Ultraviyole Koruma ve Geçirgenlik: Tekstil Malzemeleri

Abstract

Güneş ışığının en tehlikeli bileşeni olan ultraviyole radyasyon, görünmez ve hissedilmez. Tekstil materyalleri, güneş ışığının etkilerinden korunmak için önemli bir rol oynar. Işık, bir tekstil yüzeyine temas ettiğinde, bir kısmı yüzey tarafından emilir, bir kısmı geçer ve bir kısmı da yansır. Bu koruyucu özellikler, kumaşların yapısal özelliklerine bağlıdır. Bu çalışma, pamuk ve polyester materyallerinin UV ışınlarını geçirme özellikleri arasındaki ilişkiyi incelemeyi amaçlar. Kumaşların UV geçirgenliğini etkileyen faktörler arasında lif yapısı (pamuk/polyester), iplik yapısı (numara) ve kumaş geometrisi (sıklık) gibi birçok parametre bulunmaktadır. Bu çalışmada, bulanık mantık yöntemi kullanılarak polyester/pamuk karışımlı kumaşlardaki UV geçirgenliği tahmin edilmiştir. Analiz sonuçları, polyester/pamuk kumaşların UV geçirgenliği açısından karşılaştırmalı bir değerlendirme sunmaktadır.

Keywords

• Ultraviyole koruma
• Geçirgenlik
• Tekstil malzemeleri
• Bulanık mantık

The Ultraviolet Protection and Transmission: Textile Materials

Abstract

From the sun; ultraviolet radiation, which is invisible, insensible and the most dangerous. When light touches a textile surface, some of the light is absorbed by the surface, some of it passes through the surface, and some of it is reflected. Radiation protection may vary in the degree of protection depending on the structural parameters of the materials. There are many parameters that affect the behavior of fabrics against light, such as fiber structure (cotton / polyester), thread structure (count), and fabric geometry (tightness). The study aims to present a relationship between the UV permeability properties of cotton and polyester materials. In the study, the UV transmittance of polyester/cotton fabric was estimated by the fuzzy logic method. The analysis shows the results obtained in comparison with the UV transmittance of polyester/cotton fabrics.

Keywords

• Utraviolet protection
• Transmission
• Textile materials
• Fuzzy logic.

References

1. [1] Haleem, N., Ibrahim, S., Hussain, T., Jabbar, A., Malik, M. H., Malik, Z. A., 2014. Determining The Light Transmission Of Woven Fabrics Through Different Measurement Methods and Its Correlation With Air Permeability. Journal of Engineered Fibers and Fabrics, 9(4)
2. [2] Stankovic, S. B., Popovic, D., Poparic, G. B., Bizjak, M., 2009. Ultraviolet Protection Factor Of Gray-State Plain Cotton Knitted Fabrics. Textile Research Journal, 79(11), 1034-1042.
3. [3] Alvarez, J., Lipp-Symonowicz, B., 2003. Examination of The Absorption Properties Of Various Fibres in Relation to UV Radiation. Autex Research Journal, 3(2), 72-77.
4. [4] Gambichler, T., Avermaete, A., Bader, A., Altmeyer, P., Hoffmann, K., 2001. Ultraviolet Protection by Summer Textiles. Ultraviolet Transmission Measurements Verified by Determination of The Minimal Erythema Dose with Solar‐Simulated Radiation. British Journal of Dermatology, 144(3), 484-489.
5. [5] Wilson, C. A., Parisi, A. V., 2006. Protection From Solar Erythemal Ultraviolet Radiation–Simulated Wear and Laboratory Testing. Textile Research Journal, 76(3), 216-225.
6. [6] Khazova, M., O'Hagan, J. B., Grainger, K. L., 2007. Assessment Of Sun Protection for Children's Summer 2005 Clothing Collection. Radiation Protection Dosimetry, 123(3), 288-294.
7. [7] Gabrijelčič, H. Urbas, R. Sluga F, and Dimitrovski K., 2009. Influence Of Fabric Constructional Parameters and Thread Colour on UV Radiation Protection. Fibres & Textiles in Eastern Europe, January/March, vol. 17, No. 1 (72), 46-54.
8. [8] Oda, H., 2011. Development Of UV Absorbers for Sun Protective Fabrics. Textile Research Journal, 81(20), 2139-2148.

