A stress intensity factor solution for a cracked slab subjected to an arbitrary thermal shock on one surface has been derived. As a first step, the transient temperature distribution was calculated for an arbitrary surface loading through the use of Duhamul’s integral relationship and the unit response for a slab that is insulated on the other face. The arbitrary nature of the transient surface loading was accommodated by a versatile polynomial containing both integral- and half-order terms. Once the resulting transient stress states were determined via elasticity theory, the resulting stress intensification for an arbitrary crack was approximated using a weight-function approach. The procedure was checked with known stress intensity solutions for an edge-cracked plate subjected to a linear down shock followed by a constant temperature soak. Excellent agreement was observed for this test case for a variety of crack lengths.

Issue Section:
Research Papers
Keywords:
slabs, thermal stress cracking, thermal shock, crack-edge stress field analysis, plates (structures), thermoelasticity, polynomials, structural engineering
Topics:
Polynomials, Slabs, Stress, Thermal shock, Transients (Dynamics), Fracture (Materials), Thermoelasticity
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 by American Society of Mechanical Engineers
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