Numerical and experimental analysis on anisotropic thermal conductivity of carding quartz fiber web based on the reconstruction model Du, P, Ding, Xiang, Liang, Q, Chen, X, Zhang, Y and Chen, L 2022, Numerical and experimental analysis on anisotropic thermal conductivity of carding quartz fiber web based on the reconstruction model, Textile Research Journal, vol. 92, no. 11-12, pp. 2100-2111, doi: 10.1177/00405175221076036. Attached Files Name Description MIMEType Size Downloads Title Numerical and experimental analysis on anisotropic thermal conductivity of carding quartz fiber web based on the reconstruction model Author(s) Du, P Ding, Xiang Liang, Q Chen, X Zhang, Y Chen, L Journal name Textile Research Journal Volume number 92 Issue number 11-12 Article ID ARTN 00405175221076036 Start page 2100 End page 2111 Total pages 12 Publisher SAGE Place of publication London, Eng. Publication date 2022 ISSN 0040-5175 1746-7748 Keyword(s) anisotropic thermal conduction carding quartz fiber web COMPOSITES Large slenderness ratio fiber Materials Science Materials Science, Textiles ORIENTATION Python reconstructed 3D model Science & Technology Technology Summary In order to analyze the thermal and mechanical properties of the carding quartz fiber web and the needle-punched quartz fiber preform containing the carding quartz fiber web, we propose a ‘three-step’ method to establish a three-dimensional quartz carding fiber web model containing large slenderness ratio fibers. First, the thickness and areal density of the carding quartz fiber web were measured and statistical analysis of fiber length and orientation distribution was carried out, which provided data support for establishing the three-dimensional carding fiber web model. Based on the wide application of Python language in finite element software, then spatial layered fibers of the beam element were generated by running Python scripts in finite element software; second, the three-dimensional carding fiber web model of beam element was established through a deposition and compression process by the explicit method of the finite element software; finally, the three-dimensional carding fiber web model of the beam element was converted into the solid element model for heat transferring analysis by Python. The converted process is the reconstruction process. Furthermore, anisotropic heat transmission of the three-dimensional carding fiber web model that includes temperature distribution and heat flux distribution were analyzed. Meanwhile, anisotropic thermal conductivity of the three-dimensional carding fiber web model was predicted in finite element software. A hot-disk thermal analyzer was used to measure the anisotropic thermal conductivity of the three-dimensional carding quartz fiber web. Experimental anisotropic thermal conductivity showed an excellent agreement with anisotropic thermal conductivity predicted by the finite element method. Moreover, the method in this paper is not only suitable for any other fibrous materials with randomly distributed fibers and large slenderness ratio fibers, but also is more efficient and low cost to obtain detailed heat conductions and anisotropic thermal conductivity. Language eng DOI 10.1177/00405175221076036 Field of Research 0910 Manufacturing Engineering 0912 Materials Engineering HERDC Research category C1 Refereed article in a scholarly journal Persistent URL http://hdl.handle.net/10536/DRO/DU:30163940 Document type: Journal Article Collections: Institute for Frontier Materials GTP Research Related Links Link Description Connect to published version Go to link with your DU access privileges   Connect to Elements publication management system Go to link with your DU access privileges     Unless expressly stated otherwise, the copyright for items in DRO is owned by the author, with all rights reserved. Versions Version Filter Type Mon, 07 Mar 2022, 08:28:48 EST Mon, 07 Mar 2022, 14:43:04 EST Sat, 12 Mar 2022, 01:32:11 EST Fri, 13 May 2022, 06:05:00 EST Mon, 18 Jul 2022, 14:20:39 EST Mon, 18 Jul 2022, 14:24:17 EST Mon, 18 Jul 2022, 14:39:36 EST Filtered Full Citation counts:   Cited 0 times in TR Web of Science Cited 0 times in Scopus Search Google Scholar Access Statistics: 7 Abstract Views, 0 File Downloads  -  Detailed Statistics Created: Mon, 07 Mar 2022, 08:28:48 EST