A new exhaustive semi-analytical method to calculate stress distribution on the surface of a curved beam with circular cross section, with an application to helical compression springs
DOI10.1016/j.euromechsol.2023.105191zbMath1530.74042OpenAlexW4388921298MaRDI QIDQ6141165
Guillaume Cadet, Manuel Paredes
Publication date: 2 January 2024
Published in: European Journal of Mechanics. A. Solids (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.euromechsol.2023.105191
Rods (beams, columns, shafts, arches, rings, etc.) (74K10) Analytic approximation of solutions (perturbation methods, asymptotic methods, series, etc.) of equilibrium problems in solid mechanics (74G10) Finite element methods applied to problems in solid mechanics (74S05)
Cites Work
- Unnamed Item
- Theory of optimal residual stresses and defects distribution
- A novel finite element model for helical springs
- Exact analysis of curved beams and arches with arbitrary end conditions: a Hamiltonian state space approach
- A concise finite element model for simple straight wire rope strand
- Maximum principal tensile stress and fatigue crack origin for compression springs
- A concise finite element model for three-layered straight wire rope strand
- Stress analysis of generally asymmetric non-prismatic beams subject to arbitrary loads
- Linear static isogeometric analysis of an arbitrarily curved spatial Bernoulli-Euler beam
- An engineering theory of thick curved beams loaded in-plane and out-of-plane: 3D stress analysis
- Geometrically exact static isogeometric analysis of an arbitrarily curved spatial Bernoulli-Euler beam
- A simplified theory of FG curved beams
- A geometrically exact beam finite element for curved thin-walled bars with deformable cross-section
- Statically indeterminate contacts in axially loaded wire strand
- Finite element method for the stress analysis of isotropic cylindrical helical spring
- Geometrically exact isogeometric Bernoulli-Euler beam based on the Frenet-Serret frame
- On helical springs of finite thickness
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