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Journal articles on the topic 'Fatigue (Materials)'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 August 2024

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1

Shiozawa, Daiki, Tsuyoshi Inagawa, Takaya Washio, and Takahide Sakagami. "OS8-2 Fatigue Limit Estimation Based on Dissipated Energy for Pre-Strained Materials(Fatigue monitoring,OS8 Fatigue and fracture mechanics,STRENGTH OF MATERIALS)." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2015.14 (2015): 112. http://dx.doi.org/10.1299/jsmeatem.2015.14.112.

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2

Qiu, Xingwen, Haishan Yin, and Qicheng Xing. "Research Progress on Fatigue Life of Rubber Materials." Polymers 14, no. 21 (October 28, 2022): 4592. http://dx.doi.org/10.3390/polym14214592.

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Rubber products will be fatigued when subjected to alternating loads, and working in harsh environments will worsen the fatigue performance, which will directly affect the service life of such products. Environmental factors have a great influence on rubber materials, including temperature, humidity, ozone, etc., all of which will affect rubber’s properties and among which temperature is the most important. Different rubber materials have different sensitivity to the environment, and at the same time, their own structures are different, and their bonding degree with fillers is also different, so their fatigue lives are also different. Therefore, there are generally two methods to study the fatigue life of rubber materials, namely the crack initiation method and the crack propagation method. In this paper, the research status of rubber fatigue is summarized from three aspects: research methods of rubber fatigue, factors affecting fatigue life and crack section. The effects of mechanical conditions, rubber composition and environmental factors on rubber fatigue are expounded in detail. The section of rubber fatigue cracking is expounded from macroscopic and microscopic perspectives, and a future development direction is given in order to provide reference for the research and analysis of rubber fatigue and rubber service life maximization.
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3

JONO, Masahiro. "Fatigue of Advanced Materials. Fundamentals of Fatigue and Advanced Materials." Journal of the Society of Materials Science, Japan 43, no. 488 (1994): 587–93. http://dx.doi.org/10.2472/jsms.43.587.

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4

TOKAJI, Keiro. "Fatigue of Advanced Materials. 2. Fatigue of Advanced Metallic Materials." Journal of the Society of Materials Science, Japan 43, no. 489 (1994): 710–16. http://dx.doi.org/10.2472/jsms.43.710.

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5

Kobayashi, Yukiyoshi, Yoshinao Kishimoto, and Toshihisa Ohtsuka. "OS8-9 Simple Method for Fatigue Life Prediction Based on Fatigue Mechanism(Fatigue life prediction,OS8 Fatigue and fracture mechanics,STRENGTH OF MATERIALS)." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2015.14 (2015): 119. http://dx.doi.org/10.1299/jsmeatem.2015.14.119.

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6

Krejčí, Pavel. "Modelling of singularities in elastoplastic materials with fatigue." Applications of Mathematics 39, no. 2 (1994): 137–60. http://dx.doi.org/10.21136/am.1994.134250.

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7

Tanaka, Keisuke, and Hirohisa Kimachi. "OS8-37 Fatigue Properties of Nano-Crystalline Nickel Films Made by Electrodeposition(Advanced materials,OS8 Fatigue and fracture mechanics,STRENGTH OF MATERIALS)." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2015.14 (2015): 147. http://dx.doi.org/10.1299/jsmeatem.2015.14.147.

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8

Okada, Kohei, Toshihiro Omori, Tatsuro Morita, and Hideaki Maeda. "OS8-19 Fretting Fatigue Strength of Various Stainless Steel(Environmental effect on fatigue,OS8 Fatigue and fracture mechanics,STRENGTH OF MATERIALS)." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2015.14 (2015): 129. http://dx.doi.org/10.1299/jsmeatem.2015.14.129.

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9

Klesnil, M., and P. Lukás. "Fatigue of Metallic Materials." International Journal of Materials Research 84, no. 4 (April 1, 1993): 291. http://dx.doi.org/10.1515/ijmr-1993-840416.

