determination of molecular diffusion coefficient of organic vapor-air[J].Chinese Journal of Environmental Engineering,2017,11(3):1633-1638.)
[16]李丽,黄维秋,周宁,等.有机蒸气-空气分子扩散系数实测数据及分析[J].环境工程学报,2017,11(5):2903-2908.(LI Li,HUANG Weiqiu,ZHOU Ning,et al.Measured values and analysis of molecular diffusion coefficient of organic vapor-air[J].Chinese Journal of Environmental Engineering,2017,11(5):2903-2908.)
[17]鲁玉莹,李永祥,龙军,等.C4烷基化反应机理的分子模拟[J].石油学报(石油加工),2016,32(1):14-21.(LU Yuying,LI Yongxiang,LONG Jun,et al.Molecular simulation of mechanism for C4alkylation[J].Acta Petrolei Sinica(Petroleum Processing Section),2016,32(1):14-21.)
[18]RAMDIN M,BALAJI S P,VICENT-LUNA J M,et al.Computing bubble-points of CO2/CH4 gas mixtures in ionic liquids from Monte Carlo simulations[J].Fluid Phase Equilibria,2016,418(9):100-107.
[19]CHEN L P,HUI Q,WANG C L,et al.Molecular simulation on the transport properties of poly[1-trimethylsilyl-1-propyne]for organic-vapor/permanentgas separation[J].Fluid Phase Equilibria,2011,310(8):142-149.
[20]HABIB A,SCHALAU B,SCHMIDT D.Comparing tools of varying complexity for calculating the gas dispersion[J].Process Safety and Environmental Protection,2014,92(2):305-310.
[21]黄维秋,李峰,王丹莉,等.API小呼吸油品蒸发损耗新旧计算式介绍及其应用[J].油气储运,2011,30(12):859-863.(HUANG Weiqiu,LI Feng,WANGDanli,et al.Comparison and application of API old and new formulas for small breathing evaporation loss of oil tank[J].Oil&Gas Storage and Transportation,2011,30(12):859-863.)
[22]USA Environmental Protection Agency(EPA).Final report:Section 7.1 organic liquid storage tanks,emission factor documentation for AP-42[R].Washington D C:USA EPA,2006:38-116.
[23]SHARMAY K,MAJHI A,KUKRETI V S,et al.Stock loss studies on breathing loss of gasoline[J].Fuel,2010,89(7):1695-1699.
[24]LU C Y,HUANG H Y,CHANG S T,et al.Emission characteristics of VOCs from three fixed-roof p-xylene liquid storage tanks[J].Environmental Monitoring and Assessment,2013,185(8):6819-6830.
[25]WU C F,WU T G,HASHMONAYR A,et al.Measurement of fugitive volatile organic compound emissions from a petrochemical tank farm using openpath Fourier transform infrared spectrometry[J].Atmospheric Environment,2014,82(5):335-342.
[26]魏巍.中国人为源挥发性有机化合物的排放现状及未来趋势[D].北京:清华大学,2009.
[27]张国宁,郝郑平,江梅,等.国外固定源VOCs排放控制法规与标准研究[J].环境科学,2011,32(12):3501-3508.(ZHANG Guoning,HAO Zhengping,JIANG Mei,et al.Study on foreign regulations and standards of stationary sources VOCs emission control[J].Environmental Science,2011,32(12):3501-3508.)
[28]黄维秋,钟秦.非稳态油品蒸发的数值分析Ⅰ数学模型的建立[J].石油学报(石油加工),2003,19(6):58-63.(HUANG Weiqiu,ZHONG Qin.Numerical analysis of petroleum products evaporation under unsteady conditions I Establishment of mathematical model[J].Acta Petrolei Sinica(Petroleum Processing Section),2003,19(6):58-63.)
[29]HUANG W Q,BAI J,ZHAO S H,et al.Investigation of oil vapor emission and its evaluation methods[J].Journal of Loss Prevention in the Process Industries,2011,24(2):178-186.
[30]何仁,韦海燕,梁琳林,等.汽油车油箱加油蒸发排放的数值分析[J].江苏大学学报(自然科学版),2011,32(3):277-280.(HE Ren,WEI Haiyan,LIANGLinlin,et al.Numerical analysis of refueling emission of gasoline vehicle tank[J].Journal of Jiangsu University(Natural Science Edition),2011,32(3):277-280.)
[31]HUANG W Q,LI F,ZHAO S H,et al.Analysis of vapor evaporation loss in filling gasoline into tank[J].Advanced Materials Research,2011,347-353:372-375.
[32]HUANG W Q,WANG D L,ZHAO S H,et al.Investigation to VOCs emission factors in filling gasoline into tank[J].Advanced Materials Research,2011,1:802-805.
[33]黄维秋,李峰,刘海.油品蒸发损耗及油气回收评价软件[PELVRES]3.0:软著登字第0356614号[CP].2011-12-09.
[34]黄维秋,郭淑婷,秦秀豫,等.油品蒸发损耗评价软件[PELVRES]4.0:软著登字第2091904号[CP].2017-09-12.
[35]TAMADDONI M,SOTUDEH-GHAREBAGH R,NARIO S,et al.Experimental study of the VOC emitted from crude oil tankers[J].Process Safety&Environmental Protection,2014,92(6):929-937.
