Waveform impact on thermo-mechanical fatigue crack growth of a non-crystallizing rubber: Experimental observation and numerical simulation

被引：7

作者：

Liu, Chen ^{[1
,2
]}

Gu, Bochao ^{[2
]}

Wang, Feng ^{[3
]}

Lu, Bo ^{[3
]}

Liu, Fengzhu ^{[3
]}

Liu, Jun ^{[1
]}

Lu, Yonglai ^{[1
,2
]}

Zhang, Liqun ^{[1
,2
]}

Li, Fanzhu ^{[1
,2
]}

机构：

[1] Beijing Univ Chem Technol, State Key Lab Organ Inorgan Composites, Beijing 100029, Peoples R China

[2] Beijing Univ Chem Technol, Key Lab Beijing City Preparat & Proc Novel Polymer, Beijing 100029, Peoples R China

[3] Shandong Linglong Tyre Co LTD, Yantai 265406, Shandong, Peoples R China

来源：

COMPOSITES PART B-ENGINEERING | 2023年 / 255卷

基金：

中国国家自然科学基金;

关键词：

Rubber; Thermo-mechanical; Fatigue crack growth; Pulse waveform; Finite element analysis; NATURAL-RUBBER; HEAT BUILDUP; TEMPERATURE; BEHAVIOR; PROPAGATION; MECHANISM; LIFE; TIP;

D O I：

10.1016/j.compositesb.2023.110604

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

Compared with the sine waveform, the pulse waveform load is more in line with the real service condition of tire. It was investigated the effect of two pulse waveform loads on the thermo-mechanical fatigue crack growth rate (FCGR) of filled styrene-butadiene rubber and explained the underlying mechanism. The fatigue test and infrared thermal imaging test revealed that the shorter the pulse excitation time, the higher the heat build-up and the faster the FCGR. The underlying mechanism was explained by an established thermo-mechanical coupling method, and it was pointed out that the faster FCGR under high-frequency loading condition resulted from higher hysteresis energy rather than higher strain energy. The Parallel Rheological Framework model could not explain this phenomenon well.

引用

页数：9

共 44 条

[1] Energy release rate of small cracks in hyperelastic materials
Ait-Bachir, M.
Mars, W. V.
Verron, E.
[J]. INTERNATIONAL JOURNAL OF NON-LINEAR MECHANICS, 2012, 47 (04) : 22 - 29
[2] CRACK GROWTH BEHAVIOR OF STYRENE-BUTADIENE RUBBER, NATURAL RUBBER, AND POLYBUTADIENE RUBBER COMPOUNDS: COMPARISON OF PURE-SHEAR VERSUS STRIP TENSILE TEST
Andreini, G.
Straffi, P.
Cotugno, S.
Gallone, G.
Polacco, G.
[J]. RUBBER CHEMISTRY AND TECHNOLOGY, 2013, 86 (01): : 132 - 145
[3] Configurational Mechanics and Critical Plane Approach: Concept and application to fatigue failure analysis of rubberlike materials
Andriyana, A.
Saintier, N.
Verron, E.
[J]. INTERNATIONAL JOURNAL OF FATIGUE, 2010, 32 (10) : 1627 - 1638
[4] Mixed-mode fracture in EPDM/SBR/nanoclay rubber composites: An experimental and theoretical investigation
Ayatollahi, M. R.
Heydari-Meybodi, M.
Berto, F.
Yahya, M. Yazid
[J]. COMPOSITES PART B-ENGINEERING, 2019, 176
[5] Kinetics of Strain-Induced Crystallization in Natural Rubber Studied by WAXD: Dynamic and Impact Tensile Experiments
Bruening, Karsten
Schneider, Konrad
Roth, Stephan V.
Heinrich, Gert
[J]. MACROMOLECULES, 2012, 45 (19) : 7914 - 7919
[6] Modeling of the thermomechanical behavior of rubbers during fatigue tests from infrared measurements
Cruanes, C.
Deffarges, M-P
Lacroix, F.
Meo, S.
[J]. INTERNATIONAL JOURNAL OF FATIGUE, 2019, 126 : 231 - 240
[7] Microfocused Beam SAXS and WAXS Mapping at the Crack Tip and Fatigue Crack Propagation in Natural Rubber
Demassieux, Quentin
Berghezan, Daniel
Creton, Costantino
[J]. FATIGUE CRACK GROWTH IN RUBBER MATERIALS: EXPERIMENTS AND MODELLING, 2021, 286 : 467 - 491
[8] New numerical stress solutions to calibrate hyper-visco-pseudo-elastic material models effectively
Fazekas, Balint
Goda, Tibor J.
[J]. MATERIALS & DESIGN, 2020, 194 (194)
[9] Assessment of strain-induced cavitation of silica-filled styrene-butadiene rubber nanocomposite by synchrotron radiation tomography
Federico, Carlos Eloy
Fleming, Yves
Kotecky, Ondrej
Rommel, Robert
Philippe, Adrian-Marie
Westermann, Stephan
Addiego, Frederic
[J]. COMPOSITES PART B-ENGINEERING, 2022, 247
[10] Futamura S., 2004, Tire Sci Technol, V32, P56

← 1 2 3 4 5 →