Formation of the package of materials of adaptive multifunctional clothing

Authors

DOI:

https://doi.org/10.15587/2312-8372.2017.102151

Keywords:

adaptive multifunctional clothing, seam thickness, energy-information impact, package of materials

Abstract

The object of research is the process of designing of adaptive multifunctional clothing. The problematic issue of the object is to ensure its effectiveness through properties. The basis for improvement of designing of adaptive multifunctional clothing is the application of energy-information effects of materials on the functional state of the human body. On the basis of this, it is justified to form a package of materials for development of adaptive men's underwear for treatment and prevention of chronic prostatitis. Selected paintings have a high inertness level for the functional state of the human body 0.87...1.0. Positive energy-information impact on the functional state of the body is achieved due to the influence of silver plates located in the product, according to certain biologically active zones of the human body. For a reasonable choice of the technology of joining materials and means of energy-information impact, the thickness of the overhead seams is studied. The rationale is that by increasing the design thickness of the package of materials by 32 %, the thickness of the seam increases by 28.8 %. The effectiveness of the developed adaptive multifunctional underwear is confirmed by experimental wearing and clinical approbation. It is determined that the functional state of the male patients improved after the use of developed clothing for one month. The conducted researches ensure the provision of adaptive multi-functional clothing with expanded functional capabilities that has a positive social and economic effect.

Author Biographies

Ludmyla Buhantsova, Khmelnitsky National University, 11, Institytska str., Khmelnitsky, Ukraine, 29016

PhD, Associate Professor

Department of Technology and Design of Garments

Оlena Luschevska, Khmelnitsky National University, 11, Institytska str., Khmelnitsky, Ukraine, 29016

PhD, Associate Professor

Department of Technology and Design of Garments

Oleksandr Troyan, Khmelnitsky National University, 11, Institytska str., Khmelnitsky, Ukraine, 29016

PhD, Associate Professor

Department of Technology and Design of Garments

Larysa Krasnіuk, Khmelnitsky National University, 11, Institytska str., Khmelnitsky, Ukraine, 29016

PhD, Associate Professor

Department of Technology and Design of Garments

Оleksandr Yantsalovskyі, Khmelnytskyi City Polyclinic № 4, 9, Molodizhna str., Khmelnytsky, Ukraine, 29016

