甘蔗渣/废旧聚乙烯发泡复合材料的制备及研究
|
摘要
我国植物资源丰富,但利用水平还很低,随着农村生活水平的不断提高,过去被大量用做燃料的农作物秸杆逐渐被液化气、煤气等清洁燃料所代替,除少数被用于生产饲料外,大部分被焚烧处理,这不仅对环境造成了损害,更是对自然资源的严重浪费。另一方面,随着我国经济的快速发展,塑料用量逐日剧增,造成了大量塑料的废弃,给环境带来了不小负担,因此国家越来越重视塑料回收利用的问题。在这样的背景下,使用植物纤维填充改性废旧塑料生产木塑复合材料,不仅可以有效地利用植物纤维和废旧塑料,防止污染,保护环境,同时还可以开发新型仿木材料解决目前木材资源短缺的问题。
木塑复合材料兼有木材和塑料的特点,可以在一些场合替代塑料或木材,但相对于纯塑料来说,其脆性大、冲击强度低;相对于天然木材来说,密度又较大。本文针对这两个弱点,引入发泡工艺,在木塑复合材料的基础上制得发泡木塑复合材料。由于发泡木塑复合材料中的泡孔结构可以钝化裂纹尖端,阻止裂纹的扩展,从而可有效地克服一般木塑复合材料脆性大、抗冲击性能差的缺点,同时泡孔的存在可以降低材料的密度、节省原料。
本文以甘蔗渣、AC发泡剂和废旧地膜(主要成分为聚乙烯PE)为主要原料,通过混炼熔融后热压成型的方法制备了甘蔗渣/废旧聚乙烯发泡复合材料。文章首先研究了发泡木塑复合材料的制备工艺及性能,探讨了发泡剂用量、甘蔗渣含量、预热温度对发泡木塑复合材料的力学性能、密度及吸水率的影响,并通过正交试验法确定了制备发泡木塑复合材料的最佳工艺组合为:发泡剂用量为1.0份,甘蔗渣含量为20份,预热温度为200℃。用扫描电镜观察了材料的微观结构,计算得发泡木塑复合材料的发泡倍数为1.38,孔隙率为27.9%。
另外,针对甘蔗渣与废旧聚乙烯界面相容性差的问题,研究了改善发泡木塑复合材料界面相容性的途径。采用了物理、化学以及两者相结合的方法来提高甘蔗渣与聚乙烯两相间的相容性,比较了碱(NaOH)处理、硅烷偶联剂(KH550)处理、马来酸酐接枝聚乙烯(MAPE)处理及双重处理等处理方法对复合材料力学性能的影响。结果表明:对于拉伸强度和弯曲强度来说,单独处理时以硅烷偶联剂的效果最好,MAPE次之,NaOH处理效果不大;NaOH与硅烷偶联剂双重处理、NaOH与MAPETA重处理对拉伸强度和弯曲强度具有协同增强作用,而硅烷偶联剂和MAPE的双重处理具有对抗减弱作用。对于冲击强度,单独处理以NaOH处理的效果最好,MAPE次之,硅烷偶联剂效果不大,双重处理对复合材料冲击强度没有起到额外作用。
Vegetable fiber resources is rich in Our country, but its utilization rate is very low. Along with the village life level unceasing enhancement,the vegetable fiber which massively used as fuel in the past is being replaced by the clean fuel such as the liquid gas, the coal gas and so on. Except minority use to produce the feed, majority is burnt down, this is not only harmful to the environment, but also waste the natural resource seriously. On the other hand, along with the fast development of our country economy,the amout of plastic used sharp increase, so massively waste plastics are abandoned, therefore the country took the plastic recycling value more and more. Under such background, using vegetable fiber and waste plastic producing wood plastic composites(WPC), not only may effectively use the vegetable fiber and waste plastic, protect the environment, but also may develop new imitating-wood material solve the timber resources short question at present.
WPC(Wood Plastic Composites) has been researched much currently. Though WPC has many advantages of wood and plastic, the mechanical performances such as tenacity and impact strength are lower than plastic,and density is greater than wood. In this paper, according to these weaknesses, foamed WPC has been prepared to increase impact strength and decrease density due to the foams.
