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Modal characterization of 3D printed compliant mechanisms for space exploration

Modal characterization of 3D printed compliant mechanisms for space exploration
Modal characterization of 3D printed compliant mechanisms for space exploration
The moon’s surface is covered with dust (regolith) and microscopic particles created by numerous meteorite impacts (lunar meteoric gardening). The lack of the smoothening actions of hydrological and aeolian process and the interaction with cosmic radiation have made regolith abrasive and electrostatically charged. Due to these characteristics, regolith has been identified as a major issue to lunar (and other planets) exploration, being responsible for clogging and wearing in the exposed hinges of the tools used in extravehicular activities. Compliant mechanisms permit to eliminate the use of hinges and, therefore, of sliding motions between adjacent surfaces, because they use elastic deformation to supply the desired kinematic behavior. Due to their design, these mechanisms present areas that undergo large deformations and alternating stress concentrations and, therefore, fatigue effects. In this work, we examine the dynamic behavior of a compliant mechanism designed for extravehicular space exploration using additive manufacturing. The vibration mode-shapes and the corresponding natural frequencies will be identified, with particular focus on the equivalent structural characteristics and their linearity.
Compliant mechanisms, Dust mitigation, Topology optimization
155-160
Budzyń, Dorota
8536f9fa-eed0-485d-b4a7-1dc30f559849
Zare-Behtash, Hossein
74be9b97-cb09-49c6-9f75-7ec58c0dd16c
Cammarano, Andrea
c0c85f55-3dfc-4b97-9b79-e2554406a12b
Walber, Chad
Stefanski, Matthew
Seidlitz, Stephen
Budzyń, Dorota
8536f9fa-eed0-485d-b4a7-1dc30f559849
Zare-Behtash, Hossein
74be9b97-cb09-49c6-9f75-7ec58c0dd16c
Cammarano, Andrea
c0c85f55-3dfc-4b97-9b79-e2554406a12b
Walber, Chad
Stefanski, Matthew
Seidlitz, Stephen

Budzyń, Dorota, Zare-Behtash, Hossein and Cammarano, Andrea (2023) Modal characterization of 3D printed compliant mechanisms for space exploration. Walber, Chad, Stefanski, Matthew and Seidlitz, Stephen (eds.) In Sensors and Instrumentation and Aircraft/Aerospace Testing Techniques, Volume 8 : Proceedings of the 41st IMAC, A Conference and Exposition on Structural Dynamics 2023. pp. 155-160 . (doi:10.1007/978-3-031-34938-6_20).

Record type: Conference or Workshop Item (Paper)

Abstract

The moon’s surface is covered with dust (regolith) and microscopic particles created by numerous meteorite impacts (lunar meteoric gardening). The lack of the smoothening actions of hydrological and aeolian process and the interaction with cosmic radiation have made regolith abrasive and electrostatically charged. Due to these characteristics, regolith has been identified as a major issue to lunar (and other planets) exploration, being responsible for clogging and wearing in the exposed hinges of the tools used in extravehicular activities. Compliant mechanisms permit to eliminate the use of hinges and, therefore, of sliding motions between adjacent surfaces, because they use elastic deformation to supply the desired kinematic behavior. Due to their design, these mechanisms present areas that undergo large deformations and alternating stress concentrations and, therefore, fatigue effects. In this work, we examine the dynamic behavior of a compliant mechanism designed for extravehicular space exploration using additive manufacturing. The vibration mode-shapes and the corresponding natural frequencies will be identified, with particular focus on the equivalent structural characteristics and their linearity.

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More information

Published date: 22 November 2023
Keywords: Compliant mechanisms, Dust mitigation, Topology optimization

Identifiers

Local EPrints ID: 492814
URI: http://eprints.soton.ac.uk/id/eprint/492814
DOI: doi:10.1007/978-3-031-34938-6_20
PURE UUID: f321b297-1413-4f0a-aaa2-9f2e6045e89d
ORCID for Hossein Zare-Behtash: ORCID iD orcid.org/0000-0002-4769-4076
ORCID for Andrea Cammarano: ORCID iD orcid.org/0000-0002-8222-8150

Catalogue record

Date deposited: 15 Aug 2024 16:31
Last modified: 16 Aug 2024 02:12

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Contributors

Author: Dorota Budzyń
Author: Hossein Zare-Behtash ORCID iD
Author: Andrea Cammarano ORCID iD
Editor: Chad Walber
Editor: Matthew Stefanski
Editor: Stephen Seidlitz

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