An elastic–plastic and residual stress analysis steel reinforced thermoplastic composite cantilever beam

In this study an elastic-plastic stress analysis is carried out on a steel fiber reinforced thermoplastic composite cantilever beam loaded uniformly at the upper surface. An analytical solution is found satisfying both the governing differential equation in two dimensional case and boundary conditions. In this solution, the intensity of the uniform force is chosen small, therefore the transversely normal stress component is neglected in comparison with the other stress components. The thermoplastic matrix is reinforced unidirectionally by steel fibers. The orientation angles of the fibers are chosen as 0°, 30°, 45°, 60° and 90°. The plastic region begins first at the upper surface of the beam for 30° and 45° orientation angles. However, it starts earlier at the lower surface for 60° orientation angle. The intensity of the normal residual stress component in the axial direction of the beam is maximum at the upper and/or lower surfaces in the beam. The intensity of the shear residual stress is maximum on or around the axial axis of the beam.

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Implicit Algorithm of Hybrid Hardening Elastic-Plastic Constitutive Relation and its Application in Autofrettage Residual Stress Analysis

Journal of Software Engineering ◽

10.3923/jse.2015.144.156 ◽

2014 ◽

Vol 9 (1) ◽

pp. 144-156

Author(s):

Li Ning ◽

Li Yourong ◽

Zhou Sizhu

Keyword(s):

Residual Stress ◽

Stress Analysis ◽

Constitutive Relation ◽

Implicit Algorithm ◽

Elastic Plastic ◽

Residual Stress Analysis

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Elastic-Plastic Stress Analysis in a Thermoplastic Composite Cantilever Beam Loaded by Bending Moment

Journal of Reinforced Plastics and Composites ◽

10.1177/073168440202100202 ◽

2002 ◽

Vol 21 (2) ◽

pp. 175-176

Author(s):

Onur Sayman ◽

Mesut Uyaner ◽

Necmeitin Tarakçioglu

Keyword(s):

Stress Analysis ◽

Cantilever Beam ◽

Yield Criterion ◽

Stress Component ◽

Bending Moment ◽

Thermoplastic Composite ◽

Plastic Deformations ◽

Elastic Plastic ◽

Governing Differential Equation ◽

Plastic Stress

In this study, an elastic-plastic stress analysis is carried out in a thermoplastic composite cantilever beam loaded by a bending moment at the free end. The composite beam is reinforced unidirectionally by steel fibers at 0, 30. 45, 60, and 90° orientation angles. An analytical solution is performed for satisfying both the governing differential equation in the plane stress case and boundary conditions for small plastic deformations. The solution is carried out under the assumption of the Bernoulli-Navier hypotheses. It is found that the intensity of the residual stress component of σ x is maximum at the upper and lower surfaces or at the boundary of the elastic and plastic regions. The composite material is assumed to be as hardening linearly. The Tsai-Hill theory is used as a yield criterion.

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An Elastic-Plastic Stress Analysis in a Unidirectional Reinforced Steel Fiber Thermoplastic Composite Cantilever Beam Loaded by a Single Force at the Free End

Journal of Reinforced Plastics and Composites ◽

10.1177/0731684405044894 ◽

2005 ◽

Vol 24 (5) ◽

pp. 457-469 ◽

Cited By ~ 2

Author(s):

Nurettin Arslan ◽

Tamer Ozben

Keyword(s):

Stress Analysis ◽

Cantilever Beam ◽

Steel Fiber ◽

Thermoplastic Composite ◽

Elastic Plastic ◽

Reinforced Steel ◽

Single Force ◽

Plastic Stress

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Elastic-Plastic Stress Analysis in a Thermoplastic Composite Cantilever Beam Loaded by Bending Moment

Journal of Reinforced Plastics and Composites ◽

10.1177/0731684402021002367 ◽

2002 ◽

Vol 21 (2) ◽

pp. 175-192

Author(s):

Onur Sayman ◽

Mesut Uyaner ◽

Necmettin Tarakçioglu

Keyword(s):

Stress Analysis ◽

Cantilever Beam ◽

Yield Criterion ◽

Stress Component ◽

Bending Moment ◽

Thermoplastic Composite ◽

Plastic Deformations ◽

Elastic Plastic ◽

Governing Differential Equation ◽

Plastic Stress

In this study, an elastic-plastic stress analysis is carried out in a thermoplastic composite cantilever beam loaded by a bending moment at the free end. The composite beam is reinforced unidirectionally by steel fibers at 0, 30, 45, 60, and 90° orientation angles. An analytical solution is performed for satisfying both the governing differential equation in the plane stress case and boundary conditions for small plastic deformations. The solution is carried out under the assumption of the Bernoulli-Navier hypotheses. It is found that the intensity of the residual stress component of σ x is maximum at the upper and lower surfaces or at the boundary of the elastic and plastic regions. The composite material is assumed to be as hardening linearly. The Tsai-Hill theory is used as a yield criterion.

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