Determination of the Wall Thickness of Cylindrical Pressure Vessels Intended for Elevated Temperature Service: New Proposals for the Guidance of Design Engineers

British Standards Institution B.S. 1515:1965 Fusion welded pressure vessels for use in chemical, petroleum and allied industries 1965 (London).

Report of the committee of enquiry on pressure vessels 1969 (H.M.S.O.).

Bailey R. W. ‘Creep relationships and their application to pipes, tubes and cylindrical parts under internal pressure’, Proc. Instn mech. Engrs 1951 164, (No. 4), 425.

Johnson A. E. Henderson J. Khan B. ‘Behaviour of metallic thick-walled cylindrical vessels or tubes subject to high internal or external pressures at elevated temperatures’, Proc. Instn mech. Engrs 1961 175, (No. 25), 1043.

Smith E. M. ‘Primary creep behaviour of thick tubes’, Proc. Instn mech. Engrs 1963–64 178, (Pt 3L), 135.

Larke E. C. Parker R. J. ‘Circumferential creep strain of cylinders subjected to internal pressure: A comparison of the theories of Johnson and Bailey’, J. mech. Engng Sci. 1966 8, (No. 1), 22.

Larke E. C. Parker R. J. Advances in creep design: the A. E. Johnson Memorial Volume (to be published 1971, Elsevier Publishing Co. Ltd, Barking, Essex).

Skelton W. J. Crossland B. ‘Creep of thick-walled cylinders: Development of a testing machine and preliminary results’, Proc. Instn mech. Engrs 1967–68 182, (Pt 3C), 139.

Skelton W. J. Crossland B. ‘Results of high sensitivity tensile creep tests on a 019 per cent carbon steel used for thick-walled cylinder creep tests’, Proc. Instn mech. Engrs 1967–68 182, (Pt 3C), 151.

Parker R. J. ‘Expansion and deformation in thick cylinders’, Chem. Process Engng 1967 48, (No. 11), 103.