低温等离子体引发亚麻接枝改善染色性能
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摘要
亚麻是一种重要的纺织纤维,因其独特的纤维结构,使得亚麻织物具有吸湿好、挺括、穿着凉爽、舒适等特点,这是其它纤维无法比拟的,因此倍受人们的青睐,这使得人们对亚麻纤维的染色性能有了更高的要求,提高麻类织物的染整加工技术以增加其附加值已势在必行。
现在人们对于改善亚麻染色性能的方法已不再只局限于传统的化学方法,而是更青睐那些污染少、效率高、资源消耗少的方法。本论文中采用了介质阻挡放电和辉光放电两种低温等离子体技术对亚麻进行处理引发接枝,同时采用混合丙烯酸和苯乙烯为接枝单体来减少均聚产物,提高接枝率,改善亚麻织物的染色性能。
采用介质阻挡放电装置处理亚麻试样并进行接枝,确定混合单体的最优配比为苯乙烯:丙烯酸值为3:7,然后采用L_9(3~4)正交表分析后发现接枝温度、接枝溶液浓度、等离子体处理时间对上染率影响程度依次减小。在实验取值范围内,认为合适的处理条件为接枝温度60℃,接枝溶液浓度80%,等离子体处理时间为4min。
采用辉光放电装置对亚麻试样进行处理并进行接枝,发现在短时间内功率为10w时的上染率好于功率为5w时的上染率,而延长时间后,情况相反。而随喷头温度的升高,在70℃时上染率出现最大值。对比两种等离子体处理方式所产生的效果发现,采用介质阻挡放电设备时效果理想且成本较低,更适合于应用在工业化生产中,所以本实验更倾向于使用介质阻挡放电设备来处理亚麻试样以改善其染色性能。
采用红外光谱对接枝共聚物进行表征,发现接枝后的亚麻试样红外光谱中出现了丙烯酸和苯乙烯特征吸收峰,结果证明了在亚麻大分子上接枝上了丙烯酸和苯乙烯的混合单体。采用扫描电镜对接枝共聚物的结构进行分析,结果显示亚麻纤维上覆盖了一层物质为接枝共聚物。
接枝前后的亚麻试样均采用阳离子染料进行染色,分析上染率的变化,结果表明接枝前织物的上染率为22.4%,经过接枝后在最佳条件下上染率可达到57.74%,改善了其染色性能,同时通过对比接枝前后亚麻织物的染色牢度,发现其干摩擦牢度和湿摩擦牢度及耐水洗牢度都有提高。随着等离子体处理时间的增加,织物的强力有所下降。
Linen is an important kind of fibers. It has good hygroscopicity、straight and upright because of its unique fiber structure. These characters are better than any other fibers. And the linen suffers the favor of the consumers all over the world. So people need the linen fiber has a high dyeability. As the development of linen fabric, improving linen fabric's quality coloration and finishing processes technology is must be done.
Compared to the chemistry method for improving linen dyeability, people prefer to the method of little pollution, high efficiency. The thesis researches initiation graft linen by using dielectric barrier discharge and glow-discharge treatment. In this thesis uses blend acrylic acid and styrene as grafting monomer to reduce homopolymers and improve degree of grafting and dyeability.
Using dielectric barrier discharge initiates grafting polymerization onto linen. And the best blending ratio is styrene : acrylic acid is 3 : 7. Using L9(3~4) orthogonal analyzes the effect degree of dye-uptake. The result is grafting temperature's effect is best and time of plasma treatment is lest. The best disposing conditions is grafting temperature 60℃, grafting concentration 80%, and plasma treatment 4 minute in the experiment range.
Using glow-discharge treatment initiates grafting polymerization onto linen. In short time the dye-uptake of 10w is better than 5w. Elongating the time it is reverse. When the temperature of spray head is 70℃the dye-uptake reaches the best. When using dielectric barrier discharge treatment it can reach better effect and low cost than using glow-discharge treatment. And the equipment of former is more adapt to use in industry. Because of all above factors this thesis prefers former.
