废弃PET的降解及其降解产物制备表面活性剂的研究
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摘要
废弃的塑料已经成为了一个全球性的问题。不仅造成了污染,而且浪费了资源。本文以废弃PET为研究对象,应用催化剂和乙二醇对其降解做研究工作,并使用自制催化剂降解废弃PET。并对其降解产物制备表面活性剂做了一些探索性的工作。主要包括:
第一,研究了在普通加热条件下应用醋酸锌做催化剂催化降解PET的各种工艺条件。包括:温度、时间、投料比、催化剂用量。
第二,对催化剂进行了研究,主要应用了掺杂法来制备催化剂,制作出了比醋酸锌更加高效的金属氧化物催化剂。对自制的催化剂内的各种条件:金属的种类、金属的比例、老化温度、老化时间、煅烧温度、煅烧时间。
第三,使用微波加热条件下应用催化剂降解的温度、时间、投料比、催化剂用量和微波功率的工艺条件。
第四,降解的产物用氯磺酸磺化,对BHET上的苯环磺化,改变其化学结构,得到了发泡性较好,具有表面活性剂的物质。并测定了其表面张力和接触角。
第五,用化学溶剂溶解了降解后产物,并将其用乌氏粘度计测定PET降解前后的分子量,并应用得到的数据对降解产物的成分进行了分析。
第六,应用红外检测了降解产物及表面活性剂。应用高效液相色谱分析了产物的各种比例,并验证用粘度法测定的数据。应用DSC测定了降解产物的热性能。
Waste plastic have been a global problem. It’s not only lead environment problem,but also waste resource. This paper focuses on waste PET, use catalyzer and ethyleneglycol (EG) to degradation it. After that we prepare two kinds of catalyzers, and testtheir catalyst capability. Then explore some method use the degradation product toprepare surfactant. This paper contains:
1. Research PET degradation use electric jacket, and study factors affect BHET yield,include: temperature, reaction time, mole ratio, dosage of catalyst.
2. Study on use doping method to prepare metallic oxide catalyzer, and we gain acatalyzer have more catalyst capability than zinc acetate, and we study different factorinfluence catalyst capability: kind of metal, metal mole ratio, aging time, agingtemperature, calcination temperature, calcination time.
3. Use microwave to degrade PET plastic, and explore temperature, react time, moleratio, dosage of catalyzer and microwave power influence BHET yield.
4. Sulfonate degradation product, use chlorosulfonic acid to sulfonate benzene ring,change molecular structure. We gain a foaminess well product. Then we measure thesurface tension and contact angle.
5. Use agent solve degrade product, employ Ubbelohde viscometer measuremolecular weight before and after degradation. Use this data to analysis thecomposition of the product.
6. Apply IR characteristic degradation product and self-make surfactant, HPLC toanalysis pureness, DSC to test degradation product.
第一,研究了在普通加热条件下应用醋酸锌做催化剂催化降解PET的各种工艺条件。包括:温度、时间、投料比、催化剂用量。
第二,对催化剂进行了研究,主要应用了掺杂法来制备催化剂,制作出了比醋酸锌更加高效的金属氧化物催化剂。对自制的催化剂内的各种条件:金属的种类、金属的比例、老化温度、老化时间、煅烧温度、煅烧时间。
第三,使用微波加热条件下应用催化剂降解的温度、时间、投料比、催化剂用量和微波功率的工艺条件。
第四,降解的产物用氯磺酸磺化,对BHET上的苯环磺化,改变其化学结构,得到了发泡性较好,具有表面活性剂的物质。并测定了其表面张力和接触角。
第五,用化学溶剂溶解了降解后产物,并将其用乌氏粘度计测定PET降解前后的分子量,并应用得到的数据对降解产物的成分进行了分析。
第六,应用红外检测了降解产物及表面活性剂。应用高效液相色谱分析了产物的各种比例,并验证用粘度法测定的数据。应用DSC测定了降解产物的热性能。
Waste plastic have been a global problem. It’s not only lead environment problem,but also waste resource. This paper focuses on waste PET, use catalyzer and ethyleneglycol (EG) to degradation it. After that we prepare two kinds of catalyzers, and testtheir catalyst capability. Then explore some method use the degradation product toprepare surfactant. This paper contains:
1. Research PET degradation use electric jacket, and study factors affect BHET yield,include: temperature, reaction time, mole ratio, dosage of catalyst.
2. Study on use doping method to prepare metallic oxide catalyzer, and we gain acatalyzer have more catalyst capability than zinc acetate, and we study different factorinfluence catalyst capability: kind of metal, metal mole ratio, aging time, agingtemperature, calcination temperature, calcination time.