Urologist

References

  1. Chuprina, N. V. (2013). Enerhozberihaiuchi tekhnolohii ekodyzainu u stvorenni suchasnoho odiahu yak produktu industrii mody. Visnyk Kyivskoho natsionalnoho universytetu tekhnolohii i dyzainu, 6 (74), 245–253.
  2. Deepti, G. (2011). Functional clothing – definition and classification. Indian Journal of Fibre & Textile Research, 36 (4), 321–326. Available: http://hdl.handle.net/123456789/13225
  3. Cunha, J., Broega, A. C. (2009). Designing multifunctional textile fashion products classification. Autex 2009 World Textile Conference. Available: https://repositorium.sdum.uminho.pt/ bitstream/1822/19207/3/AUTEX09_JC_CB.pdf
  4. Haydon, B. (01.05.2017). Les nanomatériaux et leur utilisation dans les textiles – Normes. Normalisation interne pour les fabricants et les importateurs canadiens et développements internationaux en matière de normalisation classification. Government of Canada. Available: https://www.ic.gc.ca/eic/site/textiles-textiles.nsf/fra/h_tx03226.html
  5. Nikolaev, E. L., Lazareva, E. Yu. (2013). Adaptation and personality adaptive potential: current research approaches. Vestnik psihiatrii i psihologii Chuvashii, 9, 18–32.
  6. Kobylianska, R. M., Kobylianskyi, V. Ya. (2016). Monitorynh stanu imunnoi systemy ta efektyvnosti zastosuvannia informatsiinykh imunokorektoriv. Materialy naukovo-praktychnoi konferentsii z mizhnarodnoiu uchastiu «Suchasni teoretychni ta praktychni aspekty shchodo stratehii rozvytku narodnoi i netradytsiinoi medytsyny», 28-29 zhovtnia 2016 r. Kyiv, 68–69. Available: http://uanm.org.ua/wp-content/uploads/2016/12/Print_Konferencia_Books_1_182A5_281016_li_211016.pdf
  7. Bereznenko, M. P., Fedotkin, I. M., Bereznenko, S. M., Yantsalovskyі, O. Y. (2013). The physical nature of disease and the role of clothing as a factor of healthcare. Visnyk of Kherson National Technical University, 3, 16–19.
  8. Bereznenko, K. P., Bereznenko, S. M., Pawłowa, M., Yantsalovskyі, O. I., Vlasenko, V. (2011). Influence of Textile Materials on the Functional State of Human Body – Assessment. Towaroznawcze Problemy Jakosci, 4, 59–65. Available: http://bazekon.icm.edu.pl/bazekon/element/bwmeta1.element.ekon-element-000171197633
  9. Lushchevska, O. M., Yantsalovskyі, O. I., Peteherych, S. V., Bereznenko, M. P. (2012). Doslidzhennia ekolohichnoi bezpechnosti materialiv dlia vyhotovlennia verkhnoho odiahu. Problemy legkoi i tekstilnoi promyshlennosti Ukrainy, 1 (19), 105–109.
  10. Bereznenko, M. P., Vlasenko, V. I., Yantsalovskyі, O. I., Lushchevska, O. M. (2011). Enerho-informatsiinyi aspekt funktsionuvannia systemy «Liudyna-odiah-navkolyshnie seredovyshche». Bulletin of the Kyiv National University of Technologies and Design, 4, 104–109.
  11. About Complex. Intera-DiaCor. Available: http://www.diacor.com.ua/en/?page=complex
  12. Lushchevska, O. M., Troyan, O. M., Yantsalovskyі, O. I. (2008). Rozrobka metodyky doslidzhennia komfortnosti tekstylnykh materialiv. Visnyk of Kherson National Technical University, 6, 151–155.
  13. Skrypnyk, Yu. O., Shevchenko, K. L., Suprun, N. P., Vahanov, O. A. (2005). Intehralna otsinka komfortnosti tekstylnykh materialiv za elektromahnitnymy pokaznykamy. Bulletin of the Kyiv National University of Technologies and Design, 1, 104–109.
  14. Khammatova, V. V. (2016). Manufacture of experimental samples of nanomodified textile materials affect the strength of special – purpose clothing. Izvestiia vuzov. Tehnologiia tekstil'noi promyshlennosti, 2 (362), 59–65.
  15. Rakhimova, S. M., Vig, A., Taussarova, B. R., Kutzhanova, A. Zh. (2015). The use of nanosized metal oxides for antimicrobial finish of cotton fabric. Izvestiia vuzov. Tehnologiia tekstil'noi promyshlennosti, 3 (357), 202–205.
  16. Shchutska, G. (2016). Development and application of the discrete model of multi-layered textile materials. Eastern-European Journal of Enterprise Technologies, 6(5(84)), 39–45. doi:10.15587/1729-4061.2016.85784
  17. In: Cho, G. (2009). Smart Clothing. Technology and Applications. FL, USA: CRC Press, Inc. Boca Raton, 287. doi:10.1201/9781420088533
  18. Ariyatum, B., Holland, R., Harrison, D., Kazi, T. (2005). The future design direction of Smart Clothing development. Journal of the Textile Institute, 96 (4), 199–210. doi:10.1533/joti.2004.0071
  19. Berglin, L. T. H. (2008). Interactive Textile Structures Creating Multifunctional Textiles based on Smart Materials. Gothenburg, Sweden: Department of Computer Science and Engineering, Chalmers University of Technology, Available: https://www.diva-portal.org/smash/get/diva2:876879/FULLTEXT01.pdf
  20. Krasniuk, L. V., Troyan, O. M., Yantsalovskyі, O. Y., Torokanets, V. S. (2016). Prospects for the creation of multifunctional garments based on biologically active points and biologically active zones of the human body. Visnyk of Kherson National Technical University, 5, 110–115.
  21. Skrypnyk, Yu. O., Suprun, N. P., Kholodenko, V. M. (2005). Elektrofiziolohichni metody otsinky komfortnosti odiahu. Bulletin of the Kyiv National University of Technologies and Design, 5, 152–159.
  22. Bikbulatova, A. A. (2014). Determining the Thickness of Materials in Therapeutic and Preventive Heat-saving Garments. Izvestiia vuzov. Tehnologiia tekstil'noi promyshlennosti, 1 (349), 119–123.
  23. Buhantsova, L. V. (2016). Research on influence of seams parameters on seam thickness of single-layer clothing. Visnyk of Kherson National Technical University, 4, 56–61.
  24. Sarhan, T. M. A. (2013). Interaction between Sewing Thread Size and Stitch Density and Its Effects on the Seam Quality of Wool Fabrics. Journal of Applied Sciences Research, 9 (8), 4548–4557.
  25. Choudhary, A. K., Goel, A. (2013). Effect of Some Fabric and Sewing Conditions on Apparel Seam Characteristics. Journal of Textiles, 2013, 1–7. doi:10.1155/2013/157034
  26. Zamyshlyaeva, V. V., Smirnova, N. A., Volkova, S. V., Tatarnikova, L. M. (2014). Research of Influence of Thread Connections on Indicators of Shape Stability Package Clothes. Izvestiia vuzov. Tehnologiia tekstil'noi promyshlennosti, 5 (353), 8–12.
  27. Dobilaite, V., Juciene, M. (2006). The influence of mechanical properties of sewing threads on seam pucker. International Journal of Clothing Science and Technology, 18 (5), 335–345. doi:10.1108/09556220610685276
  28. Buhantsova, L. (2016). The coefficient of seam thickness of multifunctional clothing. Abstracts of scientific papers XIІI International Scientific-Practical Conference: «Actual Problems of Modern Science», Moscow–Astana–Vienna–Kharkov, 28 October 2016. International Science Center, 19–21.

Published

2017-05-30

How to Cite

Buhantsova, L., Luschevska О., Troyan, O., Krasnіuk L., & Yantsalovskyі О. (2017). Formation of the package of materials of adaptive multifunctional clothing. Technology Audit and Production Reserves, 3(3(35), 4–12. https://doi.org/10.15587/2312-8372.2017.102151

Issue

Section

Chemical and Technological Systems: Original Research