Foamed WPC has been prepared with bagasse, AC foaming agent and waste mulching film(PE) by moulding. The effect of foaming agent usage, bagasse content, preheating temperature on the properties of Bagasse/Waste PE Foamed WPC were studied, and the best parameter were certained by orthogonal experiment: the usage of AC foaming agent was 1.0 per, the content of bagasse was 20 per and the preheating temperature was 200℃. The microtectology of composites fracture was viewed by SEM. The foam multiple of the foamed WPC is 1.38,and the porosity is 27.9%.
Additionally, the ways of improving interfacal compatibility of Foamed WPC were studied. The ways of physical, chemical and both were used to improve the compatibility. The effect of alkaloid,silane coupling agent, MAPE on the manchanical propertity of Bagasse/Waste PE Foamed WPC were studied. The research indicated that, for tensile strength and flexural strength, when handle alone, the effect of silicon coupling agent was best, MAPE takes second place,effect of NaOH handling was not large. NaOH and silicon coupling agent double handling,NaOH and MAPE double handling had synergism, but silicon coupling agent and MAPE had confrontation role. For impact strength, individual handling with NaOH was best, MAPE takes second place, the effect of silicon coupling agent was not large. Double handling had no extra function on impact strength.
木塑复合材料兼有木材和塑料的特点,可以在一些场合替代塑料或木材,但相对于纯塑料来说,其脆性大、冲击强度低;相对于天然木材来说,密度又较大。本文针对这两个弱点,引入发泡工艺,在木塑复合材料的基础上制得发泡木塑复合材料。由于发泡木塑复合材料中的泡孔结构可以钝化裂纹尖端,阻止裂纹的扩展,从而可有效地克服一般木塑复合材料脆性大、抗冲击性能差的缺点,同时泡孔的存在可以降低材料的密度、节省原料。
本文以甘蔗渣、AC发泡剂和废旧地膜(主要成分为聚乙烯PE)为主要原料,通过混炼熔融后热压成型的方法制备了甘蔗渣/废旧聚乙烯发泡复合材料。文章首先研究了发泡木塑复合材料的制备工艺及性能,探讨了发泡剂用量、甘蔗渣含量、预热温度对发泡木塑复合材料的力学性能、密度及吸水率的影响,并通过正交试验法确定了制备发泡木塑复合材料的最佳工艺组合为:发泡剂用量为1.0份,甘蔗渣含量为20份,预热温度为200℃。用扫描电镜观察了材料的微观结构,计算得发泡木塑复合材料的发泡倍数为1.38,孔隙率为27.9%。
另外,针对甘蔗渣与废旧聚乙烯界面相容性差的问题,研究了改善发泡木塑复合材料界面相容性的途径。采用了物理、化学以及两者相结合的方法来提高甘蔗渣与聚乙烯两相间的相容性,比较了碱(NaOH)处理、硅烷偶联剂(KH550)处理、马来酸酐接枝聚乙烯(MAPE)处理及双重处理等处理方法对复合材料力学性能的影响。结果表明:对于拉伸强度和弯曲强度来说,单独处理时以硅烷偶联剂的效果最好,MAPE次之,NaOH处理效果不大;NaOH与硅烷偶联剂双重处理、NaOH与MAPETA重处理对拉伸强度和弯曲强度具有协同增强作用,而硅烷偶联剂和MAPE的双重处理具有对抗减弱作用。对于冲击强度,单独处理以NaOH处理的效果最好,MAPE次之,硅烷偶联剂效果不大,双重处理对复合材料冲击强度没有起到额外作用。
Vegetable fiber resources is rich in Our country, but its utilization rate is very low. Along with the village life level unceasing enhancement,the vegetable fiber which massively used as fuel in the past is being replaced by the clean fuel such as the liquid gas, the coal gas and so on. Except minority use to produce the feed, majority is burnt down, this is not only harmful to the environment, but also waste the natural resource seriously. On the other hand, along with the fast development of our country economy,the amout of plastic used sharp increase, so massively waste plastics are abandoned, therefore the country took the plastic recycling value more and more. Under such background, using vegetable fiber and waste plastic producing wood plastic composites(WPC), not only may effectively use the vegetable fiber and waste plastic, protect the environment, but also may develop new imitating-wood material solve the timber resources short question at present.
