Chemical Industry and Engineering Progress ›› 2017, Vol. 36 ›› Issue (10): 3832-3849.DOI: 10.16085/j.issn.1000-6613.2017-0195
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ZHANG Hong1, LI Wang2, ZHAO Heping1, WANG Jie1, CHEN Jingyi1, KANG Tianli1
Received:
2017-02-13
Revised:
2017-06-15
Online:
2017-10-05
Published:
2017-10-05
张宏1, 李望2, 赵和平1, 王捷1, 陈经义1, 亢田礼1
通讯作者:
张宏(1985-),男,硕士,工程师,从事硫化工产品研发和技术创新等工作.
作者简介:
张宏(1985-),男,硕士,工程师,从事硫化工产品研发和技术创新等工作.E-mail:jinhong_chemical@126.com.
基金资助:
CLC Number:
ZHANG Hong, LI Wang, ZHAO Heping, WANG Jie, CHEN Jingyi, KANG Tianli. Latest development of the sulfur-containing chemicals from hydrogen sulfide in waste gas[J]. Chemical Industry and Engineering Progress, 2017, 36(10): 3832-3849.
张宏, 李望, 赵和平, 王捷, 陈经义, 亢田礼. 以废气中的硫化氢开发含硫化学品的研究进展[J]. 化工进展, 2017, 36(10): 3832-3849.
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[1] 赵明,陈春琳,高鹏,等. 我国硫资源供需状况及需求预测[J]. 化工矿产地质,2014,36(3):173-181. ZHAO M,CHEN C L,GAO P,et al. Analysis of supply and demand of sulfur resources and its demand forecast in china[J]. Geology of Chemical Minerals,2014,36(3):173-181. [2] 马鑫. 硫磺回收装置工艺方案确定及设备选择[D]. 青岛:中国石油大学(华东),2007. MA X. Definition of SRU technology plan and the analysis of equipment choice[D]. Qingdao:China University of Petroleum,2007. [3] 彭仁杰,周继承,罗羽裳,等. 硫化氢分解制取氢和单质硫研究进展[J]. 天然气化工,2015,40(1):89-93. PENG R J,ZHOU J C,LUO Y S,et al. Research progress in hydrogen and sulfur production from hydrogen sulfide[J]. Natural Gas Chemical Industry,2015,40(1):89-93. [4] 白雪峰. 硫化氢分解制氢技术研究进展[J]. 石油化工,2009,38(3):225-233. BAI X F. Progress in research of H2S decomposition for hydrogen production[J]. Petrochemical Technology,2009,38(3):225-233. [5] 中国化工信息中心. 中国化学工业年鉴(27/28/29/30卷)[M]. 北京:中国化工信息中心,2013/2014/2015/2016. CNCIC. China chemical industry yearbook(Vol. 27/28/29/30)[M]. Beijing:CNCIC,2013/2014/2015/2016. [6] 戴正亮,宋晓轩. 硫化钠节能生产工艺探索[J]. 广州化工,2015,43(11):185. DAI Z L,SONG X X. Exploration of the energy-saving production process of sodium sulfide[J]. Guangzhou Chemical Industry,2015,43(11):185. [7] 冯伟,杨启奎,韩维维. 硫化钠生产工艺的优化[J]. 无机盐工业,2016,48(2):37-39. FENG W,YANG Q K,HAN W W. Optimization for production process of sodium sulfide[J]. Inorganic Chemicals Industry,2016,48(2):37-39. [8] 戴承志,武鹤婷. 中国硫化碱产业的发展与展望[J]. 无机盐工业,2014,46(8):1-5. DAI C Z,WU H T. Development and prospect of akali sulphide industry[J]. Inorganic Chemicals Industry,2014,46(8):1-5. [9] 尚方毓. 用氢氧化钠溶液吸收硫化氢制取硫化钠工业技术[J]. 无机盐工业,2012,44(2):42-43. SHANG F Y. Industrial technology of preparing sodium sulfide from absorption of hydrogen sulfide with sodium hydroxide solution[J]. Inorganic Chemicals Industry,2012,44(2):42-43. [10] 张喜荣. 片状硫氢化钠生产工艺改进[J]. 无机盐工业,2003,35(5):41-42. ZHANG X R. The process improvement of flaky sodium hydrosulfide production[J]. Inorganic Chemicals Industry,2003,35(5):41-42. [11] 杨信成,薛永强,石建青. 均匀沉淀法制备不同粒径的纳米硫化锌[J]. 