Using infrared spectrum characterizes the nature of the grafting copolymer. The result manifests the characteristic absorption peak of acrylic acid and styrene taking place, which proving the acrylic acid and styrene blending monomer are grafted onto the linen macromolecule. Using scanning electron microscope analyzes the structure of copolymer. The result manifests that copolymer overlay onto the linen.
Dye the linen with cationic dye. And the dye-uptake of linen which has been grafted is 57.74% but nature linen's up-take is 22.4%. So the dye-uptake is improved. Compared the color fastness of nature linen to grafted linen, the dry rubbing fastness and wet rubbing fastness are improved. Fabric strength descends as the plasma treatment time elongation.
现在人们对于改善亚麻染色性能的方法已不再只局限于传统的化学方法,而是更青睐那些污染少、效率高、资源消耗少的方法。本论文中采用了介质阻挡放电和辉光放电两种低温等离子体技术对亚麻进行处理引发接枝,同时采用混合丙烯酸和苯乙烯为接枝单体来减少均聚产物,提高接枝率,改善亚麻织物的染色性能。
采用介质阻挡放电装置处理亚麻试样并进行接枝,确定混合单体的最优配比为苯乙烯:丙烯酸值为3:7,然后采用L_9(3~4)正交表分析后发现接枝温度、接枝溶液浓度、等离子体处理时间对上染率影响程度依次减小。在实验取值范围内,认为合适的处理条件为接枝温度60℃,接枝溶液浓度80%,等离子体处理时间为4min。
采用辉光放电装置对亚麻试样进行处理并进行接枝,发现在短时间内功率为10w时的上染率好于功率为5w时的上染率,而延长时间后,情况相反。而随喷头温度的升高,在70℃时上染率出现最大值。对比两种等离子体处理方式所产生的效果发现,采用介质阻挡放电设备时效果理想且成本较低,更适合于应用在工业化生产中,所以本实验更倾向于使用介质阻挡放电设备来处理亚麻试样以改善其染色性能。
采用红外光谱对接枝共聚物进行表征,发现接枝后的亚麻试样红外光谱中出现了丙烯酸和苯乙烯特征吸收峰,结果证明了在亚麻大分子上接枝上了丙烯酸和苯乙烯的混合单体。采用扫描电镜对接枝共聚物的结构进行分析,结果显示亚麻纤维上覆盖了一层物质为接枝共聚物。
接枝前后的亚麻试样均采用阳离子染料进行染色,分析上染率的变化,结果表明接枝前织物的上染率为22.4%,经过接枝后在最佳条件下上染率可达到57.74%,改善了其染色性能,同时通过对比接枝前后亚麻织物的染色牢度,发现其干摩擦牢度和湿摩擦牢度及耐水洗牢度都有提高。随着等离子体处理时间的增加,织物的强力有所下降。
Linen is an important kind of fibers. It has good hygroscopicity、straight and upright because of its unique fiber structure. These characters are better than any other fibers. And the linen suffers the favor of the consumers all over the world. So people need the linen fiber has a high dyeability. As the development of linen fabric, improving linen fabric's quality coloration and finishing processes technology is must be done.
Compared to the chemistry method for improving linen dyeability, people prefer to the method of little pollution, high efficiency. The thesis researches initiation graft linen by using dielectric barrier discharge and glow-discharge treatment. In this thesis uses blend acrylic acid and styrene as grafting monomer to reduce homopolymers and improve degree of grafting and dyeability.
Using dielectric barrier discharge initiates grafting polymerization onto linen. And the best blending ratio is styrene : acrylic acid is 3 : 7. Using L9(3~4) orthogonal analyzes the effect degree of dye-uptake. The result is grafting temperature's effect is best and time of plasma treatment is lest. The best disposing conditions is grafting temperature 60℃, grafting concentration 80%, and plasma treatment 4 minute in the experiment range.
Using glow-discharge treatment initiates grafting polymerization onto linen. In short time the dye-uptake of 10w is better than 5w. Elongating the time it is reverse. When the temperature of spray head is 70℃the dye-uptake reaches the best. When using dielectric barrier discharge treatment it can reach better effect and low cost than using glow-discharge treatment. And the equipment of former is more adapt to use in industry. Because of all above factors this thesis prefers former.
