PROGRESS IN RESEARCH OF THE CREEP BEHAVIOR OF RESIN COMPOSITES

Abstract

Abstract: Creep at room temperature is considered as a major limitation to the more extensive use of resin composites. This paper provided an overview of the progress in research of the creep behavior of resin composites. Effects of the creep of fiber and resin,temperature,external stress and the material properties on the creep of resin composites were investigated and the mechanism of creep was probed in this paper. The models popularly used to predicate the creep of resin composites and their valid ranges were analyzed,and the prospect of creep of resin composites was given finally.

Key words: resin composites, creep, stress-relaxation, viscoelastic

CLC Number:

TB332

LIU Peng-fei, ZHAO Qi-lin, WANG Jing-quan. PROGRESS IN RESEARCH OF THE CREEP BEHAVIOR OF RESIN COMPOSITES[J]. COMPOSITES SCIENCE AND ENGINEERING, 2013, 0(3): 109-117.

References

[1] 张少实等编著. 复合材料与粘弹性力学[M]. 北京: 机械工业出版社, 2005.
[2] G. C. Papanicolaou,A. G. Xepapadaki,K. Karagounaki,S. P. Zaoutsos Time and Temperature Effect on the Linear-Nonlinear Viscoelastic Transition Threshold of a Polymeric System[J]. Journal of Applied Polymer Science,2008, 108: 640-649.
[3] Jun Koyanagi,Genyakiyota,Takashi Kaniya and Hiroyuki Kawada. Prediction of creep rupture in unidirectional composite Creep rupture model with interfacial debonding and its propagation[J]. Composite Mater.,2004, 13: 3-4,199-213.
[4] Rui Miranda Guedes. Lifetime predictions of polymer matrix composites under constant or monotonic load[J]. Composites: Part A, 2006, 37: 703-715.
[5] R. M. Guedes. Creep and fatigue lifetime prediction of polymer matrix composites based on simple cumulative damage laws[J]. Composites: Part A,2008,39: 1716-1725.
[6] 杨挺青编著. 粘弹性力学[M]. 华中理工大学出版社,1992.
[7] 上海玻璃钢结构研究所. 玻璃钢结构设计[M]. 北京: 中国建筑工业出版社,1980.
[8] 张斌等. 橡胶减震器蠕变试验研究[J]. 噪声与振动控制,2008,56(4): 56-59.
[9] 付建农等. 高分子材料的一种应力松弛试验方法[J]. 工程塑料应用,2010,38(7): 57-59.
[10] T. MIYAKE,et al. Evaluation of time-dependent change in fiber stress profiles during long-term pull-out tests at constant loads using Raman spectroscopy[J]. Journal of Materials Science,2001,36: 5169-5175.
[11] Pegoretti A,Kolarik J,Peroni C,et al. Recycled poly(ethylene terephthalate)/layered silicate nanocomposites: morphology and tensible mechanical properties[J]. Polymer,2004,45(8 ): 2751-2759.
[12] Drozdov AD,Lejre A L H,Christiansen J D. Viscoelasticity,viscoplasticity, and creep failure of polypropylene/claynanocomposites[J]. Compos Sci Technol, 2009,69(15-16): 2596-2603.
[13] 王西昌,刘廷栋. 环氧树脂的蠕变行为———单环氧活性稀释剂对蠕变的影响[J]. 环氧树脂,1986,1: 11-16.
[14] 张忠,贾玉,高云,杨晶磊. 聚合物纳米复合材料蠕变性能研究进展[J]. 力学进展,2011,41(3): 266-278.
[15] 周祝林,万友生,杨云娣. 关于复合材料弯曲蠕变试验方法的研究[J]. 纤维复合材料,1999,(41),2: 41-44.
[16] 益小苏. 静应力下聚合物材料对温度变化的应变响应[J]. 高分子材料科学与工程, 1989,1: 27-31.
[17] 周祝林,杨云娣. 纤维增强塑料蠕变机理的初步探讨[M]. 上海玻璃钢研究院.
[18] 黄发荣,周燕等. 先进树脂基复合材料[M]. 北京: 化学工业出版社,2007.
