Preparation and Rheological Property of Single- and Double-Grading Magnetorheological Composite Gel
摘 要
在以甲基硅油、明胶、琼脂胶为原料制备的复合胶状基体中添加了单一粒径(单级配)和两种粒径级配(双级配)的改性羰基铁粉, 通过真空减压制备了单级配和双级配磁流变复合胶, 研究了羰基铁粉粒径及其级配对该磁流变复合胶流变性能的影响。结果表明: 单级配磁流变复合胶的剪切强度随着羰基铁粉粒径的减小逐渐减小; 90%(质量分数, 下同)未球磨混合10%球磨羰基铁粉的双级配磁流变复合胶的剪切强度则随球磨时间的延长(羰基铁粉粒径的减小)先增后降, 球磨24 h后的剪切强度可达99.6 kPa, 相比于未球磨单级配磁流变复合胶, 其剪切强度提高了17.8 kPa。
Abstract
The modified carbonyl iron powders with single particle size (single-grading) and binary particle sizes (double-grading) were added in the composite gel, which was prepared by using methyl silicone oil, gelatin and agaropectin colloids as raw materials, and then the single- and double-grading magnetorheological composite gel (MRCG) was prepared by vacuum decompression. The effects of particle size and gradation of carbonyl iron powder on the rheological behaviors of the MRCG were studied. The results show that the shear strength of single-grading MRCG decreased gradually with the decrease of the carbonyl iron particle size. However, the shear strength of the double-grading MRCG with the gradation of 90wt% un-ball-milled and 10wt% ball-milled carbonyl iron powders first increased then decreased with the increase of milling time (the decrease of the carbonyl iron particle size) and reached 99.6 kPa after ball milling for 24 h, which was 17.8 kPa larger than that of un-ball-milled single-grading MRCG.
中图分类号 TB381 TM27 DOI 10.11973/jxgccl201610008
所属栏目 新材料 新工艺
基金项目 国家自然科学基金青年基金资助项目(51508237); 江苏省自然科学基金青年基金资助项目(BK20140560); 江苏大学高级专业人才科研启动基金资助项目(14JDG161); 江苏省普通高校研究生科研创新计划项目(B14042/B1305310); 常州市工业支撑计划(工业)(CE20150056)
收稿日期 2016/1/28
修改稿日期 2016/8/25
网络出版日期
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备注于国军(1981-), 男, 江苏盐城人, 讲师, 博士。
引用该论文: YU Guo-jun,GUO Fei,GE Jing. Preparation and Rheological Property of Single- and Double-Grading Magnetorheological Composite Gel[J]. Materials for mechancial engineering, 2016, 40(10): 34~37
于国军,郭 斐,葛 晶. 单级配和双级配磁流变复合胶的制备及其流变特性[J]. 机械工程材料, 2016, 40(10): 34~37
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参考文献
【1】SHIGA T, OKADA A, KURAUCHI T. Magnetroviscoelastic behavior of composite gels [J]. Journal of Applied Polymer Science, 1995, 58(4): 787-792.
【2】WILSON M J, FUCHS A, GORDANINEJAD F. Development and characterization of magnetorheological polymer gels[J]. Journal of Applied Polymer Science, 2002, 84(14): 2733-2742.
【3】FUCHS A, XIN M, GORDANINEJAD F, et al. Development and characterization of hydrocarbon polyol polyurethane and silicone magnetorheological polymeric gels[J]. Journal of Applied Polymer Science, 2004, 92(2): 1176-1182.
【4】FUCHS A, HU B, GORDANINEJAD F, et al. Synthesis and characterization of magnetorheological polyimide gels[J]. Journal of Applied Polymer Science, 2005, 98(6): 2402-2413.
【5】HU B, FUCHS A, HUSEYIN S, et al. Supramolecular magnetorheological polymer gels[J]. Journal of Applied Polymer Science, 2006, 100(3): 2464-2479.
【6】WEI B, GONG X L, JIANG W Q, et al. Study on the properties of magnetorheological gel based on polyurethane[J].Journal of Applied Polymer Science,2010,118(5): 2765-2771.
【7】MITSUMATA T, ABE N. Giant and reversible magneto-rheology of carrageenan/iron oxide magnetic gels[J]. Smart Materials and Structures,2011,20(12): 124003.