9. [9] Hoque, M. T., Mahltig, B., 2020. Realisation of Polyester Fabrics With Low Transmission for Ultraviolet Light. Coloration Technology, 136(4), 346-355.
10. [10] Abidi, N., Hequet, E., Tarimala, S., Dai, L. L., 2007. Cotton Fabric Surface Modification for Improved UV Radiation Protection Using Sol–Gel Process. Journal of Applied Polymer Science, 104(1), 111-117.
11. [11] Rashid, M., Mahltig, B., Mamun, K., 2019. Surface Modification of Cotton Fabric with Effect Pigment-A Review of Improved Textile Optical Functionalization. International Journal of Textile Science, 8(1), 10-15.
12. [12] Riva, A., Algaba, I., 2006. Ultraviolet Protection Provided by Woven Fabrics Made With Cellulose Fibres: Study Of The Influence of Fibre Type And Structural Characteristics of The Fabric. Journal of the Textile Institute, 97(4), 349-358.
13. [13] Narayanan, D. L., Saladi, R. N., Fox, J. L., 2010. Ultraviolet Radiation and Skin Cancer. International Journal Of Dermatology, 49(9), 978-986.
14. [14] Yelkovan, S., Çeven, E. K., Günaydın, G. K., 2023. Tekstil Ürünlerinde Solar Geçirgenlik. In International Conference on Frontiers in Academic Research (Vol. 1, pp. 351-361).
15. [15] Mahltig, B., Leisegang, T., Jakubik, M., Haufe, H., 2023. Hybrid Sol-Gel Materials for Realization of Radiation Protective Coatings—A Review With Emphasis On UV Protective Materials. Journal of Sol-Gel Science and Technology, 107(1), 20-31.
16. [16] Akarslan, F., Kodaloğlu, M., 2023. Determining The Drying Rates of Fabrics with Different Knit Structures by Fuzzy Logic Method. International Journal of Computational and Experimental Science and Engineering, 9(2), 191-196.
17. [17] Kodaloğlu, M., Akarslan Kodaloğlu, F., 2022. Evaluatıon of Thermal Comfort In Terms Of Occupational Safety In Weaving Facilities By Fuzzy Logic. International Journal of 3D Printing Technologies and Digital Industry, 6(2), 273-279.
18. [18] Kodaloğlu, M., Akarslan Kodaloğlu, F., 2024. Thermal Comfort Effect Of Natural Radiation: Color Factor In Industrial Safety Helmets, Human Health. Uluborlu Mesleki Bilimler Dergisi, vol. 7, no. 2, 20-33.
19. [19] Kodaloğlu, M., Akarslan Kodaloğlu, F., 2024. Prediction of The Ultraviolet Protection Provided by Woven Fabric Construction Using Fuzzy Logic. Süleyman Demirel University Faculty of Arts and Science Journal of Science, vol. 19 no. 1, 40-52.
20. [20] Tian, Y., Ding, R., Yoon, S. S., Zhang, S., Yu, J., Ding, B., 2025. Recent Advances in Next‐Generation Textiles. Advanced Materials, 2417022.
21. [21] Alshehri, L. A. A., Attia, N. F., 2025. Sustainable and Green Treatment Approach For Embroidered Based Fabrics For Integrating Antibacterial, UV Protection And Strengthening Properties. Chemical Papers, 1-11.
22. [22] Masae, M., Worachetwarawat, P., Pitsuwan, P., Kongsong, P., Sangchay, W., El-Lateef, H. M. A., Mohamed, I. M., 2025. Development and Characterization of Silica And PVA–Tio2-Coated Cotton Fabrics for Enhanced Hydrophobicity, Antibacterial Activity, and UV-Protective Properties. Fibers and Polymers, 1-12.
23. [23] Alkhatib, F., Al-Ghamdi, S. A., Alatawi, N. M., Munshi, A. M., Almotairy, A. R., Mogharbel, R. T., El-Metwaly, N. M., 2025. Technical Viscose Textiles Treated with Ln-Metal Organic Framework:photochromic/uv-Protective/antimicrobial Potentiality. Fibers and Polymers, 1-17.