无机盐工业,2011,43(7):13-15. YANG X C,XUE Y Q,SHI J Q. Preparation of nano-sized zinc sulphide with different sizes by homogeneous precipitation method[J]. Inorganic Chemicals Industry,2011,43(7):13-15. [12] 杨超舜,叶鹏,周雅伟,等. 均匀沉淀法制备单分散纳米ZnS及发光性能[J]. 无机化学学报,2010,26(9):1561-1566. YANG C S,YE P,ZHOU Y W,etal. Preparation and luminescent performance of monodispersed ZnS nanoparticle by homogeneous precipitation method[J]. Chinese Journal of Inorganic Chemistry,2010,26(9):1561-1566. [13] THOMAS B,ABDULKHADAR M. Elastic properties of consolidated nano-particles of ZnS and CdS[J]. Solid State Communicatoins,1995,94(3):205-210. [14] 马洪刚,司西强. 烯烃加成硫化氢直接生成硫醇研究进展[J]. 山东化工,2010,39s(1):36-38. MA H G,SI X Q. Developments in the synthesis of mercaptans by addition of alkene with hydrogen sulfide[J]. Shandong Chemical Industry,2010,39(1):36-38. [15] 徐琼,尹笃林. 硫化氢加成直接合成硫醇的催化剂研究进展[J]. 精细化工中间体,2005,35(1):17-19. XU Q,YIN D L. Developments of catalyts in the synthesis of mercaptans by the of alkene with hydrogen sulfide[J]. Fine Chemical Intermediates,2005,35(1):17-19. [16] ARRETZ E,MIRASSOU A,LANDOUSSY C,et al. Process of synthesis of mercaptans from olefins and hydrogen sulphide by heterogeneous catalysis:US4565893A[P]. 1986-01-21. [17] EATON J L,OLIN J F. Condensation of olefinic compounds with hydrogen sulfide:US2443852A[P]. 1948-06-22. [18] FRIED H E. Preparation of secondary thiols:EP0122654A1[P]. 1984-10-24. [19] BUCHHOLZ B. Manufacture of tertiary mercaptans using zeolite catalysts:US4102931A[P]. 1978-07-25. [20] GIACOBBE T J. Process for making tertiary-thiols:US5453544A[P]. 1995-09-26. [21] KUBICEK D H. Mercaptans by addition of hydrogen sulfide to olefins in presence of carbon disulfide:US3963785A[P]. 1976-06-15. [22] SATTICH W E. Selective production of ethyl mercaptan:US5352838A[P]. 1994-10-04. [23] BERNARD B,GOSHORN R H. Process for the preparation of ethyl mercaptan and diethyl sulfide:US3257464A[P]. 1966-06-21. [24] 赵莺,杨焙燃,罗兰,等. 载体对W基催化剂及其催化合成甲硫醇的影响[J]. 贵州大学学报(自然科学版),2014,31(6):30-33. ZHAO Y,YANG B R,LUO L,et al. Effect of different supports on W-based catalysts and methanthiol catalytic synthesis[J]. Journal of Guizhou University(Natural Sciences),2014,31(6):30-33. [25] 陈爱平. 钼基催化剂上的高硫合成气制甲硫醇的研究[D]. 厦门:厦门大学,2008. CHEN A P. Studyon the synthesis of methanethiol from H2S-rich syngas over Mo-based catalysts[D]. Xiamen:Xiamen University,2008. [26] YANG Y Q,DAI S J,YUAN Y Z,et al. The promoting effects of La2O3 and CeO2 on K2MoS4/SiO2 catalyst for methanethiol synthesis from synthesis gas blending with H2S[J]. Appl. Catal. A,2000,192(2):175-180. [27] 王琪,郝影娟,陈爱平,等. 热处理对高硫化氢合成气一步法制甲硫醇K2MoO4-NiO/SiO2催化剂结构及性能的影响[J]. 催化学报,2010,31(2):242-247. WANG Q,HAO Y J,CHEN A P,et al. Effect of thermal treatment on structure and catalytic performance of K2MoO4-NiO/SiO2 catalyst for one-step synthesis of methanethiol from high H2S-containing syngas[J]. Chinese Journal of Catalysis(Chinese Version),2010,31(2):242-247. [28] 周布康,王琪,陈亚中,等. 