Access the full text.
Sign up today, get DeepDyve free for 14 days.
Vahid Babaahmadi, M. Montazer, Wei Gao (2017)
Low temperature welding of graphene on PET with silver nanoparticles producing higher durable electro-conductive fabricCarbon, 118
(J. O. Park, C. Park, S. Choi, and O. Y. Park, “Proceedings of the Korean Society of Disaster Information”, p.123, 2017.)
J. O. Park, C. Park, S. Choi, and O. Y. Park, “Proceedings of the Korean Society of Disaster Information”, p.123, 2017.J. O. Park, C. Park, S. Choi, and O. Y. Park, “Proceedings of the Korean Society of Disaster Information”, p.123, 2017., J. O. Park, C. Park, S. Choi, and O. Y. Park, “Proceedings of the Korean Society of Disaster Information”, p.123, 2017.
(Y. Yang and G. Cho, “Novel Stretchable Textile-Based Transmission Bands: Electrical Performance and Appearance After Abrasion/Laundering, and Wearability”, in Proceedings of the 13th International Conference on Human-Computer Interaction International 2009, pp.806–813, San Diego, 2009.)
Y. Yang and G. Cho, “Novel Stretchable Textile-Based Transmission Bands: Electrical Performance and Appearance After Abrasion/Laundering, and Wearability”, in Proceedings of the 13th International Conference on Human-Computer Interaction International 2009, pp.806–813, San Diego, 2009.Y. Yang and G. Cho, “Novel Stretchable Textile-Based Transmission Bands: Electrical Performance and Appearance After Abrasion/Laundering, and Wearability”, in Proceedings of the 13th International Conference on Human-Computer Interaction International 2009, pp.806–813, San Diego, 2009., Y. Yang and G. Cho, “Novel Stretchable Textile-Based Transmission Bands: Electrical Performance and Appearance After Abrasion/Laundering, and Wearability”, in Proceedings of the 13th International Conference on Human-Computer Interaction International 2009, pp.806–813, San Diego, 2009.
Inhwan Kim, Eugene Lee, Eunji Jang, G. Cho (2018)
Characteristics of polyurethane nanowebs treated with silver nanowire solutions as strain sensorsTextile Research Journal, 88
Xiaodong Wu, Yangyang Han, Xinxing Zhang, Canhui Lu (2016)
Highly Sensitive, Stretchable, and Wash-Durable Strain Sensor Based on Ultrathin Conductive Layer@Polyurethane Yarn for Tiny Motion Monitoring.ACS applied materials & interfaces, 8 15
Yoonjung Yang, G. Cho (2009)
Novel Stretchable Textile-Based Transmission Bands: Electrical Performance and Appearance after Abrasion/Laundering, and Wearability
Jeong-hwa Kim, Jungsoon Lee (2018)
Fabrication and Changes in Physical and Functional Properties after Repeated Laundering of PU Nanocomposite Laminates Loaded with Electrospun Juniperus Chinensis ExtractsFibers and Polymers, 19
Eugene Lee, Inhwan Kim, Hang Liu, G. Cho (2017)
Exploration of AgNW/PU nanoweb as ECG textile electrodes and comparison with Ag/AgCl electrodesFibers and Polymers, 18
Woojin Kim, Eugene Lee, J. Choi, G. Cho (2020)
Improved Electrical Conductivity of Polyurethane Nanoweb Coated with Graphene Ink through Heat TreatmentFibers and Polymers, 21
(ISO 6330:2012(en), Textiles — Domestic Washing and Drying Procedures for Textile Testing, 2012.)
ISO 6330:2012(en), Textiles — Domestic Washing and Drying Procedures for Textile Testing, 2012.ISO 6330:2012(en), Textiles — Domestic Washing and Drying Procedures for Textile Testing, 2012., ISO 6330:2012(en), Textiles — Domestic Washing and Drying Procedures for Textile Testing, 2012.