[19] 陈聚文,潘婉莲,于俊荣,刘兆峰. UHMWPE 纤维蠕变性能及其数学模型拟合[J]. 合成纤维工业,2003, 26(6): 21-23.
[20] 樊愈波. 超高相对分子质量聚乙烯长丝蠕变性能的研究[J]. 合成纤维工业, 2011,6: 28-32.
[21] 陈聚文,潘婉莲,黎倩倩,胡祖明,于俊荣. 超高分子量聚乙烯纤维蠕变性能改性研究[J]. 合成纤维,2003,2: 15-17.
[22] Pomeroy,C. D,Creep of Engineering Materials London,1978.
[23] N. L. HANCOX and D. C. C. MINTY. The torsional creep of carbon fibre reinforced epoxide resins[J]. Journal of Materials Science, 1978,(13): 797-806.
[24] S. Bruckmeier and J. Wellnitz. Flexural Creeping Analysis of Polyurethane Composites Produced by an Innovative Pultrusion Process, 2011.
[25] S. SOMIYA,K. YAMADA and T. SAKAI. Study on Crystallinity Dependency of Creep Deformation on GFRTP of Polyoxythlene (POM) [C]. in Conference Proceedings of the Society for Experimental Mechanics Series,2011: The Society for Experimental Mechanics,Inc.
[26] 关长斌,赵玉成,陆文明. CG 混合纤维/橡胶复合材料的黏弹性[J]. 复合材料学报,2008,25(1): 75-79.
[27] Chandra Viswanathan. Individual and interactive influence of temperature, stress,physical aging and moisture on creep, creep rupture and fracture of epoxy matrix and its composite[D]. The University of Manitoba,Canada,2001.
[28] KISHORE KANTI BISWAS,SATOSHI SOMIYA and JUN ENDO. Creep Behavior of Metal Fiber-PPE Composites and Effect of Test Surroundings[J]. Mechanics of Time-Dependent Materials,1999, (3): 85-101.
[29] Saurabh Batra. Creep rupture and life prediction of polymer composites[D]. College of Engineering and Mineral Resources at West Virginia University,2009.
[30] Mallick P. K. Fiber-Reinforced Composites: Materials,Manufacturing and Design[J]. Marcel Dekker Inc., New York, USA,2008.
[31] 樊建平,彭立华,沈为. 正交玻璃布/环氧复合材料蠕变损伤实验研究[J]. 复合材料学报, 1995, 12(4): 84-89.
[32] 周祝林. 玻璃钢II 型梁的结构试验与分析[J]. 玻璃钢,1997,4: 1-8.
[33] 沈叔曾. 玻璃钢的蠕变性能[J]. 上海力学, 1982,2: 71-78.
[34] R. Mohan and D. F. Adams. Nonlinear creep-recovery response of a polymer matrix and its composites[J]. 1985,(7): 260-269.
[35] Ayman Soliman Mosallam. Short and Long-Term Behavior of a Pultruded Fiber Reinforced Plastic Frame[D]. The Catholic University of America.
[36] 江冰,李兴丹,吴代华. 平面应力作用下复合材料的蠕变分析[J]. 复合材料学报,1993, 10(2): 7-12.
[37] Strengthening of Reinforce Concrete Structures[M] Strengthening of Reinforce Concrete Structures[M]. Published by Woodhead Publishing Limited,1999. 183-203.
[38] J. C. Haplin. Introduction to viscoelasticity[M]. Technomic Publishing Co. ., 1968.
[39] R. A. Schapery. Stress Analysis of Viscoelastic Composite Materials[M]. Technomic Publishing Co. .,1968.
[40] J. V. Suvorova. The Influence of Time and Temperature on the Reinforced Plastic Strength[J]. vol. 3 of Handbooks of Composites, Elsevier Applied Science Publishers,Ltd.,England,1985.
[41] D. A. Dillard. Viscoelastic Behavor of Laminated Composite Materials[M]. Elsevier Applied Science Publishers,Ltd.,England, 1991.
[42] R. A. Schapery. On nonlinear viscoelastic constitutive equations for composite materials[C]. The Society for Experimental Mechanics, Vol. 2 of Proceedings of the 7th International Congress on Experimental Mechanics,1992.