WPC(Wood Plastic Composites) has been researched much currently. Though WPC has many advantages of wood and plastic, the mechanical performances such as tenacity and impact strength are lower than plastic,and density is greater than wood. In this paper, according to these weaknesses, foamed WPC has been prepared to increase impact strength and decrease density due to the foams.
Foamed WPC has been prepared with bagasse, AC foaming agent and waste mulching film(PE) by moulding. The effect of foaming agent usage, bagasse content, preheating temperature on the properties of Bagasse/Waste PE Foamed WPC were studied, and the best parameter were certained by orthogonal experiment: the usage of AC foaming agent was 1.0 per, the content of bagasse was 20 per and the preheating temperature was 200℃. The microtectology of composites fracture was viewed by SEM. The foam multiple of the foamed WPC is 1.38,and the porosity is 27.9%.
Additionally, the ways of improving interfacal compatibility of Foamed WPC were studied. The ways of physical, chemical and both were used to improve the compatibility. The effect of alkaloid,silane coupling agent, MAPE on the manchanical propertity of Bagasse/Waste PE Foamed WPC were studied. The research indicated that, for tensile strength and flexural strength, when handle alone, the effect of silicon coupling agent was best, MAPE takes second place,effect of NaOH handling was not large. NaOH and silicon coupling agent double handling,NaOH and MAPE double handling had synergism, but silicon coupling agent and MAPE had confrontation role. For impact strength, individual handling with NaOH was best, MAPE takes second place, the effect of silicon coupling agent was not large. Double handling had no extra function on impact strength.
引文
[1] 李思远.木塑复合材料的制备、结构与性能[D].四川:四川大学,2004
[2] 蔡赐春.高填充塑料仿木板材的研制[J].塑料技术,1996,16(3):10~11
[3] 薛平,张明珠等.木塑复合材料及挤出成型特性的研究[J].中国塑料,2001,15(8):53~59
[4] 杨鸣波,李忠明.秸秆/聚氯乙烯复合材料的初步研究[J].材料科学与工程,2000,18(4):27~29
[5] 郭万良.国外木塑复合材料研究概况[J].林业勘察设计,2002,(3):59~61
[6] Oksman K., Lindberg H..Influence of Thermoplastic Elastomers on Adhesion in Polyethylene-Wood Flour Composite[J].Journal of Applied Polymer Science, 1998,68:1845~1855
[7] Oksman K..Improved Interraction between Wood and Synthetic Polymer in Wood/Polymer Composite[J].Wood Science and Technology, 1996,30:197~204.
[8] 林铭,谢拥群等.木塑复合材料的研究现状及发展[J].林业机械与木工设备,2004,32(6):4~6
[9] 高黎,王正.木塑复合材料的发展及展望[J].人造板通讯,2005,12(2):5~8
[10] 赵学峰,白树林,楚小瀛.木塑复合材料的发展回顾[J].材料导报,2004,18(2):52~55
[11] 丁建生,唐伟家,吴汾.塑木复合材料及其制备加工[J].现代塑料加上应用,2003,15(1):16~18
[12] Rana A. K., Mandal A., Mitra B. C.,et al. Short fiber-reinforced polypropylene composites: Effect of compatibilizer[J].J. Appl. Polym. Sci.,1998,69:329~338
[13] Mitra B.C.,Basak R.K.,Sarkar M. Studies on jute-reinforced composites, its limitations, and some solutions through chemical modifications of fibers[J].J. Apply. Polym. Sci.,1998,67:1093~1100
[14] Bledzki A. K., Gassan J.. Composite reinforced with cellulose based fibres[J].Prog. Polym. Sci.,1999,24:221~274
