In this paper, a mode identification technique in the context of spline finite strip method (SFSM) is presented to compute the contribution of primary (global, distortional and local) and secondary (shear/transverse extension) buckling modes. The base vectors corresponding to individual buckling modes are developed based on the principles of generalized beam theory. The buckling mode shape in SFSM is approximated as a linear combination of these orthonormal base vectors to evaluate the participation of individual buckling mode. The proposed mode identification technique is able to successfully quantify the participation of different buckling modes and the mode participation is comparable with mode identification using finite strip method (FSM) and generalized beam theory (GBT). Illustrative examples are presented to calculate the participation of individual modes in cold-formed steel sections under different loading and boundary conditions. Also the specific application of mode identification in SFSM is demonstrated. © 2017 Elsevier Ltd

Arul Jayachandran S

Department Of Civil Engineering

Strip Metal

Studs (structural members)

BUCKLING MODE SHAPES

COLD FORMED STEEL SECTION

Cold-formed steel

COLD-FORMED STEEL MEMBERS

FINITE STRIP METHOD

GENERALIZED BEAM THEORIES

MODE IDENTIFICATION

SPLINE FINITE STRIP METHOD

Buckling

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IIT Madras

Thin-Walled Structures

Direct strength method (DSM) for the design of cold-formed steel members recommends finite strip method (FSM) for calculating the elastic buckling stresses corresponding to local, distortional and global buckling, which are considered to be the basic input parameters for design. This paper presents application of constrained spline finite strip method (cSFSM) developed by authors for calculating pure elastic buckling stresses in DSM and hence predicting the ultimate member capacity in uniform flexure and axial compression. The elastic buckling stresses are determined for a specified set of experiments available in literature using cSFSM by considering different end conditions and failure modes and the elastic stress values are applied in DSM for calculating ultimate member capacity. For beams with simply supported-warping free ends and columns with simply supported-warping fixed ends, the DSM evaluated results using cSFSM produces results comparable with experiments. The results obtained by the comparison of DSM with experiments were not satisfactory for fixed columns and beams with simply supported-warping fixed ends. © 2019, Korean Society of Steel Construction.

International Journal of Steel Structures

Direct Strength Design of Cold-Formed Steel Members Using Constrained Spline Finite Strip Method

In this paper, an analysis procedure has been presented for cold-formed steel sections, for decomposing the buckling modes obtained using spline finite strip method (SFSM) into their primary and independent buckling modes such as local, distortional and global buckling. This procedure utilizes principles of generalized beam theory (GBT) to evaluate the restraint matrices corresponding to different modes. The restraint matrices are integrated in to spline stiffness matrices using transformation technique to extract pure modes corresponding to local, distortional and global modes. The proposed analysis technique termed as constrained spline finite strip method (cSFSM) has been validated for cold-formed steel open cross-sections subjected to axial compression and bending under various boundary conditions. The results are in agreement with buckling stresses evaluated using constrained finite strip method (cFSM) and GBT. © 2017 Elsevier Ltd

A constrained spline finite strip method for the mode decomposition of cold-formed steel sections using GBT principles

Modal buckling analysis of thin-walled members with rounded corners by using the constrained finite strip method with elastic corner elements

Constrained shell Finite Element Method for thin-walled members, Part 1: constraints for a single band of finite elements

Constrained shell Finite Element Method, Part 2: application to linear buckling analysis of thin-walled members

Shell element for constrained finite element analysis of thin-walled structural members

Identification of buckling modes in generalized spline finite strip analysis of cold-formed steel members

Journal	Data powered by TypesetThin-Walled Structures
Publisher	Data powered by TypesetElsevier Ltd
ISSN	02638231
Open Access	No