3. Use microwave to degrade PET plastic, and explore temperature, react time, moleratio, dosage of catalyzer and microwave power influence BHET yield.
4. Sulfonate degradation product, use chlorosulfonic acid to sulfonate benzene ring,change molecular structure. We gain a foaminess well product. Then we measure thesurface tension and contact angle.
5. Use agent solve degrade product, employ Ubbelohde viscometer measuremolecular weight before and after degradation. Use this data to analysis thecomposition of the product.
6. Apply IR characteristic degradation product and self-make surfactant, HPLC toanalysis pureness, DSC to test degradation product.
引文
[1]韩春艳.PET瓶级聚酯质量及加工性能研究[D].浙江大学硕士专业学位论文,2005:1-2
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[3]薛大明,全燮,赵雅芝等.废弃聚乙烯塑料热解过程能量收支理论分析[J].大连理工大学学报,1997,37(4):410~413
[4] Viksne A, Kalnins M, et al.[J] Polymer . Recycling, 2000, 5(1):15-22
[5] Dupont L A, et al. [J].J.of Viny Tech., 1993, 15 (2):100-104
[6]姚培建.纺织废料的回收与利用[J].纺织装饰科技,2008(02):29-30.
[7] M.Ghaemy,K.Mossaddegh.Depolymerisation of poly(ethylene terephthalate) fibre wastesusing ethylene glycol[J].Polymer Degradation and Stability, 2005(90):270-276.
[8] Chris Sammon. An FT-IR study of the effect of hydrolytic degradation on the structure ofthin PET films[J].Polymer Degradation and Stability, 2000(67): 149-158.
[9] Minoru Genta. Heterogeneous continuous kinetics modeling of PET depolymerization insupercritical methanol[J]. The Journal of Supercritical Fluids,2010(52):266-275.
[10]张吴宏,相宏伟,杨勇等.聚酯循环利用新进展[J].高分子材料科学与工程,2003,19(6):6-9
[11] CHEN JY,et al Depolymerization of Poly(ethylene terephthalate) Resin UnderPressure[J]. Journal of Applied Polymer Science, 1991, 42(6):1501-1507.
[12] XI D X, XING X Y, SUN C. Study on Glycolysis Condition of Waste Poly(EthyleneTerephthalate)[J].Research of Environmental Sciences,2004,5(17):38-40.
[13] SUH D J,PARK O O,YOON K H. Properties of Unsaturated Polyester Based on theGlycolyzed Poly(ethylene terephthalate)with Various Glycol Compositions[J]. Polymer,2000,41(2):461-466.
[14] Pusztaszeri S F. Method for recovery of terephthalic acid from Polyester scraps[P].US4355175,1982.
[15] Blackmon K P,et al EP,365842[P].1998.(余不详)
[16] IND.US,Patent154774[P].1998.(余不详)
[17] Sako T, Godo M, et al. Process for continuously producing monomer components fromaromatic polyester [P].US622294,2001
[18]王汉夫,孙辉等.PET在超临界甲醉和乙醇中的降解[J].吉林大学自然科学学报
[19]逯德木,许忠斌,佟立芳等.废聚对苯二甲酸乙二醇酯的复合解聚条件[J].高分子材料科学与工程,2008,24(7):148-150
[20] Rubén López-Fonseca et,al. Kinetics of catalytic glycolysis of PET wastes with sodiumcarbonate[J]. Chemical Engineering Journal,168(2011),312-320
[21]周文聪,杨锋,陈飞飞等.废弃PET聚酯醇解技术进展[J].武汉科技学院学报,2008,12,12(21):15-18
[22] Lin Chen-Chong. Macromol.Symp.[J] 1998,135:129-135
[23]周波.表面活性剂[M].北京:化学工业出版社,2006.1—2
[24]金谷.表面活性剂化学[M].合肥:中国科学技术大学出版社,2008: 171- 175.
[25] Bunton C A,Robinson L,Schaak J et al. Catalysis of nucleophilic substitution by micellesof dicationic detergent[J].Org.Chem.,1971,36
[26] Menger F M.,Littau C A.. Gemini surfactants: synthesis and properties [J].J Am ChemSoc, 1991, 113
[27] Rosen M J. Geminis: a new generation of surfactants [J].Chemtech 1993
[28]肖进新,罗妙宣.孪连表面活性剂[J].自然杂志,1997,19(6)
[29]廖险峰,陈全良.废聚酯碎片醇解条件探讨[J].聚酯工业,2006,19(6):20-22
[30]周传佩.物理化学实验[M].北京:中国医药科技出版社,1999.