[36]OKAMOTO K,WATANABE N,HAGIMOTO Y,et al.Changes in evaporation rate and vapor pressure of gasoline with progress of evaporation[J].Fire Safety Journal,2009,44(5):756-763.
[37]OKAMOTO K,WATANABE N,HAGIMOTO Y,et al.Evaporation characteristics of multi-component liquid[J].Journal of Loss Prevention in the Process Industries,2010,23(1):89-97.
[38]OKAMOTO K,HIRAMATSU M,MIYAMOTO H,et al.Evaporation and diffusion behavior of fuel mixtures of gasoline and kerosene[J].Fire Safety Journal,2012,49(1):47-61.
[39]ZHU L,CHEN J Q,LIU Y,et al.Experimental analysis of the evaporation process for gasoline[J].Journal of Loss Prevention in the Process Industries,2012,25(6):916-922.
[40]朱玲,陈家庆,柳岩,等.汽油挥发过程的试验分析[J].车用发动机,2011,193(2):68-72.(ZHU Ling,CHEN Jiaqing,LIU Yan,et al.Experimental analysis of gasoline evaporation process[J].Vehicle Engine,2011,193(2):68-72.)
[41]MONCALVO D,DAVIES M,WEBER R,et al.Breathing losses from low-pressure storage tanks due to atmospheric weather change[J].Journal of Loss Prevention in the Process Industries,2016,43:702-705.
[42]SRIKANTHS A,NARASIMHAN S.Modeling and simulation of unloading operations in petroleum product storage terminals[J].Computers&Chemical Engineering,2012,46(35):59-68.
[43]STAMOUDIS N,CHRYSSAKIS C,KAIKTSIS L.Atwo-component heavy fuel oil evaporation model for CFDstudies in marine Diesel engines[J].Fuel,2014,115(1):145-153.
[44]HASSANVAND A,HASHEMABADI S H,BAYAT M.Evaluation of gasoline evaporation during the tank splash loading by CFD techniques[J].International Communications in Heat and Mass Transfer,2010,37(7):907-913.
[45]YAMADA H.Contribution of evaporative emissions from gasoline vehicles toward total VOC emissions in Japan[J].Science of the Total Environment,2013,449(2):143-149.
[46]KOYNOV A,KHINAST J G.Micromixing in reactive,deformable bubble and droplet swarms[J].Chemical Engineering&Technology,2006,29(1):13-23.
[47]DAVIDSON M R,RUDMAN M.Volume of fluid calculations of heat or mass transfer across deforming interfaces in two-fluid flow[J].Numerical Heat Transfer Part B Fundamentals,2002,41(3/4):291-308.
[48]WAHEED M A,HENSCHKE M,ANDREAS P.Mass transfer by free and forced convection from single spherical liquid drops[J].International Journal of Heat and Mass Transfer,2002,22(45):4507-4514.
[49]HAELSSIG J B,ANDRE Y T,THIBAULT J,et al.Direct numerical simulation of interphase heat and mass transfer in multicomponent vapor-liquid flows[J].International Journal of Heat and Mass Transfer,2010,53(19/20):3947-3960.
[50]HASSANVAND A,HASHEMABADI S H.Direct numerical simulation of interphase mass transfer in gasliquid multiphase systems[J].International Communications in Heat and Mass Transfer,2011,38(7):943-950.
[51]BANERJEE R.A numerical study of combined heat and mass transfer in an inclined channel using the VOFmultiphase model[J].Numerical Heat Transfer Part A:Applications,2007,52(2):163-183.
[52]BANERJEE R.Turbulent conjugate heat and mass transfer from the surface of a binary mixture of ethanol/iso-octane in a countercurrent stratified two-phase flow system[J].International Journal of Heat and Mass Transfer,2008,51(25):5958-5974.
[53]赵晨露,黄维秋,石莉,等.内浮顶罐中油气扩散运移的数值模拟[J].安全与环境学报,2015,15(3):72-77.(ZHAO Chenlu,HUANG Weiqiu,SHI Li,et al.Numerical simulation model of the oil-vapor diffusion and its migration from the internal floating-roof tank[J].Journal of Safety and Environment,2015,15(3):72-77.)
[54]SAID N M,MHIRI H,BOURNOT H,et al.Experimental and numerical modelling of the threedimensional incompressible flow behaviour in the near wake of circular cylinders[J].Journal of Wind Engineering and Industrial Aerodynamics,2008,96(5):471-502.
[55]MUDDADA S,PATNAIK B S V.An assessment of turbulence models for the prediction of flow past a circular cylinder with momentum injection[J].Journal of Wind Engineering and Industrial Aerodynamics,2010,98(10/11):575-591.
[56]ABDELDAYEM A M,BAYOMI N N.Experimental and numerical flow visualization of a single square cylinder[J].International Journal for Computational Methods in Engineering Science and Mechanics,2006,7(2):113-127.
[57]KONDO N,MATSUKUMA D.Numerical simulation for flow around two circular cylinders in tandem[J].International Journal of Computational Fluid Dynamics,2005,19(4):277-288.
[58]PASLEY H,CLARK C.Computation fluid dynamics study of flow around floating-roof oil storage tanks[J].Journal of Wind Engineering and Industrial Aerodynamics,2000,86(1):37-54.
