Numerical analysis of space deployable structure based on shape memory polymers

Zepeng He; Yang Shi; Xiangchao Feng; Zhen Li; Yan Zhang; Chunai Dai; Pengfei Wang; Liangyu Zhao

doi:10.3390/mi12070833

Numerical analysis of space deployable structure based on shape memory polymers

Zepeng He^*, Yang Shi, Xiangchao Feng, Zhen Li^*, Yan Zhang, Chunai Dai, Pengfei Wang^*, Liangyu Zhao^*

^*Corresponding author for this work

School of Aerospace Engineering

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

Shape memory polymers (SMPs) have been applied in aerospace engineering as deployable space structures. In this work, the coupled finite element method (FEM) was established based on the generalized Maxwell model and the time–temperature equivalence principle (TTEP). The thermodynamic behavior and shape memory effects of a single-arm deployment structure (F-DS) and four-arm deployment structure (F-DS) based on SMPs were analyzed using the coupled FEM. Good consistency was obtained between the experimental data and simulation data for the tensile and S-DS recovery forces, verifying that the coupled FEM can accurately and reliably describe the thermodynamic behavior and shape memory effects of the SMP structure. The step-by-step driving structure is suitable for use as a large-scale deployment structure in space. This coupled FEM provides a new direction for future research on epoxy SMPs.

Original language	English
Article number	833
Journal	Micromachines
Volume	12
Issue number	7
DOIs	https://doi.org/10.3390/mi12070833
Publication status	Published - Jul 2021

Keywords

Finite element method
Shape memory characteristics
Shape memory polymers
Space structure
Time–temperature equivalence principle

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10.3390/mi12070833

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title = "Numerical analysis of space deployable structure based on shape memory polymers",

abstract = "Shape memory polymers (SMPs) have been applied in aerospace engineering as deployable space structures. In this work, the coupled finite element method (FEM) was established based on the generalized Maxwell model and the time–temperature equivalence principle (TTEP). The thermodynamic behavior and shape memory effects of a single-arm deployment structure (F-DS) and four-arm deployment structure (F-DS) based on SMPs were analyzed using the coupled FEM. Good consistency was obtained between the experimental data and simulation data for the tensile and S-DS recovery forces, verifying that the coupled FEM can accurately and reliably describe the thermodynamic behavior and shape memory effects of the SMP structure. The step-by-step driving structure is suitable for use as a large-scale deployment structure in space. This coupled FEM provides a new direction for future research on epoxy SMPs.",

keywords = "Finite element method, Shape memory characteristics, Shape memory polymers, Space structure, Time–temperature equivalence principle",

author = "Zepeng He and Yang Shi and Xiangchao Feng and Zhen Li and Yan Zhang and Chunai Dai and Pengfei Wang and Liangyu Zhao",

note = "Publisher Copyright: {\textcopyright} 2021 by the authors. Licensee MDPI, Basel, Switzerland.",

year = "2021",

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doi = "10.3390/mi12070833",

language = "English",

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T1 - Numerical analysis of space deployable structure based on shape memory polymers

AU - He, Zepeng

AU - Shi, Yang

AU - Feng, Xiangchao

AU - Li, Zhen

AU - Zhang, Yan

AU - Dai, Chunai

AU - Wang, Pengfei

AU - Zhao, Liangyu

PY - 2021/7

Y1 - 2021/7

N2 - Shape memory polymers (SMPs) have been applied in aerospace engineering as deployable space structures. In this work, the coupled finite element method (FEM) was established based on the generalized Maxwell model and the time–temperature equivalence principle (TTEP). The thermodynamic behavior and shape memory effects of a single-arm deployment structure (F-DS) and four-arm deployment structure (F-DS) based on SMPs were analyzed using the coupled FEM. Good consistency was obtained between the experimental data and simulation data for the tensile and S-DS recovery forces, verifying that the coupled FEM can accurately and reliably describe the thermodynamic behavior and shape memory effects of the SMP structure. The step-by-step driving structure is suitable for use as a large-scale deployment structure in space. This coupled FEM provides a new direction for future research on epoxy SMPs.

AB - Shape memory polymers (SMPs) have been applied in aerospace engineering as deployable space structures. In this work, the coupled finite element method (FEM) was established based on the generalized Maxwell model and the time–temperature equivalence principle (TTEP). The thermodynamic behavior and shape memory effects of a single-arm deployment structure (F-DS) and four-arm deployment structure (F-DS) based on SMPs were analyzed using the coupled FEM. Good consistency was obtained between the experimental data and simulation data for the tensile and S-DS recovery forces, verifying that the coupled FEM can accurately and reliably describe the thermodynamic behavior and shape memory effects of the SMP structure. The step-by-step driving structure is suitable for use as a large-scale deployment structure in space. This coupled FEM provides a new direction for future research on epoxy SMPs.

KW - Finite element method

KW - Shape memory characteristics

KW - Shape memory polymers

KW - Space structure

KW - Time–temperature equivalence principle

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U2 - 10.3390/mi12070833

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JO - Micromachines

JF - Micromachines

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M1 - 833

ER -

Numerical analysis of space deployable structure based on shape memory polymers

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Keywords

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