Numerical Investigation of the Air Gap Distribution of Jackets with Different Fits and its Influence on Human Temperature

Awais, Muhammad; Krzywinski, Sybille; Kyosev, Yordan

doi:10.5604/01.3001.0015.2727

Artykuł - szczegóły

Tytuł artykułu

Numerical Investigation of the Air Gap Distribution of Jackets with Different Fits and its Influence on Human Temperature

Autorzy

Awais Muhammad , Krzywinski Sybille , Kyosev Yordan

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.5604/01.3001.0015.2727

Warianty tytułu

Języki publikacji

Abstrakty

The air gaps underneath clothing have a great influence on the thermal regulation of the human body. The distribution of the air gaps depends on the shape of the human body as well as on clothing style, fit, and deformation properties. This paper reports on the influence of clothing fit on thermophysiological parameters of the human body through thermal simulation. Four different fits of jacket and a test person were considered for the investigation and for simulation purposes. The results of the simulation concluded that different thermal regulations of the human body were exhibited for different fits of the jacket, which is due to distinct air gaps between the human body and clothing for each fit of the jacket. This research work presents a fast method to predict the influence of clothing fit on thermal comfort, which is usually studied by a time-consuming, laborious method – the wear trial.

Słowa kluczowe

thermal simulation 3D fit simulation of clothing 3D scanning air gap clothing fit thermo-physiological model

Wydawca

Sieć Badawcza Łukasiewicz - Łódzki Instytut Technologiczny

Czasopismo

Fibres & Textiles in Eastern Europe

Rocznik

2021

Tom

Vol. 29, no. 6 (150)

Strony

77--86

Opis fizyczny

Bibliogr. 45 poz., rys., tab.

Twórcy

autor

Awais Muhammad

TU Dresden, Institute of Textile Machinery and High-Performance Material Technology, Germany

https://orcid.org/0000-0002-2431-4771

autor

Krzywinski Sybille

TU Dresden, Institute of Textile Machinery and High-Performance Material Technology, Germany

https://orcid.org/0000-0002-3515-6756

autor

Kyosev Yordan

TU Dresden, Institute of Textile Machinery and High-Performance Material Technology, Germany

