Research on the Heating of Woven Carbon Fiber Fabrics Using Thin-Film Solar Cells

1 Parida B, Iniyan S, Goic R. A Review Of Solar Photovoltaic Technologies. Renewable and Sustainable Energy Reviews 2011; 15(3): 1625–1636. ParidaB IniyanS GoicR A Review Of Solar Photovoltaic Technologies Renewable and Sustainable Energy Reviews 2011 15 3 1625 1636 10.1016/j.rser.2010.11.032 Search in Google Scholar

2 Compaan A D. Photovoltaics: Clean Power for The 21st Century. Solar Energy Materials and Solar Cells 2006; 90(15): 2170–2180. CompaanA D Photovoltaics: Clean Power for The 21st Century Solar Energy Materials and Solar Cells 2006 90 15 2170 2180 10.1016/j.solmat.2006.02.017 Search in Google Scholar

3 Ohkita H, Ito S. Transient Absorption Spectroscopy of Polymer-Based Thin-Film Solar Cells. Polymer 2011; 52(20): 4397–4417. OhkitaH ItoS Transient Absorption Spectroscopy of Polymer-Based Thin-Film Solar Cells Polymer 2011 52 20 4397 4417 10.1016/j.polymer.2011.06.061 Search in Google Scholar

4 Pouladi S, Asadirad M, Oh SK, et al. Effects of Grain Boundaries on Conversion Efficiencies of Single-Crystal-Like Gaas Thin-Film Solar Cells on Flexible Metal Tapes. Solar Energy Materials and Solar Cells 2019; 199:122–128. PouladiS AsadiradM OhSK Effects of Grain Boundaries on Conversion Efficiencies of Single-Crystal-Like Gaas Thin-Film Solar Cells on Flexible Metal Tapes Solar Energy Materials and Solar Cells 2019 199 122 128 10.1016/j.solmat.2019.04.032 Search in Google Scholar

5 Guo Z, Sun C, Wang J et al. High-Performance Laminated Fabric with Enhanced Photothermal Conversion and Joule Heating Effect for Personal Thermal Management. ACS Applied Materials & Interfaces 2021; 13(7): 8851–8862. GuoZ SunC WangJ High-Performance Laminated Fabric with Enhanced Photothermal Conversion and Joule Heating Effect for Personal Thermal Management ACS Applied Materials & Interfaces 2021 13 7 8851 8862 10.1021/acsami.0c2312333565864 Search in Google Scholar

6 Fafenrot S, Silbermann P, Grimmelsmann N, et al. Integration of Solar Cells and Other Electronic Components into Clothes/Narrow and Smart Textiles. Springer, Cham, 2018: 229–239. FafenrotS SilbermannP GrimmelsmannN Integration of Solar Cells and Other Electronic Components into Clothes/Narrow and Smart Textiles Springer Cham 2018 229 239 10.1007/978-3-319-69050-6_20 Search in Google Scholar

7 Bertoni M, He K, Wang V, et al. Wearable Flexible Solar Cell Charger. NJ Governor’s School of Engineering and Technology 2017; 1(1): 1–7. BertoniM HeK WangV Wearable Flexible Solar Cell Charger NJ Governor’s School of Engineering and Technology 2017 1 1 1 7 Search in Google Scholar

8 Feng A, Jia Z, Yu Q, et al. Preparation and Characterization of Carbon Nanotubes/Carbon Fiber/Phenolic Composites on Mechanical and Thermal Conductivity Properties. Nano, 2018:1850037. FengA JiaZ YuQ Preparation and Characterization of Carbon Nanotubes/Carbon Fiber/Phenolic Composites on Mechanical and Thermal Conductivity Properties Nano 2018 1850037 10.1142/S1793292018500376 Search in Google Scholar

9 Wei L, Dong X, Lei W, et al. Simultaneous Enhancement of Electrical Conductivity and Interlaminar Fracture Toughness of Carbon Fiber/Epoxy Composites Using Plasma-Treated Conductive Thermoplastic Film Interleaves. RSC Advances 2018; 8(47): 26910–26921. WeiL DongX LeiW Simultaneous Enhancement of Electrical Conductivity and Interlaminar Fracture Toughness of Carbon Fiber/Epoxy Composites Using Plasma-Treated Conductive Thermoplastic Film Interleaves RSC Advances 2018 8 47 26910 26921 10.1039/C8RA05366A908330235541037 Search in Google Scholar

10 Dhanabalan SC, Dhanabalan B, Chen X, et al. Hybrid Carbon Nanostructured Fibers: Stepping Stone for Intelligent Textile-Based Electronics. Nanoscale 2019; 11(7): 3046–3101. DhanabalanSC DhanabalanB ChenX Hybrid Carbon Nanostructured Fibers: Stepping Stone for Intelligent Textile-Based Electronics Nanoscale 2019 11 7 3046 3101 10.1039/C8NR07554A Search in Google Scholar

11 Lee S Y, Cho J W, Kim Y H. Electrical Heating Effect and Water Repelling Property of Fabrics Spray-Coated with Mixed Solution of Carbon Nanotubes and Hyperbranched Polyurethane. Textile Science and Engineering 2010; 47(3): 184–190. LeeS Y ChoJ W KimY H Electrical Heating Effect and Water Repelling Property of Fabrics Spray-Coated with Mixed Solution of Carbon Nanotubes and Hyperbranched Polyurethane Textile Science and Engineering 2010 47 3 184 190 Search in Google Scholar

