Morphing composite cylindrical lattices: enhanced modelling and experiments
| Main Author: | McHale, CiarĂ¡n |
|---|---|
| Format: | info dataset eJournal |
| Bahasa: | eng |
| Terbitan: |
, 2019
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| Subjects: | |
| Online Access: |
https://zenodo.org/record/3539249 |
Daftar Isi:
- Advanced composite materials enable the development of lightweight and stiff deployable structures that have significant potential for the space sector. In particular, the morphing cylindrical lattice can deploy from a small cylinder to one that is substantially thinner and longer, and is particularly suited for deploying solar arrays or antennae. The morphing behaviour of the lattice stems from the nonlinear strain energy state obtained from prestressing strips of orthotropic material. Current analytical models used to describe the behaviour of morphing lattices only consider bending strains in the strain energy formulation. This paper extends the state-of-the-art modelling techniques by including both transverse curvature and membrane strains, associated with non-zero Gaussian curvature, in the strain energy formulation. Transverse curvatures in tandem with longitudinal curvatures lead to the development of membrane strains, giving a complex interplay between membrane and bending strain energies and their combined effect on morphing properties of the lattice providing a rich tailorable nonlinear response. The analytical model developed is compared against finite element modelling and the first experimental results reported for such multistable composite helical lattices, showing good agreement over a range of designs. Related publications/conference objects: C. McHale, D. A. Hadjiloizi, R. Telford and P. M. Weaver, " The Significance of Transverse Curvature and Membrane Strains in Modelling of Morphing Composite Lattice Structures", MECHCOMP 2019, Lisbon, Portugal C. McHale, D. A. Hadjiloizi, R. Telford and P. M. Weaver, "Morphing composite cylindrical lattices: enhanced modelling and experiments" Journal of the Mechanics and Physics of Solids, p. (2nd Review), 2019