Using infrared spectrum characterizes the nature of the grafting copolymer. The result manifests the characteristic absorption peak of acrylic acid and styrene taking place, which proving the acrylic acid and styrene blending monomer are grafted onto the linen macromolecule. Using scanning electron microscope analyzes the structure of copolymer. The result manifests that copolymer overlay onto the linen.
Dye the linen with cationic dye. And the dye-uptake of linen which has been grafted is 57.74% but nature linen's up-take is 22.4%. So the dye-uptake is improved. Compared the color fastness of nature linen to grafted linen, the dry rubbing fastness and wet rubbing fastness are improved. Fabric strength descends as the plasma treatment time elongation.
引文
[1] 叶秀兰,李燕娟.亚麻纤维染色性能研究.针织工业,1991,(4):1~4
[2] 姚穆,周锦芳等.纺织材料学.北京:中国纺织出版社,1990,76
[3] 吉敏,吴婵娟.双官能团活性染料在亚麻织物上染色性能的研究.北京纺织,2002,(4):42~47
[4] 史加强,董勤霞.亚麻纤维染色难点分析及稀土在亚麻粗纱染色中的应用.印染助剂,1997,(4):7~8
[5] 史加强.亚麻纤维理化性能对染色机理的影响.纺织学报,1999,(2):16~18
[6] 杜建民,罗晓红.浅谈亚麻纤维的化学改性和染色.甘肃轻纺科技,1991,(5):10~16
[7] 高洁,李青山等.阳离子化改性亚麻及其混纺纱染色性能的研究.装饰织物,1996,(3):28~30
[8] 赵铁笔,于宏.浅谈稀土在亚麻织物染色中的应用.印染,1989,(9):1~3
[9] 孟繁杰.涂料在亚麻染色中的应用.印染,1991,(2):1~3
[10] 唐淑娟,高云岭.过氧化氢对亚麻的超声漂白与染色.山东纺织科技,2001,(3):7~9
[11] 巫拱生.亚麻等麻类纤维与乙烯基类单体接枝共聚反应的研究进展.高分子通报,1990,(3):135~141
[12] 宋心远,沈熠如.新型染整技术.北京:中国纺织出版社,1999,21
[13] 吕晶.等离子及其在纺织染整工业中的应用.丝绸,2001,(12):19~21
[14] 陈杰瑢.低温等离子体化学及其应用.北京:科学出版社,2001,11
[15] 陈杰瑢.等离子体清洁技术在纺织印染中的应用.北京:中国纺织出版社,2005,8
[16] 杨文芳,顾振亚.低温等离子体技术在纺织工业中的应用.针织工业,2000,(6):53~55
[17] 宋心远,沈熠如.新型染整技术.北京:中国纺织出版社,1999,29
[18] 杨文芳,顾振亚.低温等离子体技术在纺织工业中的应用.针织工业,2000,(6):53~55
[19] 吕晶.等离子及其在纺织染整工业中的应用.丝绸,2001,(12):19~21
[20] 苏建波.等离子体处理对织物染色性能的影响.济南纺织化纤科技,2002,(4):37~39
[21] 杨文芳,顾振亚.低温等离子体技术在纺织工业中的应用.针织工业,2000,(6):53~55
[22] Kan C W, Chank. Treatment of wool with plasma at low temperature[J]. Textile Asia, 1997 (9): 39
[23] Gregorski K S. Parlath AE. Fabric modification using the plasma [J]. TRJ,1982,50:42~45
[24] Tomiji Wakida, Seiji Tokino. Dyeing properties of wool treated with low-temperature plasma under atmospheric pressure [J].TRJ,1993,63:438