[15] 杨玉和,侯雅丽.木粉填充聚氯乙烯的研究[J].现代塑料加工应用,1995,(6),10~19
[16] 李忠明,杨鸣波.秸秆/聚丙烯复合材料[J].塑料工业,2000,28(4),9~11
[17] 敖欢,刘延华.木塑复合材料发泡成型技术研究进展[J].塑料工业,2005,33(9):1~4
[18] 蔡剑平.木粉/聚乙烯复合发泡挤出技术的研究[J].中国塑料,2004,18(6):54~57
[19] Patterson J.. J. Vinyl. Addit. Technol., 2001, 7(3):138~140
[20] 苑会林,李运德等.木粉填充聚氯乙烯发泡体系的力学性能研究[J].聚氯乙烯,2002,(6):29~32
[21] Mengeloglu F., Matuana L. M.. J. Vinyl. Addit. Technol., 2001, 7 (3): 142~145
[22] Matuana L. M., Mengeloglu F.. J. Vinyl. Addit. Technol., 2002, 8(4):264~267
[23] Matuana L.M., Li Q.X.. J. thermoplast, compos, mater., 2004, 17(2):185~188
[24] Mengeloglu F., Matuana L.M..J Vinyl. Addit. Technol., 2003, 9(1): 26~29
[25] Matuana L. M., Park C. B., Balatinecz J.. Polym. Eng. Sci., 1997, 37(7):1137~1140
[26] Matuana L.M., Park C.B. , Balatinecz J..Cell morphology and property relationships of microcellular foamed PVC/wood-fiber composites. Polym. Eng. Sci., 1998, 38(11): 1862~1865
[27] Li Q.X., Matuana L.M..Appl. Polym. Sci., 2003, 88:3139~3142
[28] Rodrigue D., Souiei S... J. Vinly. Addit. Technol., 2006, 12:19~22
[29] Zhang H., Rizvi G.M., Park C. B.. Adv. Polym. Technol., 2004, 23(4):263~265
[30] Matuana L.M., Li Q.X.. Thermoplastic Compos. Mater., 2004, 17(2) : 185~188
[31] Rizvi G., Matuana L.M., Park C.B.. Polym. Eng. Sci., 2000, 40(10): 2124~2127
[32] Domudiani S., Kortschot M. T.. Thermoplastic Compos. Mater., 2004, 17(1):13~15
[33] Domudiani S., Chafey C. E., Kortsehot M.T.. J. Polym. Sci., Part B: Polym. Phys.,2002, 40(8): 723~726
[34] Zhou J.H., Hanna M. A.. Starch/Staerke, 2004, 56(10): 484486
[35] Jan H. Schut. Foaming Expand Possibilities for Wood-Fiber Composites[J]. Wood-Foam Composites, 2001, 6, 58~65
[36] 陈玉放,揣成智等.植物纤维/热塑性复合材料的开发及有关问题[J].现代塑料加工应用,1998,10(2),50~53
[37] A.K. Rana, A. Mandal, et al.J. Appl. Polym. Sci., 1998,69,32
[38] 乌义明.植物纤维化学[M].北京:中国轻工业出版社,1991
[39] 陈彪,叶红等.植物纤维资源的利用[J].化工时刊.1999(8):8~10
[40] 陈庆云,王云海,农作物秸秆综合利用新技术[J].再生资源研究,2002(2):33~35
[41] 杨之礼,王庆瑞编.粘胶纤维工艺学[M],北京:北京纺织工业出版社,1991
[42] 卜宪华,周南桥,朱文莉.PVC基木塑复合发泡材料界面改性[J].塑料科技,2006,34(4):58~62
[43] 刘建勇,钟圣兆等.木塑复合材料及其研究进展[J].合成材料老化与应用,2004,33(3):48~50
[44] Bledzki A.K. et al.J. Appl. Polym. Sci., 1996,59:1329
[45] 廖兵,黄玉惠等.改性木纤维对LDPE力学性能的影响[J].高分子材料科学与工程,1999,15(3):123~125
[46] 殷吉祥.非木纤维填充PVC复合材料的制备和性能研究[D].湖北:武汉大学,2004
[47] 薛平,王哲等.木塑复合材料加工工艺与设备的研究[J].人造板通讯,2004,11:9~13
[48] 藏克峰,项素云等.MAH-g-PP及偶联剂处理木粉填充PP的研究[J].中国塑料,2001,15(2):71~73
[49] 潘祖仁,邱文豹,王贵恒主编.塑料工业手册/聚氯乙烯[M],1999
[50] 藤建新,吴舜英.微孔塑料性能及制备[J].材料科学与工程,2000(2):105~109
[51] 吴舜英等编著.泡沫塑料成型[M].北京:化学工业出版社,1992
[52] 罗海安,陈炳进等.界面相性态对纤维增强复合材料内应力传递的影响[J].复合材料学报,1996,13(10):123~125
[53] 王清,稿醒等.纤维增强复合材料圆柱型界面裂纹分析[J].力力学报,1997,29(24):421~428
[54] 陈华辉主编.现代复合材料[M].北京:中国物资出版社,1998.8
[55] 胡福增,郑安呐等合编.聚合物及其复合材料的表界面[M].北京:中国轻工业出版社,2001
[56] R. L. Heck.. Review of commercially used chemical foaming agents for thermoplastic foams[J].Journal of Vinyl. and Additive Technology, 1998,4(2):113~116
[57] J.A. Kosin, C.L. Tice. Novel endothermic chemical foaming agents and their applications[J]. Journal of Cellular Plastic, 1990, 26:332~344.
