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Erschienen in:

2017 | OriginalPaper | Buchkapitel

8. Thermal Properties of Textiles

verfasst von : Andrea Ehrmann, Tomasz Blachowicz

Erschienen in: Examination of Textiles with Mathematical and Physical Methods

Verlag: Springer International Publishing

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Abstract

Thermal properties are essential for textile materials due to their common everyday use and protection against cold.

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Vorheriges Kapitel Image Processing Techniques for Evaluation of Textile Materials

Nächstes Kapitel Hydrophobic and Hydrophilic Textiles

Abdel-Rehim, Z.S., Saad, M.M., El-Shakankery, M., Hanafy, I.: Textile fabrics as thermal insulators. AUTEX Res. J. 6, 148–161 (2006)

Adam, E.A., Jones, P.J.: Thermophysical properties of stabilised soil building blocks. Build. Environ. 30, 245–253 (1995)CrossRef

Angelova, R.A., Reiners, P., Georgieva, E., Konova, H.P., Pruss, B., Kyosev, Y.: Heat and mass transfer through outerwear clothing for protection from cold: influence of geometrical, structural and mass characteristics of the textile layers. Text. Res. J. online first (2016)

Asdrubali, F., Baldinelli, G.: Thermal transmittance measurements with the hot box method: calibration, experimental procedures, and uncertainty analyses of three different approaches. Energy Buildings 43, 1618–1626 (2011)CrossRef

Bhattacharjee, D., Kothari, K.V.: Heat transfer through woven textiles. Int. J. Heat Mass Transf. 52, 2155–2160 (2009)CrossRef

Diswat, J., Hes, L., Bal, K.: Thermal resistance of cut pile hand tufted carpet and its prediction. Text. Res. J. online first (2016)

Epps, H.H., Goswami, B., Hassenboehler Jr., C.B.: The influence of indoor relative humidity and fabric properties on thermal transmittance of textile draperies. ASHRAE Trans. 90, 104–115 (1984)

Hassenboehler Jr., C.B., Vigo, T.L.: A mixed flow thermal transmittance tester for textiles. Text. Res. J. 52, 510–517 (1982)CrossRef

Hes, L.: Non-destructive determination of comfort parameters during marketing of functional garments and clothing. Indian J. Fibre Text. Res. 33, 239–245 (2008)

Hes, L., Araújo, D.M.: Effect of mutual bonding of textile layers on thermal insulation and thermal contact properties of fabric assemblies. Text. Res. J. 66, 245–250 (1996)CrossRef

Hes, L., Dolezal, I.: New method and equipment for measuring thermal properties of textiles. J. Text. Mach. Soc. Jpn. 42, 124–128 (1989)CrossRef

Hes, L., Stanek, J.: Theoretical and Experimental Analysis of Heat Conductivity for Nonwoven Fabrics. INDA-TEC Transactions, Philadelphia, PA (1989)

Hes, L., Kus, Z.: Non-destructive testing of thermophysiological properties of protective clothing. In: ECPC International Conference on Protective Clothing, Montreaux (2003)

Huang, J.: Review of heat and water vapor transfer through multilayer fabrics. Text. Res. J. 86, 325–336 (2016)CrossRef

Jin, X., Zhang, J., Hurren, C., Li, J., Rajkhowa, R., Wang, X.: The effect of fibrous structural difference on thermal insulation properties of biological composites: silkworm cocoons. Text. Res. J. online first (2015)

Kofler, P., Herten, A., Heinrich, D., Bottoni, G., Hasler, M., Faulhaber, M., Bechtold, T., Nachbauer, W., Burtscher, M.: Viscose as an alternative to aramid in workwear: influence on endurance performance, cooling, and comfort. Text. Res. J. 83, 2085–2092 (2013)CrossRef

Limare, A., Duvaut, T., Henry, J.F., Bissieux, C.: Non-contact photopyroelectric method applied to thermal and optical characterization of textiles. Four-flux modeling of a scattering sample. Int. J. Therm. Sci. 42, 951–961 (2003)CrossRef

Lizák, P., Mojumdar, S.C.: Thermal properties of textile fabrics. J. Therm. Anal. Calorim. 112, 1095–1100 (2013)CrossRef

Mangat, M.M., Hes, L., Bajzik, V.: Thermal resistance models of selected fabrics in wet state and their experimental verification. Text. Res. J. 85, 200–210 (2015)CrossRef

Morrissey, M.P., Rossi, R.M.: The effect of wind, body movement and garment adjustments on the effective thermal resistance of clothing with low and high air permeability insulation. Text. Res. J. 84, 583–592 (2014)CrossRef

Mumaw, J.R.: Calibrated hot box: an effective means for measuring thermal conductance in large wall sections. In: American Society for Testing and Materials, ASTM STP 544, Heat transmission measurements in thermal insulations, West Conshohocken, pp. 193–211 (1974)

Oğlakcioğlu, N., Marmarali, A.: Thermal comfort properties of some knitted structures. Fibres Text. East. Eur. 15, 94–96 (2007)

Pola, T., Häkkinen, T., Hännikäinen, J., Vanhala, J.: Thermal performance analysis of 13 heat sink materials suitable for wearable electronics applications. Sci. Technol. 3, 67–73 (2013)

Puszkarz, A.K., Krucinska, I.: The study of knitted fabric thermal insulation using thermography and finite volume method. Text. Res. J. online first (2016)

Ricciardi, P., Belloni, E., Cotana, F.: Innovative panels with recycled materials: thermal and acoustic performance and life cycle assessment. Appl. Energy 134, 150–162 (2014)CrossRef

Richards, M., Mattle, N.: A sweating agile thermal manikin (SAM) developed to test complete clothing systems under normal and extreme conditions, RTO-MP-076, pp. 1–7 (2001)

Romeli, D., Barigozzi, G., Esposito, S., Rosace, G., Salesi, G.: High sensitivity measurements of thermal properties of textile fabrics. Polym. Test. 32, 1029–1036 (2013)CrossRef

Uzun, M.: Processing and characterisation of the copper treated polylactic acid and cotton fabrics: thermophysiological comfort properties. Mater. Sci. 20, 67–72 (2014)

Yang, C., Wang, J., Li, L.: A novel approach for developing high thermal conductive artificial leather by utilizing smart electronic materials. Text. Res. J. online first (2016)

Titel: Thermal Properties of Textiles
verfasst von: Andrea Ehrmann
Tomasz Blachowicz
Verlag: Springer International Publishing
Buch: Examination of Textiles with Mathematical and Physical Methods
Print ISBN: 978-3-319-47406-9

Electronic ISBN: 978-3-319-47408-3

Copyright-Jahr: 2017
DOI: https://doi.org/10.1007/978-3-319-47408-3_8

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