[25] Jangmi Ryu, Tomiji Wakida. Effect of corona discharge on the surface of wool and its application to nrinting[J]. TRJ.1991, 61: 595~601
[26] 朱若英,滑钧凯.羊毛低温等离子体处理后的染色性能研究.天津工业大学学报,2002,(4):22~25
[27] 杨文芳,顾振亚.低温等离子体技术在纺织工业中的应用.针织工业,2000,(6):53~55
[28] 王雪燕,陈杰湾.低温等离子体处理对苎麻织物的深染性的研究[J].印染,1997,(4):5~9
[29] 王雪燕,陈杰湾.低温等离子体处理对苎麻织物的深染性的研究[J].印染,1997,(4):5~9
[30] 袁雨庭,王秀玲.亚麻的低温等离子体处理.印染译丛,2000,(4):71~80
[31] 吕晶.等离子及其在纺织染整工业中的应用.丝绸,2001,(12):19~21
[32] 孙宁,刘倩.等离子体处理PET纤维表面形态结构的研究.高分子材料科学与工程,1994,(2):34~37
[33] 谢洪德,王红卫.柞丝绸等离子体接枝甲基丙烯酸羟乙酯研究.纺织学报,2002,(5):38~40
[34] 张菁.真丝织物等离子体接枝聚合改性.纺织学报,1996,(4):8~11
[35] 任忠海,郭雅林.等离子体引发丙烯酸在亚麻织物上的接枝聚合.辐射研究与辐射工艺学报,2004,(4):205~208
[36] 张镁,涂赞润.细旦丙纶丙烯酸接枝提高可染性的研究.印染,1999,(7):5~9
[37] Sun Y J,Hu G H,Lambla M Free radical grafting of glycidyl metbacrylate on polypropylene in a co-rotation rein screw extruder[J]. Journal of Applied Polymer Science,1995,57:1043~1054
[38] 陈年欢,谢续明.多组分单体熔融接枝聚丙烯及其性能研究[J].功能高分子学报,1998,(1):111
[39] Mamart B S, Oaman E L, Sayed A . etal. Polymer International, 1995, (1):47
[40] Kaur Inderjeat, Baraola Raghoit J. Appl. Polym. Sci. 1990, 41:2067
[41] 张莹,许志立.预辐射聚乙烯膜共接枝丙烯酸和苯乙烯单体的研究.1995,(5):5~9
[42] 朱谱新,杜宗良.乙烯基单体接枝苎麻的染色性能.印染,2000,(1):8~12
[43] A.M.EL—Naggar,M.B.EL-Hosamy.辐射接枝剑麻纤维的表面形态机械性能和染色性能.麻纺织技术,1997,(3):44~48
[44] Flona-Gallardo S G, etal. J Appl Polym Sci, 2001, (8):1497
[45] Chun H J, etal. J Appl Polym Sci, 1999, 72:251
[46] 巫拱生.亚麻等麻类纤维与乙烯基类单体接枝共聚反应的研究进展.高分子通报,1990,(3):135~141
[47] 潘祖仁.高分子化学(第二版).北京:化学工业出版社,1986,76~94
[48] Chapito A. Radiatior. Chemistry of Polymeric Systems. New York, Interscience, 1962,385~440
[49] 范大茵,陈永华.概率论与数理统计.浙江:浙江大学出版社,2000,283
[50] 郭雅林.亚麻化学接枝共聚反应的研究.高分子材料科学与工程,2004,(1):90~92
[51] 冯长根,胡秀峰等.聚丙烯纤维接枝丙烯酸反应条件优化.化工学报,2005(3):555~558
[52] 朱若英,滑钧凯.羊毛低温等离子体处理后的染色性能研究.天津工业大学学报,2002,(4):22~25
[53] 潘祖仁.高分子化学(第二版).北京:化学工业出版社,1986,76~94
[54] 郭雅林.亚麻化学接枝共聚反应的研究.高分子材料科学与工程,2004,(1):90~92
[55] 张莹,许志立.预辐射聚乙烯膜共接枝丙烯酸和苯乙烯单体的研究.1995,(5):5~9
[56] 张菁.真丝织物等离子体接枝聚合改性.纺织学报,1996,(4):8~11
[57] Kubota H,Ogiwara Y. Effect of lignin in graft copolymerization of methyl methacrylate on cellulose by ceric ion.J Appl Polym Sci,1969,13:1569