[31]章守权等.粘度法测定高聚物分子量实验方法的改进[J].滁州学院报,2010,12(5):96.
[32]王顶,王益龙.反应挤出中PET相对分子量的研究[J].现代塑料加工应用,2005,17(2):6-8.
[33]宁永成编著.有机化合物结构鉴定与有机波谱学[M].第二版.北京:科学出版社,2000.
[34]朱洪法.催化剂载体制备及应用技术[M].北京:石油工业出版社,2002:1
[35]潘再富.铂族金属均相催化剂的研究和应用[J].贵金属,2009,8,30(3):42-46
[36]甑开吉等.催化作用基础[M].北京:科学出版社,2005:269-271
[37]郭绍义,王红新.共沉淀法制备铜基催化剂的研究[J].池州师专学报,2007,6,21(3):49-51
[38]谭亚军,蒋展鹏,祝万鹏等.有机污染物湿式氧化降解中Cu系催化剂的稳定[J].环境科学,2004(4);82- 85.
[39] Grace W R.USP, 3.639.099.1972;3.6271.191(1972)
[40]向德辉,翁玉攀,李庆水等.固体催化剂[M].北京:化学工业出版社,1983
[41]江义等.工业废水催化湿式氧化处理的研究,环境科学[J].1990,11(5):34-37.
[42]叶强,曾科.改性PET结晶动力学研究,包装学报[J].2011,(04)
[43]王国荣等.自然百科辞典:数学、物理、化学[M].上海:少年儿童出版社,1995:555
[44]金钦汉,戴树珊,黄卡玛.微波化学[M].北京:科学出版社,1999,1
[45] Andrej Krzan. Poly(ethylene terephthalate) glycolysis under microwave irradiation[J].polymer advance technology.1999,10
[46]王禹等.纯水中PET的微波解聚——方法的研究[D]:[硕士学位论文].大庆:大庆石油学院,2006
[47]徐寒松.应用微波法对废PET进行醇解的研究,聚酯工业[J].2009-03, 22(2):22-25
[48]刘军.化学反应工程[M].北京:化学工业出版社,2009,8
[49]黄卡玛,杨晓庆.微波加快化学反应中非热效应研究的新进展[J].自然科学进展;2006,16(3):273-279
[50]王正烈.物理化学(下)[M].北京:高等教育出版社,2001,12.
[51]赵学庄等.化学反应动力学原理.北京:高等教育出版社,1984(上),1990(下)
[52]易晓霆等.红花籽粕中苯丙烯酰5-羟色胺化合物的缩芯萃取模型[J].粮油加工,2008(08):74-77
[53]毛培坤编.表面活性剂产品工业分析[M].北京:化学工业出版社,2003
[2]韩亚东.PET树脂的生产状况及其发展趋势[J].塑料工业,1988,(6):4
[3]薛大明,全燮,赵雅芝等.废弃聚乙烯塑料热解过程能量收支理论分析[J].大连理工大学学报,1997,37(4):410~413
[4] Viksne A, Kalnins M, et al.[J] Polymer . Recycling, 2000, 5(1):15-22
[5] Dupont L A, et al. [J].J.of Viny Tech., 1993, 15 (2):100-104
[6]姚培建.纺织废料的回收与利用[J].纺织装饰科技,2008(02):29-30.
[7] M.Ghaemy,K.Mossaddegh.Depolymerisation of poly(ethylene terephthalate) fibre wastesusing ethylene glycol[J].Polymer Degradation and Stability, 2005(90):270-276.
[8] Chris Sammon. An FT-IR study of the effect of hydrolytic degradation on the structure ofthin PET films[J].Polymer Degradation and Stability, 2000(67): 149-158.
[9] Minoru Genta. Heterogeneous continuous kinetics modeling of PET depolymerization insupercritical methanol[J]. The Journal of Supercritical Fluids,2010(52):266-275.
[10]张吴宏,相宏伟,杨勇等.聚酯循环利用新进展[J].高分子材料科学与工程,2003,19(6):6-9
[11] CHEN JY,et al Depolymerization of Poly(ethylene terephthalate) Resin UnderPressure[J]. Journal of Applied Polymer Science, 1991, 42(6):1501-1507.
[12] XI D X, XING X Y, SUN C. Study on Glycolysis Condition of Waste Poly(EthyleneTerephthalate)[J].Research of Environmental Sciences,2004,5(17):38-40.
[13] SUH D J,PARK O O,YOON K H. Properties of Unsaturated Polyester Based on theGlycolyzed Poly(ethylene terephthalate)with Various Glycol Compositions[J]. Polymer,2000,41(2):461-466.
[14] Pusztaszeri S F. Method for recovery of terephthalic acid from Polyester scraps[P].US4355175,1982.