https://orcid.org/0000-0003-3376-1423

Bibliografia

1. Parsons K. Human Thermal Environments [Internet]. Second. The Effects of Hot, Moderate, and Cold Environments on Human Health, Comfort and Performance. London and New York: Taylor and Francis Group; 2003. 1–538 p. Available from: http://onlinelibrary.wiley.com/doi/10.1002/cbdv.200490137/abstract
2. Lu Y, Song G, Li J. A Novel Approach for Fit Analysis of Thermal Protective Clothing Using Three-Dimensional Body Scanning. Appl Ergon [Internet]. 2014;45(6):1439–46. Available from: http://dx.doi.org/10.1016/j.apergo.2014.04.007
3. McCullough EA, Jones BW. A Comprehensive Data Base for Estimating Clothing Insulation. ASHRAE Trans. 1984; 2888(2888): 29.
4. Havenith G, Heus R, Lotens Wa. Resultant Clothing Insulation: A Function of Body Movement, Posture, Wind, Clothing Fit and Ensemble Thickness. Ergonomics [Internet]. 1990 Jan 1;33(1):67–84. Available from: https://doi.org/10.1080/00140139008927094
5. Chen YS, Fan J, Qian X, Zhang W. Effect of Garment Fit on Thermal Insulation and Evaporative Resistance. Text Res J [Internet]. 2004 Aug 1;74(8):742–8. Available from: https://doi.org/10.1177/004051750407400814.
6. Daanen HAM, Hatcher K, Havenith G. Determination of clothing microclimate volume. In: 10th International Conference on Environmental Ergonomics [Internet]. Fukuoka, Japan; 2002. Available from: https://repository.lboro.ac.uk/articles/Determination_of_clothing_microclimate_volume/9339344.
7. Zhang Z, Li J. Volume of Air Gaps Under Clothing And Its Related Thermal Effects. J Fiber Bioeng Informatics [Internet]. 2011;4(2):137–44. Available from: http://globalsci.org/intro/article_detail/jfbi/4910.html.
8. Psikuta A, Frackiewicz-Kaczmarek J, Frydrych I, Rossi R. Quantitative Evaluation of Air Gap Thickness and Contact Area Between Body and Garment. Text Res J. 2012; 82(14): 1405–13.
9. Daanen HAM, Psikuta A. 10-3D body scanning. In: Nayak R, Padhye RBT-A in GM, editors. The Textile Institute Book Series [Internet]. United Kingdom: Woodhead Publishing; 2018. p. 237–52. Available from: http://www.sciencedirect.com/science/article/pii/B9780081012116000100.
10. Lee Y, Hong K, Hong SA. 3D Quantification of Microclimate Volume in Layered Clothing for the Prediction of Clothing Insulation. Appl Ergon 2007; 38(3): 349–55.
11. Frackiewicz-Kaczmarek J, Psikuta A, Bueno M. Effect of Garment Properties on Air Gap Thickness and the Contact Area Distribution. Text Res J. 2015; 85(18): 1907–18.
12. Mert E, Psikuta A, Arevalo M, Charbonnier C, Luible-Bär C, Bueno M-A, et al. Quantitative Validation of 3D Garment Simulation Software for Determination of Air Gap Thickness in Lower Body Garments Quantitative Validation of 3D Garment Simulation Software for Determination of Air Gap Thickness in Lower Body Garments. In: AUTEX World Textile Conference 2017. Corfu, Greece.
13. Awais M, Krzywinski S. Method Development for Modeling, Designing, and Digital Representation of Outdoor and Protective Clothing. In: Majumdar A, Gupta D, Gupta S, editors. Functional Textiles and Clothing. Singapore: Springer Singapore; 2019. p. 205–18.
14. Mert E, Psikuta A, Arévalo M, Charbonnier C, Luible-Bär C, Bueno M-A, et al. A Validation Methodology and Application of 3D Garment Simulation Software to Determine the Distribution of Air Layers in Garments During Walking. Measurement [Internet]. 2018;117:153–64. Available from: http://www.sciencedirect.com/science/article/pii/S0263224117307510.
15. Lotens WA, Havenith G. Calculation of Clothing Insulation and Vapour Resistance. Ergonomics [Internet]. 1991 Feb 1;34(2):233–54. Available from: https://doi.org/10.1080/00140139108967309.
16. Li Y, Holcombe BV. Mathematical Simulation of Heat and Moisture Transfer in a Human-Clothing-Environment System. Text Res J [Internet]. 1998 Jun 1;68(6):389–97. Available from: https://doi.org/10.1177/004051759806800601.
17. Fan J, Luo Z, Li Y. Heat and Moisture Transfer with Sorption and Condensation in Porous Clothing Assemblies and Numerical Simulation. Int J Heat Mass Transf [Internet]. 2000; 43(16): 2989–3000. Available from: http://www.sciencedirect.com/science/article/pii/S0017931099002355.
18. Berger X, Sari H. A New Dynamic Clothing Model. Part 1: Heat and Mass Transfers. Int J Therm Sci [Internet]. 2000; 39(6): 673–83. Available from: http://www.sciencedirect.com/science/article/pii/S1290072980002116.
19. Stolwijk JA, Nadel ER, Wenger CB, Roberts MF. Development and Application of a Mathematical Model of Human Thermoregulation. Arch Sci Physiol (Paris). 1973; 27(3): 303.
20. Fiala D, Lomas KJ, Stohrer M. A Computer Model of Human Thermoregulation for a Wide Range of Environmental Conditions: The Passive System. J Appl Physiol [Internet]. 1999 Nov 1;87(5):1957–72. Available from: https://doi.org/10.1152/jappl.1999.87.5.1957