[58] Jean M D.Grafting of acrylic acid to cellulose and reslting morphology and propertirs.Raleigh:North Carolina State Univ,1984
[59] Gaylord N G.Tmomono T.Alternating copolymer graft copolymers.J Polym Sci,1975,B 13:697~699
[60] TCC (美国) , 1993, (12): 33
[61] 吴冠英.染整工艺学(第三册).北京:中国纺织出版社,2001,50~71
[62] 蔡苏英,田恬.染整工艺学(第三册).北京:中国纺织出版社,1999,80~101,351~370
[63] 周其凤,胡汉杰.高分子化学.化学工业出版社,2001,76
[64] 夏炎.高分子科学简明教程.北京:科学出版社,2002,134
[2] 姚穆,周锦芳等.纺织材料学.北京:中国纺织出版社,1990,76
[3] 吉敏,吴婵娟.双官能团活性染料在亚麻织物上染色性能的研究.北京纺织,2002,(4):42~47
[4] 史加强,董勤霞.亚麻纤维染色难点分析及稀土在亚麻粗纱染色中的应用.印染助剂,1997,(4):7~8
[5] 史加强.亚麻纤维理化性能对染色机理的影响.纺织学报,1999,(2):16~18
[6] 杜建民,罗晓红.浅谈亚麻纤维的化学改性和染色.甘肃轻纺科技,1991,(5):10~16
[7] 高洁,李青山等.阳离子化改性亚麻及其混纺纱染色性能的研究.装饰织物,1996,(3):28~30
[8] 赵铁笔,于宏.浅谈稀土在亚麻织物染色中的应用.印染,1989,(9):1~3
[9] 孟繁杰.涂料在亚麻染色中的应用.印染,1991,(2):1~3
[10] 唐淑娟,高云岭.过氧化氢对亚麻的超声漂白与染色.山东纺织科技,2001,(3):7~9
[11] 巫拱生.亚麻等麻类纤维与乙烯基类单体接枝共聚反应的研究进展.高分子通报,1990,(3):135~141
[12] 宋心远,沈熠如.新型染整技术.北京:中国纺织出版社,1999,21
[13] 吕晶.等离子及其在纺织染整工业中的应用.丝绸,2001,(12):19~21
[14] 陈杰瑢.低温等离子体化学及其应用.北京:科学出版社,2001,11
[15] 陈杰瑢.等离子体清洁技术在纺织印染中的应用.北京:中国纺织出版社,2005,8
[16] 杨文芳,顾振亚.低温等离子体技术在纺织工业中的应用.针织工业,2000,(6):53~55
[17] 宋心远,沈熠如.新型染整技术.北京:中国纺织出版社,1999,29
[18] 杨文芳,顾振亚.低温等离子体技术在纺织工业中的应用.针织工业,2000,(6):53~55
[19] 吕晶.等离子及其在纺织染整工业中的应用.丝绸,2001,(12):19~21
[20] 苏建波.等离子体处理对织物染色性能的影响.济南纺织化纤科技,2002,(4):37~39
[21] 杨文芳,顾振亚.低温等离子体技术在纺织工业中的应用.针织工业,2000,(6):53~55
[22] Kan C W, Chank. Treatment of wool with plasma at low temperature[J]. Textile Asia, 1997 (9): 39
[23] Gregorski K S. Parlath AE. Fabric modification using the plasma [J]. TRJ,1982,50:42~45
[24] Tomiji Wakida, Seiji Tokino. Dyeing properties of wool treated with low-temperature plasma under atmospheric pressure [J].TRJ,1993,63:438
[25] Jangmi Ryu, Tomiji Wakida. Effect of corona discharge on the surface of wool and its application to nrinting[J]. TRJ.1991, 61: 595~601
[26] 朱若英,滑钧凯.羊毛低温等离子体处理后的染色性能研究.天津工业大学学报,2002,(4):22~25
[27] 杨文芳,顾振亚.低温等离子体技术在纺织工业中的应用.针织工业,2000,(6):53~55
[28] 王雪燕,陈杰湾.低温等离子体处理对苎麻织物的深染性的研究[J].印染,1997,(4):5~9
[29] 王雪燕,陈杰湾.低温等离子体处理对苎麻织物的深染性的研究[J].印染,1997,(4):5~9
[30] 袁雨庭,王秀玲.亚麻的低温等离子体处理.印染译丛,2000,(4):71~80
[31] 吕晶.等离子及其在纺织染整工业中的应用.丝绸,2001,(12):19~21
