Journal articles: 'Temperature-Strain Rate'

1

Alden, Thomas H. "Temperature-dependent strain rate discontinuity." Materials Science and Engineering: A 103, no. 2 (September 1988): 213–21. http://dx.doi.org/10.1016/0025-5416(88)90511-3.

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2

Kim, K. T., and Y. H. Cho. "A temperature and strain rate dependent strain hardening law." International Journal of Pressure Vessels and Piping 49, no. 3 (January 1992): 327–37. http://dx.doi.org/10.1016/0308-0161(92)90120-5.

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3

Sung, Ji Hyun, Ji Hoon Kim, and R. H. Wagoner. "A plastic constitutive equation incorporating strain, strain-rate, and temperature." International Journal of Plasticity 26, no. 12 (December 2010): 1746–71. http://dx.doi.org/10.1016/j.ijplas.2010.02.005.

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4

Gupta, Mahesh Kumar, Akash Shankhdhar, Abhinav Kumar, Anant Vermon, Aayush Kumar Singh, and Vinay Panwar. "Temperature and strain rate dependent stress-strain behaviour of nitinol." Materials Today: Proceedings 43 (2021): 395–99. http://dx.doi.org/10.1016/j.matpr.2020.11.685.

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5

Charalambakis, Nicolas. "Shear stability and strain, strain-rate and temperature-dependent “cold” work." International Journal of Engineering Science 39, no. 17 (November 2001): 1899–911. http://dx.doi.org/10.1016/s0020-7225(01)00041-6.

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6

Kreyca, Johannes, and Ernst Kozeschnik. "Analysis of the Temperature and Strain-Rate Dependences of Strain Hardening." Metallurgical and Materials Transactions A 49, no. 1 (November 16, 2017): 18–21. http://dx.doi.org/10.1007/s11661-017-4402-5.

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7

Larour, Patrick, Annette Bäumer, Kirsten Dahmen, and Wolfgang Bleck. "Influence of Strain Rate, Temperature, Plastic Strain, and Microstructure on the Strain Rate Sensitivity of Automotive Sheet Steels." steel research international 84, no. 5 (November 5, 2012): 426–42. http://dx.doi.org/10.1002/srin.201200099.

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8

Vigié, Héloise, Thalita de Paula, Martin Surand, and Bernard Viguier. "Low Temperature Strain Rate Sensitivity of Titanium Alloys." Solid State Phenomena 258 (December 2016): 570–73. http://dx.doi.org/10.4028/www.scientific.net/ssp.258.570.

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Titanium alloys are widely used in many industrial applications such as in aeronautics due to their combination of good mechanical properties, excellent corrosion resistance and low density. The mechanical behaviour of titanium alloys is known to exhibit a peculiar dependence on both deformation temperature and strain rate. Titanium alloys show significant room temperature creep and they are very sensitive to dwell fatigue and sustained load cracking. This behaviour is related to the viscosity of plastic deformation in titanium alloys, which can be represented by a strain rate sensitivity (SRS) parameter. The present study aims to compare the tensile behavior of two different titanium alloys, Ti-6Al-4V and β21S, which exhibit dissimilar microstructures. Results of tensile tests, performed under constant strain rate and including strain rate changes, are reported in terms of flow stress, ductility and SRS over a wide range of temperatures.

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9

Yan, Dong Ming, and Wei Xu. "Strain-Rate Sensitivity of Concrete: Influence of Temperature." Advanced Materials Research 243-249 (May 2011): 453–56. http://dx.doi.org/10.4028/www.scientific.net/amr.243-249.453.

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Knowledge about the dynamic properties of concrete is vital to the design and safety evaluation of large-scale concrete structures subjected to seismic excitation. There are many factors affecting the dynamic properties of concrete such as moisture content and temperature. Though a lot of concrete structures have been designed to withstand low temperature, research on the strain-rate sensitivity of concrete under low temperature condition is still very limited so far. In this study, both tensile and compressive experiments were carried out to investigate the influence of temperature on the rate-dependent characteristics of concrete. Tensile experiments of dumbbell-shaped specimens were carried out on a MTS810 testing machine and compressive tests on cubic specimens were performed using a servo-hydraulic testing machine. Specimens at two types of temperature, room temperature 20oC and low temperature -30oC, were characterized. The strain rate varied over a wide range. It was concluded from the test data that the strengths of specimens at both types of temperature tended to increase as strain rate increased. Temperature had slight influence on the rate-sensitive behavior of concrete when concrete specimens were dry; however, test on saturated specimens indicated that the role of temperature on the mechanical behavior of concrete subject to dynamic loading was very significant. This phenomenon may be attributed to the state of free water in concrete.

