Numerical form-finding of geotensoid tension truss for mesh reflector

Numerical form-finding of geotensoid tension truss for mesh reflector

The parabolic surface of most large deployable reflectors is formed by a reflective mesh attached to a cable net. This paper presents a new approach to calculate a geodesic tension truss that ensures both appropriate node positioning and uniform tension. It is based on a force density strategy coupl...

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Bibliographic Details
Published in:Acta astronautica Vol. 76; pp. 154 - 163
Main Authors: Morterolle, Sébastien, Maurin, Bernard, Quirant, Jérôme, Dupuy, Christian
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-07-2012
Elsevier
Subjects:
Cable net
Engineering Sciences
Force density method
Materials and structures in mechanics
Mechanics
Mechanics of materials
Physics
Structural mechanics
Uniform tension
Uniform tension
Cable net
Force density method
cable net
force density method
uniform tension
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Summary:The parabolic surface of most large deployable reflectors is formed by a reflective mesh attached to a cable net. This paper presents a new approach to calculate a geodesic tension truss that ensures both appropriate node positioning and uniform tension. It is based on a force density strategy coupled with geometrical constraints. Uniform tension is achieved by iterations on coefficients of force density. Nodes of net are located on the paraboloid by controlling additional forces. Several applications illustrate the method on various types of net patterns and parabolic surfaces. The accuracy of obtained net is then evaluated by calculation of the systematic surface error due to faceting. Attachment of the net to a rim structure with additional cables is also discussed. ► LDR parabolic surface is formed by a reflective mesh attached to a cable net. ► We propose a new method to calculate the form of the tension truss. ► It ensures uniform tension and exact node positioning (“geotensoid” configuration). ► Applications on axi-symetric and offset antennas show the efficiency of the approach.
ISSN:0094-5765
1879-2030
DOI:10.1016/j.actaastro.2012.02.025