Development of a Multifunctional Intelligent Elbow Brace (MIEB) Using a Knitted Textile Strain Sensor-Reference-Cited by-同舟云学术

Development of a Multifunctional Intelligent Elbow Brace (MIEB) Using a Knitted Textile Strain Sensor

Published:2022-02-28 Issue:1(151) Volume:30 Page:22-30
ISSN:1230-3666
Container-title:Fibres and Textiles in Eastern Europe
language:
Short-container-title:FIBRES & TEXTILES in Eastern Europe

Author:

Salam Abdul¹,Phan Duy-Nam²,Khan Saif Ullah³,Ul Hassan Syed Zameer³,Hassan Tufail¹,Ullah Khan Raja Muhammad Waseem⁴,Pasha Khalid¹,Khan Muhammad Qamar¹,Kim Ick Soo⁵

Affiliation:

1. Pakistan, Karachi, National Textile University Karachi Campus, Faculty of Engineering and Technology, Department of Textile and Clothing

2. Veit Nam, Hanoi University of Science and Technology, School of Textile – Leather and Fashion

3. Pakistan, Quetta, Baluchistan University of Information Technology Engineering and Management Sciences, Faculty of Engineering, Department of Textile Engineering and Fashion Design

4. Pakistan, Faisalabad, National Textile University, Faculty of Engineering, Department of Fabric Manufacturing

5. Japan, Nagano, Shinshu University, Faculty of Textile Sciences, Interdisciplinary Cluster for Cutting Edge Research (ICCER), Institute of Fiber Engineering, Division of Frontier Fiber

Abstract

Passive smart textiles are the textile structures that can sense stimuli, which may come from mechanical, thermal, electrical, or chemical sources. Textile strain sensors are smart textiles products in which the sensor’s resistance changes with applied strain. This study consists in the development of a textile strain sensor and its application on a Multifunctional Intelligent Elbow Brace (MIEB). The hand-knitted sensor was developed using knitting needles. The material used for this sensor was conductive yarn and lycra. The sensor developed was subjected to a stretch recovery test using a universal testing machine,, and the electrical resistance was measured using an electrical multimeter. The sensor developed has good sensing ability against cyclic loading and unloading at a 5%, 20%, 35% strain level. After testing, the sensor was stitched on an elbow brace to develop an MIEB. This study involved the best economical method for measuring the bowling angle of the player using this MIEB without any need for a biomechanical test, which is very expensive. This MIEB can also be used for rehabilitation purposes and for monitoring joint movement.

Publisher

Walter de Gruyter GmbH

Subject

Industrial and Manufacturing Engineering,General Environmental Science,Materials Science (miscellaneous),Business and International Management

Link

https://ftee.com.pl/gicid/pdf/01.3001.0015.6457

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4. ConclusionIn this study, a multifunctional intelligent elbow brace was developed using a textile strainsensor. The sensing stability results show that the textile strain sensor possessed excellentBall Delivery Angle = 40°Ball Delivery Angle = 30°Ball Delivery Angle = 15°a)b)c) 30 FIBRES & TEXTILES in Eastern Europe 2022, Vol. 30, 1(151)[Internet]. 2019 May 7; 12(9): 1469. Availablefrom: https://www.mdpi.com/1996-1944/12/9/1469.

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