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Impact compressibility and spall strength of ultra-high molecular weight polyethylene at temperatures from -120^oC to 145^oC
Russian version
Cherepanov I.A. 1, Savinykh A. S. 1, Garkushin G.V. 1, Razorenov S. V. 1, Zhukov A.N. 1, Chernyayev D. A. 1, Panin S.V. 2, Alexenko V. O. 2
1Federal Research Center for Problems of Chemical Physics and Medical Chemistry, Russian Academy of Sciences, Chernogolovka, Moscow region, Russia
2Institute of Strength Physics and Materials Science Siberian Branch of RAS, Tomsk, Russia
Email: i.cherepanov95@yandex.ru
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The analysis of full wave profiles for ultra-high molecular weight polyethylene samples enabled the determination of the dependences of the shock wave velocity US on the particle velocity up (Hugoniots) in the range of maximum shock compression stresses from 0.3 to 1.3 GPa at initial temperatures of -95^oC to 95^oC. Spall strength measurements were conducted over a broad range of initial temperatures, between -120^oC to 145^oC, at a maximum compression stress of 0.8 GPa. The samples were loaded by the impact of aluminium plates accelerated to velocities between 210 m/s and 660 m/s using special explosive devices or a pneumatic gun. Wave profiles were recorded using a laser Doppler velocimeter VISAR. The results demonstrate that, as observed in other polymeric materials, elevated temperatures result in a reduction in spall strength. Keywords: UHMWPE, shock waves, deformation, temperature, spall strength, Hugoniots.
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