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Abstract

The effects of machine stiffness on the strain rates occurring in testpieces are discussed. The actual rate of strain can be markedly different from the simple expression of (crosshead velocity ÷ gauge length) for nominal strain rate. As the speed of testing machines is increased, an upper speed limit is set on the use of conventional machines by the effects of wave propagation in the testpiece: non-uniform stress and strain patterns are set up which make normal interpretation of mechanical property data very difficult. Some criteria determining the upper range of machine speeds are given in terms of the machine stiffness and specimen size. These bounds are further modified at high testing rates by the acceleration available on the machine-drive system. The overall restrictive limits are more noticeable the slower the propagation of waves in the testpiece, i.e. the limiting speed is lower for polymers than for metals.

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References

Goforth

R. E.

‘High strain rate effects’, High velocity forming of metals (Ed. Wilson

) 1964 (Prentice-Hall, Inc., Englewood Cliffs, N.J.).

Lindholm

U. S.

‘Dynamic deformation of metals’, Behavior of materials under dynamic loading (Ed. Huffington

N. J.

) 1965 (American Society of Mechanical Engineers, New York).

Hamstad

M. A.

Gillis

P. P.

‘Effective strain rates in low speed uniaxial tension tests’, Mat. Res. Stands 1966 6, 569.

Cooper

R. H.

Campbell

J. D.

‘Testing of materials at medium rates of strain’, J. mech. Engng Sci. 1967 9, 278.

Atkins

A. G.

‘High strain rates in metal forming processes’, Oxford University Engineering Department Report.

Orowan

‘The cam plastometer’, 1950 B.I.S.R.A. Report MW/F/22/50.

Balchin

N. C.

Mordike

B. L.

‘An improved tensile testing apparatus’, Lab. Meth. 1961 63, 313.

Kolsky

‘The propagation of mechanical pulses in anelastic solids’, Behavior of materials under dynamic loading (Ed. Huffington

N. J.

) 1965 (American Society of Mechanical Engineers, New York).

Shippy

D. N.

Gillis

P. P.

Hodge

K. G.

‘Computer simulation of a high speed tension test’, Appl. Polymer Symp. 1967 5, 311 (Interscience, New York, for Plas-Tech. Equipment Corporation).

10.

Baron

H. G.

‘Stress/strain curves of some metals and alloys at low temperatures and high rates of strain’, J. Iron Steel Inst. 1956 182, 354.

11.

Clark

D. S.

‘The behavior of metals under dynamic loading’, Trans. Am. Soc. Metals 1954 46, 34.

12.

Lee

E. H.

Wolf

‘Plastic wave propagation effects in high speed testing’, J. appl. Mech., Trans. Am. Soc. mech. Engrs 1951 73, 379.

13.

Krafft

J. M.

‘Instrumentation for high speed strain measurement’, Response of metals to high velocity deformation (Ed. Shewman

P. G.

Zackay

V. F.

) 1961 (Interscience, New York).

14.

Fry

L. H.

‘Speed in tension testing and its influence on yield point values’, Proc. Am. Soc. Test Mater. 1940 40, 625.

Maximum attainable uniform strain rates with high-speed-crosshead testing machins: Theoretical considerations

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References