21. Fiala D, Lomas KJ, Stohrer M. Computer Prediction of Human Thermoregulatory and Temperature Responses to a Wide Range of Environmental Conditions. Int J Biometeorol [Internet]. 2001; 45(3): 143–59. Available from: http://search.ebscohost.com/login.aspx?direct=true&db=cmedm&AN=11594634&site=ehost-live.
22. Tanabe S, Kobayashi K, Nakano J, Ozeki Y, Konishi M. Evaluation of Thermal Comfort Using Combined Multi-Node Thermoregulation (65MN) and Radiation Models and Computational Fluid Dynamics (CFD). Energy Build [Internet]. 2002; 34(6): 637–46. Available from: http://www.sciencedirect.com/science/article/pii/S0378778802000142.
23. Huizenga C, Hui Z, Arens E. A Model of Human Physiology and Comfort for Assessing Complex Thermal Environments. Build Environ. 2001; 36: 691–9.
24. Fanger P. Thermal Comfort : Analysis and Applications in Environmental Engineering. Danish Technical Press; 1970.
25. Fiala D, Lomas KJ, Stohrer M. First Principles Modeling of Thermal Sensation Responses in Steady-State and Transient Conditions. ASHRAE Trans. 2003; 109: 179.
26. Zhang H. Human Thermal Sensation and Comfort in Transient and Non-Uniform Thermal Environments. University of California, Berkley; 2003.
27. Fiala D, Havenith G, Bröde P, Kampmann B, Jendritzky G. UTCI-Fiala Multi-Node Model of Human Heat Transfer and Temperature Regulation. Int J Biometeorol. 2012; 56(3): 429–41.
28. Severens NMW, Lichtenbelt WD van M, Frijns AJH, Steenhoven AA Van, Mol BAJM de, Sessler DI. A Model to Predict Patient Temperature During Cardiac Surgery. Phys Med. Biol [Internet]. 2007; 52(17): 5131–45. Available from: http://dx.doi.org/10.1088/0031-9155/52/17/002.
29. Psikuta A, Richards M, Fiala D. Single- and Multi-Sector Thermophysiological Human Simulators For Clothing Research. In: 7th International Thermal Manikin and Modelling Meeting. Coimbra; 2008. p. 1–5.
30. Fiala D, Lomas KJ. Application of a Computer Model Predicting Human Thermal Responses to the Design of Sports Stadia. In: CIBSE ’99, Conference Proc. Harrogate, UK; p. 492–9.
31. Yang T, Cropper PC, Cook MJ, Yousaf R, Fiala D. A New Simulation System to Predict Human-Environment Thermal Interactions in Naturally Ventilated Buildings. In: Proceedings of the 10th International Conference on Building Simulation [Internet]. Beijing; 2007. p. 751–6. Available from: https://dspace.lboro.ac.uk/dspacejspui/bitstream/2134/5255/1/BS2007_paper424.pdf.
32. Awais M, Krzywinski S, Wölfling B-M, Classen E. Thermal Simulation of Close-Fitting Sportswear. vol. 13, Energies. 2020.
33. Awais M, Krzywinski S, Wendt E. A Novel Modeling and Simulation Approach for the Prediction of Human Thermophysiological Comfort. Text Res J [Internet]. 2020 Sep 11;0040517520955227. Available from: https://doi.org/10.1177/0040517520955227.
34. Theseus FE [Internet]. [cited 2017 Oct 3]. Available from: http://www.theseusfe.com/simulation-software/human-thermal-model.
35. Paulke S. Finite Element Based Implementation of Fiala’s Thermal Manikin in TheseusFE [Internet]. 2007 [cited 2017 Aug 3]. Available from: http://www.theseusfe.com/simulation-software/human-thermal-model.
36. Fiala D. Dynamic Simulation of Human Heat Transfer and Thermal Comfort (Thesis). Sustain Dev. 1998; 45(2001):1.
37. Pennes HH. Analysis of Tissue and Arterial Blood Temperatures in the Resting Human Forearm. J Appl Physiol. 1948; 1: 5–34.
38. Theseus-FE. Theory Manual 7.1.09. Munich, Germany; 2020.
39. Pandolf K, Givoni B, Goldman R. Predicting Energy Expenditure with Loads While Standing or Walking Very Slowly. J Appl Physiol. 1977; 43(4): 577–81.
40. Vitronic [Internet]. Available from: https://www.vitronic.com/industrial-and-logisticsautomation/sectors/3d-body-scanner.html.
41. 3D scanning, design and reverse engineering software from 3D Systems Geomagic [Internet]. [cited 2016 Sep 7]. Available from: http://www.geomagic.com/en/.
42. GbR DKF. GRAFIS-Software [Internet]. [cited 2019 Aug 16]. Available from: https://www.grafis.com/files/Downloads/Infomaterial/Prospekt V12_EN_web.pdf.
43. Lectra [Internet]. [cited 2017 Jun 10]. Available from: http://www.lectra.com/en.
44. Incropera FP, DeWitt DP, Bergman TL, Lavine AS. Fundamentals of Heat and Mass Transfer [Internet]. SIXTH EDIT. US Patent 5,328,671. Chichester: John Willey & Sones; 2007. 997 p. Available from: http://www.google.com/patents?hl=en&lr=&vid=USPAT5328671&id=rb8lAAAAEBAJ&oi=fnd&dq=Heat+and+Mass+Transfer&printsec=abstract%5Cnhttp://www.google.com/patents?hl=en&lr=&vid=USPAT5328671&id=rb8lAAAAEBAJ&oi=fnd&dq=Heat+and+mass+transfer&printsec=abstract%5Cnh
45. Mert E, Psikuta A, Bueno MA, Rossi RM. Effect of heterogenous and homogenous air gaps on dry heat loss through the garment. Int J Biometeorol. 2015;59(11):1701–10.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-18794f8f-865f-4c39-b090-a5bdd776fb2e