ASM Metals HandBook Vol. 8 - Mechanical Testing and Evaluation
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Fig. 17 Stress-time diagrams from high rate tension testing of carbon steel (0.45% C) between room
temperature and 600 °C (1100 °F)
References cited in this section
51. H. C. Mann, High Velocity Tension Impact Tests, Proc. ASTM, Vol 36 (part 2), 1936, p 85–109
52. R.O. Fehr, E. Parker, and D.J. DeMichael, Measurement of Dynamic Stress and Strain in Tensile Test
Specimens, J. Appl. Mech. (Trans. ASME), Vol 6A, 1944, p 65–71
53. R. Dormeval and M. Stelly, Influence of Grain Size and Strain Rate of the Mechanical Behavior of
High-Purity Polycrystalline Copper, Second Conf. on Mechanical Properties at High Rates of Strain,
1979 (Oxford), Institute of Physics, London, Serial No. 47, p 154–165
54. C.E. Frantz, P.S. Follansbee, and W.E. Wright, New Experimental Techniques with the Split Hopkinson
Pressure Bar, High Energy Rate Forming, Berman and Schroeder, Ed., American Society of Mechanical
Engineers, 1984, p 229
55. A.M. Lennon and K.T. Ramesh, A Technique for Measurement the Dynamic Behaviour of Materials at
High Temperatures, Int. J. Plast., Vol 14 (No. 12), 1998, p 1279–1292
High Strain Rate Tension and Compression Tests
Acknowledgments
The discussion of rotating wheel tension testing was prepared for this Volume by L.W. Meyer, S. Abdel-Malek,
and T. Halle, Technical University Chemnitz and Nordmetall GbR, Germany. Other portions of this article
were adapted from the following articles in Volume 8 of the 9th Edition Metals Handbook:
• “Drop Tower Compression Testing” by G.B. Dudder (p 196–198)
• “Rod Impact (Taylor) Test” by D.C. Erlich (p 203–207)
• “High Strain Rate Compression Testing: Introduction” by P.S. Follensbee (p 190–192)
• “The Hopkinson Bar” by P.S. Follensbee (p 198–203)
• “Compression Testing by Conventional Load Frames at Medium Strain Rates” by P.S. Follansbee and
P.E. Armstrong (p 192–193)
• “The Cam Plastometer” by J.E. Hockett (p 193–196)
• “High Strain Rate Tension Testing” by T. Nicholas and S.J. Bless (p 208–214)
• “Introduction to High Strain Rate Testing” by M.R. Staker (p 187–189)
High Strain Rate Tension and Compression Tests
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52. R.O. Fehr, E. Parker, and D.J. DeMichael, Measurement of Dynamic Stress and Strain in Tensile Test
Specimens, J. Appl. Mech. (Trans. ASME), Vol 6A, 1944, p 65–71
53. R. Dormeval and M. Stelly, Influence of Grain Size and Strain Rate of the Mechanical Behavior of
High-Purity Polycrystalline Copper, Second Conf. on Mechanical Properties at High Rates of Strain,
1979 (Oxford), Institute of Physics, London, Serial No. 47, p 154–165
54. C.E. Frantz, P.S. Follansbee, and W.E. Wright, New Experimental Techniques with the Split Hopkinson
Pressure Bar, High Energy Rate Forming, Berman and Schroeder, Ed., American Society of Mechanical
Engineers, 1984, p 229
55. A.M. Lennon and K.T. Ramesh, A Technique for Measurement the Dynamic Behaviour of Materials at
High Temperatures, Int. J. Plast., Vol 14 (No. 12), 1998, p 1279–1292
High Strain Rate Tension and Compression Tests
Selected References
1990 to 1999
• T.J. Ahrens, G.Q. Chen, W. Yang, and J.K. Knowles, Effect of Irreversible Phase Change on Shock-
Wave Propagation, J. Mech. Phys. Solids, Vol 47 (No. 4), 1999, p 763–783
• T. Aizawa, K. Ito, and M. Tsuchida, Intense High-Strain-Rate Loading Devices for Advanced Materials
Synthesis and Processing, J. School Eng., Univ. Tokyo, Vol 45, 1998, p 41–86
• A. Al-Tounsi, M.S.J. Hashmi, Effect of Sintering Temperature on High Strain Rate Properties of Iron
Powder Compacts, 3rd International Conference on Mechanical and Physical Behaviour of Materials
under Dynamic Loading (DYMAT 91), 14–18 Oct 1991 (Strasbourg, France) or J. Phys. (France) IV,
Vol 1 (Colloq. 3, Suppl. JP III, 8), 1991, p 203–208
• C. Albertini, M. Montagnani, E.V. Pizzinato, and A. Rodis, Comparison of Mechanical Properties in
Tension and Shear at High Strain Rate for AISI 316 and Armco Iron, Mechanical Behaviour of
Materials VI, Vol I, 29 July–2 Aug 1991 (Kyoto, Japan), Pergamon Press plc, Oxford, UK, 1992, p
351–356
• C. Albertini, M. Montagnani, E.V. Pizzinato, A. Rodis, S. Berlenghi, G. Berrini, G. Pazienza, and A.
