综述了常用于超导磁体浸渍的环氧树脂及其增韧改性的研究进展,并简要概述了预测环氧树脂及其复合材料性能的方法及难点,提出了超导磁体浸渍用环氧树脂增韧改性的发展方向.
The research progresses of epoxy resin used in superconducting magnet impregnation and its toughening modification were reviewed. The methods of predicting the properties of epoxy resin and its composites and difficulties were summarized briefly. The development direction of toughening modifica-tion of epoxy resin for superconducting magnet impregnation was proposed.
参考文献
| [1] | Fruth B.;Niemeyer L..The importance of statistical characteristics of partial discharge data[J].IEEE transactions on electrical insulation. (Institute of Electrical and Electronics Engineers. Electrical Insulation Group). New York.,19921(1):60-69. |
| [2] | 崔益民,潘皖江,武松涛,万元熙.大型超导磁体低温胶的研究分析[C].第五届全国低温工程大会论文集,2001:83-86. |
| [3] | Baldan C.A.;Shigue C.Y.;Filho E.R..Development of a new epoxy resin for superconducting magnetimpregnation[J].IEEE Transactions on Applied Superconductivity: A Publication of the IEEE Superconductivity Committee,20001(1):1347-1349. |
| [4] | Iwamoto A.;Nishijima S..Study of impregnating materials for stable superconducting magnets[J].IEEE Transactions on Applied Superconductivity: A Publication of the IEEE Superconductivity Committee,19931(1):269-272. |
| [5] | 吴云龙,王文虎,熊玉峰,赵伟栋,耿东兵.纳米SiO<,2>增韧对碳纤维/环氧复合材料低温力学性能的影响[C].复合材料—生命、环境与高技术(第12届全国复合材料学术会议:论文专辑),2002:225-228. |
| [6] | C.J. Huang;S.Y. Fu;Y.H. Zhang.Cryogenic properties of SiO_2/epoxy nanocomposites[J].Cryogenics,20056(6):450-454. |
| [7] | Hyun Ju Oh;Song Hee Han;Hak Yong Kim.The influence of the core-shell structured meta-aramid/epoxy nanofiber mats on interfacial bonding strength and the mechanical properties of epoxy adhesives at cryogenic environment[J].Journal of Adhesion Science and Technology: The International Journal of Theoredtical and Basic Aspects of Adhesion Science and Its Applications in All Areas of Technology,201410(10):950-962. |
| [8] | Harani H.;Bakar M.;Fellahi S..Toughening of epoxy resin using synthesized polyurethane prepolymer based on hydroxyl-terminated polyesters[J].Journal of Applied Polymer Science,199813(13):2603-2618. |
| [9] | K. P. O. Mahesh;M. Alagar;S. Ananda Kumar.Mechanical, thermal and morphological behavior of bismaleimide modified polyurethane-epoxy IPN matrices[J].Polymers for advanced technologies,20032(2):137-146. |
| [10] | Yu-xin He;Qi Li;Tapas Kuila;Nam Hoon Kim;Tongwu Jiang;Kin-tak Lau;Joong Hee Lee.Micro-crack behavior of carbon fiber reinforced thermoplastic modified epoxy composites for cryogenic applications[J].Composites, Part B. Engineering,20131(1):533-539. |
| [11] | 杨果;潘勤彦;潘皖江;付绍云.柔性胺改性剂对环氧树脂力学性能的影响[J].材料工程,2006(5):16-20,24. |
| [12] | Yang, JP;Chen, ZK;Yang, G;Fu, SY;Ye, L.Simultaneous improvements in the cryogenic tensile strength, ductility and impact strength of epoxy resins by a hyperbranched polymer[J].Polymer,200813/14(13/14):3168-3175. |
| [13] | T. Ueki;S. Nishijima;Y. Izumi.Designing of epoxy resin systems for cryogenic use[J].Cryogenics,20052(2):141-148. |
| [14] | Myung-Gon Kim;Joong-Sik Hong;Sang-Guk Kang.Enhancement of the crack growth resistance of a carbon/epoxy composite by adding multi-walled carbon nanotubes at a cryogenic temperature[J].Composites, Part A. Applied science and manufacturing,20084(4):647-654. |
| [15] | Myung-Gon Kim;Jin-Bum Moon;Chun-Gon Kim.Effect of CNT functionalization on crack resistance of a carbon/epoxy composite at a cryogenic temperature[J].Composites. Part A, Applied science and manufacturing,20129(9):1620-1627. |
| [16] | Thostenson ET.;Chou TW..On the elastic properties of carbon nanotube-based composites: modelling and characterization[J].Journal of Physics, D. Applied Physics: A Europhysics Journal,20035(5):573-582. |
| [17] | Chunyu Li;Tsu-Wei Chou.Elastic moduli of multi-walled carbon nanotubes and the effect of van der Waals forces[J].Composites science and technology,200311(11):1517-1524. |
| [18] | D. Qian;E. C. Dickey;R. Andrews.Load transfer and deformation mechanisms in carbon nanotube-polystyrene composites[J].Applied physics letters,200020(20):2868-2870. |
| [19] | F.H. GOJNY;M.H.G. WICHMANN;U. KOPKE.Carbon nanotube-reinforced epoxy-composites: enhanced stiffness and fracture toughness at low nanotube content[J].Composites science and technology,200415(15):2363-2371. |
| [20] | Byung Chul Kim;Sang Wook Park;Dai Gil Lee.Fracture toughness of the nano-particle reinforced epoxy composite[J].Composite structures,20081/3(1/3):69-77. |
| [21] | Feng, Qing-Ping;Deng, Yin-Hu;Xiao, Hong-Mei;Liu, Yu;Qu, Cheng-Bing;Zhao, Yang;Fu, Shao-Yun.Enhanced cryogenic interfacial normal bond property between carbon fibers and epoxy matrix by carbon nanotubes[J].Composites science and technology,2014Nov.(Nov.):59-65. |
| [22] | M.Deng;V.B.C.Tan;T.E.Tay.Atomistic modeling:interfacial diffusion and adhesion of polycarbonate and silanes[J].Polymer: The International Journal for the Science and Technology of Polymers,200418(18):6399-6402. |
| [23] | Fan HB;Yuen MMF.Material properties of the cross-linked epoxy resin compound predicted by molecular dynamics simulation[J].Polymer: The International Journal for the Science and Technology of Polymers,20077(7):2174-2178. |
| [24] | Yarovsky I.;Evans E..Computer simulation of structure and properties of crosslinked polymers: application to epoxy resins[J].Polymer: The International Journal for the Science and Technology of Polymers,20023(3):963-969. |
| [25] | Gou JH;Minaie B;Wang B;Liang ZY;Zhang C.Computational and experimental study of interfacial bonding of single-walled nanotube reinforced composites[J].Computational Materials Science,20043/4(3/4):225-236. |
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