钾对高硫合成气制甲硫醇磷钼基催化剂的影响[J]. 应用化学,2016,33(9):1079-1084. ZHOU B K,WANG Q,CHEN Y Z,et al. Effect of potassium on the performance of MoP-based catalysts in methyl mercaptan synthesis from high H2S-containing syngas[J]. Chinese Journal of Applied Chemistry,2016,33(9):1079-1084. [29] LIU F,CAO J X,CHAN G Y,et al. Method for preparing methanthiol:102993067A[P]. 2013-03-27. [30] 苏海兰. 乙烯-硫化氢催化加成合成乙硫醇[D]. 天津:天津大学,2007. SU H L. Synthesis of ethyl mercaptan by catalytic addition of hydrogen sulfide to ethylene[D]. Tianjin:Tianjin University,2007. [31] 袁照华. 合成乙硫醇的Co-Mo/γ-Al2O3催化剂研究[D]. 天津:天津大学,2007. YUANZ H. Investigation on Co-Mo/γ-Al2O3 catalysts for synthesis of ethyl mercaptan[D]. Tianjin:Tianjin University,2007. [32] 张强,刘玲娜. 2-巯基乙醇生产技术与应用[J]. 化工中间体,2011(11):43-45. ZHANG Q,LIU L N. A review of the production technology and application on 2-mercaptoethanol[J]. Chemical Intermediate,2011(11):43-45. [33] 田勇,刘传玉,王文彬,等. 2-巯基乙醇的合成与应用进展[J]. 黑龙江科学,2011,2(3):35. TIAN Y,LIU C Y,WANG W B,et al. Advances in the synthesis and application of 2-mercaptoethanol[J]. Heilongjiang Science,2011,2(3):35. [34] 徐曲,邱学婷,衷明华. β-疏基乙醇的合成新工艺[J]. 化学工程师,1996,55(4):14-15. XU Q,QIU X T,ZHONG M H. A new synthetic method of β-mercaptoethanol[J]. Chemical Engineer,1996,55(4):14-15. [35] 罗艳辉. 巯基乙酸绿色合成工艺研究[D]. 郑州:郑州大学,2006. LUO Y H. Study on the green process for synthesis of thioglycolic acid[D]. Zhengzhou:Zhengzhou University,2006. [36] 张展. 巯基乙酸的提纯工艺研究与巯基乙酸铵合成开发[D]. 郑州:郑州大学,2007. ZHANG Z. Purification of thioglycolic acid and synthesis of ammonium thioglycolate[D]. Zhengzhou:Zhengzhou University,2007. [37] 王松. 组合反应器在巯基乙酸合成中的应用[D]. 郑州:郑州大学,2011. WANG S. The application of combination reactor in the synthesis of thioglycolic acid[D]. Zhengzhou:Zhengzhou University,2011. [38] 刘广义,冯其明,钟宏. 提高硫氢化钠法合成巯基乙酸选择性的方法[J]. 中南工业大学学报,2002,33(2):153-156. LIU G Y,FENG Q M,ZHONG H. The methods of improving the selectivity of the synthesis of thioglycolic acid with sodium hydrosulphide[J]. J. Cent. South Univ. Technol.,2002,33(2):153-156. [39] TSUI M E,SHERWIN M B. Synthesis of thioglycolic acid:US5023371A[P]. 1991-06-11. [40] HIROSE Y,MISAWA T,MASATOMI T,et al. Synthesis of thioglycolic acid:JPS5129440A[P]. 1976-03-12. [41] 侯清麟. 巯基乙酸的合成研究[J]. 化工进展,1999,18(6):57-58. HOU Q L. Researchon synthesis of mercapoacetic acid[J]. Chemical Industry and Engineering Progress,1999,18(6):57-58. [42] 钟宏,符剑刚. 巯基乙酸的合成方法[J]. 湖南化工,2000,30(4):6. ZHONG H,FU J G. The applications and synthesis methods of thioglycolic acid[J]. Hunan Chemical Industry,2000,30(4):6. [43] BERGFELD M J,BLAUFELDER C. Process for the manufacture of thioglycolic acid:CA2193055A1[P]. 1997-06-22. [44] 胡永玲,张春荣,徐晓沐. 叔十二硫醇制备方法[J]. 化学工程师,2008,148(1):37-39. HU Y L,ZHANG C R,XUX M. Synthesis of tert-dodecyl mercaptan[J]. Chemical Engineer,2008,148(1):37-39. [45] 田勇. 加成法合成叔十二烷基硫醇的工业试验[J]. 