Paluffi, Mechanical Properties in Shear at Very High Strain Rate of AISI 316 Stainless Steel and of a
Pure Iron Comparison with Tensile Properties, Shock-Wave and High-Strain-Rate Phenomena in
Materials, Marcel Dekker, Inc., 1992, p 681–691
• R.W. Armstrong, X.J. Zhang, C. Feng, J.D. Williams, and F.J. Zerilli, High Strain Rate Deformation
Behavior of Tantalum, Tantalum, 5–8 Feb 1996 (Anaheim, CA), Minerals, Metals and Materials
Society/AIME, Warrendale, PA, 1996, p 157–162
• R.W. Armstrong and F.J. Zerilli, Deformation Twinning: From Atomic Modeling to Shock Wave
Loading, Advances in Twinning, 28 Feb–4 Mar 1999 (San Diego), Advances in Twinning, Minerals,
Metals and Materials Society/AIME, 1999, p 67–81
• R. Asfahani, E. Chen, and A. Crowson, High Strain Rate Behavior of Refractory Metals and Alloys,
Minerals, Metals and Materials Society, Warrendale, PA, 1992, p 316
• P.B. Berbon, M. Furukawa, Z. Horita, M. Nemoto, N.K. Tsenev, R.Z. Valiev, and T.G. Langdon,
Processing of Aluminum Alloys for High Strain Rate Superplasticity, Second Symp. on Hot
Deformation of Aluminum Alloys II, 11–15 Oct 1998 (Rosemont, IL), Hot Deformation of Aluminum
Alloys II, Minerals, Metals and Materials Society/AIME, 1998, p 111–124
• T.R. Bieler and A.K. Mukherjee, Region I Deformation Mechanisms in High Strain Rate Superplastic
IN9021, Superplasticity and Superplastic Forming 1995, 13–15 Feb 1995 (Las Vegas, NV), Minerals,
Metals and Materials Society/AIME, Warrendale, PA, 1995, p 153–160
• J.J. Blandin, B. Baudelet, and R. Dendievel, Mechanical Approach of High Strain Rate Superplastic
Behavior of Composite Materials, Towards Innovation in Superplasticity I, 23–24 July 1996 (Kyoto,
Japan), 1997 or Mater. Sci. Forum, Vol 233–234, 1997, p 3–20
• M. Carsi, A. Fernandez-Vicente, O.A. Ruano, and O.D. Sherby, Processing, Microstructure, Strength,
and Ductility Relationships in Ultrahigh Carbon Steel Assessed by High Strain Rate Torsion Testing,
Mater. Sci. Technol., Vol 15 (No. 9), 1999, p 1087–1095
• E.P. Carton, M. Stuivinga, H. Keizers, H.J. Verbeek, and P.J. Van Der Put, Shock Wave Fabricated
Ceramic-Metal Nozzles, Appl. Compos. Mater., Vol 6 (No. 3), 1999, p 139–165
• D.R. Chichili, K.T. Ramesh, and K.J. Hemker, High Strain Rate Deformation Mechanisms in Alpha
Titanium, The Johannes Weertman Symposium, 4–8 Feb 1996 (Anaheim, CA), Minerals, Metals and
