化学物理联合微孔发泡成型制备聚己内酯多孔材料

doi:10.3969/j.issn.0438-1157.2014.06.059

化工学报 ›› 2014, Vol. 65 ›› Issue (6): 2386-2392.DOI: 10.3969/j.issn.0438-1157.2014.06.059

• 材料化学工程与纳米技术 • 上一篇下一篇

化学物理联合微孔发泡成型制备聚己内酯多孔材料

王小峰^1,2, 蒋晶^1,2, 侯建华^1,2, 王市伟^1,2, 李倩^1,2, Turng Lih-Sheng^1,3, 申长雨^1,2

1. 微纳成型技术国际联合研究中心, 微成型技术河南省重点实验室, 河南郑州 450001;
2. 郑州大学橡塑模具国家工程研究中心, 河南郑州 450002;
3. The Wisconsin Institute for Discovery, UW-Madison, Madison WI, USA 53705

收稿日期:2013-08-23 修回日期:2013-11-08 出版日期:2014-06-05 发布日期:2014-06-05
通讯作者: 李倩，Turng Lih-Sheng
作者简介:王小峰（1982- ），男，博士研究生。
基金资助:
河南省重大公益科研项目（HNZB[2010]N91）。

Fabrication of porous structure of poly(e-caprolactone) via microcellular injection molding combined with chemical foaming

WANG Xiaofeng^1,2, JIANG Jing^1,2, HOU Jianhua^1,2, WANG Shiwei^1,2, LI Qian^1,2, TURNG Lih-Sheng^1,3, SHEN Changyu^1,2

1. International Joint Research Laboratory for Micro-Nano Moulding Technology, Micro-moulding Technology Key Laboratory of Henan Province, Zhengzhou 450001, Henan, China;
2. National Engineering Research Center for Advanced Polymer Processing Technology, Zhengzhou University, Zhengzhou 450002, Henan, China;
3. The Wisconsin Institute for Discovery, University of Wisconsin, Madison WI 53705, USA

Received:2013-08-23 Revised:2013-11-08 Online:2014-06-05 Published:2014-06-05
Supported by:
supported by the Key Commonwealth Aid Project of Henan Province (HNZB[2010]N91).

摘要/Abstract

摘要： 将超临界气体发泡技术与化学发泡技术联合用于制备多孔材料。采用碳酸氢钠作为化学发泡剂，将聚己内酯与碳酸氢钠挤出共混之后，使用传统注射成型和微注射成型，进行了发泡实验对比。结果表明，物理化学联合发泡用于制备多孔材料具有可行性，化学发泡剂的加入不仅改善了整体发泡效果，还能够作为气泡成核剂促进物理发泡的质量。对于所得结构在一定程度上表现的泡孔相互连通性进行了讨论，同时对泡孔壁面上出现的“网”状结构进行了分析。气泡在成核生长过程中，对于泡孔壁产生多方向拉伸的作用，相邻气泡共同作用于公共壁面，最终导致壁面部分形成“网”状结构。

关键词: 聚己内酯, 超临界流体, 二氧化碳, 碳酸氢钠, 发泡, 成核, 多孔状结构

Abstract: The physical foaming technology of supercritical fluid foaming and chemical foaming technology were combined to fabricate porous structure for polymers. Sodium bicarbonate was used as a chemical foaming agent. Poly(ε-caprolactone) (PCL) was first blended with sodium bicarbonate by a twin screw extruder and pelletized. The different foaming processes were conducted on a conventional injection molding machine and a microcellular injection molding machine separately. The foaming results were investigated by comparing the two methods of injection molding and microcellular injection molding. The results revealed that it was feasible by combining physical foaming and chemical foaming to fabricate porous structure for PCL, whose foaming quality was better than that of only chemical foaming method. The introduction of chemical foaming agent not only improved general foaming, but also served as nucleating agent of the gas bubbles of physical foaming. The interconnectivity of the pores was investigated, as well as the "web" structure on the cell walls. When the bubbles were growing, the cell walls were stretched in different directions, and the mutual wall of neighbored pores was stretched by the pores, therefore the "web" structure was obtained.

Key words: poly(ε-caprolactone), supercritical fluid, carbon dioxide, sodium bicarbonate, foaming, nucleation, porous structure

中图分类号:

TQ328.06

王小峰, 蒋晶, 侯建华, 王市伟, 李倩, Turng Lih-Sheng, 申长雨. 化学物理联合微孔发泡成型制备聚己内酯多孔材料[J]. 化工学报, 2014, 65(6): 2386-2392.

