TY - GEN
T1 - A Static Analysis of Compression and Torsion of Kresling Origami Springs
AU - Joseph, Kevin Kuriakose
AU - Dalaq, Ahmed S.
AU - Daqaq, Mohammed F.
N1 - Publisher Copyright:
© 2024, Avestia Publishing. All rights reserved.
PY - 2024
Y1 - 2024
N2 - Origami-inspired structures have increasingly been used to design various functional systems from solar cells to fluidic muscles due to their unique properties such as modulation of stiffness, and the extent of compressibility. Recently, Kresling origami springs (KOS) have gained large attention because they are deployed from compact cylindrical bellow-like structures while being able to exhibit several distinct restoring behaviours together with having a unique tension-torsion coupling. There have been few studies exploring the uniaxial response of KOS, but not the torsional aspect of the springs. In this short manuscript, we discuss the torsional response of KOS in terms of torque, relative rotation, torsional stiffness and their relation with the uniaxial response. We used a simple shell-based finite element model, specifically for KOS with a linear response (i.e. linear spring). The torsional behaviour of the KOS shown here along with the ease of manufacturing, cheap materials, and light and modular properties make origami-inspired systems a great fit for applications such as the design of torsional actuators.
AB - Origami-inspired structures have increasingly been used to design various functional systems from solar cells to fluidic muscles due to their unique properties such as modulation of stiffness, and the extent of compressibility. Recently, Kresling origami springs (KOS) have gained large attention because they are deployed from compact cylindrical bellow-like structures while being able to exhibit several distinct restoring behaviours together with having a unique tension-torsion coupling. There have been few studies exploring the uniaxial response of KOS, but not the torsional aspect of the springs. In this short manuscript, we discuss the torsional response of KOS in terms of torque, relative rotation, torsional stiffness and their relation with the uniaxial response. We used a simple shell-based finite element model, specifically for KOS with a linear response (i.e. linear spring). The torsional behaviour of the KOS shown here along with the ease of manufacturing, cheap materials, and light and modular properties make origami-inspired systems a great fit for applications such as the design of torsional actuators.
KW - Kresling Origami Springs
KW - Non-linear Dynamics
KW - Restoring Force
KW - Restoring Torque
KW - Torsional Stiffness
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U2 - 10.11159/icmie24.127
DO - 10.11159/icmie24.127
M3 - Conference contribution
AN - SCOPUS:85205120909
SN - 9781990800443
T3 - Proceedings of the World Congress on Mechanical, Chemical, and Material Engineering
BT - Proceedings of the 10th World Congress on Mechanical, Chemical, and Material Engineering, MCM 2024
A2 - Qiu, Huihe
PB - Avestia Publishing
T2 - 10th World Congress on Mechanical, Chemical, and Material Engineering, MCM 2024
Y2 - 22 August 2024 through 24 August 2024
ER -