[59]孙国明,关仲波.基于CFD技术的油罐群风场数值模拟研究[J].化工机械,2009,36(5):467-470.(SUNGuoming,GUAN Zhongbo.Numerical simulation study of the wind field around the oil can group based on computational fluid dynamics(CFD)technology[J].Chemical Engineering&Machinery,2009,36(5):467-470.)
[60]KOUNTOURIOTIS A,ALEIFERISP G,CHARALAMBIDESA G.Numerical investigation of VOC levels in the area of petrol stations[J].Science of the Total Environment,2014,470-471(2):1205-1224.
[61]HOU Y,CHEN J Q,ZHU L,et al.Numerical simulation of gasoline evaporation in refueling process[J].Advances in Mechanical Engineering,2017,9(8):1-8.
[62]刘君,黄维秋,彭群.加油站油气扩散与回收效果的数值分析[J].环境工程学报,2009,3(5):864-868.(LIU Jun,HUANG Weiqiu,PENG Qun.Numerical analysis of gasoline vapor diffusion and recovery results in gasoline stations[J].Chinese Journal of Environmental Engineering,2009,3(5):864-868.)
[63]金颖,周伟国,阮应君.烟气扩散的CFD数值模拟[J].安全与环境学报,2002,2(1):21-23.(JIN Ying,ZHOU Weiguo,RUAN Yingjun.CFD numerical simulation of gas diffusion[J].Journal of Safety and Environment,2002,2(1):21-23.)
[64]中国石化抚顺石油化工研究院.抚研院“化工装置尾气综合治理技术”通过中国石化技术鉴定[EB/OL].(2016-12-20).http://fripp.sinopec.com/fripp/tech/tech_news/20170210/news_20170210_375473123899.shtml.
[65]江苏省产业技术研究院.膜科学技术研究所[EB/OL].http://www.jitri.org/yanjiuyuan1.html.
[66]章亮.微孔-中孔超高交联吸附树脂的制备及对典型VOCs的吸附特性[D].南京:南京大学,2012.
[67]JIA L,YAO X,MA J,et al.Adsorption kinetics of water vapor on hypercrosslinked polymeric adsorbent and its comparison with carbonaceous adsorbents[J].Microporous&Mesoporous Materials,2017,241:178-184.
[68]李启芬,龙超,刘鹏,等.吸附树脂和活性炭对气体中苯的吸附研究[J].离子交换与吸附,2009,25(2):137-144.(LI Qifen,LONG Chao,LIU Peng,et al.A study on adsorption of benzene vapour on hypercrosslinked adsorption resin and activated carbon[J].Ion Exchange and Adsorption,2009,25(2):137-144.)
[69]高冠道,陈金龙,费正皓,等.超高交联树脂催化剂对水溶液中孔雀绿的催化降解研究[J].高分子学报,2006,50(1):113-117.(GAO Guandao,CHENJinlong,FEI Zhenghao,et al.Degradation of malachite green in aqueous solutions with a novel catalyst of hypercrosslinked resin[J].Acta Polymerica Sinica Acta Polym Sin,2006,50(1):113-117.)
[70]刘鹏,龙超,李莹,等.超高交联吸附树脂对气体中三氯乙烯的吸附研究[J].离子交换与吸附,2009,25(5):411-418.(LIU Peng,LONG Chao,LI Ying,et al.Adsorption of trichloroethylene vapor onto hypercrosslinked adsorption resin[J].Ion Exchange and Adsorption,2009,25(5):411-418.)
[71]黄维秋,赵书华,高锡祺.推广应用油气回收技术势在必行[J].石油库与加油站,2000,9(1):25-28.(HUANG Weiqiu,ZHAO Shuhua,GAO Xiqi.Application and dissemination of oil and gas recovery technologies is required by circumstances and beneficial for enterprises[J].Oil Depot and Gas Station,2000,9(1):25-28.)
[72]黄维秋,徐效梅,林毅,等.基于吸收和吸附的油气回收集成工艺[J].石油化工高等学校学报,2009,22(1):56-60.(HUANG Weiqiu,XU Xiaomei,LIN Yi,et al.Gasoline vapor recovery based on integrated technology of absorption-adsorption[J].Journal of Petrochemical Universities,2009,22(1):56-60.)
[73]纪妍妍,黄维秋,胡志伦,等.基于太阳能驱动的有机废气冷凝和吸附回收系统的经济评价[J].环境工程,2015,33(7):122-126.(JI Yanyan,HUANG Weiqiu,HU Zhilun,et al.Economic evaluation of the system for VOCs recovery driven by solar energy[J].Environmental Engineering,2015,33(7):122-126.)
[74]HUANG Weiqiu,SHI Li.Methods for the control of oil vapor emissions[J].International Journal of Oil,Gas and Coal Technology,2013,6(3):271-287.
[75]黄维秋,秦秀豫,刘俊.油气回收工艺设计专家系统V4.0:软著登字第1840477号[CP].2017-06-12.
[76]中华人民共和国财政部.挥发性有机物排污收费试点办法[EB/OL].(2015-06-18).http://szs.mof.gov.cn/zhengwuxinxi/zhengcefabu/201506/t20150625_1261143.html.