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10

Horibe, Susumu. "Fatigue in Ceramic Materials." Materia Japan 36, no. 9 (1997): 889–91. http://dx.doi.org/10.2320/materia.36.889.

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11

KUMAI, Shinji. "Fatigue in metallic materials." Journal of Japan Institute of Light Metals 47, no. 3 (1997): 182–91. http://dx.doi.org/10.2464/jilm.47.182.

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12

Bonnand, Vincent, Didier Pacou, and Frauck Gallerneau. "Fatigue of anisotropic materials." Materials Testing 46, no. 6 (June 2004): 301–5. http://dx.doi.org/10.3139/120.100589.

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13

Curtis, P. T., and G. Dorey. "Fatigue of Composite Materials." Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering 203, no. 1 (January 1989): 31–37. http://dx.doi.org/10.1243/pime_proc_1989_203_051_01.

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This paper reviews the area of fatigue of composite materials, particularly fibre-reinforced plastics, used in aerospace and other industries. The review concentrates on carbon, glass and aramid reinforcing fibres and epoxy resin as a matrix material. Mention is also made of newer matrices such as those based on thermoplastics.
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14

Baran, G., K. Boberick, and J. McCool. "Fatigue of Restorative Materials." Critical Reviews in Oral Biology & Medicine 12, no. 4 (July 2001): 350–60. http://dx.doi.org/10.1177/10454411010120040501.

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Failure due to fatigue manifests itself in dental prostheses and restorations as wear, fractured margins, delaminated coatings, and bulk fracture. Mechanisms responsible for fatigue-induced failure depend on material ductility: Brittle materials are susceptible to catastrophic failure, while ductile materials utilize their plasticity to reduce stress concentrations at the crack tip. Because of the expense associated with the replacement of failed restorations, there is a strong desire on the part of basic scientists and clinicians to evaluate the resistance of materials to fatigue in laboratory tests. Test variables include fatigue-loading mode and test environment, such as soaking in water. The outcome variable is typically fracture strength, and these data typically fit the Weibull distribution. Analysis of fatigue data permits predictive inferences to be made concerning the survival of structures fabricated from restorative materials under specified loading conditions. Although many dental-restorative materials are routinely evaluated, only limited use has been made of fatigue data collected in vitro: Wear of materials and the survival of porcelain restorations has been modeled by both fracture mechanics and probabilistic approaches. A need still exists for a clinical failure database and for the development of valid test methods for the evaluation of composite materials.
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15

Harris, Bryan. "Fatigue of composite materials." Composites Science and Technology 31, no. 2 (January 1988): 160. http://dx.doi.org/10.1016/0266-3538(88)90090-5.

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16

Harris, Bryan. "Fatigue of composite materials." Composites Science and Technology 49, no. 1 (January 1993): 105. http://dx.doi.org/10.1016/0266-3538(93)90026-d.

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17

Knowles, Kevin. "Fatigue of metallic materials." International Journal of Fatigue 15, no. 6 (November 1993): 526. http://dx.doi.org/10.1016/0142-1123(93)90268-u.

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18

Huang, J. S., and J. Y. Lin. "Fatigue of cellular materials." Acta Materialia 44, no. 1 (January 1996): 289–96. http://dx.doi.org/10.1016/1359-6454(95)00170-4.

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19

Baker, A. A. "Fatigue of composite materials." Composites 19, no. 2 (March 1988): 169. http://dx.doi.org/10.1016/0010-4361(88)90734-3.

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20

HAYASHI, Kozaburo. "Fatigue of Advanced Materials. 7. Fatigue of Biomaterials." Journal of the Society of Materials Science, Japan 43, no. 494 (1994): 1502–6. http://dx.doi.org/10.2472/jsms.43.1502.