[32] 孙宁,刘倩.等离子体处理PET纤维表面形态结构的研究.高分子材料科学与工程,1994,(2):34~37
[33] 谢洪德,王红卫.柞丝绸等离子体接枝甲基丙烯酸羟乙酯研究.纺织学报,2002,(5):38~40
[34] 张菁.真丝织物等离子体接枝聚合改性.纺织学报,1996,(4):8~11
[35] 任忠海,郭雅林.等离子体引发丙烯酸在亚麻织物上的接枝聚合.辐射研究与辐射工艺学报,2004,(4):205~208
[36] 张镁,涂赞润.细旦丙纶丙烯酸接枝提高可染性的研究.印染,1999,(7):5~9
[37] Sun Y J,Hu G H,Lambla M Free radical grafting of glycidyl metbacrylate on polypropylene in a co-rotation rein screw extruder[J]. Journal of Applied Polymer Science,1995,57:1043~1054
[38] 陈年欢,谢续明.多组分单体熔融接枝聚丙烯及其性能研究[J].功能高分子学报,1998,(1):111
[39] Mamart B S, Oaman E L, Sayed A . etal. Polymer International, 1995, (1):47
[40] Kaur Inderjeat, Baraola Raghoit J. Appl. Polym. Sci. 1990, 41:2067
[41] 张莹,许志立.预辐射聚乙烯膜共接枝丙烯酸和苯乙烯单体的研究.1995,(5):5~9
[42] 朱谱新,杜宗良.乙烯基单体接枝苎麻的染色性能.印染,2000,(1):8~12
[43] A.M.EL—Naggar,M.B.EL-Hosamy.辐射接枝剑麻纤维的表面形态机械性能和染色性能.麻纺织技术,1997,(3):44~48
[44] Flona-Gallardo S G, etal. J Appl Polym Sci, 2001, (8):1497
[45] Chun H J, etal. J Appl Polym Sci, 1999, 72:251
[46] 巫拱生.亚麻等麻类纤维与乙烯基类单体接枝共聚反应的研究进展.高分子通报,1990,(3):135~141
[47] 潘祖仁.高分子化学(第二版).北京:化学工业出版社,1986,76~94
[48] Chapito A. Radiatior. Chemistry of Polymeric Systems. New York, Interscience, 1962,385~440
[49] 范大茵,陈永华.概率论与数理统计.浙江:浙江大学出版社,2000,283
[50] 郭雅林.亚麻化学接枝共聚反应的研究.高分子材料科学与工程,2004,(1):90~92
[51] 冯长根,胡秀峰等.聚丙烯纤维接枝丙烯酸反应条件优化.化工学报,2005(3):555~558
[52] 朱若英,滑钧凯.羊毛低温等离子体处理后的染色性能研究.天津工业大学学报,2002,(4):22~25
[53] 潘祖仁.高分子化学(第二版).北京:化学工业出版社,1986,76~94
[54] 郭雅林.亚麻化学接枝共聚反应的研究.高分子材料科学与工程,2004,(1):90~92
[55] 张莹,许志立.预辐射聚乙烯膜共接枝丙烯酸和苯乙烯单体的研究.1995,(5):5~9
[56] 张菁.真丝织物等离子体接枝聚合改性.纺织学报,1996,(4):8~11
[57] Kubota H,Ogiwara Y. Effect of lignin in graft copolymerization of methyl methacrylate on cellulose by ceric ion.J Appl Polym Sci,1969,13:1569
[58] Jean M D.Grafting of acrylic acid to cellulose and reslting morphology and propertirs.Raleigh:North Carolina State Univ,1984
[59] Gaylord N G.Tmomono T.Alternating copolymer graft copolymers.J Polym Sci,1975,B 13:697~699
[60] TCC (美国) , 1993, (12): 33
[61] 吴冠英.染整工艺学(第三册).北京:中国纺织出版社,2001,50~71
[62] 蔡苏英,田恬.染整工艺学(第三册).北京:中国纺织出版社,1999,80~101,351~370
[63] 周其凤,胡汉杰.高分子化学.化学工业出版社,2001,76
[64] 夏炎.高分子科学简明教程.北京:科学出版社,2002,134