Classification System for Semi-Rigid Beam-to-Column Connections

Faridmehr, Iman; Tahir, M. M.; Lahmer, Tom

doi:10.1590/1679-78252595

Cited by 11 publications

(5 citation statements)

References 20 publications

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“…Thus, element (2,3) can be replaced at node 2 by an equivalent rotational spring whose rigidity acts in parallel with the flexural rigidity of the element (1,2); so that the of this spring is equal to k r1 = 3EI L . Two other situations, corresponding to the presence of a vertical element (3,4) whose node ( 4) is considered articulated, then fixed. As before, one can assimilate elements (2,3) and (3,4) to an equivalent rotational spring whose rigidity acts in parallel with the flexural rigidity of element (1,2); so that by adopting the principle of static condensation, the rigidity of this spring is respectively equal to k r2 = which corresponds to cases (a1-4) then by adopting an embedding at node (1) which corresponds to cases (b1-4).…”

Section: Application To Examples Of Practicementioning

confidence: 99%

“…Two other situations, corresponding to the presence of a vertical element (3,4) whose node ( 4) is considered articulated, then fixed. As before, one can assimilate elements (2,3) and (3,4) to an equivalent rotational spring whose rigidity acts in parallel with the flexural rigidity of element (1,2); so that by adopting the principle of static condensation, the rigidity of this spring is respectively equal to k r2 = which corresponds to cases (a1-4) then by adopting an embedding at node (1) which corresponds to cases (b1-4). The mechanicals and geometrical characteristics adopted for the frame are: modulus of elasticity : E = 200 kN/mm 2 ; length: L = 1m; section area: A = 13,2×10 -4 m 2 ; moment of inertia: I = 27,7×10 -8 m 4 ; density: ρ = 8050kg/m 3 .…”

Section: Application To Examples Of Practicementioning

confidence: 99%

“…Previous research on the behaviour of connections shows that such assumptions are not entirely valid and do not represent the real behaviour of nodal connections [3][4][5][6][7][8][9]. They have been adopted in practice for their simplicity in the analysis and design of structures.…”

Section: Introductionmentioning

confidence: 99%

“…𝐚 = 21β 8 − 8β6 (3186 + 61(α ri + α rj )) + 1620β4 (6408 + 268(α rj + α ri ) + 7α ri α rj )) − 583200β 2 (2808 + 192(α ri + α rj ) + 11α ri α rj ) + 157464000(540 + 52(α rj + α ri ) + 5α ri α rj )) C 1 = 4897760256000 − 32β 10 + 702919296000α ri + 702919296000α rj + 90699264000α ri α rj + 108β 8 (376 + 7α ri + 7α rj ) − 576β 6 (30996 + 1256α ri + 1256α rj + 31α ri α rj ) + 155520β4 (20952 + 1395α ri + 1395α rj + 74α ri α rj ) − 1007769600β 2 (234 + 23α rj + α ri (23 + 2α rj )) (21β 8 − 8β 6 (3186 + 61α ri + 61α rj ) − 583200β 2 (2808 + 192(α ri + α rj ) + 11α ri α rj ) + 157464000(540 + 52(α rj + α ri ) + 5α rj )) + 1620β4 (6408 + 268(α rj + α ri ) + 7α rj )))…”

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Mechanical Modeling and General Analytical Solution for the Dynamic Buckling of Plane Structures Using a Beam-Column Element with Varying End Restraints

Beldjazia

Adman

Slimani

et al. 2021

Int. J. Str. Stab. Dyn.

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The stability of structures is an important aspect that the designer must pay particular attention to in order to ensure safety against collapse. This investigation is concerned with analytical and numerical analyses of the dynamic buckling of plane structures. A rigorous mechanical model is proposed, consisting of a beam-column element with nodal ends possessing two rotational springs of rigidities acting in parallel with the bending stiffness of the beam-column. The model is first analyzed with respect to the dynamic behavior by investigating the influence of the variation in the stiffness of the nodal springs on the fundamental frequency of the proposed mechanical model. Compression axial loading is applied to the beam-column in order to study the nonlinear dynamic behavior by introducing buckling. This novel approach is used to highlight the interaction between the fundamental frequency and the critical buckling load. Simple examples are treated using the approach and the results are compared with those obtained from a global analysis. The results revealed that it is possible to reproduce the stability analysis of a global structure by simply analyzing a target element, taking into account all elements adjacent to it with less than 1% error on the results.

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Section: Application To Examples Of Practicementioning

confidence: 99%

Section: Application To Examples Of Practicementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Mechanical Modeling and General Analytical Solution for the Dynamic Buckling of Plane Structures Using a Beam-Column Element with Varying End Restraints

Beldjazia

Adman

Slimani

et al. 2021

Int. J. Str. Stab. Dyn.

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“…The resolution of the case using an incremental method is only one element of the heuristic: the fundamental difficulty is in modelling the union when the stiffness matrix is not constant throughout the process. In the context of the idea of a tangent stiffness matrix, or simply a tangent matrix, in a non-linear finite element method (FEM), some previous works are still relevant [ 6 , 7 , 8 ].…”

Section: Introductionmentioning

confidence: 99%

Nonlinear Analysis of Rotational Springs to Model Semi-Rigid Frames

Antonio

Mancera

Hernández-Torres

et al. 2022

Entropy

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This paper explains the mathematical foundations of a method for modelling semi-rigid unions. The unions are modelled using rotational rather than linear springs. A nonlinear second-order analysis is required, which includes both the effects of the flexibility of the connections as well as the geometrical nonlinearity of the elements. The first task in the implementation of a 2D Beam element with semi-rigid unions in a nonlinear finite element method (FEM) is to define the vector of internal forces and the tangent stiffness matrix. After defining the formula for this vector and matrix in the context of a semi-rigid steel frame, an iterative adjustment of the springs is proposed. This setting allows a moment–rotation relationship for some given load parameters, dimensions, and unions. Modelling semi-rigid connections is performed using Frye and Morris’ polynomial model. The polynomial model has been used for type-4 semi-rigid joints (end plates without column stiffeners), which are typically semi-rigid with moderate structural complexity and intermediate stiffness characteristics. For each step in a non-linear analysis required to adjust the matrix of tangent stiffness, an additional adjustment of the springs with their own iterative process subsumed in the overall process is required. Loops are used in the proposed computational technique. Other types of connections, dimensions, and other parameters can be used with this method. Several examples are shown in a correlated analysis to demonstrate the efficacy of the design process for semi-rigid joints, and this is the work’s application content. It is demonstrated that using the mathematical method presented in this paper, semi-rigid connections may be implemented in the designs while the stiffness of the connection is verified.

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