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21

Pejkowski, Łukasz, Dariusz Skibicki, and Jan Seyda. "Fatigue behaviour of selected materials under multiaxial asynchronous loadings." MATEC Web of Conferences 300 (2019): 15006. http://dx.doi.org/10.1051/matecconf/201930015006.

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Four types of materials: PA38 aluminium alloy, E235 steel, E355 steel and 1.4301 austenitic steel were subjected to low-cycle multiaxial loadings. All tests were strain-controlled and typical, thin-walled, hollow specimens were used. Various synchronous and asynchronous loadings were applied. The analysis of experimental results involved: cyclic stress-strain response, fatigue life and observation of microcracks behaviour on the surfaces of fatigued specimens. Obtained results indicate that the difference in the strain components frequency of the asynchronous loadings has a significant influence on the fatigue behaviour of the materials.
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22

Pokhyl, Y. A., L. F. Yakovenko, E. N. Aleksenko, and V. A. Lototskaya. "Proposals for the ISS: «Penta-Fatigue» - Experiment Influence of space factors on fatigue fractureresistance of structural materials." Kosmìčna nauka ì tehnologìâ 6, no. 4 (July 30, 2000): 45. http://dx.doi.org/10.15407/knit2000.04.045.

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23

Mironov, V., O. Lukashuk, and D. Vichuzhanin. "Method for Describing Fatigue Processes in Structural Materials." Solid State Phenomena 265 (September 2017): 815–20. http://dx.doi.org/10.4028/www.scientific.net/ssp.265.815.

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The article studies one of the methods for phenomenological description of fatigue processes in structurally-inhomogeneous structural materials. The initial statement about the interrelationship between the static and cyclic material properties is investigated using the complete stress-strain curves or diagrams method (CSSD). Based on the analysis of the mathematic modeling results, the interrelationship is predicted to exist between the highly-localized fatigue process in a structurally-inhomogeneous material and the degradation of a static CSSD for a macroscopic specimen. It is noted that the conditions under which the specimen fails in a testing machine are similar to the ones for the material in a construction. Then the results are given for the direct experimental testing of the model predictions, illustrated with the examples of cyclic degradation of several structural materials. The tests on multiple-cycle fatigued specimens reveal degradation of several mechanical properties. The justification for the selection of the available plasticity of a material as a parameter representative of the fatigue process is given. The authors describe a few examples of building one-parameter cyclic degradation models for steels and some prospects of using the complete strain-stress diagrams for various purposes.
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24

Schonbauer, Bernd M., Keiji Yanase, Andrea Perlega, Stefanie E. Stanzl-Tschegg, and Masahiro Endo. "OS8-27 Very High Cycle Fatigue Properties of 17-4PH Stainless Steel(Fatigue and fracture,OS8 Fatigue and fracture mechanics,STRENGTH OF MATERIALS)." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2015.14 (2015): 137. http://dx.doi.org/10.1299/jsmeatem.2015.14.137.

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25

Petersen, DR, R. Bagheri, and GA Miller. "Fatigue and Corrosion Fatigue of Beryllium-Copper Spring Materials." Journal of Testing and Evaluation 21, no. 2 (1993): 101. http://dx.doi.org/10.1520/jte11751j.

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26

BAGHERI, R., and G. MILLER. "Fatigue and corrosion fatigue of beryllium-copper spring materials." International Journal of Fatigue 16, no. 3 (April 1994): 233. http://dx.doi.org/10.1016/0142-1123(94)90065-5.

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27

Wang, Rongguang, Naoki Morihiro, Yoshiko Shinhara, and Mitsuo Kido. "OS11W0021 Fatigue behavior of thermally sprayed materials at high temperature." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2003.2 (2003): _OS11W0021. http://dx.doi.org/10.1299/jsmeatem.2003.2._os11w0021.