[77]秦秀豫.油气回收工艺优化及辅助设计软件开发[D].常州:常州大学,2017.
[78]李汉勇,宫敬,陈家庆.油气回收技术[M].北京:化学工业出版社,2007:123-124.
[79]BELAISSAOUI B,MOULLECY L,FAVRE E.Energy efficiency of a hybrid membrane/condensation process for VOC(volatile organic compounds)recovery from air:A generic approach[J].Energy,2016,95:291-302.
[80]侯德毅.浅谈油气回收技术[J].油气田地面工程,2009,28(9):85-85.(HOU Deyi.Discussion on oil vapor recovery technology[J].Oil-Gas field Surface Engineering,2009,28(9):85-85.)
[81]赵海洋,卢晗锋,姜波,等.挥发性有机物在活性炭纤维上的吸附和电致热脱附[J].中国环境科学,2016,36(7):1981-1987.(ZHAO Haiyang,LU Hanfeng,JIANG Bo,et al.Adsorption and electro-thermal desorption of VOCs on activated carbon fibers[J].China Environmental Science,2016,36(7):1981-1987.)
[82]SARAWADE P B,KIM J K,HILONGA A,et al.Synthesis of hydrophilic and hydrophobic xerogels with superior properties using sodium silicate[J].Microporous&Mesoporous Materials,2011,139(1/2/3):138-147.
[83]吴剑.超高交联树脂吸附烷烃类蒸汽的平衡与固定床穿透特性及预测研究[D].南京:南京大学,2016:128-129.
[84]WANG H N,TANG M,HAN L,et al.Synthesis of hollow organosiliceous spheres for volatile organic compound removal[J].Journal of Materials Chemistry A,2014,2(45):19298-19307.
[85]WANG H N,RONG X,HAN L,et al.Controlled synthesis of hexagonal mesostructure silica and macroporous ordered siliceous foams for VOCs adsorption[J].RSCAdvances,2015,5(8):5695-5703.
[86]WANG H N,WANG T,YU M H,et al.Elaborate control over the morphology and pore structure of porous silicas for VOCs removal with high efficiency and stability[J].Adsorption,2017,23(1):37-50.
[87]WU Q G,XU R,LI J,et al.Preparation of ZIF-69membranes for gasoline vapor recovery[J].Journal of Porous Materials,2015,22(5):1195-1230.
[88]LI J,ZHONG J,HUANG W Q,et al.Study on the development of ZIF-8 membranes for gasoline vapor recovery[J].Industrial and Engineering Chemistry Research,2014,53(9):3662-3668.
[89]VIVOVILCHES J F,BAILóNGARCíA E,PREZCADENAS A F,et al.Tailoring activated carbons for the development of specific adsorbents of gasoline vapors[J].Journal of Hazardous Materials,2013,263(2):533-540.
[90]许继星,黄维秋,王翊红,等.稻壳基脱硅活性炭的制备及对油气吸附性能研究[J].化工新型材料,2017,45(9):212-214.(XU Jixing,HUANG Weiqiu,WANG Yihong,et al.Preparation of activated carbon from the desilication residue of rice husk and adsorption of oil vapor[J].New Chemical Materials,2017,45(9):212-214.)
[91]REN B.Kinetics and thermodynamics of the phosphine adsorption on the modified activated carbon[J].Frontiers of Chemical Science&Engineering,2011,5(2):203-208.
[2]MU?OZ R,SOUZA T S O,GLITTMANN L,et al.Biological anoxic treatment of O2-free VOC emissions from the petrochemical industry:A proof of concept study[J].Journal of Hazardous Materials,2013,260(6):442-450.
[3]方文政.大气氧化及光氧化挥发性有机物生成二次有机气溶胶的研究[D].合肥:中国科学技术大学,2012.
[4]YUAN B,SHAO M,LU S H,et al.Source profiles of volatile organic compounds associated with solvent use in Beijing,China[J].Atmospheric Environment,2010,44(15):1919-1926.
[5]CAIC J,GENGF H,TIEX X,et al.Characteristics and source apportionment of VOCs measured in Shanghai,China[J].Atmos Environ,2010,44(38):5005-5014.
[6]LEUCHNER M,RAPPENGLCK B.VOC sourcereceptor relationships in Houston during TexAQS-II[J].Atmospheric Environment,2010,44(33):4056-4067.
[7]中华人民共和国环境保护部.“十三五”挥发性有机物污染防治工作方案[EB/OL].(2017-09-13).http://www.zhb.gov.cn/gkml/hbb/bwj/201709/t20170919_421835.htm.
[8]中华人民共和国环境保护部.大气环境保护标准(汇总)[EB/OL].(2017-01-26).http://kjs.mep.gov.cn/hjbhbz/bzwb/dqhjbh/.
[9]张加成,刘艺,胡乃科,等.轻质油品罐区油气密闭收集系统的设计及安保措施[J].油气储运,2016,35(2):167-172.(ZHANG Jiacheng,LIU Yi,HUNaike,et al.Design and safety measures of oil/gas sealed collection system in the light oil tank farm[J].Oil&Gas Storage and Transportation,2016,35(2):167-172.)