Materials Society/AIME, Warrendale, PA, 1996, p 437–448
• Y. Estrin and A. Molinari, Constitutive Modelling of High Strain-Rate Deformation: Application to
Adiabatic Shear Banding, Advances in Fracture Research, ICF9, Vol 6, High Strain Rate Fracture and
Impact Mechanics, 1–5 April 1997 (Sydney, Australia), Elsevier Science Ltd., Oxford, UK, 1997, p
2755–2769
• J.C. Fu, C. Labbe, J.L. Lataillade, F. Collombet, E. Sellier, and Y. Le Petitcorps, Mechanical Properties
of Composite Materials (SiC/224 and SiC/8090) in Torsion and Tension at High Strain Rate and
Temperature, EURODYMAT 94, 26–30 Sept 1994 (Oxford, UK), Les Editions de Physique Les Ulis,
Les Ulis cedex A, France, 1994 or J. Phys. (France) IV, Vol 4, (C8), p 219–224 Sept 1994
• Y. Gordeev, V. Redkin, and A. Staver, Influence Of Shock-Wave Ultrafine Particles on Some Properties
of Hard Metals Composites, 1996 European Conference on Advances in Hard Materials Production,
27–29 May 1996 (Stockholm, Sweden), European Powder Metallurgy Association, Shrewsbury, UK,
1996, p 135–140
• D. Grady, Scattering as a Mechanism for Structured Shock Waves in Metals, Dynamic Deformation and
Failure Mechanics of Materials, 22–24 May 1997 (Pasadena), J. Mech. Phys. Solids, Vol 46 (No. 10),
1998, p 2017–2032
• G.T. Gray III, Influence of High-Strain Rate and Temperature on the Mechanical Behavior of Ni-, Fe-,
and Ti-Based Aluminides, Deformation and Fracture of Ordered Intermetallic Materials III, 6–10 Oct
1996 (Cincinnati, OH), Minerals, Metals and Materials Society/AIME, Warrendale, PA, 1996, p 57–73
• B.Q. Han, S.R. Agnew, and D.C. Dunand, High-Strain-Rate Deformation of Pure Aluminum Reinforced
with 25% Alumina Submicron Particles near the Solidus Temperature, Scr. Mater., Vol 40 (No. 7),
1999, p 801–808
• M.S.J. Hashmi and M.M. Haque, High Strain Rate Properties of an Aluminum Alloy and High Purity
Copper at Room Temperature (Retroactive Coverage), International Symposium on Intense Dynamic
Loading and Its Effects, 3–7 June 1986 (Beijing, China), Science Press, Beijing, China, 1986, p 637–
648
• K. Higashi, T. Mukai, K. Kaizu, S. Tanimura, and S. Tsuchida, Influence of Temperature on Stability of
High Strain Rate Deformation in Some Commercial Aluminum Alloys, Mechanical Behaviour of
Materials—VI, Vol I, 29 July–2 Aug 1991 (Kyoto, Japan), Pergamon Press plc, Oxford, UK, 1992, p
307–312.
