Abstract
Abstract
Fabric shape retention is a critical property that directly determines the functional performance and aesthetic quality of textile products; existing numerical simulation methods have limitations in simultaneously capturing the geometric deformation and internal stress distribution of fabrics during shape retention processes. This paper proposes a yarn-scale finite-element simulation model specifically designed for fabric shape retention detection, which covers three sequential stages of fabric shape change: the lifting and arching process, the compression process, and the release and recovery process. Three common fabric types were tested under different compression durations to verify the model’s applicability. To ensure the reliability of the proposed simulation model, an image-based verification method was developed. This method introduces crease image technology into yarn-scale simulation validation, representing an innovative application. Results confirm high simulation accuracy and mechanical reliability. Pearson correlation coefficients between simulated and experimental curvature values are 0.967 (cotton), 0.978 (polyester), and 0.969 (linen), with all fabrics showing satisfactory fitting precision ( P < 0.01). Stress analysis reveals distinct gradient distributions in the crease regions. Cotton exhibits the highest residual stress, reaching 37 MPa under 90-second compression. Residual stress increases nonlinearly with arching duration. The yarn-scale simulation model integrated with the image-based validation method enables internal stress evaluation without physical crease tests. This provides key theoretical support for fabric structure optimization and high-performance textile development.
Direct answer
What can I do from this paper page?
Use this page to scan "Yarn-scale fabric simulation with crease image validation for shape retention analysis" quickly: start with the summary and abstract, then check the authors, source, topics, and related papers. From here, open Scollr to follow Textile materials and evaluations research, save the paper, or map adjacent work.
Research areas
Follow related topics
Citation
BibTeX
@article{Zhang2026Yarn,
title = {Yarn-scale fabric simulation with crease image validation for shape retention analysis},
author = {Pengfei Zhang and Xilin Peng and Junhao Hu and Lei Wang and Ruru Pan},
journal = {Textile Research Journal},
year = {2026},
doi = {10.1177/00405175261458776},
url = {https://doi.org/10.1177/00405175261458776}
}
FAQ
Using this paper in a discovery workflow
How do I find related work for this paper?
Use the related papers and topic links on this page as starting points. In Scollr, you can also open the paper and build a literature map around its references, citing papers, and related work.
How can I keep up with new Textile materials and evaluations research papers?
Follow Textile materials and evaluations research in Scollr. New papers from the topic flow into a personalized feed, and you can save useful studies to revisit later.
Can I cite this paper from this page?
This page includes a static BibTeX block for Yarn-scale fabric simulation with crease image validation for shape retention analysis. Always verify the DOI, source, and publication details against the publisher record before submitting a manuscript.
Follow this research in Scollr
Follow the topics and authors behind this paper, save useful studies, and build a literature map when you are ready to go deeper.
Get the app