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28

Ishii, Hitoshi, Yohei Taguchi, Kazuo Ishii, and Hirofumi Akagi. "OS11W0239 Ultrasonic bending fatigue testing method for thin sheet materials." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2003.2 (2003): _OS11W0239. http://dx.doi.org/10.1299/jsmeatem.2003.2._os11w0239.

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29

Omori, Toshihiro, Tatsuro Morita, Kohei Okada, and Hideaki Maeda. "OS8-20 Estimation of Fretting Fatigue Strength by Using Elastic-Plastic FEA(Environmental effect on fatigue,OS8 Fatigue and fracture mechanics,STRENGTH OF MATERIALS)." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2015.14 (2015): 130. http://dx.doi.org/10.1299/jsmeatem.2015.14.130.

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30

Altenberger, I., Ivan Nikitin, P. Juijerm, and Berthold Scholtes. "Residual Stress Stability in High Temperature Fatigued Mechanically Surface Treated Metallic Materials." Materials Science Forum 524-525 (September 2006): 57–62. http://dx.doi.org/10.4028/www.scientific.net/msf.524-525.57.

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Different classes of metallic materials (aluminum alloys, steels, titanium alloys) were mechanically surface treated by deep rolling and laser shock peening and isothermally fatigued at elevated temperature under stress control. The fatigue tests were interrupted after different numbers of cycles for several stress amplitudes and residual stresses and FWHM-values were measured by X-ray diffraction methods at the surface and as a function of depth. The results summarize the response of the surface treatment induced residual stress profiles to thermomechanical loading conditions in the High Cycle Fatigue (HCF)- as well as in the Low Cycle Fatigue (LCF) regime. The effects of stress amplitude, plastic strain amplitude, temperature and frequency are addressed in detail and discussed. The results indicate that residual stress relaxation during high temperature fatigue can be predicted for sufficiently simplified loading conditions and that thermal and mechanical effects can be separated from each other. A plastic strain based approach appears to be most suitable to describe residual stress relaxation. Frequency effects were found to be not very pronounced in the frequency range investigated.
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31

HORIBE, Susumu. "Cyclic Fatigue of Ceramic Materials." Tetsu-to-Hagane 75, no. 4 (1989): 578–86. http://dx.doi.org/10.2355/tetsutohagane1955.75.4_578.

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32

Toda, Hiroyuki, and Masakazu Kobayashi. "Thermal fatigue fracture of materials." Journal of Japan Institute of Light Metals 59, no. 6 (2009): 312–19. http://dx.doi.org/10.2464/jilm.59.312.

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33

Plaksin, V. N. "Materials on student mental fatigue." Neurology Bulletin XVIII, no. 1 (July 6, 2021): 92–109. http://dx.doi.org/10.17816/nb70708.

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In 1907, at the Kazan Commercial School, teachers headed by the director A. I. Nemirovsky conducted experiments. the aim is to find out the mental fatigue of students in the course of the week. At the suggestion of prof. V.P. Osipov adopted the method set forth in the instructions for the production of school psychological experience No. 1, developed by A.P. Nechaev with the participation of members of the Russian Society of Normal and Pathological Psychology.
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34

Pachurin, G. V., D. A. Goncharova, A. A. Filippov, T. V. Nuzhdina, and V. B. Deev. "FATIGUE PROCESS OF AUTOMOBILE MATERIALS." Izvestiya. Ferrous Metallurgy 62, no. 9 (October 23, 2019): 732–38. http://dx.doi.org/10.17073/0368-0797-2019-9-732-738.