Hyocheol Lee, Eugene Lee, G. Cho (2020)
Electrical, surface, chemical, tensile, and respiratory signal properties of non-oxidized graphene/polyurethane nanoweb according to heat, ethanol, and polydimethylsiloxane treatmentsSmart Materials and Structures, 29
L. Persano, A. Camposeo, C. Tekmen, D. Pisignano (2013)
Industrial Upscaling of Electrospinning and Applications of Polymer Nanofibers: A ReviewMacromolecular Materials and Engineering, 298
C. Zhang, Suna Fan, H. Shao, Xue-chao Hu, Bo Zhu, Yaopeng Zhang (2019)
Graphene trapped silk scaffolds integrate high conductivity and stabilityCarbon
Eugene Lee, G. Cho (2019)
PU nanoweb-based textile electrode treated with single-walled carbon nanotube/silver nanowire and its application to ECG monitoringSmart Materials and Structures, 28
Eugene Lee, G. Cho (2018)
Polyurethane nanoweb-based textile sensors treated with single-walled carbon nanotubes and silver nanowireTextile Research Journal, 89
Inhwan Kim, G. Cho (2018)
Polyurethane nanofiber strain sensors via in situ polymerization of polypyrrole and application to monitoring joint flexionSmart Materials and Structures, 27
(2009)
and G
G. Cho, Keesam Jeong, Minjoo Paik, Youngeun Kwun, M. Sung (2011)
Performance Evaluation of Textile-Based Electrodes and Motion Sensors for Smart ClothingIEEE Sensors Journal, 11
S Ramakrishna (2005)
10.1142/5894An Introduction to Electrospinning and Nanofibers
N. Velden, K. Kuusk, A. Köhler (2015)
Life cycle assessment and eco-design of smart textiles: The importance of material selection demonstrated through e-textile product redesignMaterials & Design, 84
D. Herrmann (2016)
An Introduction To Electrospinning And Nanofibers
(2017)
and O
Haoxuan Li, Wenxin Zhang, Q. Ding, Xiangyu Jin, Q. Ke, Zhaoling Li, Dong Wang, Chen Huang (2019)
A Facile Strategy for Fabrication of Flexible, Breathable and Washable Piezoelectric Sensor via Welding of Nanofibers with Multiwalled Carbon Nanotube(MWCNT).ACS applied materials & interfaces
In this study, to investigate the effects of heat treatment and polydimethylsiloxane (PDMS) coating on durability to laundering, the changes in the porosity, electrical resistance, and surface property of the heat-treated silver nanowire (AgNW)/PDMS/polyurethane (PU) nanofiber-web before and after laundering were examined. To prepare the conductive specimens, PU nanofiber-web, 1 wt% of AgNW dispersion in ethanol, and two types of PDMS precursors were used. A total of four specimens were prepared: Specimen A (The AgNW/PU nanofiber-web), Specimen AH (The heat-treated AgNW/PU nanofiber-web), Specimen AP (The PDMS-coated AgNW/PU nanofiber-web), and Specimen AHP (The heat-treated AgNW/PDMS/PU nanofiber-web). The specimen was rinsed and dehydrated after laundering under the conditions according to ISO 6330. To investigate the changes of porosity after a single washing cycle, mean pore diameter and pore size distribution were measured. Linear electrical resistance and microscopic surface view of the specimen were evaluated. As a result, many micro-pores were distributed in Specimen AH because of the heat treatment. After laundering, Specimen AH still had the micro-pores, and thus, the heat treatment improved the durability to laundering. Also, the electrical resistance of Specimen AH was only changed slightly even after laundering, which was because the heat treatment strengthened the bonding between the nanofibers and the silver nanowires, thus the silver nanowires sufficiently remained on the specimen surface even after laundering. And, Specimen AH showed that the silver nanowires formed a network even after laundering and were evenly covered with silver nanowires onto the specimen surface. This result affected the aforementioned electrical performance, and in fact, the electrical resistance of Specimen AH was the lowest regardless of laundering. However, it was impossible to measure the porosity of Specimen AP and Specimen AHP due to the PDMS coating. Therefore, the heat treatment affected the durability to laundering as well as the electrical conductivity to increase, but PDMS coating blocked the micro-pores of the nanofiber-web and enabled higher initial resistance.
Fibers and Polymers – Springer Journals
Published: Aug 1, 2021
Keywords: Polyurethane nanofiber-web; Silver nanowire; Heat treatment; Durability to laundering; Electronic-textile
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.