现代化工,2006,26(2):51-53. TIAN Y. Additive method for industrial synthesis of tert-dodecyl mercaptan[J]. Modern Chemical Industry,2006,26(2):51-53. [46] ROBERTS J S. Process to produce organosulfur compounds:EP0354460A1[P]. 1990-02-14. [47] 胡永玲,张春荣,田勇,等. 叔十二碳硫醇的合成方法[J]. 化工进展,2008,27(5):720-723. HUY L,ZHANG C R,TIAN Y,et al. Synthesis technology of tert-dodecyl mercaptan[J]. Chemical Industry and Engineering Progress,2008,27(5):720-723. [48] COOK C M,ALBRIGHT D E,SAVIDAKIS M C. Production of mercaptans using heterogeneous acidic catalysts:US6162952A[P]. 2000-12-19. [49] 常桂兰,荀库. 硫醚合成生产工艺[J]. 辽宁化工,2015,44(4):395-398. CHANG G L,XUN K. Analysis on synthesis process of sulfur ether[J]. Liaoning Chemical Industry,2015,44(4):395-398. [50] 胡文宾,解秀清,唐昭峥,等. 一种用于合成二甲基硫醚的催化剂及其制备方法:1486786A[P]. 2004-04-07. HU W B,XIE X Q,TANG Z Z,et al. Catalyst for synthesizing dimethyl thioether and its preparation method:1486786A[P]. 2004- 04-07. [51] 关莉莉,汪颖,慕旭宏,等. 一种二甲基硫醚的制备方法:104974066A[P]. 2015-10-14. GUAN L L,WANG Y,MU X H,et al. Preparation method of dimethyl sulfide:104974066A[P]. 2015-10-14. [52] MILAM S N,TEGELAAR E W,FREEMAN J J,et al. Systems and methods for producing dimethyl sulfide from gasified coke:105408308A[P]. 2016-03-16. [53] 高文亮,李林凤,张静静,等. 蛋氨酸生产工艺及核心制备技术研究进展[J]. 化工进展,2012,31(4):866-873. GAO W L,LIL F,ZHANG J J,et al. Advance in production process and key manufacture technology for methionine[J]. Chemical Industry and Engineering Progress,2012,31(4):866-873. [54] 党万利,金利群,郑裕国,等. 蛋氨酸生产工艺研究进展[J]. 食品与发酵工业,2012,38(4):152-158. DANG W L,JINL Q,ZHENG Y G,et al. Advance on production of methionine[J]. Food and Fermentation Industries,2012,38(4):152-158. [55] HSU Y C,BLACKBURN T F,PELLEGRIN P F,et al. Continuous hydrolysis process for preparing 2-hydroxy-4-methylthiobutanoic acid or salts thereof:US6268531B1[P]. 2001-07-31. [56] HSU Y C,BLACKBURN T F,PELLEGRIN PF,et al. Continuous hydrolysis process for the preparation of 2-hydroxy-4- methylthiobutanoic acid:US2003144547A1[P]. 2003-07-31. [57] GEIGER F,HALSBERGHE B,HASSELBACH H J,et al. Process for the preparation of methionine from hydrotrope of methionine alkali metal salt:1636975A[P]. 2005-07-13. [58] KAWABE T,OKUBO T,UMEZAWA T,et al. Process for production of methionine:US7223884B2[P]. 2007-05-29. [59] SADA M,TAMIO T,OBATA K,et al. Process for producing methionine:JP4856144[P]. 1975-01-16. [60] MIZIMO T. Production of methionine:JP0393146[P]. 1991-09-27. [61] 季绘明. 聚苯硫醚合成工艺优化[D]. 上海:华东理工大学,2012. JI H M. Study on improving process of polyphenylene sulfide production[D]. Shanghai:East China University of Science and Technology,2012. [62] 魏成武. 聚苯硫醚生产工艺技术开发[D]. 成都:四川大学,2004. WEI C W.Polyphenylene sulfide production technology development[D]. Chengdu:Sichuan University,2004. [63] 强新雷,扈广法,高超峰. 聚苯硫醚的合成与应用[J]. 应用化工,2014,43(2):357-359. QIANG X L,HU G F,GAO C F. Development of synthesis and application of PPS[J]. Applied Chemical Industry,2014,43(2):357-359. [64] 古旗高,李晓陇. 