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During operation, the structural elements of cars are exposed to temperatures and vibrations. Overwhelming majority of the destruction of metal structures is caused by their fatigue. It causes economic losses and often human casualties from accidents. Therefore, the task of ensuring the operability of parts and components of automobiles is one of the most relevant in the modern automotive industry. So it is necessary to know the patterns of behavior of metallic materials, obtained by different technologies, when they are exposed to vibration. Destruction of the metal structure directly affects the behavior of the samples deflection, reflecting the competition of two mutually oppositephenomena – hardening and softening. It directly influences structural damageability of the metal. The article is devoted to the study of kinetics of fatigue failure of automotive materials using the calibration of structural damage to their surface with behavior of the curves of changes in current deflection under alternating loading. The paper considers automotive materials (steel grades 20KhI3, 14Kh17N2, 35KhGSА) and model metals and alloys (Copper M1, Brass L63T, aluminum alloy V95pchT2) in different structural state under cyclic loading for low, room and high temperatures with fixation of the sample deflection and structural damage corresponding to it. It is possible to study kinetics of fatigue destruction of the sample material by the deflection curves, which is an integral characteristic of destructive processes occurring under alternating loading. Using these processes, one can track the stages of damage during fatigue of metallic materials – damage to the structure at the initial stage, moment of the macroscopic crack appearance, its subsequent advancement up to complete separation of the structural material. It is probable to identify ratio of the period duration before the appearance of a fatigue crack and its subsequent growth, as well as to determine the average rate at which the fatigue crack moves through the body of the metal sample. It is important that it is also possible to estimate the kinetics of materials destruction under the conditions when direct study of the structural state of the sample surface is impossible, for example, in conditions of cryogenic and high temperatures, and also, for example, in the presence of corrosive media. In combination with fractographic and metallographic analysis of the fatigue process, the deflection curves allow, based on the evaluation of the stages of materials destruction, to carry out selection of the latter for the structural elements of a car taking into account its operating conditions and optimizing the technology of parts manufacturing to increase serviceability and maintainability.
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35

Berlin, A. A. "Fatigue Strength of Natural Materials." Polymer Science, Series D 13, no. 1 (January 2020): 57. http://dx.doi.org/10.1134/s1995421220010062.

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36

NISHIDA, Shin-ichi, Nobusuke HATTORI, Takahiro NIJO, and Seiichi FUKUMOTO. "Fatigue Strength of Bonded Materials." Proceedings of Conference of Kyushu Branch 2004.57 (2004): 13–14. http://dx.doi.org/10.1299/jsmekyushu.2004.57.13.

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37

Kun, F., M. H. Costa, R. N. Costa Filho, J. S. Andrade, J. B. Soares, S. Zapperi, and H. J. Herrmann. "Fatigue failure of disordered materials." Journal of Statistical Mechanics: Theory and Experiment 2007, no. 02 (February 2, 2007): P02003. http://dx.doi.org/10.1088/1742-5468/2007/02/p02003.

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38

Lee, John, and Adam Huang. "Fatigue analysis of FDM materials." Rapid Prototyping Journal 19, no. 4 (June 7, 2013): 291–99. http://dx.doi.org/10.1108/13552541311323290.

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39

Nijo, Takahiro, Shinichi Nishida, and Nobusuke Hattori. "Fatigue Strength of Bonded Materials." Proceedings of the JSME annual meeting 2003.6 (2003): 117–18. http://dx.doi.org/10.1299/jsmemecjo.2003.6.0_117.

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40

Albe, Karsten. "Electrical fatigue in functional materials." Materials Science and Engineering: B 192 (February 2015): 2. http://dx.doi.org/10.1016/j.mseb.2014.12.018.

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41

Xiang, Chunping, Zhengjin Wang, Canhui Yang, Xi Yao, Yecheng Wang, and Zhigang Suo. "Stretchable and fatigue-resistant materials." Materials Today 34 (April 2020): 7–16. http://dx.doi.org/10.1016/j.mattod.2019.08.009.

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42

Goder, D., H. Kalman, and A. Ullmann. "Fatigue characteristics of granular materials." Powder Technology 122, no. 1 (January 2002): 19–25. http://dx.doi.org/10.1016/s0032-5910(01)00390-4.