WANG Xiaofeng, JIANG Jing, HOU Jianhua, WANG Shiwei, LI Qian, TURNG Lih-Sheng, SHEN Changyu. Fabrication of porous structure of poly(e-caprolactone) via microcellular injection molding combined with chemical foaming[J]. CIESC Journal, 2014, 65(6): 2386-2392.

参考文献 21

[1]	Liu C, Xia Z, Czernuszka J T. Design and development of three-dimensional scaffolds for tissue engineering[J]. Chemical Engineering Research and Design, 2007,85(7): 1051-1064
[2]	Yang S F, Leong K F, Du Z H, Chua C K.The design of scaffolds for use in tissue engineering(Ⅰ):Traditional factors[J]. Tissue Engineering, 2001, 7(6): 679-689
[3]	Sachlos E, Czernuszka J T. Making tissue engineering scaffolds work: review on the application of solid freeform fabrication technology to the production of tissue engineering scaffolds[J]. European Cells & Materials, 2003,5: 29-40
[4]	Tateishi, T, Chen G, Ushida T. Biodegradable porous scaffolds for tissue engineering[J]. Journal of Artificial Organs, 2002, 5(2): 77-83
[5]	Loh Q L,Choong C. Three-dimensional scaffolds for tissue engineering: role of porosity and pore size[J]. Tissue Eng. Part B: Rev., 2013, 19(6):485-502
[6]	Yang S F, Leong K F, Du Z H, Chua C K.The design of scaffolds for use in tissue engineering(Ⅱ):Rapid prototyping techniques[J]. Tissue Engineering, 2002, 8(1): 1-11
[7]	Rezwan K, Chen Q Z, Blaker J J, Boccaccini A R. Biodegradable and bioactive porous polymer/inorganic composite scaffolds for bone tissue engineering[J]. Biomaterials, 2006, 27(18): 3413-3431
[8]	Kramschuster A, Turng L S. An injection molding process for manufacturing highly porous and interconnected biodegradable polymer matrices for use as tissue engineering scaffolds[J]. Journal of Biomedical Materials Research Part B: Applied Biomaterials, 2009, 92(2): 366-376
[9]	Hwang S S, Hsu P P, Yeh J M, Chang K C, Lai Y Z. The mechanical/thermal properties of microcellular injection-molded poly-lactic-acid nanocomposites[J]. Polymer Composites, 2009, 30(11): 1625-1630
[10]	Turng L S,Kharbas H. Effect of process conditions on the weld-line strength and microstructure of microcellular injection molded parts[J]. Polymer Engineering & Science, 2003,43(1): 157-168
[11]	Lee J J, Cha S W.Characteristics of the skin layers of microcellular injection molded parts[J]. Polymer-Plastics Technology and Engineering, 2006,45(7): 871-877
[12]	Lee J, Turng L S, Kramschuster A. The microcellular injection molding of low-density polyethylene (LDPE) composites[J]. Polymer-Plastics Technology and Engineering, 2010,49(13): 1339-1346
[13]	Kramschuster A, Cavitt R, Ermer D, Chen Z, Turng L S. Quantitative study of shrinkage and warpage behavior for microcellular and conventional injection molding[J]. Polymer Engineering & Science, 2005,45(10): 1408-1418
[14]	Yuan M, Turng L S, Caulfield D F. Crystallization and thermal behavior of microcellular injection-molded polyamide-6 nanocomposites [J]. Polymer Engineering & Science, 2006, 46(7): 904-918
[15]	Cui Z, Nelson B, Peng Y, Li K, Pilla S, Li W J, Turng L S, Shen C.Fabrication and characterization of injection molded poly(e-caprolactone) and poly(e-caprolactone)/hydroxyapatite scaffolds for tissue engineering[J]. Materials Science and Engineering: C, 2012, 32(6): 1674-1681
[16]	Duarte A R C, Mano J F, Reis R L. Supercritical fluids in biomedical and tissue engineering applications: a review[J]. International Materials Reviews, 2009, 54(4): 214-222
[17]	Wang Yaming(王亚明), Shen Changyu (申长雨), Zhao Wenyan (赵文彦). Progress of chemical foaming agent for plastics abroad[J]. Chemical Materials for Construction(化学建材), 2000, 2: 21-22
[18]	Cai Hongguo (蔡宏国). Chemical blowing agents in plastics processing[J]. Moden Plastics Processing and Applications (现代塑料加工应用), 2001, 13(4): 45-48
[19]	Naguib H E, Park C B, Panzer U, Reichelt N.Strategies for achieving ultra low-density polypropylene foams[J]. Polymer Engineering & Science, 2002, 42(7): 1481-1492
[20]	Colton J S, Suh N P.Nucleation of microcellular foam: theory and practice[J]. Polymer Engineering & Science, 1987, 27(7): 500-503
[21]	Stevens M M,George J H.Exploring and engineering the cell surface interface[J]. Science, 2005, 310(5751): 1135-1138

