Instrumentation on Impact Shock Study of Polymers and Possibility of Non-Equilibrium Shock Hugoniot

Kunihito Nagayama; Yasuhito Mori

doi:10.4028/www.scientific.net/MSF.638-642.1059

Paper Titles

Explosively Driven Expansion and Fragmentation Behavior for Cylinders, Spheres and Rings of 304 Stainless Steel
p.1035

Some Trials on Underwater Explosive Welding of Thin W Plate onto Copper Substrate
p.1041

Development of Compact Blast Containment Vessel for 10 kg Explosive
p.1047

Phase Transition Behavior of Solids under Shock Compression
p.1053

Instrumentation on Impact Shock Study of Polymers and Possibility of Non-Equilibrium Shock Hugoniot
p.1059

Advanced Use of a Split Hopkinson Bar Setup for the Extended Characterization of Multiphase Steel Sheets
p.1065

Impact Behavior of Concretes Taking Account of Strain-Rate Effect, Stress-State Effect and Damage Evolution
p.1071

In Situ Observation of Grain Growth and Recrystallization of Steel at High Temperature
p.1077

Characterization of Hydrogen Sorption Properties and Microstructure of Cast Mg-10wt%Ni Alloys
p.1085

HomeMaterials Science ForumMaterials Science Forum Vols. 638-642Instrumentation on Impact Shock Study of Polymers...

Instrumentation on Impact Shock Study of Polymers and Possibility of Non-Equilibrium Shock Hugoniot

Abstract:

Polymer materials have widespread applications in various situations for structural materials by themselves as well as by combining with other materials such as carbon fiber. Some of them are also candidates for energetic materials in space applications.[1] Due to their general use, shock response of them has attracted attention for many researchers.[2-4] One of the striking characteristics of the dynamic response of them is that stress and/or particle velocity profile has a relaxation structure of s range.[5, 6]

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Materials Science Forum (Volumes 638-642)

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1059-1064

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https://doi.org/10.4028/www.scientific.net/MSF.638-642.1059

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Online since:

January 2010

Authors:

Kunihito Nagayama, Yasuhito Mori

Keywords:

Laser-Based Observation System, Polymer, Shock Compression, Shock Hugoniot, Stress Relaxation

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References

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