A linear one-dimensional model for the flexural-torsional vibrations of tapered thin-walled bars with open cross-secti

A concept of a beam superelement is suggested as a new tool in the static analysis of structures made of thin‐walled members. This proposal seems to be especially attractive for treating the problems where the existing one‐dimensional models do not provide proper solutions. This class of problems includes, for instance, the torsion of thin‐walled beams with battens and the determination of the bimoment distribution at the nodes of frames made of thin‐walled members. The entire segment of the thin‐walled beam with warping stiffener or the whole node of the frame is modelled with shell elements. The stiffness matrix of such thin‐walled beam superelement can be estimated according to the standard procedure of the enforced unit displacements. The accuracy of the proposed one‐dimensional model has proved to be comparable to that offered by the detailed FEM model where the whole structure is represented by a very large number of shell elements.

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Effect of local stiffeners and warping constraints on the buckling of symmetric open thin-walled beams with high warping stiffness

Meccanica ◽

10.1007/s11012-021-01349-9 ◽

2021 ◽

Author(s):

G. Piana ◽

E. Lofrano ◽

A. Carpinteri ◽

G. Ruta

Keyword(s):

Cross Section ◽

Bending Stiffness ◽

Dimensional Model ◽

One Dimensional ◽

Practical Applications ◽

Thin Walled ◽

Compressive Buckling ◽

The Way

AbstractLocal stiffeners affect the behaviour of thin-walled beams (TWBs). An in-house code based on a one-dimensional model proved effective in several instances of compressive buckling of TWBs but gave counterintuitive results for locally stiffened TWBs. To clarify the matter, we investigated TWBs with multi-symmetric double I cross-section, widely used in practical applications where high bending stiffness is required. Several samples were manufactured and stiffened on purpose, closing them over a small portion of the axis at different places. The samples were tested with end constraints accounting for various warping conditions. The experimental and numerical outputs from a commercial FEM code gave a key to overcome the unexpected results by the in-house code, paving the way for further studies.

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A One-dimensional Model for Thin-walled Box Girder Structures Considering the Deformable Cross-section in Dynamics

DEStech Transactions on Engineering and Technology Research ◽

10.12783/dtetr/ecae2018/27750 ◽

2019 ◽

Author(s):

LEI ZHANG ◽

WEI-DONG ZHU ◽

HAO WANG ◽

AI-MIN JI

Keyword(s):

Cross Section ◽

Dimensional Model ◽

Box Girder ◽

One Dimensional ◽

Thin Walled

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One-Dimensional Model for the Combined Heat Transfer in Open-Cell Metal Foam

Proceeding of Thermal Sciences 2004. Proceedings of the ASME - ZSIS International Thermal Science Seminar II ◽

10.1615/ichmt.2004.intthermscisemin.160 ◽

2004 ◽

Author(s):

Nihad Dukhan ◽

Pablo D. Quinones ◽

Carolina Briano ◽

Jessica Fontanez

Keyword(s):

Heat Transfer ◽

Metal Foam ◽

Dimensional Model ◽

Open Cell ◽

One Dimensional ◽

Combined Heat Transfer

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A TRANSIENT ONE-DIMENSIONAL MODEL OF MIXING AND SEGREGATION OF LIQUIDS IN PIPES

Multiphase Science and Technology ◽

10.1615/multscientechn.v22.i2.50 ◽

2010 ◽

Vol 22 (2) ◽

pp. 177-196

Author(s):

R. I. Issa ◽

A. Tomasello

Keyword(s):

Dimensional Model ◽

One Dimensional

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Modelling Techniques in Applied Glaciology: Numerical Modelling of Avalanches

Annals of Glaciology ◽

10.3189/s026030550000567x ◽

1983 ◽

Vol 4 ◽

pp. 297-297

Author(s):

G. Brugnot

Keyword(s):

Finite Difference Method ◽

Transverse Velocity ◽

Longitudinal Velocity ◽

Momentum Conservation ◽

Dimensional Model ◽

One Dimensional ◽

Modelling Techniques ◽

Reference Grid ◽

The One ◽

Near Future

We consider the paper by Brugnot and Pochat (1981), which describes a one-dimensional model applied to a snow avalanche. The main advance made here is the introduction of the second dimension in the runout zone. Indeed, in the channelled course, we still use the one-dimensional model, but, when the avalanche spreads before stopping, we apply a (x, y) grid on the ground and six equations have to be solved: (1) for the avalanche body, one equation for continuity and two equations for momentum conservation, and (2) at the front, one equation for continuity and two equations for momentum conservation. We suppose the front to be a mobile jump, with longitudinal velocity varying more rapidly than transverse velocity.We solve these equations by a finite difference method. This involves many topological problems, due to the actual position of the front, which is defined by its intersection with the reference grid (SI, YJ). In the near future our two directions of research will be testing the code on actual avalanches and improving it by trying to make it cheaper without impairing its accuracy.

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