【8】KIM J E, CHOI H J. Magnetic carbonyl iron particle dispersed in viscoelastic fluid and its magnetorheological property [J]. IEEE Transactions on Magnetics,2011,47(10): 3173-3176.
【9】叶兴柱, 龚兴龙, 江万权,等. 新型磁流变胶的流变性能[J].机械工程材料, 2008, 32(7): 21-23.
【10】秦利军, 龚兴龙, 江万权,等. 铁粉含量对明胶基磁流变胶流变性能的影响[J].机械工程材料, 2010, 34(5): 8-11.
【11】汪建晓, 孟光. 磁流变液研究进展[J].航空学报, 2002,23(1): 6-12.
【12】张正勇, 张耀华, 虞承端,等. 磁流变液的特性研究[J].功能材料与器件学报, 2001, 7(4): 340-344.
【13】陈维清, 杜成斌, 万发学. 表面活性剂与触变剂对磁流变液沉降稳定性的影响[J].磁性材料及器件,2010,41(2): 55-58.
【14】JOLLY M R, CARLSON J D, MUNOZ B C. A model of the behaviour of magnetorheological materials[J]. Smart Materials and Structures, 1996, 5(5): 607-614.
【15】SHEN Y, GOLNARAGHI M F, HEPPLER G R. Experimental research and modeling of magnetorheological elastomers[J]. Journal of Intelligent Material Systems and Structures, 2004,15(1): 27-35.
【16】SUN H, PENG X H, GUO K Y, et al. Magnetorheological materials theory system and experimental investigation[J]. Materials Focus, 2013, 4(2): 283-287.
【2】WILSON M J, FUCHS A, GORDANINEJAD F. Development and characterization of magnetorheological polymer gels[J]. Journal of Applied Polymer Science, 2002, 84(14): 2733-2742.
【3】FUCHS A, XIN M, GORDANINEJAD F, et al. Development and characterization of hydrocarbon polyol polyurethane and silicone magnetorheological polymeric gels[J]. Journal of Applied Polymer Science, 2004, 92(2): 1176-1182.
【4】FUCHS A, HU B, GORDANINEJAD F, et al. Synthesis and characterization of magnetorheological polyimide gels[J]. Journal of Applied Polymer Science, 2005, 98(6): 2402-2413.
【5】HU B, FUCHS A, HUSEYIN S, et al. Supramolecular magnetorheological polymer gels[J]. Journal of Applied Polymer Science, 2006, 100(3): 2464-2479.
【6】WEI B, GONG X L, JIANG W Q, et al. Study on the properties of magnetorheological gel based on polyurethane[J].Journal of Applied Polymer Science,2010,118(5): 2765-2771.
【7】MITSUMATA T, ABE N. Giant and reversible magneto-rheology of carrageenan/iron oxide magnetic gels[J]. Smart Materials and Structures,2011,20(12): 124003.
【8】KIM J E, CHOI H J. Magnetic carbonyl iron particle dispersed in viscoelastic fluid and its magnetorheological property [J]. IEEE Transactions on Magnetics,2011,47(10): 3173-3176.
【9】叶兴柱, 龚兴龙, 江万权,等. 新型磁流变胶的流变性能[J].机械工程材料, 2008, 32(7): 21-23.
【10】秦利军, 龚兴龙, 江万权,等. 铁粉含量对明胶基磁流变胶流变性能的影响[J].机械工程材料, 2010, 34(5): 8-11.
【11】汪建晓, 孟光. 磁流变液研究进展[J].航空学报, 2002,23(1): 6-12.
【12】张正勇, 张耀华, 虞承端,等. 磁流变液的特性研究[J].功能材料与器件学报, 2001, 7(4): 340-344.
【13】陈维清, 杜成斌, 万发学. 表面活性剂与触变剂对磁流变液沉降稳定性的影响[J].磁性材料及器件,2010,41(2): 55-58.
【14】JOLLY M R, CARLSON J D, MUNOZ B C. A model of the behaviour of magnetorheological materials[J]. Smart Materials and Structures, 1996, 5(5): 607-614.
【15】SHEN Y, GOLNARAGHI M F, HEPPLER G R. Experimental research and modeling of magnetorheological elastomers[J]. Journal of Intelligent Material Systems and Structures, 2004,15(1): 27-35.
【16】SUN H, PENG X H, GUO K Y, et al. Magnetorheological materials theory system and experimental investigation[J]. Materials Focus, 2013, 4(2): 283-287.
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