[58] 刘星生,张鸿雁等.甘蔗渣制浆技术研究进展[J].江西化工,2005(1):38~41
[59] 肖泽芳,赵林波,谢延军.木材-热塑性塑料复合材料的研究进展[J].东北林业大学学报,2003,31(1):39~41
[60] Andrzej. M. Kzysik, John, A. Youngquist, et al. Forest Products Research Society, 1991:183~189
[61] 王汝敏,郑水蓉等编著.聚合物基复合材料成型工艺[M].北京:科学出版社,2004
[62] 连荣炳,张卫勤等.软质PVC鞋底发泡材料的研制[J].现代塑料加工应用,2006,18(1):1~4
[63] 李华,王芳.植物纤维的碱法处理[J].山西化工,2002,22(2):18~19
[64] 才红,韦春.SF/PF复合材料冲击性能的研究[J].现代塑料加工应用,2004,16(4):1~3
[65] 刘文鹏,姚姗姗等.影响聚丙烯基木塑复合材料力学性能因素[J].现代塑料加工应用,2006,18(2):19~22
[66] 吴人洁.高聚物的表面与界面[M].北京:科学出版社,1998
[67] 姜洪丽,李斌.界面相容剂对PE-HD/木粉复合材料力学性能的影响[J].高分子材料科学与工程,2005,21(2):204~207
[68] 丁筠,薛平等.纤维表面处理对PVC/木纤维复合材料性能的影响[J].工程塑料应用,2004,32(9):29~31
[69] 徐世忠,翁志学.AC发泡剂在RPVC体系中的分解动力学[J].中国塑料,1995,9(5):19~25
[70] 李卓伟.RPVC低密度自由发泡挤出板材生产工艺探讨[J].聚氯乙烯,2001,(1):23~28
[2] 蔡赐春.高填充塑料仿木板材的研制[J].塑料技术,1996,16(3):10~11
[3] 薛平,张明珠等.木塑复合材料及挤出成型特性的研究[J].中国塑料,2001,15(8):53~59
[4] 杨鸣波,李忠明.秸秆/聚氯乙烯复合材料的初步研究[J].材料科学与工程,2000,18(4):27~29
[5] 郭万良.国外木塑复合材料研究概况[J].林业勘察设计,2002,(3):59~61
[6] Oksman K., Lindberg H..Influence of Thermoplastic Elastomers on Adhesion in Polyethylene-Wood Flour Composite[J].Journal of Applied Polymer Science, 1998,68:1845~1855
[7] Oksman K..Improved Interraction between Wood and Synthetic Polymer in Wood/Polymer Composite[J].Wood Science and Technology, 1996,30:197~204.
