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Abstrakty
This article concerns the widespread matter of biophysical comfort. In this work, 10 double-layer knitted fabrics with potential application in multilayer garments addressed to a specific group of users, such as newborns, were investigated. The materials were constructed with the following raw materials: cotton, polypropylene, polyester, polyamide, bamboo, and viscose. The textiles with a comparable geometrical structure and different composition were tested for their air permeability. In the experimental part, the materials were tested in specific constant ambient conditions using an air permeability tester. In the simulation part, 3D models of actual textiles were designed and air permeability based on the performed simulations using finite volume method was calculated. Both measurements and simulations yielded comparable results and showed that the air permeability of the knitted fabric strongly depends on the thickness and geometrical parameters of yarn.
Czasopismo
Rocznik
Tom
Strony
364--376
Opis fizyczny
Bibliogr. 26 poz.
Twórcy
autor
- Lodz University of Technology, Department of Material and Commodity Sciences and Textile Metrology, 116 Zeromskiego Street, 90-924 Lodz, Poland
autor
- Lodz University of Technology, Department of Material and Commodity Sciences and Textile Metrology, 116 Zeromskiego Street, 90-924 Lodz, Poland
Bibliografia
- [1] Ogulata R.T., Mavruz S. Investigation of Porosity and Air Permeability Values of Plain Knitted Fabrics. Fibres and Textiles in Eastern Europe 2010; 18, 5 (82): 71–75.
- [2] Arumugam V., Mishra R., Militky J., Salacova J. Investigation on thermo-physiological and compression characteristics of weft-knitted 3D spacer fabrics. The Journal of The Textile Institute, doi: 10.1080/00405000.2016.1220035
- [3] Doczyova K., Glombikova V., Komarkova P. Application of Microtomography in Textile Metrology. Tekstilec 2014; 57(1): 4−11
- [4] Mezarciöz Serin., Mezarciöz Serkan, Oğulata R. T. Prediction of air permeability of knitted fabrics by means of computational fluid dynamics. Tekstilvekonfeksiyon 2014; 24(2): 202−211
- [5] Ogulata R.T. Air Permeability of Woven Fabrics. Journal of Textile and apparel. Technology Management 2006; 5: 1–10.
- [6] Havlová M. Air Permeability and Constructional Parameters of Woven Fabrics. Fibres and Textiles in Eastern Europe 2013; 21, 2(98): 84–89.
- [7] Ghada Ahmad Mohamad. Comparative Study of Air Permeability of Polyester/Metallic Blended Woven Fabrics. Life Science Journal 2015; 12 (6): 78–82
- [8] Angelova R.A. Determination of the pore size of woven structures through image analysis. Central European Journal of Engineering 2012; 2(1): 129–135
- [9] Zupin Z., Hladnik A., Dimitrovski K. Prediction of one-layer woven fabrics air permeability using porosity parameters. Textile Research Journal 2011; 82(2): 117–128
- [10] Polipowski M., Więcek P., Więcek B., Jasińska I. Study on Woven Fabric Structure Using 3D Computer Image Analysis for In-Depth Identification of Thread Channels. Fibres and Textiles in Eastern Europe 2015; 23, 2(110): 33−39.
- [11] Strąkowska M., Więcek P., Polipowski M., Więcek B. Estimation of the Inter-Yarn Channel Inlet Diameter in Textile Materials Using Structured Light 3D Micro-Scanning. Fibres and Textiles in Eastern Europe 2016; 24, 6(120): 88−93. doi: 10.5604/12303666.1221741
- [12] Havlová M. Detection of fabric structure irregularities using air permeability measurements. Journal of Engineered Fibers and Fabrics 2014; 9, 4:157−164
- [13] Havlová M. Model of vertical porosity occurring in woven fabrics and its effect on air permeability. Fibres and Textiles in Eastern Europe 2014; 22, 4(106): 58−63
- [14] Puszkarz A.K., Krucińska I. The study of knitted fabric thermal insulation using thermography and finite volume method. Textile Research Journal, 2017; 87(6): 643–656 doi:10.1177/0040517516635999
- [15] Puszkarz A.K., Korycki R., Krucińska I. Simulations of heat transport phenomena in a three-dimensional model of knitted fabric. 2015; 16(3): 128−137 doi: 10.1515/aut-2015-0042 ©AUTEX
- [16] Puszkarz A.K., Krucińska I. Study of multilayer clothing thermal insulation using thermography and the finite volume method. Fibres and Textiles in Eastern Europe 2016; 24 6(120): 129–137
- [17] Lipp-Symonowicz B., Sztajnowski S., Wojciechowska D. New Commercial Fibres Called “Bamboo Fibres” – Their Structure and Properties. Fibres and Textiles in Eastern Europe 2011; 19, 1 (84): 18−23
- [18] Lipp-Symonowicz B., Sztajnowski S., Kulak A. IR spectroscopy as a possible method of analysing fibre structures and their changes under various impacts.” Infrared Radiation”, book edited by Vasyl Morozhenko, ISBN 978-953-51-0060-7, Shanghai: Intech, 2012; 1: 27–39
- [19] Kowalski K., Janicka J., Massalska-Lipińska T., Nyka M. Impact of Raw Material combinations on the Biophysical Parameters and Underwear Microclimate of Two-Layer Knitted Materials. Fibres and Textiles in Eastern Europe 2010; 18, 5(82): 64–70.
- [20] EN ISO 5084. Textiles - Determination of thickness of textiles and textile products
- [21] EN 12127. Textiles - Fabrics - Determination of mass per unit area using small samples
- [22] EN ISO 2060. Textiles - Yarn From Packages-Determination Of Linear Density (mass Per Unit Length) - Skein method
- [23] ISO 139. Textiles - Standard atmospheres for conditioning and testing
- [24] EN ISO 9237. Textiles - Determination of the permeability of fabrics to air
- [25] SolidWorks Flow Simulation - Technical Reference 2014
- [26] Jeżowiecka-Kabsch K., Szewczyk H.. Mechanika płynów. Oficyna Wydawnicza Politechniki Wrocławskiej, Wrocław 2001
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
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