• K. Higashi, T. Mukai, S. Tanimura, T.G. Nieh, and J. Wadsworth, Temperature Dependence of
Mechanical Properties at High Strain Rate in Three Mechanically Alloyed Aluminum Alloys,
Proceedings of the Thirty-Seventh Japan Congress on Materials Research, Sept 1993 (Kyoto, Japan),
Society of Materials Science, Kyoto, Japan, 1994, p 27–32
• M.F. Horstemeyer and D.A. Mosher, High Strain Rate Effects on Cast A356 Aluminum Alloy,
Materials Solutions 98, 12–15 Oct 1998 (Rosemont, IL), Advances in Aluminum Casting Technology,
ASM International, 1998, p 149–150
• J.W. House, L.L. Wilson, and M.E. Nixon, High Strain-Rate Material Behavior Using Taylor Anvil
Experiments, Mechanical Behaviour of Materials—VI, Vol I, 29 July–2 Aug 1991 (Kyoto, Japan),
Pergamon Press plc, Oxford, UK, 1992, p 343–349
• N. Igata, K. Kawata, M. Itabashi, H. Yumoto, K. Sawada, and H. Kitahara, Plastic Deformation of Iron
and Steel at High Strain Rate, Advanced Materials for Future Industries: Needs and Seeds, 11–14 Dec
1991 (Chiba, Japan), International Convention Management, Inc., Tokyo, Japan, 1991, p 1121–1129
• International Workshop on Industrial Applications of Explosion, Shock-Wave and High Pressure
Phenomena (ESHP Workshop), 27–28 Oct 1997 (Kumamoto, Japan), J. Mater. Process. Technol., Vol
85 (No. 1–3), 1999
• Z. Jin and T.R. Bieler, An Investigation of High Strain Rate Superplastic Deformation Mechanisms by
Means of Texture Analysis, Advances in Superplasticity and Superplastic Forming, 2–5 Nov 1992
(Chicago, IL), Minerals, Metals and Materials Society, Warrendale, PA, 1993, p 121–132
• Z. Jin, G.T. Gray III, and M. Yamaguchi, Deformation of Polysynthetically Twinned (PST) TiAl
Crystals at High-Strain Rate and High Temperature, High-Temperature Ordered Intermetallic Alloys
VII, 2–5 Dec 1996 (Boston, MA), Materials Research Society, Pittsburgh, PA, 1997, p 189–194
• G.I. Kanel, Some New Data on Deformation and Fracture of Solids under Shock-Wave Loading,
Dynamic Deformation and Failure Mechanics of Materials, 22–24 May 1997 (Pasadena, CA), J. Mech.
Phys. Solids, Vol 46 (No. 10), 1998, p 1869–1886
• L.J. Kecskes and I.W. Hall, High-Strain-Rate Response of Hot-Explosively Consolidated W-Ti Alloys,
J. Mater. Res., Vol 14 (No. 7), 1999, p 2838–2848
• W.-J. Kim and J.-K. Kim, High Strain-Rate Superplasticity in a Fine-Grained PM 7475 Al Alloy,
Metals and Mater., Vol 4 (No. 6), 1998, p 1133–1141
• D.W. Kum, W.J. Kim, and G. Frommeyer, High Strain Rate Superplasticity of an Ultra-Fine Grained
Al-Ti-Fe Alloy, Scr. Mater., Vol 40 (No. 2), 1988, p 223–228
• J. Lankford, A. Bose, and H. Couque, High Strain Rate Behavior of Tungsten Heavy Alloys, High
Strain Rate Behavior of Refractory Metals and Alloys, Oct 1991 (Cincinnati, OH), Minerals, Metals and
Materials Society, Warrendale, PA, 1992, p 267–287
• J. Lankford, H. Couque, A. Bose, and C.E. Anderson, Microstructure Dependence of High-Strain-Rate
Deformation and Damage Development in Tungsten Heavy Alloys, Shock-Wave and High-Strain-Rate
Phenomena in Materials, Marcel Dekker, Inc., 1992, p 137–145
• D.H. Lassila, M. Leblanc, and G.T. Gray III, High-Strain-Rate Deformation Behavior of Shocked
Copper, Shock-Wave and High-Strain-Rate Phenomena in Materials, Marcel Dekker, Inc., 1992, p 587–
595
• B.F. Levin, K.S. Vecchio, J.N. DuPont, and A.R. Marder, Solid Particle Erosion Resistance and High
Strain Rate Deformation Behavior of Inconel-625 Alloy, Superalloys 718, 625, 706 and Various
Derivatives, 15–18 June 1997 (Pittsburgh, PA), Minerals, Metals and Materials Society/AIME,