12 Aouraghe MA, Xu F, Liu X, et al. Flexible, Quickly Responsive and Highly Efficient E-Heating Carbon Nanotube Film. Composites Science and Technology 2019; 183: 107824. AouragheMA XuF LiuX Flexible, Quickly Responsive and Highly Efficient E-Heating Carbon Nanotube Film Composites Science and Technology 2019 183 107824. 10.1016/j.compscitech.2019.107824 Search in Google Scholar

13 Pang EJX, Pickering SJ, Chan A, et al. Use of Recycled Carbon Fibre as a Heating Element. Journal Of Composite Materials 2013; 47(16): 2039–2050. PangEJX PickeringSJ ChanA Use of Recycled Carbon Fibre as a Heating Element Journal Of Composite Materials 2013 47 16 2039 2050 10.1177/0021998312454033 Search in Google Scholar

14 Mo S, Mo M, Ho KC. Fabrication of Electric Heating Garment with Plasma-Assisted Metal Coating (PAC) Technology. International Journal of Clothing Science and Technology 2019; 32(3):297–306. MoS MoM HoKC Fabrication of Electric Heating Garment with Plasma-Assisted Metal Coating (PAC) Technology International Journal of Clothing Science and Technology 2019 32 3 297 306 10.1108/IJCST-04-2019-0050 Search in Google Scholar

15 Li Q W, Li Y, Zhang X F, et al. Structure-Dependent Electrical Properties of Carbon Nanotube Fibers. Advanced Materials 2007; 19(20): 3358–3363. LiQ W LiY ZhangX F Structure-Dependent Electrical Properties of Carbon Nanotube Fibers Advanced Materials 2007 19 20 3358 3363 10.1002/adma.200602966 Search in Google Scholar

16 Hung CH, Bai YW, Wu HJ, et al. Monitor and Remote Control of a Heating Cloth for The Aged, Consumer Electronics (ICCE). 2014 IEEE International Conference, 2014: 266–267. HungCH BaiYW WuHJ Monitor and Remote Control of a Heating Cloth for The Aged, Consumer Electronics (ICCE) 2014 IEEE International Conference 2014 266 267 Search in Google Scholar

17 Shokuhfar A, Afghahi SSS. The Heating Effect of Iron-Cobalt Magnetic Nanofluids in an Alternating Magnetic Field: Application In Magnetic Hyperthermia Treatment. Nanoscale Research Letters 2013; 8(1): 1–11. ShokuhfarA AfghahiSSS The Heating Effect of Iron-Cobalt Magnetic Nanofluids in an Alternating Magnetic Field: Application In Magnetic Hyperthermia Treatment Nanoscale Research Letters 2013 8 1 1 11 10.1186/1556-276X-8-540387812824359163 Search in Google Scholar

18 Wang F, Gao C, Kuklane K, et al. A Review of Technology of Personal Heating Garments. International Journal of Occupational Safety and Ergonomics 2010; 16(3): 387–404. WangF GaoC KuklaneK A Review of Technology of Personal Heating Garments International Journal of Occupational Safety and Ergonomics 2010 16 3 387 404 10.1080/10803548.2010.1107685420828494 Search in Google Scholar

19 Meng S, Kong T, Ma W, et al. 2D Crystal–Based Fibers: Status and Challenges. Small 2019, 15(39): 1902691. MengS KongT MaW 2D Crystal–Based Fibers: Status and Challenges Small 2019 15 39 1902691. 10.1002/smll.20190269131410999 Search in Google Scholar

20 Wang QW, Zhang HB, Liu J, et al. Multifunctional and Water-Resistant MXene-Decorated Polyester Textiles with Outstanding Electromagnetic Interference Shielding and Joule Heating Performances. Advanced Functional Materials 2019; 29(7): 1806819. WangQW ZhangHB LiuJ Multifunctional and Water-Resistant MXene-Decorated Polyester Textiles with Outstanding Electromagnetic Interference Shielding and Joule Heating Performances Advanced Functional Materials 2019 29 7 1806819. 10.1002/adfm.201806819 Search in Google Scholar

21 Zhu J, Chew DAS, Lv S, et al. Optimization Method for Building Envelope Design to Minimize Carbon Emissions of Building Operational Energy Consumption Using Orthogonal Experimental Design (OED). Habitat International 2013; 37: 148–154. ZhuJ ChewDAS LvS Optimization Method for Building Envelope Design to Minimize Carbon Emissions of Building Operational Energy Consumption Using Orthogonal Experimental Design (OED) Habitat International 2013 37 148 154 10.1016/j.habitatint.2011.12.006 Search in Google Scholar

22 Zou G, Xu J, Wu C. Evaluation of Factors that Affect Rutting Resistance of Asphalt Mixes by Orthogonal Experiment Design. International Journal of Pavement Research and Technology 2017; 10(3): 282–288. ZouG XuJ WuC Evaluation of Factors that Affect Rutting Resistance of Asphalt Mixes by Orthogonal Experiment Design International Journal of Pavement Research and Technology 2017 10 3 282 288 10.1016/j.ijprt.2017.03.008 Search in Google Scholar

23 Liu D, Xia S, Tang H, et al. Parameter Optimization of PEMFC Stack Under Steady Working Condition Using Orthogonal Experimental Design. International Journal of Energy Research 2019; 43(7): 2571–2582. LiuD XiaS TangH Parameter Optimization of PEMFC Stack Under Steady Working Condition Using Orthogonal Experimental Design International Journal of Energy Research 2019 43 7 2571 2582 10.1002/er.4131 Search in Google Scholar