Review of Graphene-Based Textile Strain Sensors, with Emphasis on Structure Activity Relationship

Review of Graphene-Based Textile Strain Sensors, with Emphasis on Structure Activity Relationship

Graphene-based textile strain sensors were reviewed in terms of their preparation methods, performance, and applications with particular attention on its forming method, the key properties (sensitivity, stability, sensing range and response time), and comparisons. Staple fiber strain sensors, staple...

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Main Authors: Rufang Yu, Chengyan Zhu, Junmin Wan, Yongqiang Li, Xinghua Hong
Format: Article
Language:English
Published: MDPI AG 2021-01-01
Series:Polymers
Subjects:
textile strain sensors
graphene-based
staple fiber
staple and filament yarn
fabric
Online Access:https://www.mdpi.com/2073-4360/13/1/151
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spelling doaj-d32c3bf448894d74a6b4ced0a5d7b65f2021-01-02T00:01:46ZengMDPI AGPolymers2073-43602021-01-011315115110.3390/polym13010151Review of Graphene-Based Textile Strain Sensors, with Emphasis on Structure Activity RelationshipRufang Yu0Chengyan Zhu1Junmin Wan2Yongqiang Li3Xinghua Hong4College of Textiles (International silk institute), Key Laboratory of Advanced Textile Materials and Manufacturing Technology, Ministry of Education, Zhejiang Sci-Tech University, Hangzhou 310018, ChinaCollege of Textiles (International silk institute), Key Laboratory of Advanced Textile Materials and Manufacturing Technology, Ministry of Education, Zhejiang Sci-Tech University, Hangzhou 310018, ChinaTongxiang Research Institute, Zhejiang Sci-Tech University, Tongxiang 314599, ChinaCollege of Textiles (International silk institute), Key Laboratory of Advanced Textile Materials and Manufacturing Technology, Ministry of Education, Zhejiang Sci-Tech University, Hangzhou 310018, ChinaCollege of Textiles (International silk institute), Key Laboratory of Advanced Textile Materials and Manufacturing Technology, Ministry of Education, Zhejiang Sci-Tech University, Hangzhou 310018, ChinaGraphene-based textile strain sensors were reviewed in terms of their preparation methods, performance, and applications with particular attention on its forming method, the key properties (sensitivity, stability, sensing range and response time), and comparisons. Staple fiber strain sensors, staple and filament strain sensors, nonwoven fabric strain sensors, woven fabric strain sensors and knitted fabric strain sensors were summarized, respectively. (i) In general, graphene-based textile strain sensors can be obtained in two ways. One method is to prepare conductive textiles through spinning and weaving techniques, and the graphene worked as conductive filler. The other method is to deposit graphene-based materials on the surface of textiles, the graphene served as conductive coatings and colorants. (ii) The gauge factor (GF) value of sensor refers to its mechanical and electromechanical properties, which are the key evaluation indicators. We found the absolute value of GF of graphene-based textile strain sensor could be roughly divided into two trends according to its structural changes. Firstly, in the recoverable deformation stage, GF usually decreased with the increase of strain. Secondly, in the unrecoverable deformation stage, GF usually increased with the increase of strain. (iii) The main challenge of graphene-based textile strain sensors was that their application capacity received limited studies. Most of current studies only discussed washability, seldomly involving the impact of other environmental factors, including friction, PH, etc. Based on these developments, this work was done to provide some merit to references and guidelines for the progress of future research on flexible and wearable electronics.https://www.mdpi.com/2073-4360/13/1/151textile strain sensorsgraphene-basedstaple fiberstaple and filament yarnfabric
collection DOAJ
language English
format Article
sources DOAJ
author Rufang Yu
Chengyan Zhu
Junmin Wan
Yongqiang Li
Xinghua Hong
spellingShingle Rufang Yu
Chengyan Zhu
Junmin Wan
Yongqiang Li
Xinghua Hong
Review of Graphene-Based Textile Strain Sensors, with Emphasis on Structure Activity Relationship
Polymers
textile strain sensors
graphene-based
staple fiber
staple and filament yarn
fabric
author_facet Rufang Yu
Chengyan Zhu
Junmin Wan
Yongqiang Li
Xinghua Hong
author_sort Rufang Yu
title Review of Graphene-Based Textile Strain Sensors, with Emphasis on Structure Activity Relationship
title_short Review of Graphene-Based Textile Strain Sensors, with Emphasis on Structure Activity Relationship
title_full Review of Graphene-Based Textile Strain Sensors, with Emphasis on Structure Activity Relationship
title_fullStr Review of Graphene-Based Textile Strain Sensors, with Emphasis on Structure Activity Relationship
title_full_unstemmed Review of Graphene-Based Textile Strain Sensors, with Emphasis on Structure Activity Relationship
title_sort review of graphene-based textile strain sensors, with emphasis on structure activity relationship
publisher MDPI AG
series Polymers
issn 2073-4360
publishDate 2021-01-01
description Graphene-based textile strain sensors were reviewed in terms of their preparation methods, performance, and applications with particular attention on its forming method, the key properties (sensitivity, stability, sensing range and response time), and comparisons. Staple fiber strain sensors, staple and filament strain sensors, nonwoven fabric strain sensors, woven fabric strain sensors and knitted fabric strain sensors were summarized, respectively. (i) In general, graphene-based textile strain sensors can be obtained in two ways. One method is to prepare conductive textiles through spinning and weaving techniques, and the graphene worked as conductive filler. The other method is to deposit graphene-based materials on the surface of textiles, the graphene served as conductive coatings and colorants. (ii) The gauge factor (GF) value of sensor refers to its mechanical and electromechanical properties, which are the key evaluation indicators. We found the absolute value of GF of graphene-based textile strain sensor could be roughly divided into two trends according to its structural changes. Firstly, in the recoverable deformation stage, GF usually decreased with the increase of strain. Secondly, in the unrecoverable deformation stage, GF usually increased with the increase of strain. (iii) The main challenge of graphene-based textile strain sensors was that their application capacity received limited studies. Most of current studies only discussed washability, seldomly involving the impact of other environmental factors, including friction, PH, etc. Based on these developments, this work was done to provide some merit to references and guidelines for the progress of future research on flexible and wearable electronics.
topic textile strain sensors
graphene-based
staple fiber
staple and filament yarn
fabric
url https://www.mdpi.com/2073-4360/13/1/151
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AT chengyanzhu reviewofgraphenebasedtextilestrainsensorswithemphasisonstructureactivityrelationship
AT junminwan reviewofgraphenebasedtextilestrainsensorswithemphasisonstructureactivityrelationship
AT yongqiangli reviewofgraphenebasedtextilestrainsensorswithemphasisonstructureactivityrelationship
AT xinghuahong reviewofgraphenebasedtextilestrainsensorswithemphasisonstructureactivityrelationship
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