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43

Pook, L. P. "Fatigue of materials S Suresh." Materials & Design 13, no. 3 (January 1992): 182. http://dx.doi.org/10.1016/0261-3069(92)90229-b.

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44

Pascoe, K. J. "Composite materials: fatigue and fracture." Composites 18, no. 5 (November 1987): 411–13. http://dx.doi.org/10.1016/0010-4361(87)90368-5.

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45

Mohammadi, Saber. "Effect of Polarization Fatigue on Harvesting Energy Using Pyroelectric Materials." Advances in Materials Science and Engineering 2014 (2014): 1–4. http://dx.doi.org/10.1155/2014/913817.

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The phenomenon of polarization fatigue in ferroelectric materials is defined and the effect of this phenomenon on harvested energy using these materials has been studied. In order to illustrate this effect, the harvested energy using PZN-4.5PT single crystal was compared in two cases of fatigued and nonfatigued samples. The results have been calculated between two temperatures of 100 and 130°C using Ericsson thermodynamic cycle.
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46

Tsivouraki, Niki, Konstantinos Tserpes, and Ioannis Sioutis. "Modelling of Fatigue Delamination Growth and Prediction of Residual Tensile Strength of Thermoplastic Coupons." Materials 17, no. 2 (January 11, 2024): 362. http://dx.doi.org/10.3390/ma17020362.

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Thermoplastic composites are continuously replacing thermosetting composites in lightweight structures. However, the accomplished work on the fatigue behavior of thermoplastics is quite limited. In the present work, we propose a numerical modeling approach for simulating fatigue delamination growth and predicting the residual tensile strength of quasi-isotropic TC 1225 LM PAEK thermoplastic coupons. The approach was supported and validated by tension and fatigue (non-interrupted and interrupted) tests. Fatigue delamination growth was simulated using a mixed-mode fatigue crack growth model, which was based on the cohesive zone modeling method. Quasi-static tension analyses on pristine and fatigued coupons were performed using a progressive damage model. These analyses were implemented using a set of Hashin-type strain-based failure criteria and a damage mechanics-based material property degradation module. Utilizing the fatigue model, we accurately foretold the expansion of delamination concerning the cycle count across all interfaces. The results agree well with C-scan images taken on fatigued coupons during interruptions of fatigue tests. An unequal and unsymmetric delamination growth was predicted due to the quasi-isotropic layup. Moreover, the combined models capture the decrease in the residual tensile strength of the coupons. During the quasi-static tension analysis of the fatigued coupons, we observed that the primary driving failure mechanisms were the rapid spread of existing delamination and the consequential severe matrix cracking.
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47

Ikeda, Yuichi, Kiyotaka Munaoka, Takashi Matsuo, and Msahiro Endo. "OS8-16 Development of Testing Machine for Small Shear-Mode Fatigue Crack Growth Test(Fatigue crack propagation,OS8 Fatigue and fracture mechanics,STRENGTH OF MATERIALS)." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2015.14 (2015): 126. http://dx.doi.org/10.1299/jsmeatem.2015.14.126.

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48

KISHIMOTO, Hidehiro. "Fatigue of Advanced Materials. 4. Cyclic Fatigue in Ceramics. II." Journal of the Society of Materials Science, Japan 43, no. 491 (1994): 1016–22. http://dx.doi.org/10.2472/jsms.43.1016.

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49

McCabe, J. F., Y. Wang, and MJA Braem. "Surface contact fatigue and flexural fatigue of dental restorative materials." Journal of Biomedical Materials Research 50, no. 3 (June 5, 2000): 375–80. http://dx.doi.org/10.1002/(sici)1097-4636(20000605)50:3<375::aid-jbm11>3.0.co;2-r.

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50

Cui, Haitao, and Qinan Han. "Fatigue Damage Mechanism and Fatigue Life Prediction of Metallic Materials." Metals 13, no. 10 (October 16, 2023): 1752. http://dx.doi.org/10.3390/met13101752.

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