Geometric Effect on the Nonlinear Force-Displacement Relationship of Awl-Shaped Serpentine Microsprings for In-Plane Deformation

Geometric Effect on the Nonlinear Force-Displacement Relationship of Awl-Shaped Serpentine Microsprings for In-Plane Deformation

Even when made by brittle materials, awl-shaped serpentine microsprings (ASSMs) were found to have a nonlinear displacement–force relationship similar to springs made by ductile material. It is found that the nonlinear displacement–force relationship is due to the geometry and dimensions of the ASSM...

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Main Authors: Meng‐Ju Lin, Hui‐Min Chou, Rongshun Chen
Format: Article
Language:English
Published: MDPI AG 2020-06-01
Series:Materials
Subjects:
awl‐shaped
serpentine spring
MEMS
hardening spring
Online Access:https://www.mdpi.com/1996-1944/13/12/2864
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spelling doaj-ae4d87c21df546398b3618271e36db5c2020-11-25T03:11:36ZengMDPI AGMaterials1996-19442020-06-01132864286410.3390/ma13122864Geometric Effect on the Nonlinear Force-Displacement Relationship of Awl-Shaped Serpentine Microsprings for In-Plane DeformationMeng‐Ju Lin0Hui‐Min Chou1Rongshun Chen2Department of Mechanical and Computer‐Aided Engineering, Feng Chia University, Taichung City 407, TaiwanDepartment of Power Mechanical Engineering, National Tsing Hua University, Hsinchu City 300, TaiwanDepartment of Power Mechanical Engineering, National Tsing Hua University, Hsinchu City 300, TaiwanEven when made by brittle materials, awl-shaped serpentine microsprings (ASSMs) were found to have a nonlinear displacement–force relationship similar to springs made by ductile material. It is found that the nonlinear displacement–force relationship is due to the geometry and dimensions of the ASSMs. The geometric effect of the nonlinear force-displacement relationship of ASSMs for in-plane motion was investigated. A theoretical solution was derived to analyze this nonlinearity. By successfully fabricating and measuring an ASSM, the theoretical results agreed well with the experimental results. The results indicated that ASSMs have a nonlinear force-displacement relationship, which is similar to that of hardening springs. The taper angle has a significant effect on the nonlinear displacement of ASSMs. When the taper angle was small, no obvious effect appeared on the nonlinearity of the microsprings with different numbers of turns. When the beam length increased, the critical force for nonlinear deflection decreased.https://www.mdpi.com/1996-1944/13/12/2864awl‐shapedserpentine springMEMShardening spring
collection DOAJ
language English
format Article
sources DOAJ
author Meng‐Ju Lin
Hui‐Min Chou
Rongshun Chen
spellingShingle Meng‐Ju Lin
Hui‐Min Chou
Rongshun Chen
Geometric Effect on the Nonlinear Force-Displacement Relationship of Awl-Shaped Serpentine Microsprings for In-Plane Deformation
Materials
awl‐shaped
serpentine spring
MEMS
hardening spring
author_facet Meng‐Ju Lin
Hui‐Min Chou
Rongshun Chen
author_sort Meng‐Ju Lin
title Geometric Effect on the Nonlinear Force-Displacement Relationship of Awl-Shaped Serpentine Microsprings for In-Plane Deformation
title_short Geometric Effect on the Nonlinear Force-Displacement Relationship of Awl-Shaped Serpentine Microsprings for In-Plane Deformation
title_full Geometric Effect on the Nonlinear Force-Displacement Relationship of Awl-Shaped Serpentine Microsprings for In-Plane Deformation
title_fullStr Geometric Effect on the Nonlinear Force-Displacement Relationship of Awl-Shaped Serpentine Microsprings for In-Plane Deformation
title_full_unstemmed Geometric Effect on the Nonlinear Force-Displacement Relationship of Awl-Shaped Serpentine Microsprings for In-Plane Deformation
title_sort geometric effect on the nonlinear force-displacement relationship of awl-shaped serpentine microsprings for in-plane deformation
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2020-06-01
description Even when made by brittle materials, awl-shaped serpentine microsprings (ASSMs) were found to have a nonlinear displacement–force relationship similar to springs made by ductile material. It is found that the nonlinear displacement–force relationship is due to the geometry and dimensions of the ASSMs. The geometric effect of the nonlinear force-displacement relationship of ASSMs for in-plane motion was investigated. A theoretical solution was derived to analyze this nonlinearity. By successfully fabricating and measuring an ASSM, the theoretical results agreed well with the experimental results. The results indicated that ASSMs have a nonlinear force-displacement relationship, which is similar to that of hardening springs. The taper angle has a significant effect on the nonlinear displacement of ASSMs. When the taper angle was small, no obvious effect appeared on the nonlinearity of the microsprings with different numbers of turns. When the beam length increased, the critical force for nonlinear deflection decreased.
topic awl‐shaped
serpentine spring
MEMS
hardening spring
url https://www.mdpi.com/1996-1944/13/12/2864
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AT huiminchou geometriceffectonthenonlinearforcedisplacementrelationshipofawlshapedserpentinemicrospringsforinplanedeformation
AT rongshunchen geometriceffectonthenonlinearforcedisplacementrelationshipofawlshapedserpentinemicrospringsforinplanedeformation
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