[8] 林铭,谢拥群等.木塑复合材料的研究现状及发展[J].林业机械与木工设备,2004,32(6):4~6
[9] 高黎,王正.木塑复合材料的发展及展望[J].人造板通讯,2005,12(2):5~8
[10] 赵学峰,白树林,楚小瀛.木塑复合材料的发展回顾[J].材料导报,2004,18(2):52~55
[11] 丁建生,唐伟家,吴汾.塑木复合材料及其制备加工[J].现代塑料加上应用,2003,15(1):16~18
[12] Rana A. K., Mandal A., Mitra B. C.,et al. Short fiber-reinforced polypropylene composites: Effect of compatibilizer[J].J. Appl. Polym. Sci.,1998,69:329~338
[13] Mitra B.C.,Basak R.K.,Sarkar M. Studies on jute-reinforced composites, its limitations, and some solutions through chemical modifications of fibers[J].J. Apply. Polym. Sci.,1998,67:1093~1100
[14] Bledzki A. K., Gassan J.. Composite reinforced with cellulose based fibres[J].Prog. Polym. Sci.,1999,24:221~274
[15] 杨玉和,侯雅丽.木粉填充聚氯乙烯的研究[J].现代塑料加工应用,1995,(6),10~19
[16] 李忠明,杨鸣波.秸秆/聚丙烯复合材料[J].塑料工业,2000,28(4),9~11
[17] 敖欢,刘延华.木塑复合材料发泡成型技术研究进展[J].塑料工业,2005,33(9):1~4
[18] 蔡剑平.木粉/聚乙烯复合发泡挤出技术的研究[J].中国塑料,2004,18(6):54~57
[19] Patterson J.. J. Vinyl. Addit. Technol., 2001, 7(3):138~140
[20] 苑会林,李运德等.木粉填充聚氯乙烯发泡体系的力学性能研究[J].聚氯乙烯,2002,(6):29~32
[21] Mengeloglu F., Matuana L. M.. J. Vinyl. Addit. Technol., 2001, 7 (3): 142~145
[22] Matuana L. M., Mengeloglu F.. J. Vinyl. Addit. Technol., 2002, 8(4):264~267
[23] Matuana L.M., Li Q.X.. J. thermoplast, compos, mater., 2004, 17(2):185~188
[24] Mengeloglu F., Matuana L.M..J Vinyl. Addit. Technol., 2003, 9(1): 26~29
[25] Matuana L. M., Park C. B., Balatinecz J.. Polym. Eng. Sci., 1997, 37(7):1137~1140
[26] Matuana L.M., Park C.B. , Balatinecz J..Cell morphology and property relationships of microcellular foamed PVC/wood-fiber composites. Polym. Eng. Sci., 1998, 38(11): 1862~1865
[27] Li Q.X., Matuana L.M..Appl. Polym. Sci., 2003, 88:3139~3142
[28] Rodrigue D., Souiei S... J. Vinly. Addit. Technol., 2006, 12:19~22
[29] Zhang H., Rizvi G.M., Park C. B.. Adv. Polym. Technol., 2004, 23(4):263~265
[30] Matuana L.M., Li Q.X.. Thermoplastic Compos. Mater., 2004, 17(2) : 185~188
[31] Rizvi G., Matuana L.M., Park C.B.. Polym. Eng. Sci., 2000, 40(10): 2124~2127
[32] Domudiani S., Kortschot M. T.. Thermoplastic Compos. Mater., 2004, 17(1):13~15
[33] Domudiani S., Chafey C. E., Kortsehot M.T.. J. Polym. Sci., Part B: Polym. Phys.,2002, 40(8): 723~726
[34] Zhou J.H., Hanna M. A.. Starch/Staerke, 2004, 56(10): 484486