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10

Senden, D. J. A., S. Krop, J. A. W. van Dommelen, and L. E. Govaert. "Rate- and temperature-dependent strain hardening of polycarbonate." Journal of Polymer Science Part B: Polymer Physics 50, no. 24 (September 17, 2012): 1680–93. http://dx.doi.org/10.1002/polb.23165.

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11

Sakka, Y., T. Matsumoto, T. S. Suzuki, K. Morita, B. N. Kim, K. Hiraga, and Y. Moriyoshi. "Low-Temperature and High-Strain Rate Superplastic Zirconia." Advanced Engineering Materials 5, no. 3 (March 26, 2003): 130–33. http://dx.doi.org/10.1002/adem.200390020.

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12

WAKASUGI, Shohachi. "Constitutive relations between stress, strain-rate and temperature." Transactions of the Japan Society of Mechanical Engineers Series A 52, no. 478 (1986): 1628–33. http://dx.doi.org/10.1299/kikaia.52.1628.

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13

Kitaeva, D. A., Sh T. Pazylov, and Ya I. Rudaev. "Temperature–strain rate deformation conditions of aluminum alloys." Journal of Applied Mechanics and Technical Physics 57, no. 2 (March 2016): 352–58. http://dx.doi.org/10.1134/s002189441602019x.

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14

Petersen, DR, VM Sample, and DP Field. "Constant Temperature-Compensated Strain Rate Testing of Aluminum." Journal of Testing and Evaluation 22, no. 2 (1994): 127. http://dx.doi.org/10.1520/jte12646j.

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15

Roy, Ajit K., Joydeep Pal, and Chandan Mukhopadhyay. "Dynamic strain ageing of an austenitic superalloy—Temperature and strain rate effects." Materials Science and Engineering: A 474, no. 1-2 (February 2008): 363–70. http://dx.doi.org/10.1016/j.msea.2007.05.056.

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16

WANG, L. L., H. S. BAO, and W. X. LU. "THE DEPENDENCE OF ADIABATIC SHEAR BANDING IN STRAIN-RATE, STRAIN AND TEMPERATURE." Le Journal de Physique Colloques 49, no. C3 (September 1988): C3–207—C3–214. http://dx.doi.org/10.1051/jphyscol:1988330.

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17

Gómez-del Río, T., and J. Rodríguez. "Compression yielding of epoxy: Strain rate and temperature effect." Materials & Design 35 (March 2012): 369–73. http://dx.doi.org/10.1016/j.matdes.2011.09.034.

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18

Kapoor, Rajeev, and Sia Nemat-Nasser. "Determination of temperature rise during high strain rate deformation." Mechanics of Materials 27, no. 1 (January 1998): 1–12. http://dx.doi.org/10.1016/s0167-6636(97)00036-7.

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19

KOBAYASHI, Hidetoshi. "Strain rate and temperature of light metals in compression." Proceedings of Mechanical Engineering Congress, Japan 2019 (2019): K04100. http://dx.doi.org/10.1299/jsmemecj.2019.k04100.

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20

Reis, J. M. L., L. J. Pacheco, and H. S. da Costa Mattos. "Temperature and variable strain rate sensitivity in recycled HDPE." Polymer Testing 39 (October 2014): 30–35. http://dx.doi.org/10.1016/j.polymertesting.2014.07.011.

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21

Zhao, H., and N. R. Aluru. "Temperature and strain-rate dependent fracture strength of graphene." Journal of Applied Physics 108, no. 6 (September 15, 2010): 064321. http://dx.doi.org/10.1063/1.3488620.

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22

van Breemen, Lambert C. A., Tom A. P. Engels, Edwin T. J. Klompen, Dirk J. A. Senden, and Leon E. Govaert. "Rate- and temperature-dependent strain softening in solid polymers." Journal of Polymer Science Part B: Polymer Physics 50, no. 24 (October 31, 2012): 1757–71. http://dx.doi.org/10.1002/polb.23199.