制备高密度线型高分子量聚苯硫醚的方法:1309142A[P]. 2001-08-22. GU Q G,LI X L. Process for preparing high-density high-molecular linear polyphenyl thioether:1309142A[P]. 2001-08-22. [65] 谢美菊,严永刚,余自力,等. 工业硫化钠法常压合成线型高分子量聚苯硫醚的研究[J]. 高分子材料科学与工程,1999,15(1):170-172. XIE M J,YAN Y G,YU Z L,etal. Study on synthesis of linear and high molecular weight poly(phenylene sulfide)at atmospheric pressure[J]. Polymeric Materials Science & Cngineering,1999,15(1):170-172. [66] EDMONDS J J T,SCOGGINS L E. Arylene sulfide polymer prepared from aminoalkanoate:US4324886A[P]. 1982-04-13. [67] 罗吉星,杨云松. 线型高分子量聚苯硫醚树脂的合成[J]. 四川大学学报(自然科学版),1998,35(3):488-490. LUO J X,YANG Y S. The synthesis of poly(p-phenylene sulfide)resin with linear high mdecular weight[J]. Journal of Sichuan University(Natural Science Edition),1998,35(3):488-490. [68] 解东. 管式反应器合成苯硫酚类化合物的工艺研究[D]. 青岛:青岛科技大学,2016. XIE D. Technical research of synthesis thiophenol compounds in tubular reactor[D]. Qingdao:Qingdao University of Science & Technology,2016. [69] VORONKOV M G,DERJAGINA E N I S,CERNYSEV J A,et al. Aromatic and heterocyclic sulphide and disulphide prepn.-by reacting (hetero)aromatic chlorine or bromine derivs. with hydrogen sulphide:DE2521896C2[P]. 1981-10-08. [70] 吉玮. 硫脲的新型合成路线及应用研究[D]. 南京:南京工业大学,2005. JI W. The research for novel synthesis of thiourea and its use[D]. Nanjing:Nanjing University of Technology,2005. [71] 李忠波. 尿素制备硫脲新工艺的研究[D]. 天津:天津大学,2005. LI Z B. Studyonthenewartofthioureapreparationfromure[D]. Tianjin:Tianjin University,2005. [72] 李丕高,李刚. 四氢噻吩合成方法的改进[J].合成化学,2007,15(3):374-375. LI P G,LI G. Improvement on the synthesis of tetrahydrothiophene[J]. Chinese Journal of Synthetic Chemistry,2007,15(3):374-375. [73] 李鸿滨. 四氢噻吩的生产技术与市场分析[J]. 化工中间体,2006(6):12. LI H B. Production technology and market analysis of tetrahydrothiophene[J]. Chemical Intermediate,2006(6):12. [74] 胡永玲,刘殿君,徐晓沐. 二甲基二硫的合成[J]. 化学工程师,2003,95(2):52. HU Y L,LIU D J,XU X M. Synthesis of dimethyl disulfiude[J]. Chemical Engineer,2003,95(2):52. [75] 陈秀仁,张怀有,田锡义. 二甲基亚砜的应用开发前景[J]. 化工进展,2000,19(1):53-56. CHEN X R,ZHANG H Y,TIAN X Y. The application and development perspective of dimethyl sulfoxide[J]. Chemical Industry and Engineering Progress,2000,19(1):53-56. [76] 常桂兰,荀钰航,杨本庆. 二甲基亚砜合成生产的技术改进[J].辽宁化工,2015,44(5):536-538. CHANG G L,XUN Y H,YANG B Q. Improvement of synthesis technique of dimethyl sulfoxide[J]. Liaoning Chemical Industry,2015,44(5):536-538. [77] 卢红波,田文慧,黄实. 二甲基亚砜的工业氧化生产方法[J]. 化肥设计,2015,53(2):24-26. LU H B,TIAN W H,HUANG S. Oxidation production method of dimethyl sulfoxide[J]. Chemical Fertilizer Design,2015,53(2):24-26. [78] 仪志宏,仁诚,胡镇华. 二甲基亚砜生产技术及市场应用[J]. 精细化工中间体,2003,33(3):11-12,18. YI Z H,REN C,HU Z H. The technology and application of dimethyl sulphoxide[J]. Fine Chemical Intermediates,2003,33(3):11-12,18. |
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