发泡剂对水性聚氨酯合成革贝斯性能的影响研究
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摘要
以高固含量水性聚氨酯为树脂浆料,偶氮二甲酰胺(AC)为发泡剂,采用发泡工艺制备了透气性优异的合成革基革(贝斯)。通过扫描电镜和Image-Pro Plus软件表征了发泡贝斯的微观结构形态,研究了AC用量对合成革贝斯形态结构和性能的影响规律。结果表明,配合发泡助剂尿素一起使用,发泡剂AC的分解温度可以降低到聚氨酯树脂的干燥温度范围,AC经乳化后可以均匀地分散在水性树脂浆料中;当发泡剂AC质量分数为0. 3%(基于树脂固体分)时,胶膜具有透气性和强度的良好平衡,胶膜的比表面积为1. 09 m2/g,约为发泡前的33倍;且泡孔大小相当,分布均匀,合成革贝斯具有良好的透气性能和较高的拉伸强度。
A foamed synthetic leather base was prepared by using high solid content waterborne polyurethane emulsion and foaming agent azodicarbonamide(AC) as the main materials. The micro-structure of the foamed base was characterized by scanning electronic microscopy(SEM) and analyzed by the Image-Pro Plus software. The effects of dosages of foaming agent azodicarbonamide(AC) on the structure and properties of the base film were studied. The results indicated that,the decomposition temperature of AC could be reduced to the drying temperature range of polyurethane resin by adding the foaming auxiliary urea. When the dosage of AC was 0. 30%(based on resin solid content),a good balance of permeability and tensile strength were achieved,which could improve the gas permeability of synthetic leather with excellent tensile strength. The specific surface area of the film was 1. 09 m2/g,which increased to about 33 times.
A foamed synthetic leather base was prepared by using high solid content waterborne polyurethane emulsion and foaming agent azodicarbonamide(AC) as the main materials. The micro-structure of the foamed base was characterized by scanning electronic microscopy(SEM) and analyzed by the Image-Pro Plus software. The effects of dosages of foaming agent azodicarbonamide(AC) on the structure and properties of the base film were studied. The results indicated that,the decomposition temperature of AC could be reduced to the drying temperature range of polyurethane resin by adding the foaming auxiliary urea. When the dosage of AC was 0. 30%(based on resin solid content),a good balance of permeability and tensile strength were achieved,which could improve the gas permeability of synthetic leather with excellent tensile strength. The specific surface area of the film was 1. 09 m2/g,which increased to about 33 times.
引文
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[9]苏奕富,陈金章.一种水性聚氨酯发泡浆料的制备方法:中国,102408698A[P]. 2012-04-11.
[10]时云刚.合成革用水性PU羊巴高温发泡树脂:中国,101705622A[P]. 2010-05-12.
[11]刘巧宾,揣成智.生态合成革用高固含量水性聚氨酯乳液的合成[J].合成树脂及塑料,2016,33(3):20-23.
[12]罗晓民,李鹏妮,郑玉,等.单组分水性聚氨酯在合成革中的应用[J].聚氨酯工业,2012,27(2):31-34.
[2] Anon.水性生态合成革的发展现状以及技术突破[EB/OL].中国国际合成革网. http:∥www. chinaleather. org/Pages/News/20130823/138141.shtml.
[3] XU W L,WANG X,LI W B,et al. Characterization of superfine wool powder/poly(propylene)blend film[J]. Macromolecular Materials and Engineering,2007,292(5):674-680.
[4]陈杨,钱晓明,宋兵.水性聚氨酯合成革发泡成型技术的研究及进展[J].中国皮革,2015,44(15):48-52.
[5]王姗姗,刘世勇,范浩军.水性聚氨酯用于发泡合成革的制造研究[J].中国皮革,2011,40(17):40-44.
[6]戴家兵,李维虎,祝彬.水性聚氨酯合成革贝斯的制备方法:中国,102797165A[P]. 2012-11-28.
[7]罗晓民,冯见艳,曲建波,等.一种水性聚氨酯合成革贝斯的制造方法:中国,102080332A[P]. 2011-06-01.
[8]苏奕富,陈尚泰.一种水性聚氨酯合成革贝斯的制备方法:中国,02418284A[P]. 2012-04-01.
[9]苏奕富,陈金章.一种水性聚氨酯发泡浆料的制备方法:中国,102408698A[P]. 2012-04-11.
[10]时云刚.合成革用水性PU羊巴高温发泡树脂:中国,101705622A[P]. 2010-05-12.
[11]刘巧宾,揣成智.生态合成革用高固含量水性聚氨酯乳液的合成[J].合成树脂及塑料,2016,33(3):20-23.
[12]罗晓民,李鹏妮,郑玉,等.单组分水性聚氨酯在合成革中的应用[J].聚氨酯工业,2012,27(2):31-34.
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