化学物理联合微孔发泡成型制备聚己内酯多孔材料

Fabrication of porous structure of poly(e-caprolactone) via microcellular injection molding combined with chemical foaming

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献 21

相关文章 15

编辑推荐

Metrics

本文评价

[1]	张义飞, 刘舫辰, 张双星, 杜文静. 超临界二氧化碳用印刷电路板式换热器性能分析[J]. 化工学报, 2023, 74(S1): 183-190.
[2]	宋瑞涛, 王派, 王云鹏, 李敏霞, 党超镔, 陈振国, 童欢, 周佳琦. 二氧化碳直接蒸发冰场排管内流动沸腾换热数值模拟分析[J]. 化工学报, 2023, 74(S1): 96-103.
[3]	程业品, 胡达清, 徐奕莎, 刘华彦, 卢晗锋, 崔国凯. 离子液体基低共熔溶剂在转化CO₂中的应用[J]. 化工学报, 2023, 74(9): 3640-3653.
[4]	杨菲菲, 赵世熙, 周维, 倪中海. Sn掺杂的In₂O₃催化CO₂选择性加氢制甲醇[J]. 化工学报, 2023, 74(8): 3366-3374.
[5]	洪瑞, 袁宝强, 杜文静. 垂直上升管内超临界二氧化碳传热恶化机理分析[J]. 化工学报, 2023, 74(8): 3309-3319.
[6]	张琦钰, 高利军, 苏宇航, 马晓博, 王翊丞, 张亚婷, 胡超. 碳基催化材料在电化学还原二氧化碳中的研究进展[J]. 化工学报, 2023, 74(7): 2753-2772.
[7]	毛磊, 刘冠章, 袁航, 张光亚. 可捕集CO₂的纳米碳酸酐酶粒子的高效制备及性能研究[J]. 化工学报, 2023, 74(6): 2589-2598.
[8]	姚晓宇, 沈俊, 李健, 李振兴, 康慧芳, 唐博, 董学强, 公茂琼. 流体气液临界参数测量方法研究进展[J]. 化工学报, 2023, 74(5): 1847-1861.
[9]	蔺彩虹, 王丽, 吴瑜, 刘鹏, 杨江峰, 李晋平. 沸石中碱金属阳离子对CO₂/N₂O吸附分离性能的影响[J]. 化工学报, 2023, 74(5): 2013-2021.
[10]	李晨曦, 刘永峰, 张璐, 刘海峰, 宋金瓯, 何旭. O₂/CO₂氛围下正庚烷的燃烧机理研究[J]. 化工学报, 2023, 74(5): 2157-2169.
[11]	王皓, 唐思扬, 钟山, 梁斌. MEA吸收CO₂富液解吸过程中固体颗粒表面的强化作用分析[J]. 化工学报, 2023, 74(4): 1539-1548.
[12]	朱兵国, 何吉祥, 徐进良, 彭斌. 冷却条件下渐扩/渐缩管内超临界压力二氧化碳的传热特性[J]. 化工学报, 2023, 74(3): 1062-1072.
[13]	何仁初, 张朝晖, 杨明磊, 王聪, 奚桢浩. 考虑碳排放因素的汽油调合在线优化[J]. 化工学报, 2023, 74(2): 818-829.
[14]	王煦清, 严圣林, 朱礼涛, 张希宝, 罗正鸿. 填料塔中有机胺吸收CO₂气液传质的研究进展[J]. 化工学报, 2023, 74(1): 237-256.
[15]	李沐紫, 贾国伟, 赵砚珑, 张鑫, 李建荣. 金属有机框架材料对非二氧化碳温室气体捕捉研究进展[J]. 化工学报, 2023, 74(1): 365-379.