Warrendale, PA, 1997, p 479–488
• Y. Liu, Y. Li, K.T. Ramesh, and J. Van Humbeeck, High Strain Rate Deformation of Martensitic NiTi
Shape Memory Alloy, Scr. Mater., Vol 41 (No. 1), 1999, p 89–95
• M. Mabuchi, T. Imai, and K. Higashi, High Strain Rate Superplastic Behavior in Si
3
N
4
/Aluminum
Composites, Aspects of High Temperature Deformation and Fracture in Crystalline Materials, 28–31
July 1993 (Nagoya, Japan), The Japan Institute of Metals, Sendai, Japan, 1993, p 471–478
• M. Mabuchi and K. Higashi, Processing, Properties and Applications of High Strain Rate Superplastic
Materials, Second Symp. on Hot Deformation of Aluminum Alloys II, 11–15 Oct 1998 (Rosemont, IL),
Hot Deformation of Aluminum Alloys II, Minerals, Metals and Materials Society/AIME, 1998, p 87–99
• D. Macdougall, A Radiant Heating Method for Performing High-Temperature High-Strain-Rate Tests,
Meas. Sci. Technol., Vol 9 (No. 10), 1998, p 1657–1662
• L.S. Magness, Jr., High Strain Rate Deformation Behaviors of Kinetic Energy Penetrator Materials
during Ballistic Impact, Shear Instabilities and Viscoplasticity Theories, 14–16 Sept 1992 (San Diego,
CA) or Mech. Mater., Vol 17 (No. 2–3), 1994, p 147–154
• T. Maki, Microstructural Evolution during High Strain Rate Superplastic Deformation in Microduplex
Stainless Steel, Towards Innovation in Superplasticity I, 23–24 July 1996 (Kyoto, Japan) or Mater. Sci.
Forum, Vol 233–234, 1997, p 139–146
• S.A. Maloy and G.T. Gray III, High Strain Rate Deformation of Cast Ti-48Al-2Nb-2Cr in the Duplex
Morphology, Gamma Titanium Aluminides, 13–16 Feb 1995 (Las Vegas, NV), Minerals, Metals and
Materials Society/AIME, Warrendale, PA, 1995, p 307–314
• K. Matsuki, M. Tokizawa, and Y. Murakami, Microstructure Change during High Strain Rate
Superplastic Deformation in a PM 7475 Al-0.7Zr Alloy, Superplasticity in Metals, Ceramics, and
Intermetallics, 16–19 April 1990 (San Francisco, CA), Materials Research Society, Pittsburgh, PA,
1990, p 265–270
• K. Matsuki, H. Kawakami, M. Tokizawa, Y. Murakami, and S. Murakami, High Strain Rate
Superplasticity and Mechanical Properties after Superplastic Deformation of MA 2024Al-Sic Particulate
Composites, Aluminum Alloys: Their Physical and Mechanical Properties, ICAA5, Part 2, 1–5 July
1996 (Grenoble, France) or Mater. Sci. Forum, Vol 217–222 (No. 2), 1996, p 1163–1174
• H. Matsumoto, Analysis of State Compressed by a Plane Shock Wave, Nippon Zairyo Kyodo Gakkaishi
(J. Jpn. Soc. Strength Fract. Mater.), Vol 32 (No. 3), 1998, p 81–90
• H. Matsumoto, Estimation of Shock-Compressed Region by Analysis of Propagation of Shock Wave
and Rarefaction Wave, Nippon Zairyo Kyodo Gakkaishi (J. Jpn. Soc. Strength Fract. Mater.), Vol 33
(No. 1), 1999, p 17–24
• L.G. Melin, P. Stahle, and K.G. Sundin, High Strain Rate Tensile Testing Using Microscopic High
Speed Photography, 11th Int. Conf. on Experimental Mechanics, 24–28 Aug 1998 (Oxford, UK),
Experimental Mechanics: Advances in Design, Testing and Analysis I, 1998, p 175–179
• L.A. Merzhievsky and A.V. Tyagel'sky, Dislocation Kinetics of Shock Wave Metal Deformation, 3rd
International Conference on Mechanical and Physical Behaviour of Materials under Dynamic Loading
(DYMAT 91), 14–18 Oct 1991 (Strasbourg, France), J. Phys. (France) IV, Vol 1, (Colloq. No. 3, Suppl.
JP III, No. 8), 1991, p 525–531
• Y. Meunier, R. Roux, and G. Pont, Experimental and Theoretical Approaches to the High Strain Rate
Effect on the Properties of Armour Steels, Structures under Shock and Impact, July 1989 (Cambridge,
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