[35] Jan H. Schut. Foaming Expand Possibilities for Wood-Fiber Composites[J]. Wood-Foam Composites, 2001, 6, 58~65
[36] 陈玉放,揣成智等.植物纤维/热塑性复合材料的开发及有关问题[J].现代塑料加工应用,1998,10(2),50~53
[37] A.K. Rana, A. Mandal, et al.J. Appl. Polym. Sci., 1998,69,32
[38] 乌义明.植物纤维化学[M].北京:中国轻工业出版社,1991
[39] 陈彪,叶红等.植物纤维资源的利用[J].化工时刊.1999(8):8~10
[40] 陈庆云,王云海,农作物秸秆综合利用新技术[J].再生资源研究,2002(2):33~35
[41] 杨之礼,王庆瑞编.粘胶纤维工艺学[M],北京:北京纺织工业出版社,1991
[42] 卜宪华,周南桥,朱文莉.PVC基木塑复合发泡材料界面改性[J].塑料科技,2006,34(4):58~62
[43] 刘建勇,钟圣兆等.木塑复合材料及其研究进展[J].合成材料老化与应用,2004,33(3):48~50
[44] Bledzki A.K. et al.J. Appl. Polym. Sci., 1996,59:1329
[45] 廖兵,黄玉惠等.改性木纤维对LDPE力学性能的影响[J].高分子材料科学与工程,1999,15(3):123~125
[46] 殷吉祥.非木纤维填充PVC复合材料的制备和性能研究[D].湖北:武汉大学,2004
[47] 薛平,王哲等.木塑复合材料加工工艺与设备的研究[J].人造板通讯,2004,11:9~13
[48] 藏克峰,项素云等.MAH-g-PP及偶联剂处理木粉填充PP的研究[J].中国塑料,2001,15(2):71~73
[49] 潘祖仁,邱文豹,王贵恒主编.塑料工业手册/聚氯乙烯[M],1999
[50] 藤建新,吴舜英.微孔塑料性能及制备[J].材料科学与工程,2000(2):105~109
[51] 吴舜英等编著.泡沫塑料成型[M].北京:化学工业出版社,1992
[52] 罗海安,陈炳进等.界面相性态对纤维增强复合材料内应力传递的影响[J].复合材料学报,1996,13(10):123~125
[53] 王清,稿醒等.纤维增强复合材料圆柱型界面裂纹分析[J].力力学报,1997,29(24):421~428
[54] 陈华辉主编.现代复合材料[M].北京:中国物资出版社,1998.8
[55] 胡福增,郑安呐等合编.聚合物及其复合材料的表界面[M].北京:中国轻工业出版社,2001
[56] R. L. Heck.. Review of commercially used chemical foaming agents for thermoplastic foams[J].Journal of Vinyl. and Additive Technology, 1998,4(2):113~116
[57] J.A. Kosin, C.L. Tice. Novel endothermic chemical foaming agents and their applications[J]. Journal of Cellular Plastic, 1990, 26:332~344.
[58] 刘星生,张鸿雁等.甘蔗渣制浆技术研究进展[J].江西化工,2005(1):38~41
[59] 肖泽芳,赵林波,谢延军.木材-热塑性塑料复合材料的研究进展[J].东北林业大学学报,2003,31(1):39~41
[60] Andrzej. M. Kzysik, John, A. Youngquist, et al. Forest Products Research Society, 1991:183~189
[61] 王汝敏,郑水蓉等编著.聚合物基复合材料成型工艺[M].北京:科学出版社,2004
[62] 连荣炳,张卫勤等.软质PVC鞋底发泡材料的研制[J].现代塑料加工应用,2006,18(1):1~4
[63] 李华,王芳.植物纤维的碱法处理[J].山西化工,2002,22(2):18~19
[64] 才红,韦春.SF/PF复合材料冲击性能的研究[J].现代塑料加工应用,2004,16(4):1~3
[65] 刘文鹏,姚姗姗等.影响聚丙烯基木塑复合材料力学性能因素[J].现代塑料加工应用,2006,18(2):19~22
[66] 吴人洁.高聚物的表面与界面[M].北京:科学出版社,1998
[67] 姜洪丽,李斌.界面相容剂对PE-HD/木粉复合材料力学性能的影响[J].高分子材料科学与工程,2005,21(2):204~207
[68] 丁筠,薛平等.纤维表面处理对PVC/木纤维复合材料性能的影响[J].工程塑料应用,2004,32(9):29~31
[69] 徐世忠,翁志学.AC发泡剂在RPVC体系中的分解动力学[J].中国塑料,1995,9(5):19~25
[70] 李卓伟.RPVC低密度自由发泡挤出板材生产工艺探讨[J].聚氯乙烯,2001,(1):23~28