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23

Zhang, Ying-Yan, Qing-Xiang Pei, Yiu-Wing Mai, and Yuan-Tong Gu. "Temperature and strain-rate dependent fracture strength of graphynes." Journal of Physics D: Applied Physics 47, no. 42 (September 18, 2014): 425301. http://dx.doi.org/10.1088/0022-3727/47/42/425301.

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24

Mohanty, Gaurav, Jeffrey M. Wheeler, Rejin Raghavan, Juri Wehrs, Madoka Hasegawa, Stefano Mischler, Laetitia Philippe, and Johann Michler. "Elevated temperature, strain rate jump microcompression of nanocrystalline nickel." Philosophical Magazine 95, no. 16-18 (September 1, 2014): 1878–95. http://dx.doi.org/10.1080/14786435.2014.951709.

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25

Scapin, M., P. Verleysen, M. Hokka, and N. Bahlouli. "Temperature Dependence of Material Behaviour at High Strain-Rate." Journal of Dynamic Behavior of Materials 5, no. 3 (July 31, 2019): 197. http://dx.doi.org/10.1007/s40870-019-00217-8.

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26

Peng, Xiaona, Hongzhen Guo, Zhifeng Shi, Chun Qin, and Zhanglong Zhao. "Constitutive equations for high temperature flow stress of TC4-DT alloy incorporating strain, strain rate and temperature." Materials & Design 50 (September 2013): 198–206. http://dx.doi.org/10.1016/j.matdes.2013.03.009.

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27

Dalla Torre, Florian H., Alban Dubach, Adrienne Nelson, and Jörg F. Löffler. "Temperature, Strain and Strain Rate Dependence of Serrated Flow in Bulk Metallic Glasses." MATERIALS TRANSACTIONS 48, no. 7 (2007): 1774–80. http://dx.doi.org/10.2320/matertrans.mj200782.

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28

Chivapornthip, P., and E. L. J. Bohez. "Dependence of bulk viscosity of polypropylene on strain, strain rate, and melt temperature." Polymer Engineering & Science 57, no. 8 (October 5, 2016): 830–37. http://dx.doi.org/10.1002/pen.24459.

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29

Brooks, N. W., A. P. Unwin, R. A. Duckett, and I. M. Ward. "Temperature and strain rate dependence of yield strain and deformation behavior in polyethylene." Journal of Polymer Science Part B: Polymer Physics 35, no. 4 (March 1997): 545–52. http://dx.doi.org/10.1002/(sici)1099-0488(199703)35:4<545::aid-polb2>3.0.co;2-p.

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30

MAE, Hiroyuki. "Stress Strain Behavior of Polypropylene Dependent on Strain Rate and Glass Transition Temperature." Proceedings of the Materials and processing conference 2004.12 (2004): 195–96. http://dx.doi.org/10.1299/jsmemp.2004.12.195.

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31

Kawashima, K., T. Ito, and M. Sakuragi. "Strain-rate and temperature-dependent stress-strain curves of Sn-Pb eutectic alloy." Journal of Materials Science 27, no. 23 (February 20, 1992): 6387–90. http://dx.doi.org/10.1007/bf00576289.

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32

Klepaczko, J. R. "A practical stress-strain-strain rate-temperature constitutive relation of the power form." Journal of Mechanical Working Technology 15, no. 2 (September 1987): 143–65. http://dx.doi.org/10.1016/0378-3804(87)90031-3.

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33

Zhang, Longhui, Antonio Pellegrino, David Townsend, and Nik Petrinic. "Strain rate and temperature dependent strain localization of a near α titanium alloy." International Journal of Impact Engineering 145 (November 2020): 103676. http://dx.doi.org/10.1016/j.ijimpeng.2020.103676.

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34

Urcola, J. J., and C. M. Sellars. "Effect of changing strain rate on stress-strain behaviour during high temperature deformation." Acta Metallurgica 35, no. 11 (November 1987): 2637–47. http://dx.doi.org/10.1016/0001-6160(87)90263-x.