[10]焦国凤,周祥,孟繁磊,等.分子水平预测汽油馏分的蒸气压[J].石油学报(石油加工),2017,33(4):662-666.(JIAO Guofeng,ZHOU Xiang,MENG Fanlei,et al.Prediction of the vapor pressure of gasoline at a molecular level[J].Acta Petrolei Sinica(Petroleum Processing Section),2017,33(4):662-666.)
[11]黄维秋,钟秦.非稳态油品蒸发的数值分析Ⅱ数值分析及应用实例[J].石油学报(石油加工),2004,20(1):52-57.(HUANG Weiqiu,ZHONG Qin.Numerical analysis of petroleum products evaporation under unsteady conditionsⅡNumerical analysis and application examples[J].Acta Petrolei Sinica(Petroleum Processing Section),2004,20(1):52-57.)
[12]黄维秋.油品蒸发损耗及其控制技术的评价体系[J].石油学报(石油加工),2005,21(4):79-85.(HUANGWeiqiu.Appraisement system of petroleum evaporation loss and its control measurements[J].Acta Petrolei Sinica(Petroleum Processing Section),2005,21(4):79-85.)
[13]王英霞,黄维秋,郑京禾,等.油品参数测定在油气排放评估中的应用[J].环境工程,2014,32(8):143-146.(WANG Yingxia,HUANG Weiqiu,ZHENGJinghe,et al.Determination of physical parameters of petroleum products and their applications in the evaluation of vapor emissions[J].Environmental Engineering,2014,32(8):143-146.)
[14]李丽,黄维秋,纪妍妍,等.气体扩散系数测试装置研制及应用[J].实验技术与管理,2016,33(2):77-86.(LI Li,HUANG Weiqiu,JI Yanyan,et al.Development and application of gas diffusion coefficient test device[J].Experimental Technology and Management,2016,33(2):77-86.)
[15]李丽,黄维秋,吕爱华,等.有机蒸气-空气分子扩散系数测定的影响因素分析[J].环境工程学报,2017,11(3):1633-1638.(LI Li,HUANG Weiqiu,LAihua,et al.Effect factors analysis of determination of molecular diffusion coefficient of organic vapor-air[J].Chinese Journal of Environmental Engineering,2017,11(3):1633-1638.)
[16]李丽,黄维秋,周宁,等.有机蒸气-空气分子扩散系数实测数据及分析[J].环境工程学报,2017,11(5):2903-2908.(LI Li,HUANG Weiqiu,ZHOU Ning,et al.Measured values and analysis of molecular diffusion coefficient of organic vapor-air[J].Chinese Journal of Environmental Engineering,2017,11(5):2903-2908.)
[17]鲁玉莹,李永祥,龙军,等.C4烷基化反应机理的分子模拟[J].石油学报(石油加工),2016,32(1):14-21.(LU Yuying,LI Yongxiang,LONG Jun,et al.Molecular simulation of mechanism for C4alkylation[J].Acta Petrolei Sinica(Petroleum Processing Section),2016,32(1):14-21.)
[18]RAMDIN M,BALAJI S P,VICENT-LUNA J M,et al.Computing bubble-points of CO2/CH4 gas mixtures in ionic liquids from Monte Carlo simulations[J].Fluid Phase Equilibria,2016,418(9):100-107.
[19]CHEN L P,HUI Q,WANG C L,et al.Molecular simulation on the transport properties of poly[1-trimethylsilyl-1-propyne]for organic-vapor/permanentgas separation[J].Fluid Phase Equilibria,2011,310(8):142-149.
[20]HABIB A,SCHALAU B,SCHMIDT D.Comparing tools of varying complexity for calculating the gas dispersion[J].Process Safety and Environmental Protection,2014,92(2):305-310.
[21]黄维秋,李峰,王丹莉,等.API小呼吸油品蒸发损耗新旧计算式介绍及其应用[J].油气储运,2011,30(12):859-863.(HUANG Weiqiu,LI Feng,WANGDanli,et al.Comparison and application of API old and new formulas for small breathing evaporation loss of oil tank[J].Oil&Gas Storage and Transportation,2011,30(12):859-863.)
[22]USA Environmental Protection Agency(EPA).Final report:Section 7.1 organic liquid storage tanks,emission factor documentation for AP-42[R].Washington D C:USA EPA,2006:38-116.
[23]SHARMAY K,MAJHI A,KUKRETI V S,et al.Stock loss studies on breathing loss of gasoline[J].Fuel,2010,89(7):1695-1699.
[24]LU C Y,HUANG H Y,CHANG S T,et al.Emission characteristics of VOCs from three fixed-roof p-xylene liquid storage tanks[J].Environmental Monitoring and Assessment,2013,185(8):6819-6830.
[25]WU C F,WU T G,HASHMONAYR A,et al.Measurement of fugitive volatile organic compound emissions from a petrochemical tank farm using openpath Fourier transform infrared spectrometry[J].Atmospheric Environment,2014,82(5):335-342.
[26]魏巍.中国人为源挥发性有机化合物的排放现状及未来趋势[D].北京:清华大学,2009.
[27]张国宁,郝郑平,江梅,等.国外固定源VOCs排放控制法规与标准研究[J].环境科学,2011,32(12):3501-3508.(ZHANG Guoning,HAO Zhengping,JIANG Mei,et al.Study on foreign regulations and standards of stationary sources VOCs emission control[J].Environmental Science,2011,32(12):3501-3508.)