[15] Blackmon K P,et al EP,365842[P].1998.(余不详)
[16] IND.US,Patent154774[P].1998.(余不详)
[17] Sako T, Godo M, et al. Process for continuously producing monomer components fromaromatic polyester [P].US622294,2001
[18]王汉夫,孙辉等.PET在超临界甲醉和乙醇中的降解[J].吉林大学自然科学学报
[19]逯德木,许忠斌,佟立芳等.废聚对苯二甲酸乙二醇酯的复合解聚条件[J].高分子材料科学与工程,2008,24(7):148-150
[20] Rubén López-Fonseca et,al. Kinetics of catalytic glycolysis of PET wastes with sodiumcarbonate[J]. Chemical Engineering Journal,168(2011),312-320
[21]周文聪,杨锋,陈飞飞等.废弃PET聚酯醇解技术进展[J].武汉科技学院学报,2008,12,12(21):15-18
[22] Lin Chen-Chong. Macromol.Symp.[J] 1998,135:129-135
[23]周波.表面活性剂[M].北京:化学工业出版社,2006.1—2
[24]金谷.表面活性剂化学[M].合肥:中国科学技术大学出版社,2008: 171- 175.
[25] Bunton C A,Robinson L,Schaak J et al. Catalysis of nucleophilic substitution by micellesof dicationic detergent[J].Org.Chem.,1971,36
[26] Menger F M.,Littau C A.. Gemini surfactants: synthesis and properties [J].J Am ChemSoc, 1991, 113
[27] Rosen M J. Geminis: a new generation of surfactants [J].Chemtech 1993
[28]肖进新,罗妙宣.孪连表面活性剂[J].自然杂志,1997,19(6)
[29]廖险峰,陈全良.废聚酯碎片醇解条件探讨[J].聚酯工业,2006,19(6):20-22
[30]周传佩.物理化学实验[M].北京:中国医药科技出版社,1999.
[31]章守权等.粘度法测定高聚物分子量实验方法的改进[J].滁州学院报,2010,12(5):96.
[32]王顶,王益龙.反应挤出中PET相对分子量的研究[J].现代塑料加工应用,2005,17(2):6-8.
[33]宁永成编著.有机化合物结构鉴定与有机波谱学[M].第二版.北京:科学出版社,2000.
[34]朱洪法.催化剂载体制备及应用技术[M].北京:石油工业出版社,2002:1
[35]潘再富.铂族金属均相催化剂的研究和应用[J].贵金属,2009,8,30(3):42-46
[36]甑开吉等.催化作用基础[M].北京:科学出版社,2005:269-271
[37]郭绍义,王红新.共沉淀法制备铜基催化剂的研究[J].池州师专学报,2007,6,21(3):49-51
[38]谭亚军,蒋展鹏,祝万鹏等.有机污染物湿式氧化降解中Cu系催化剂的稳定[J].环境科学,2004(4);82- 85.
[39] Grace W R.USP, 3.639.099.1972;3.6271.191(1972)
[40]向德辉,翁玉攀,李庆水等.固体催化剂[M].北京:化学工业出版社,1983
[41]江义等.工业废水催化湿式氧化处理的研究,环境科学[J].1990,11(5):34-37.
[42]叶强,曾科.改性PET结晶动力学研究,包装学报[J].2011,(04)
[43]王国荣等.自然百科辞典:数学、物理、化学[M].上海:少年儿童出版社,1995:555
[44]金钦汉,戴树珊,黄卡玛.微波化学[M].北京:科学出版社,1999,1
[45] Andrej Krzan. Poly(ethylene terephthalate) glycolysis under microwave irradiation[J].polymer advance technology.1999,10
[46]王禹等.纯水中PET的微波解聚——方法的研究[D]:[硕士学位论文].大庆:大庆石油学院,2006
[47]徐寒松.应用微波法对废PET进行醇解的研究,聚酯工业[J].2009-03, 22(2):22-25
[48]刘军.化学反应工程[M].北京:化学工业出版社,2009,8
[49]黄卡玛,杨晓庆.微波加快化学反应中非热效应研究的新进展[J].自然科学进展;2006,16(3):273-279
[50]王正烈.物理化学(下)[M].北京:高等教育出版社,2001,12.
[51]赵学庄等.化学反应动力学原理.北京:高等教育出版社,1984(上),1990(下)
[52]易晓霆等.红花籽粕中苯丙烯酰5-羟色胺化合物的缩芯萃取模型[J].粮油加工,2008(08):74-77
[53]毛培坤编.表面活性剂产品工业分析[M].北京:化学工业出版社,2003