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35

Suo, Tao, Yu Long Li, and Yuan Yong Liu. "Temperature and Strain Rate Effects on Mechanical Behavior of a PMMA." Key Engineering Materials 340-341 (June 2007): 1079–84. http://dx.doi.org/10.4028/www.scientific.net/kem.340-341.1079.

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In this paper, the mechanical behavior of a PMMA used as the windshield of aircraft was tested. The experiments were finished under two quasi-static strain rates and a high strain rate with the testing temperature from 299K to 373K. The results show that the mechanical property of this PMMA depends heavily on the testing temperature. The Young’s modulus and flow stress were found to decrease with increasing temperature at low strain rate. At the strain rate of 10-1 1/s, strain softening was observed under all experiment temperatures. At high strain rate, with the temperature increasing, the flow stress decreases remarkably while the failure strain increases, and the strain soften was also observed at the temperature above 333K. Comparing the experiments results at same temperature, it was found the flow stress increases with the rising strain rate. The predictions of the mechanical behavior using the ZWT theoretical model have a good agreement with experimental results in the strain range of 8%.

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36

Arruda, E. M., S. Ahzi, Y. Li, and A. Ganesan. "Rate Dependent Deformation of Semi-Crystalline Polypropylene Near Room Temperature." Journal of Engineering Materials and Technology 119, no. 3 (July 1, 1997): 216–22. http://dx.doi.org/10.1115/1.2812247.

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We examine the strain rate dependent, large plastic deformation in isotropic semi-crystalline polypropylene at room temperature. Constant strain rate uniaxial compression tests on cylindrical polypropylene specimens show very little true strain softening under quasi-static conditions. At high strain rates very large amounts (38 percent) of apparent strain softening accompanied by temperature rises are recorded. We examine the capability of a recently proposed constitutive model of plastic deformation in semi-crystalline polymers to predict this behavior. We neglect the contribution of the amorphous phase to the plastic deformation response and include the effects of adiabatic heating at high strain rates. Attention is focused on the ability to predict rate dependent yielding, strain softening, strain hardening, and adiabatic temperature rises with this approach. Comparison of simulations and experimental results show good agreement and provide insight into the merits of using a polycrystalline modeling assumption versus incorporating the amorphous contribution. Discrepancies between experiments and model predictions are explained in terms of expectations associated with neglecting the amorphous deformation.

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37

Çavusoglu, Onur, Hakan Gürün, Serkan Toros, and Ahmet Güral. "Strain rate sensitivity and strain hardening response of DP1000 dual phase steel." Metallurgical Research & Technology 115, no. 5 (2018): 507. http://dx.doi.org/10.1051/metal/2018016.

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In this study, strain hardening and strain rate sensitivity behavior of commercial DP1000 dual phase steel have been examined in detail at temperatures of 25 °C, 100 °C, 200 °C and 300 °C, at strain rates of 0.0016 s−1 and 0.16 s−1. As the strain rate has increased, the yield strength has increased but no significant change in tensile strength and strain hardening coefficient has been observed. As the temperature has increased, the yield and tensile strength has decreased in between 25 and 200 °C but it has showed an increase at 300 °C. The strain hardening coefficient has increased in parallel with temperature increase. It has been seen that the strain rate sensitivity has not been affected by temperature. No significant difference in the hardening rate has appeared in between 25 and 200 °C, but the highest value has been calculated at 300 °C. It has been determined that the fracture behavior has occurred earlier and load carrying capacity on necking has reduced with the increase of strain rate and not significantly affected by temperature.

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38

Wang, Jin, Yang Wang, and Ziran Li. "Dynamic Tension Deformation of Rare-Earth Containing Mg-1.9Mn-0.3Ce Alloy Sheet along the Rolling Direction at Various Temperatures." Metals 10, no. 11 (November 4, 2020): 1473. http://dx.doi.org/10.3390/met10111473.

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The tensile properties of rare-earth containing Mg-1.9Mn-0.3Ce alloy sheet along the rolling direction were experimentally investigated within the strain rate and temperature ranges of 0.001–1300 s−1 and 213–488 K. The obtained stress-strain responses of the alloy sheet indicate that both yield strength and strain-hardening rate increase when the strain rate increases, whereas they decrease with increase of temperature. Microscopic examination results show that basal slip, prismatic slip, and {101¯2} tension twinning take place in the tensile plastic deformation, while the occurrence of twinning is not obviously affected by the rate and temperature. Tensile samples tend to fracture in a ductile mode with increasing strain rate and temperature.