[28]黄维秋,钟秦.非稳态油品蒸发的数值分析Ⅰ数学模型的建立[J].石油学报(石油加工),2003,19(6):58-63.(HUANG Weiqiu,ZHONG Qin.Numerical analysis of petroleum products evaporation under unsteady conditions I Establishment of mathematical model[J].Acta Petrolei Sinica(Petroleum Processing Section),2003,19(6):58-63.)
[29]HUANG W Q,BAI J,ZHAO S H,et al.Investigation of oil vapor emission and its evaluation methods[J].Journal of Loss Prevention in the Process Industries,2011,24(2):178-186.
[30]何仁,韦海燕,梁琳林,等.汽油车油箱加油蒸发排放的数值分析[J].江苏大学学报(自然科学版),2011,32(3):277-280.(HE Ren,WEI Haiyan,LIANGLinlin,et al.Numerical analysis of refueling emission of gasoline vehicle tank[J].Journal of Jiangsu University(Natural Science Edition),2011,32(3):277-280.)
[31]HUANG W Q,LI F,ZHAO S H,et al.Analysis of vapor evaporation loss in filling gasoline into tank[J].Advanced Materials Research,2011,347-353:372-375.
[32]HUANG W Q,WANG D L,ZHAO S H,et al.Investigation to VOCs emission factors in filling gasoline into tank[J].Advanced Materials Research,2011,1:802-805.
[33]黄维秋,李峰,刘海.油品蒸发损耗及油气回收评价软件[PELVRES]3.0:软著登字第0356614号[CP].2011-12-09.
[34]黄维秋,郭淑婷,秦秀豫,等.油品蒸发损耗评价软件[PELVRES]4.0:软著登字第2091904号[CP].2017-09-12.
[35]TAMADDONI M,SOTUDEH-GHAREBAGH R,NARIO S,et al.Experimental study of the VOC emitted from crude oil tankers[J].Process Safety&Environmental Protection,2014,92(6):929-937.
[36]OKAMOTO K,WATANABE N,HAGIMOTO Y,et al.Changes in evaporation rate and vapor pressure of gasoline with progress of evaporation[J].Fire Safety Journal,2009,44(5):756-763.
[37]OKAMOTO K,WATANABE N,HAGIMOTO Y,et al.Evaporation characteristics of multi-component liquid[J].Journal of Loss Prevention in the Process Industries,2010,23(1):89-97.
[38]OKAMOTO K,HIRAMATSU M,MIYAMOTO H,et al.Evaporation and diffusion behavior of fuel mixtures of gasoline and kerosene[J].Fire Safety Journal,2012,49(1):47-61.
[39]ZHU L,CHEN J Q,LIU Y,et al.Experimental analysis of the evaporation process for gasoline[J].Journal of Loss Prevention in the Process Industries,2012,25(6):916-922.
[40]朱玲,陈家庆,柳岩,等.汽油挥发过程的试验分析[J].车用发动机,2011,193(2):68-72.(ZHU Ling,CHEN Jiaqing,LIU Yan,et al.Experimental analysis of gasoline evaporation process[J].Vehicle Engine,2011,193(2):68-72.)
[41]MONCALVO D,DAVIES M,WEBER R,et al.Breathing losses from low-pressure storage tanks due to atmospheric weather change[J].Journal of Loss Prevention in the Process Industries,2016,43:702-705.
[42]SRIKANTHS A,NARASIMHAN S.Modeling and simulation of unloading operations in petroleum product storage terminals[J].Computers&Chemical Engineering,2012,46(35):59-68.
[43]STAMOUDIS N,CHRYSSAKIS C,KAIKTSIS L.Atwo-component heavy fuel oil evaporation model for CFDstudies in marine Diesel engines[J].Fuel,2014,115(1):145-153.
[44]HASSANVAND A,HASHEMABADI S H,BAYAT M.Evaluation of gasoline evaporation during the tank splash loading by CFD techniques[J].International Communications in Heat and Mass Transfer,2010,37(7):907-913.
[45]YAMADA H.Contribution of evaporative emissions from gasoline vehicles toward total VOC emissions in Japan[J].Science of the Total Environment,2013,449(2):143-149.
[46]KOYNOV A,KHINAST J G.Micromixing in reactive,deformable bubble and droplet swarms[J].Chemical Engineering&Technology,2006,29(1):13-23.
[47]DAVIDSON M R,RUDMAN M.Volume of fluid calculations of heat or mass transfer across deforming interfaces in two-fluid flow[J].Numerical Heat Transfer Part B Fundamentals,2002,41(3/4):291-308.
[48]WAHEED M A,HENSCHKE M,ANDREAS P.Mass transfer by free and forced convection from single spherical liquid drops[J].International Journal of Heat and Mass Transfer,2002,22(45):4507-4514.
[49]HAELSSIG J B,ANDRE Y T,THIBAULT J,et al.Direct numerical simulation of interphase heat and mass transfer in multicomponent vapor-liquid flows[J].International Journal of Heat and Mass Transfer,2010,53(19/20):3947-3960.
[50]HASSANVAND A,HASHEMABADI S H.Direct numerical simulation of interphase mass transfer in gasliquid multiphase systems[J].International Communications in Heat and Mass Transfer,2011,38(7):943-950.
