The Stress Concentration Factors in Cylindrical Tubes with Transverse Circular Holes

H. T. Jessop; C. Snell; I. M. Allison

doi:10.1017/S0001925900001608

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The “frozen stress” techniques of photoelasticity can give a complete knowledge of the stress, system in a solid body, but the examination of the stresses requires more time and care than in corresponding flat plate tests. In tests on tubes with transverse circular holes, sponsored by The Royal Aeronautical Society, all practicable geometrical shapes are examined and the maximum stress is measured in tension, bending and torsion. The results are comprehensive and show the inadequacy of previous results. In all cases the maximum stress occurs inside the bore of the hole. The accuracy of all the graphs of stress concentration factors is better than five per cent.

References

1. Thum, A. and Kirmser, W. Tension, Bending and Torsion of Shafts with Transverse Holes. V.D.I. Forschungsheft, 419. March-April 1943.Google Scholar

2. Frocht, M. M. Stress Concentrations in Shafts with Transverse Circular Holes in Tension. Journal of Applied Physics, January 1944.Google Scholar

3. Seeger, G. Stresses in Transversely Loaded Shafts subjected to Torsion. Die Technik, 3. July 1948; Engineers’ Digest, February 1949.Google Scholar

4. Frocht, M. M. Stresses in Bent Circular Shafts with Transverse Holes. Journal of Applied Mechanics, March 1944.Google Scholar

5. Peterson, R. E. and Wahl, A. M. Two- and Three-dimensional Cases of Stress Concentration and Comparison with Fatigue Strength. Transactions of the American Society of Mechanical Engineers; Journal of Applied Mechanics, Vol. 58, 1936 Google Scholar

6. Heywood, R. B. Designing by Photoelasticity. Chapman and Hall, London, 1952.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Allison, I. M. 1961. The Elastic Stress Concentration Factors in Shouldered Shafts. Aeronautical Quarterly, Vol. 12, Issue. 2, p. 189.

Allison, I M 1965. Extrapolation methods for evaluating boundary stresses. British Journal of Applied Physics, Vol. 16, Issue. 1, p. 93.

VAN DYKE, P. 1965. Stresses about a circular hole in a cylindrical shell.

VAN DYKE, PETER 1965. Stresses about a circular hole in a cylindrical shell. AIAA Journal, Vol. 3, Issue. 9, p. 1733.

Guz, A. N. 1969. Stress concentration around orifices in thin shells (survey). Soviet Applied Mechanics, Vol. 5, Issue. 3, p. 217.

1969. Photoelasticity for Designers. p. 367.

Pierce, D. N. and Chou, S. I. 1973. Stresses around elliptic holes in circular cylindrical shells. Experimental Mechanics, Vol. 13, Issue. 11, p. 487.

Guz', A. N. Chernyshenko, I. S. Chekhov, Val N. Chekhov, Vik N. and Shnerenko, K. I. 1979. Investigations in the theory of thin shells with openings (review). Soviet Applied Mechanics, Vol. 15, Issue. 11, p. 1015.

Rajaiah, K. and Durelli, A. J. 1981. Optimization of hole shapes in circular cylindrical shells under axial tension. Experimental Mechanics, Vol. 21, Issue. 5, p. 201.

Montague, P. and Horne, M. R. 1981. The Behaviour of Circular Tubes with Large Openings Subjected to Axial Compression. Journal of Mechanical Engineering Science, Vol. 23, Issue. 5, p. 225.

Rajaiah, K. and Ramesh Kumar, R. 1982. Optimum hole shapes in circular cylindrical shells under tension and torsion. Mechanics Research Communications, Vol. 9, Issue. 2, p. 85.

Abdul-Mihsein, M J and Fenner, R T 1983. Some boundary integral equation solutions for three-dimensional stress concentration problems. The Journal of Strain Analysis for Engineering Design, Vol. 18, Issue. 4, p. 207.

Rajaiah, K. and Kumar, R.Ramesh 1985. Stresses around circular, square and optimized holes in circular cylindrical shells under torsion. International Journal of Solids and Structures, Vol. 21, Issue. 2, p. 177.

McBroom, R. J. Cheal, E. J. and Hayes, W. C. 1988. Strength reductions from metastatic cortical defects in long bones. Journal of Orthopaedic Research, Vol. 6, Issue. 3, p. 369.

Edgerton, Bradley C. An, Kai‐Nan and Morrey, Bernard F. 1990. Torsional strength reduction due to cortical defects in bone. Journal of Orthopaedic Research, Vol. 8, Issue. 6, p. 851.

Kuo, R.F. Chao, E.Y.S. Rim, K. and Park, J.B. 1991. The effect of defect size on the stress concentration and fracture characteristics for a tubular torsional model with a transverse hole. Journal of Biomechanics, Vol. 24, Issue. 2, p. 147.

Mahinfalah, M. and Harms, M. 1994. Stress concentrations associated with circular holes in cylinders and bone in torsion. Experimental Mechanics, Vol. 34, Issue. 3, p. 224.

Grant, R J and Smart, J 1997. A parametric study of the elastic stress distribution in pin-loaded tubes. The Journal of Strain Analysis for Engineering Design, Vol. 32, Issue. 3, p. 213.

Grant, R J and Smart, J 1999. Crack growth in pin-loaded tubes Part 1: Numerical analysis. The Journal of Strain Analysis for Engineering Design, Vol. 34, Issue. 4, p. 253.

Ho, Ki Wai Kevin Gilbody, Julian Jameson, Toby and Miles, Anthony W. 2010. The effect of 4 mm bicortical drill hole defect on bone strength in a pig femur model. Archives of Orthopaedic and Trauma Surgery, Vol. 130, Issue. 6, p. 797.

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