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39

Shekhar, Shashank, S. Abolghashem, S. Basu, J. Cai, and M. Ravi Shankar. "Interactive Effects of Strain, Strain-Rate and Temperatures on Microstructure Evolution in High Rate Severe Plastic Deformation." Materials Science Forum 702-703 (December 2011): 139–42. http://dx.doi.org/10.4028/www.scientific.net/msf.702-703.139.

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During high rate severe plastic deformation (HRSPD), strain and strain-rate are not the only external factors that determine microstructural transformations in materials, temperature-rise due to heat generation from deformation processes, also plays an important role. Temperature may influence the microstructure directly by controlling grain growth kinetics and it may also have an indirect effect through the interactive effect on material behavior, which in turn, influences strain and strain-rate parameters. This complex thermomechanics of HRSPD can lead to myriad of microstructure and consequently, material properties and phenomenon. These deformation parameters can be utilized as a ‘fingerprint’ for the resulting microstructure, and the properties and phenomenon related to it. Here, we capture some of these microstructural transformations by relating grain and sub-grain sizes, to the deformation parameters. In doing so, we find evidence of continuous dynamic recrystallization operative under these HRSPD conditions, where the interplay of strain, strain rate and temperatures offer varying degrees of multimodality in the grain-size distributions.

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40

Ogawa, K. "Temperature and Strain Rate Effects on Plastic Deformation of Titanium Alloys." Materials Science Forum 539-543 (March 2007): 3619–24. http://dx.doi.org/10.4028/www.scientific.net/msf.539-543.3619.

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Since titanium alloys are the most promising structural materials for the high velocity vehicles, the impact tensile strength of the materials is presently investigated. Three kinds of aging treatments on the beta-titanium alloy were performed, and the tensile deformation behaviors were identified in the wide range of the temperature and the strain rate. The stress－strain relations of the titanium alloy significantly depend on the temperature and the strain rate investigated. Thermally activated process concept was applied to explain the experimental results, and the stress-strain relations at high strain rates were well understood with taking account of adiabatic heating effect. It has been found that the stress-strain curves depend on the microstructures, while the temperature and the strain rate effects are almost independent of the different aging treatments.

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41

Kinari, Toshiyasu, Sukenori Shintaku, Nobuo Iwaki, and Junnya Hori. "Effects of Temperature, Humidity and Strain Rate on Tensile Stress-Strain Curves of Spandex." Sen'i Kikai Gakkaishi (Journal of the Textile Machinery Society of Japan) 48, no. 1 (1995): T20—T26. http://dx.doi.org/10.4188/transjtmsj.48.t20.

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42

LÜ, Wen-quan, Guo-zheng QUAN, Chun-tang YU, Lei ZHAO, and Jie ZHOU. "Effect of strain, strain rate and temperature on workability of AZ80 wrought magnesium alloy." Transactions of Nonferrous Metals Society of China 22 (December 2012): s650—s655. http://dx.doi.org/10.1016/s1003-6326(12)61780-4.

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43

Cai, M. C., L. S. Niu, T. Yu, H. J. Shi, and X. F. Ma. "Strain rate and temperature effects on the critical strain for Portevin–Le Chatelier effect." Materials Science and Engineering: A 527, no. 20 (July 2010): 5175–80. http://dx.doi.org/10.1016/j.msea.2010.05.001.

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44

Piao, Ming Jun, Hoon Huh, and Ik Jin Lee. "Characterization of Hardening Behavior at Ultra-High Strain Rate, Large Strain, and High Temperature." Key Engineering Materials 725 (December 2016): 138–42. http://dx.doi.org/10.4028/www.scientific.net/kem.725.138.

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This paper is concerned with the characterization of the OFHC copper flow stress at strain rates ranging from 10−3 s−1 to 106 s−1 considering the large strain and high temperature effects. Several uniaxial material tests with OFHC copper are performed at a wide range of strain rates from 10−3 s−1 to 103 s−1 by using a INSTRON 5583, a High Speed Material Testing Machine (HSMTM), and a tension split Hopkinson pressure bar. In order to consider the thermal softening effect, tensile tests at 25°C and 200°C are performed at strain rates of 10−3 s−1,101 s−1, and 102 s−1. A modified thermal softening model is considered for the accurate application of the thermal softening effect at high strain rates. The large strain behavior is challenged by using the swift power law model. The high strain rates behavior is fitted with the Lim–Huh model. The hardening curves are evaluated by comparing the final shape of the projectile from numerical simulation results with the Taylor impact tests.