[51]BANERJEE R.A numerical study of combined heat and mass transfer in an inclined channel using the VOFmultiphase model[J].Numerical Heat Transfer Part A:Applications,2007,52(2):163-183.
[52]BANERJEE R.Turbulent conjugate heat and mass transfer from the surface of a binary mixture of ethanol/iso-octane in a countercurrent stratified two-phase flow system[J].International Journal of Heat and Mass Transfer,2008,51(25):5958-5974.
[53]赵晨露,黄维秋,石莉,等.内浮顶罐中油气扩散运移的数值模拟[J].安全与环境学报,2015,15(3):72-77.(ZHAO Chenlu,HUANG Weiqiu,SHI Li,et al.Numerical simulation model of the oil-vapor diffusion and its migration from the internal floating-roof tank[J].Journal of Safety and Environment,2015,15(3):72-77.)
[54]SAID N M,MHIRI H,BOURNOT H,et al.Experimental and numerical modelling of the threedimensional incompressible flow behaviour in the near wake of circular cylinders[J].Journal of Wind Engineering and Industrial Aerodynamics,2008,96(5):471-502.
[55]MUDDADA S,PATNAIK B S V.An assessment of turbulence models for the prediction of flow past a circular cylinder with momentum injection[J].Journal of Wind Engineering and Industrial Aerodynamics,2010,98(10/11):575-591.
[56]ABDELDAYEM A M,BAYOMI N N.Experimental and numerical flow visualization of a single square cylinder[J].International Journal for Computational Methods in Engineering Science and Mechanics,2006,7(2):113-127.
[57]KONDO N,MATSUKUMA D.Numerical simulation for flow around two circular cylinders in tandem[J].International Journal of Computational Fluid Dynamics,2005,19(4):277-288.
[58]PASLEY H,CLARK C.Computation fluid dynamics study of flow around floating-roof oil storage tanks[J].Journal of Wind Engineering and Industrial Aerodynamics,2000,86(1):37-54.
[59]孙国明,关仲波.基于CFD技术的油罐群风场数值模拟研究[J].化工机械,2009,36(5):467-470.(SUNGuoming,GUAN Zhongbo.Numerical simulation study of the wind field around the oil can group based on computational fluid dynamics(CFD)technology[J].Chemical Engineering&Machinery,2009,36(5):467-470.)
[60]KOUNTOURIOTIS A,ALEIFERISP G,CHARALAMBIDESA G.Numerical investigation of VOC levels in the area of petrol stations[J].Science of the Total Environment,2014,470-471(2):1205-1224.
[61]HOU Y,CHEN J Q,ZHU L,et al.Numerical simulation of gasoline evaporation in refueling process[J].Advances in Mechanical Engineering,2017,9(8):1-8.
[62]刘君,黄维秋,彭群.加油站油气扩散与回收效果的数值分析[J].环境工程学报,2009,3(5):864-868.(LIU Jun,HUANG Weiqiu,PENG Qun.Numerical analysis of gasoline vapor diffusion and recovery results in gasoline stations[J].Chinese Journal of Environmental Engineering,2009,3(5):864-868.)
[63]金颖,周伟国,阮应君.烟气扩散的CFD数值模拟[J].安全与环境学报,2002,2(1):21-23.(JIN Ying,ZHOU Weiguo,RUAN Yingjun.CFD numerical simulation of gas diffusion[J].Journal of Safety and Environment,2002,2(1):21-23.)
[64]中国石化抚顺石油化工研究院.抚研院“化工装置尾气综合治理技术”通过中国石化技术鉴定[EB/OL].(2016-12-20).http://fripp.sinopec.com/fripp/tech/tech_news/20170210/news_20170210_375473123899.shtml.
[65]江苏省产业技术研究院.膜科学技术研究所[EB/OL].http://www.jitri.org/yanjiuyuan1.html.
[66]章亮.微孔-中孔超高交联吸附树脂的制备及对典型VOCs的吸附特性[D].南京:南京大学,2012.
[67]JIA L,YAO X,MA J,et al.Adsorption kinetics of water vapor on hypercrosslinked polymeric adsorbent and its comparison with carbonaceous adsorbents[J].Microporous&Mesoporous Materials,2017,241:178-184.
[68]李启芬,龙超,刘鹏,等.吸附树脂和活性炭对气体中苯的吸附研究[J].离子交换与吸附,2009,25(2):137-144.(LI Qifen,LONG Chao,LIU Peng,et al.A study on adsorption of benzene vapour on hypercrosslinked adsorption resin and activated carbon[J].Ion Exchange and Adsorption,2009,25(2):137-144.)
[69]高冠道,陈金龙,费正皓,等.超高交联树脂催化剂对水溶液中孔雀绿的催化降解研究[J].高分子学报,2006,50(1):113-117.(GAO Guandao,CHENJinlong,FEI Zhenghao,et al.Degradation of malachite green in aqueous solutions with a novel catalyst of hypercrosslinked resin[J].Acta Polymerica Sinica Acta Polym Sin,2006,50(1):113-117.)
[70]刘鹏,龙超,李莹,等.超高交联吸附树脂对气体中三氯乙烯的吸附研究[J].离子交换与吸附,2009,25(5):411-418.(LIU Peng,LONG Chao,LI Ying,et al.Adsorption of trichloroethylene vapor onto hypercrosslinked adsorption resin[J].Ion Exchange and Adsorption,2009,25(5):411-418.)
