TOUGHENED SEMICRYSTALLINE ENGINEERING POLYMERS - MORPHOLOGY, IMPACT RESISTANCE, AND FRACTURE MECHANISMS

被引:0
|
作者
FLEXMAN, EA [1 ]
机构
[1] DUPONT CO INC,EXPTL STN,DUPONT POLYMERS,WILMINGTON,DE 19880
来源
ADVANCES IN CHEMISTRY SERIES | 1993年 / 233期
关键词
D O I
暂无
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
Major factors that contribute to maximized impact resistance of semicrystalline engineering polymers include increased matrix molecular weight, minimal rubber glass-transition temperature, and optimal rubber-particle size, which depends on matrix type. Additional constraints are posed by the limitations of available materials and commercial requirements. Expanding the understanding of impact-modified crystalline engineering polymers will further extend their property ranges and utility. This chapter describes the phenomenology of certain factors, illustrates a new technique to measure rubber particle size, and contrasts the fracture mechanisms of poly(butylene terephthalate), nylon 66, and polyacetal.
引用
收藏
页码:79 / 104
页数:26
相关论文
共 50 条
  • [41] AN EVALUATION OF THE FRACTURE-RESISTANCE OF ENGINEERING MATERIALS FROM THE FRACTURE SURFACE-MORPHOLOGY
    ALCALA, J
    LEDEZMA, M
    FATIGUE & FRACTURE OF ENGINEERING MATERIALS & STRUCTURES, 1992, 15 (04) : 377 - 390
  • [42] MECHANICS AND MECHANISMS OF IMPACT FRACTURE IN SEMI-DUCTILE POLYMERS
    KHANH, TV
    DECHARENTENAY, FX
    POLYMER ENGINEERING AND SCIENCE, 1985, 25 (13): : 841 - 850
  • [43] Micromechanical deformation processes in toughened and particle-filled semicrystalline polymers: Part 1. Characterization of deformation processes in dependence on phase morphology
    Kim, GM
    Michler, GH
    POLYMER, 1998, 39 (23) : 5689 - 5697
  • [44] Micromechanical deformation processes in toughened and particle-filled semicrystalline polymers: Part 1. Characterization of deformation processes in dependence on phase morphology
    Martin-Luther-Univ Halle-Wittenberg, Merseburg, Germany
    Polymer, 23 (5689-5697):
  • [45] Effect of the crystallinity and morphology on the microcellular foam structure of semicrystalline polymers
    Doroudiani, S
    Park, CB
    Kortschot, MT
    POLYMER ENGINEERING AND SCIENCE, 1996, 36 (21): : 2645 - 2662
  • [46] Effect of the crystallinity and morphology on the microcellular foam structure of semicrystalline polymers
    Doroudiani, Saeed
    Park, Chul B.
    Kortschot, Mark T.
    Polymer Engineering and Science, 36 (21): : 2645 - 2662
  • [47] Relating Molecular Morphology to Charge Mobility in Semicrystalline Conjugated Polymers
    Jones, M. L.
    Huang, D. M.
    Chakrabarti, B.
    Groves, C.
    JOURNAL OF PHYSICAL CHEMISTRY C, 2016, 120 (08): : 4240 - 4250
  • [48] Fracture behaviour and morphology of polymers
    Seidler, S
    Grellmann, W
    ADVANCES IN FRACTURE RESEARCH, VOLS 1-6, 1997, : 1021 - 1027
  • [49] Investigation on fracture behavior and mechanisms of DGEBF toughened by CTBN
    Wang, Lulu
    Tan, Yefa
    Wang, Haitao
    Gao, Li
    Xiao, Chufan
    CHEMICAL PHYSICS LETTERS, 2018, 699 : 14 - 21
  • [50] Mode I fracture modeling of elastomer-toughened polymers
    Tohdoh, M
    Chaturvedi, SK
    Sierakowski, RL
    INTERNATIONAL JOURNAL OF FRACTURE, 1996, 75 (04) : 285 - 306
12345