An Improved Thermo-Ratcheting Boundary of Pressure Pipeline

Qian Hua Kan; Jian Li; Han Jiang; Guo Zheng Kang

doi:10.4028/www.scientific.net/KEM.725.311

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 725An Improved Thermo-Ratcheting Boundary of Pressure...

An Improved Thermo-Ratcheting Boundary of Pressure Pipeline

Abstract:

The thermal ratcheting boundary of pressure pipeline is a popular topic in nuclear power engineering. The existed thermal ratcheting boundary based on the Bree diagram is conservative for structures subjected to the thermo-mechanically coupled loadings since it was obtained only from an elastic-perfectly plastic model. Therefore, it is necessary to improve the existed thermal ratcheting boundary based on a reasonable constitutive model. The Bree diagram was validated firstly by the linear relationship between the plastic strain increment and mechanical stress by finite element method. And then the influences of different constitutive models, such as elastic-perfectly plastic, multi-linear kinematic hardening, Chaboche and Abdel Karim-Ohno models, on the thermal ratcheting boundary of pressure pipeline were investigated numerically. It is found that the elastic-perfectly plastic and multi-linear kinematic hardening models provide the lower and upper bounds for the thermal ratcheting boundary, respectively. Finally, an improved thermal ratcheting boundary by introducing the dimensionless axial tensile stress was proposed based on the Bree diagram, the improved thermal ratcheting boundary covered the present cases with different ratios of mechanical stress over thermal stress.

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Advances in Engineering Plasticity and its Application XIII

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Periodical:

Key Engineering Materials (Volume 725)

Pages:

311-315

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.725.311

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Online since:

December 2016

Authors:

Qian Hua Kan*, Jian Li, Han Jiang, Guo Zheng Kang

Keywords:

Constitutive Model, Finite Element Method (FEM), Thermal Mechanical Loading, Thermo-Ratcheting Boundary

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References

[1] J. Bree, Elastic-plastic behaviour of thin tubes subjected to internal pressure and intermittent high-heat fluxes with application to fast-nuclear-reactor fuel elements, J. Strain Anal. Eng. Design. 2 (1967) 226-238.

DOI: 10.1243/03093247v023226

Google Scholar

[2] A.M. Goodman, Incremental plastic deformation of a cylinder subjected to cyclic thermal loading, Proc. Conf. Non-Linear Problems in Stress Analysis, Durham. (1978) 317-344.

Google Scholar

[3] J.W. Simon, G. Chen, D. Weichert. Shakedown analysis of nozzles in the knuckle region of torispherical heads under multiple thermo-mechanical loadings, Int. J. Pres. Ves. Pip. 116 (2014) 47-55.

DOI: 10.1016/j.ijpvp.2014.01.004

Google Scholar

[4] M.E. Angiolini, G. Aiello, P. Matheron, L. Pilloni, G.M. Giannuzzi, Thermal ratcheting of a P91 steel cylinder under an axial moving temperature distribution, J. Nucl. Mater. 472 (2016) 215-226.

DOI: 10.1016/j.jnucmat.2016.01.028

Google Scholar

[5] J.L. Chaboche, Constitutive equations for cyclic plasticity and cyclic viscoplasticity, Int. J. Plasticity. 5 (1989) 247-302.

DOI: 10.1016/0749-6419(89)90015-6

Google Scholar

[6] M. Abdel-Karim and N. Ohno, Kinematic Hardening Model Suitable for Ratchetting with Steady State, Int. J. Plasticity. 16 (2000) 225-240.

DOI: 10.1016/s0749-6419(99)00052-2

Google Scholar