[43] Maskimov R. D.,Sokolov E. A.,Mochalov V. P. Effect of Temperature and Moisture on Creep of Polymeric Materials: One-Dimensional Extension Under Stationary Temperature-Moisture Conditions[J]. Mechanics of Composite Materials,1975,11(3): 334-339.
[44] Schapery R A. Workshop on a continuum approach to damage and life prediction[J]. National Science Federation,1980: 119-133.
[45] G. C. Papanicolaou·A. G. Xepapadaki·S. Pavlopoulou·S. P. Zaoutsos. On the investigation of the stress threshold from linear to nonlinear viscoelastic behaviour of polymer-matrix particulate composites[J]. Mech Time-Depend Mater,2009,13: 261-274.
[46] A. GRÉGORY,D. VOGEL,PH. BÉGUELIN,R. GENSLER and H. H. KAUSCH,M. JAEGER and A. VAN BUREN. A Viscoelastic Analysis of the Creep Behaviour of a Chopped Strand Mat E-Glass Fibre Reinforced Vinylester Resin[J]. Mechanics of Time-Dependent Materials, 1999,3: 71-84.
[47] R. A. SCHAPERY. Nonlinear Viscoelastic and Viscoplastic Constitutive Equations Based on Thermodynamics[J]. Mechanics of TimeDependent,1997,(1): 209-240.
[48] Findley. Mechanism and Mechanics of Creep of Plastics[J]. Society of Plastic Engineering, 1960, 51: 57-65.
[49] David W. Scott ＆ Abdul-Hamid Zureick. Compression creep of a pultruded E-glass/vinylester composite[J]. Composites Science and Technology, 1998, 58: 1361-1369.
[50] Ghyslaine McClure,l Member,ASCE,and Yaghoub Mohammadi. Compression creep of a pultruded E-glass-reinforced-plastic angles[J]. Journal of Materials in Civil Engineering, 1995: 269-276.
[51] C. T. Sun and J. L. Chen. A micromechanical model for plastic behavior of fibrous composites[J]. Comp. Sci. Tech.,1991, 40: 115.
[52] C. T. Sun and I. Chang. Modeling of elastic-plastic behavior of ldf and continuous fiber reinforced as-4/peek composites[J]. Comp. Sci. Tech.,1992,43: 339.
[53] D. Robertson and S. Mall. Micromechanical analysis for thermoviscoplastic behavior of unidirectional fibrous composites[J]. Comp. Sci. Tech.,1994,50: 483.
[54] T. S. Gates. Effect of elevated temperature on the viscoplastic modeling of graphite-polymeric composites,in High Temperature and Enviromental Effects on Polymeric Composites[J]. T. Gold. Ed.,1993,1174: 201-221.
[55] T. S. Gates. Matrix dominated stress-strain behavior in polymeric composites[J]. in Composites Materials: Testing and Design,1993,11: 177.
[56] Masayuki Nakada,et al. Prediction of long-term viscoelastic behavior of amorphous resin based on the time-temperature superposition principle[J]. Mech Time-Depend Mater,2011(15): 309-316.
[57] M. K. MCMURRAY and SHIGEO AMAGI. The effect of time and temperature on flexural creep and fatigue strength of a silica particle filled epoxy resin[J]. Journal of Materials Science,1999,34: 5927-5936.
[58] Takenobu Sakai,Satoshi Somiya. Analysis of creep behavior in thermoplastics based on visco-elastic theory[J]. Mechanics of Time-Dependent Materials,2011,15: 293-308.