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Abstract

In this paper, a study on residual stresses in a stainless steel metal-fiber reinforced aluminium metal-matrix flat plate with a central square hole has been conducted. In the solution, a finite element method with two dimensional isoparametric rectangular nine node-elements has been employed. In the calculation of the residual stresses in the plate under uniform in-plane loads, Newton-Raphson method (initial stress method) has been used. After a steel-aluminium composite plate has been manufactured by upsetting under certain pressure and at certain temperture, some experiments have been carried out through the tensile testing machine in order to obtain mechanical properties and yield strength. Results show that a central hole or cut-out in a plate causes the residual stresses in a considerable quantity particularly near itself, which increases strength of the plate. It is also seen that the hole geometry and the orientation angle have affected residual stresses. Solutions are shown in graphical forms and in illustrations.

Keywords

metal fiber-metal matrix plates Newton-Raphson method finite element method residual stress

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Residual Stresses in Stainless Steel Fiber-Reinforced Aluminium Matrix Composite Plates with Central Square Hole

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