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45

Majzoobi, Gholam-Hossein, Jamal Mohammadi, Mohammad K. Pipelzadeh, Saeed Lahmi, and Stephen J. Hardy. "A constitutive model for hardness considering the effects of strain, strain rate and temperature." Journal of Strain Analysis for Engineering Design 50, no. 5 (May 29, 2015): 284–98. http://dx.doi.org/10.1177/0309324715585070.

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46

Hörnqvist, Magnus, and Birger Karlsson. "Temperature and Strain Rate Effects on the Dynamic Strain Ageing of Aluminium Alloy AA7030." Materials Science Forum 519-521 (July 2006): 883–88. http://dx.doi.org/10.4028/www.scientific.net/msf.519-521.883.

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The effects of temperature and strain rate on the mechanical properties of aluminium alloy AA7030 (Al-5.4Zn-1.2Mg) in naturally aged and peak aged condition are investigated, with emphasis on the relation to dynamic strain ageing. It is found that the naturally aged material shows more severe signs of dynamic strain ageing, including inverse strain rate and temperature dependence of flow stress, inverse temperature dependence of the ductility and serrated yielding. The peak aged material also shows signs of dynamic strain ageing, but to a lesser extent, most pronounced through serrated yielding. The observed effects can be qualitatively explained in terms of a thermal activation based model for dislocation glide. Furthermore, inhomogeneous deformation is observed on several size scales ranging from localized glide bands to surface deformation effects (orange peel surface) and macroscopic flow localization in shear bands.

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47

Jensen, Russell R., and John K. Tien. "Temperature and strain rate dependence of stress-strain behavior in a nickel-base superalloy." Metallurgical Transactions A 16, no. 9 (September 1985): 1696. http://dx.doi.org/10.1007/bf02663029.

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48

Jensen, Russell R., and John K. Tien. "Temperature and strain rate dependence of stress-strain behavior in a nickel-base superalloy." Metallurgical Transactions A 16, no. 6 (June 1985): 1049–68. http://dx.doi.org/10.1007/bf02811675.

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49

El-Qoubaa, Zakaria, and Ramzi Othman. "Temperature, Strain Rate and Pressure Sensitivity of the Polyetheretherketone’s Yield Stress." International Journal of Applied Mechanics 09, no. 07 (October 2017): 1750099. http://dx.doi.org/10.1142/s1758825117500995.

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The polymer yield behavior is affected by temperature, strain rate and pressure. In this work, tensile yield stress of polyetheretherketone (PEEK) is characterized for temperature ranging between [Formula: see text] and [Formula: see text] ([Formula: see text]C and [Formula: see text]C). The tensile yield stress is decreasing in terms of temperature. Two temperature transitions are observed: [Formula: see text] ([Formula: see text]C) and the glass transition temperature. The temperature sensitivity is well captured by the modified-Eyring equation proposed by the authors. This paper completes three previous works where the PEEK’s yield behavior was described under compression on wide ranges of strain rate and temperature and under tension on a wide range of strain rates. Thus, the pressure effect is analyzed in terms of temperature and strain rate. Using either the experimental data or the modified-Eyring equation, the effect of the hydrostatic pressure is increasing with temperature and decreasing with strain rate.

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50

Bammann, Douglas J. "Modeling Temperature and Strain Rate Dependent Large Deformations of Metals." Applied Mechanics Reviews 43, no. 5S (May 1, 1990): S312—S319. http://dx.doi.org/10.1115/1.3120834.

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We review the development of a strain rate and temperature dependent plasticity model for finite deformation. In particular we address both the method of determining the parameters of the model and the engineering meaning of the parameters in terms of uniaxial stress-strain curves. The ability of the model to predict some aspects of anisotropic hardening, strain rate history effects, and thermal softening are then illustrated by comparison with experimental data.

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Journal articles on the topic 'Temperature-Strain Rate'

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