[71]黄维秋,赵书华,高锡祺.推广应用油气回收技术势在必行[J].石油库与加油站,2000,9(1):25-28.(HUANG Weiqiu,ZHAO Shuhua,GAO Xiqi.Application and dissemination of oil and gas recovery technologies is required by circumstances and beneficial for enterprises[J].Oil Depot and Gas Station,2000,9(1):25-28.)
[72]黄维秋,徐效梅,林毅,等.基于吸收和吸附的油气回收集成工艺[J].石油化工高等学校学报,2009,22(1):56-60.(HUANG Weiqiu,XU Xiaomei,LIN Yi,et al.Gasoline vapor recovery based on integrated technology of absorption-adsorption[J].Journal of Petrochemical Universities,2009,22(1):56-60.)
[73]纪妍妍,黄维秋,胡志伦,等.基于太阳能驱动的有机废气冷凝和吸附回收系统的经济评价[J].环境工程,2015,33(7):122-126.(JI Yanyan,HUANG Weiqiu,HU Zhilun,et al.Economic evaluation of the system for VOCs recovery driven by solar energy[J].Environmental Engineering,2015,33(7):122-126.)
[74]HUANG Weiqiu,SHI Li.Methods for the control of oil vapor emissions[J].International Journal of Oil,Gas and Coal Technology,2013,6(3):271-287.
[75]黄维秋,秦秀豫,刘俊.油气回收工艺设计专家系统V4.0:软著登字第1840477号[CP].2017-06-12.
[76]中华人民共和国财政部.挥发性有机物排污收费试点办法[EB/OL].(2015-06-18).http://szs.mof.gov.cn/zhengwuxinxi/zhengcefabu/201506/t20150625_1261143.html.
[77]秦秀豫.油气回收工艺优化及辅助设计软件开发[D].常州:常州大学,2017.
[78]李汉勇,宫敬,陈家庆.油气回收技术[M].北京:化学工业出版社,2007:123-124.
[79]BELAISSAOUI B,MOULLECY L,FAVRE E.Energy efficiency of a hybrid membrane/condensation process for VOC(volatile organic compounds)recovery from air:A generic approach[J].Energy,2016,95:291-302.
[80]侯德毅.浅谈油气回收技术[J].油气田地面工程,2009,28(9):85-85.(HOU Deyi.Discussion on oil vapor recovery technology[J].Oil-Gas field Surface Engineering,2009,28(9):85-85.)
[81]赵海洋,卢晗锋,姜波,等.挥发性有机物在活性炭纤维上的吸附和电致热脱附[J].中国环境科学,2016,36(7):1981-1987.(ZHAO Haiyang,LU Hanfeng,JIANG Bo,et al.Adsorption and electro-thermal desorption of VOCs on activated carbon fibers[J].China Environmental Science,2016,36(7):1981-1987.)
[82]SARAWADE P B,KIM J K,HILONGA A,et al.Synthesis of hydrophilic and hydrophobic xerogels with superior properties using sodium silicate[J].Microporous&Mesoporous Materials,2011,139(1/2/3):138-147.
[83]吴剑.超高交联树脂吸附烷烃类蒸汽的平衡与固定床穿透特性及预测研究[D].南京:南京大学,2016:128-129.
[84]WANG H N,TANG M,HAN L,et al.Synthesis of hollow organosiliceous spheres for volatile organic compound removal[J].Journal of Materials Chemistry A,2014,2(45):19298-19307.
[85]WANG H N,RONG X,HAN L,et al.Controlled synthesis of hexagonal mesostructure silica and macroporous ordered siliceous foams for VOCs adsorption[J].RSCAdvances,2015,5(8):5695-5703.
[86]WANG H N,WANG T,YU M H,et al.Elaborate control over the morphology and pore structure of porous silicas for VOCs removal with high efficiency and stability[J].Adsorption,2017,23(1):37-50.
[87]WU Q G,XU R,LI J,et al.Preparation of ZIF-69membranes for gasoline vapor recovery[J].Journal of Porous Materials,2015,22(5):1195-1230.
[88]LI J,ZHONG J,HUANG W Q,et al.Study on the development of ZIF-8 membranes for gasoline vapor recovery[J].Industrial and Engineering Chemistry Research,2014,53(9):3662-3668.
[89]VIVOVILCHES J F,BAILóNGARCíA E,PREZCADENAS A F,et al.Tailoring activated carbons for the development of specific adsorbents of gasoline vapors[J].Journal of Hazardous Materials,2013,263(2):533-540.
[90]许继星,黄维秋,王翊红,等.稻壳基脱硅活性炭的制备及对油气吸附性能研究[J].化工新型材料,2017,45(9):212-214.(XU Jixing,HUANG Weiqiu,WANG Yihong,et al.Preparation of activated carbon from the desilication residue of rice husk and adsorption of oil vapor[J].New Chemical Materials,2017,45(9):212-214.)
[91]REN B.Kinetics and thermodynamics of the phosphine adsorption on the modified activated carbon[J].Frontiers of Chemical Science&Engineering,2011,5(2):203-208.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |