FEATURES DESIGNING SPECIAL CLOTHING FOR THE HOT CLIMATE OF UZBEKISTAN

This paper considers the issues of establishing the relationship between the properties of fabric, clothing design and the comfort of clothing; communication of the size of the human body, allowance for free fitting, modern design when developing the design of clothing; connection of the allowance for free fitting with a suitable air gap. A diagram is given that characterizes the dependence of the comfort of clothing on its design and properties of fabrics. A mathematical model of the processes of air exchange in the underwear space is considered, which will allow obtaining more complete information and establishing more stringent dependences of the allowance on various factors affecting its value. The numerical value of the allowances for some parameters of the environment, which characterizes the hot climate, is obtained. An analytical method for calculating the allowance for free fitting is considered. The fact is stated that for the air exchange process a mathematical model has been obtained that allows one to determine the concentration of H2O or CO2 in the space under the space during diffusion air exchange, and that the mathematical model of complex convective-diffusion air exchange is based on the equation of the material balance of the transferred component for the space available; and that the curves were used to determine the influence of product design, fabric properties and environmental parameters on the free-fit allowance. The issue of verifying the correctness of the allowance for free fit, obtained by calculation, according to the formula was considered in detail. Physiological and hygienic assessment of special clothing intended for hot climates was carried out experimentally in a microclimatic room, testing samples of special clothing with different values of allowances for free fit compared to the calculated size.

Name of journalTechnical science and innovation
Number of edition2022, №3(13)
View count56

Web Address

DOI

Date of creation in the UzSCI system05-11-2022

Read count56

Date of publication30-09-2022

Main LanguageIngliz

Pages79-86

Tags

temperature

humidity

design

microclimate

special clothing

underwear parameter

carbon dioxide concentration

ventilation openings

English

This paper considers the issues of establishing the relationship between the properties of fabric, clothing design and the comfort of clothing; communication of the size of the human body, allowance for free fitting, modern design when developing the design of clothing; connection of the allowance for free fitting with a suitable air gap. A diagram is given that characterizes the dependence of the comfort of clothing on its design and properties of fabrics. A mathematical model of the processes of air exchange in the underwear space is considered, which will allow obtaining more complete information and establishing more stringent dependences of the allowance on various factors affecting its value. The numerical value of the allowances for some parameters of the environment, which characterizes the hot climate, is obtained. An analytical method for calculating the allowance for free fitting is considered. The fact is stated that for the air exchange process a mathematical model has been obtained that allows one to determine the concentration of H2O or CO2 in the space under the space during diffusion air exchange, and that the mathematical model of complex convective-diffusion air exchange is based on the equation of the material balance of the transferred component for the space available; and that the curves were used to determine the influence of product design, fabric properties and environmental parameters on the free-fit allowance. The issue of verifying the correctness of the allowance for free fit, obtained by calculation, according to the formula was considered in detail. Physiological and hygienic assessment of special clothing intended for hot climates was carried out experimentally in a microclimatic room, testing samples of special clothing with different values of allowances for free fit compared to the calculated size.

Tags

temperature

humidity

design

microclimate

special clothing

underwear parameter

carbon dioxide concentration

ventilation openings

№ Author name position Name of organisation

1 Mirtalipova N.K. teacher Tashkent Institute of Textile and Light Industry

2 Isaxujayeva N.A. teacher Tashkent Institute of Textile and Light Industry

№ Name of reference

1 I.A. Ermakova. Hygiene of clothes. “Textbook Vladivostok”, 2006. 94.

2 N.T. Gafurova., D.I. Sailieva., J.I. Ismoilov. Principles and methods of artistic design of overalls. “Young scientist”, 2015. 217

3 B.P. Kulikov., N. Sakharov., Y.A. Kostin. Hygiene, comfort and safety of clothing: “Training manual”, 2006. 256

4 V. A. Kaminsky. Calculation of diffusion fluxes and concentration distributions for threecomponent diffusion. “Journal of physical chemistry”, 2011. 2127

5 I.N. Ivashchenko., S.V. Usatikov., S.P. Shmalko. Optimization of heat-insulation of special clothing: An analysis using regression models. “Human Ecology”, 2016. 21.

6 A. Rasheed., X. Zeng., S. Thomassey. An approach to the design of a fuzzy logic model for the ease allowance calculation in loose fitting knee length ladies’ trousers. “Journal of engineered fibers and fabrics”, 2017. 126.

7 L. Hes., K. Bal., M. Boguslawska-Baczek. Why black clothes can provide better thermal comfort in hot climate than white clothes. Fiber Society Spring 2014 Technical Conference: “Fibers for progress”, 2014

8 Study on clothing insulation distribution between half-bodies and its effects on thermal comfort in cold environments. “Energy and Buildings”, 2020. 211.

9 M. Jowkar., R. Dear., J. Brusey. Influence of long-term thermal history on thermal comfort and preference. “Energy and Buildings”, 2020.

10 H. Lee., H.J. Jin. Conceptual design framework as a model for wheelchair users ‘sportswear comfort. “Fashion and textiles”, 2019.

11 C.F. Kuo., W.T. Lin. Optimum processing parameters of sue ding fabric comfort by applying the Taguchi method and fuzzy theory. “Textile research journal”, 2019. 5165

12 H.G. Atasağun., A. Okur., A. Psikuta., R.M. Rossi., S. Annaheim. The effect of garment combinations on thermal comfort of office clothing. “Textile research journal”, 2019. 4425

13 M. Guan., A. Psikuta., M. Camenzind., M.R. Rossi., S. Annaheim. Effect of perspired moisture and material properties on evaporative cooling and thermal protection of the clothed human body exposed to radiant heat. “Textile research journal”, 2019. 3663.

14 N.Kh. Mirtalipova., N.D. Abdurakhmanova., Kh.M. Yunuskhodjayeva. The use of nano materials in the design of special clothing. “International multidisciplinary research journal ISSN”, 2022. 173.

15 N.D. Abdurakhmanova., Kh.M. Yunuskhodjayeva., N.Kh. Mirtalipova. Development of a package of materials for men's uniforms of law enforcement agencies. “International Multidisciplinary Research Journal ISSN”, 2022. 80

16 R.A. Scott. Cold weather clothing for military applications. “Textiles for cold weather apparel”, 2009. 399

17 G. Ozcan., C. Candan. Properties of three-thread fleece fabrics. “textile research journal” -2005. 129

18 A.E. Fouda. Effect of backed yarn characteristics on two-thread fleece knitted fabric properties. “Indian journal of fiber textile research (IJFTR)”, 2018. 247.

Waiting

№	Author name	position	Name of organisation
1	Mirtalipova N.K.	teacher	Tashkent Institute of Textile and Light Industry
2	Isaxujayeva N.A.	teacher	Tashkent Institute of Textile and Light Industry

№	Name of reference
1	I.A. Ermakova. Hygiene of clothes. “Textbook Vladivostok”, 2006. 94.
2	N.T. Gafurova., D.I. Sailieva., J.I. Ismoilov. Principles and methods of artistic design of overalls. “Young scientist”, 2015. 217
3	B.P. Kulikov., N. Sakharov., Y.A. Kostin. Hygiene, comfort and safety of clothing: “Training manual”, 2006. 256
4	V. A. Kaminsky. Calculation of diffusion fluxes and concentration distributions for threecomponent diffusion. “Journal of physical chemistry”, 2011. 2127
5	I.N. Ivashchenko., S.V. Usatikov., S.P. Shmalko. Optimization of heat-insulation of special clothing: An analysis using regression models. “Human Ecology”, 2016. 21.
6	A. Rasheed., X. Zeng., S. Thomassey. An approach to the design of a fuzzy logic model for the ease allowance calculation in loose fitting knee length ladies’ trousers. “Journal of engineered fibers and fabrics”, 2017. 126.
7	L. Hes., K. Bal., M. Boguslawska-Baczek. Why black clothes can provide better thermal comfort in hot climate than white clothes. Fiber Society Spring 2014 Technical Conference: “Fibers for progress”, 2014
8	Study on clothing insulation distribution between half-bodies and its effects on thermal comfort in cold environments. “Energy and Buildings”, 2020. 211.
9	M. Jowkar., R. Dear., J. Brusey. Influence of long-term thermal history on thermal comfort and preference. “Energy and Buildings”, 2020.
10	H. Lee., H.J. Jin. Conceptual design framework as a model for wheelchair users ‘sportswear comfort. “Fashion and textiles”, 2019.
11	C.F. Kuo., W.T. Lin. Optimum processing parameters of sue ding fabric comfort by applying the Taguchi method and fuzzy theory. “Textile research journal”, 2019. 5165
12	H.G. Atasağun., A. Okur., A. Psikuta., R.M. Rossi., S. Annaheim. The effect of garment combinations on thermal comfort of office clothing. “Textile research journal”, 2019. 4425
13	M. Guan., A. Psikuta., M. Camenzind., M.R. Rossi., S. Annaheim. Effect of perspired moisture and material properties on evaporative cooling and thermal protection of the clothed human body exposed to radiant heat. “Textile research journal”, 2019. 3663.
14	N.Kh. Mirtalipova., N.D. Abdurakhmanova., Kh.M. Yunuskhodjayeva. The use of nano materials in the design of special clothing. “International multidisciplinary research journal ISSN”, 2022. 173.
15	N.D. Abdurakhmanova., Kh.M. Yunuskhodjayeva., N.Kh. Mirtalipova. Development of a package of materials for men's uniforms of law enforcement agencies. “International Multidisciplinary Research Journal ISSN”, 2022. 80
16	R.A. Scott. Cold weather clothing for military applications. “Textiles for cold weather apparel”, 2009. 399
17	G. Ozcan., C. Candan. Properties of three-thread fleece fabrics. “textile research journal” -2005. 129
18	A.E. Fouda. Effect of backed yarn characteristics on two-thread fleece knitted fabric properties. “Indian journal of fiber textile research (IJFTR)”, 2018. 247.