The research was focused on the heating capacity of developed, isolated from water penetration, knitted textile heating element with incorporated conductive silver (Ag)- plated yarns, which can be used in manufacturing heating textile products intended for recreation, sports, or health care for elderly. The aim of the investigation was to obtain an appropriate temperature on a human skin, generated by the textile heating element surface at a lower voltage depending on a variety of wearing conditions indoor. Depending on the supplied voltage to the heating element, an incoming electric energy can be converted into different heat. Therefore, the electrical and achieved temperature parameters of heating elements are very important by selecting and adapting required power source devices and by setting the logical parameters of programmable controllers. The heating–cooling dynamic process of developed textile heating element was investigated at different simulated wearing conditions on a standard sweating hot plate and on a human skin at applied voltages of 3V and 5V. It was discovered that a voltage of 5 V is too big for textile heating elements, because the reached steady state temperature increases to approximately 39–40°C, which is too hot for contact with the human skin. The voltage of 3 V is the most suitable to work properly and continuously, i.e., to switch on when the adjusted temperature is too low and to turn off when the necessary temperature is reached. Based on the values of reached steady-state heating temperature, the influence of the applied voltage, ambient air flow velocity, and heating efficiency, depending on various layering of clothes, was determined. Recorded temperatures on the external surface of the heating element provided the possibility to assess its heat loss outgoing into the environment. It was suggested that heat loss can be reduced by increasing thermal insulation properties of the outer layer of the heating element or using layered clothing. On the basis of the resulted heating characteristics, recommended parameters of power source necessary for wearable textile heating element were defined.
Ternopil Academy of National Economy, 2, 26-31.  Vasylkiv, N., Kochan, O., Kochan, V. Sachenko, A. (2009). Research of the temperature measurement error from the acquired thermoelectric heterogeneity of thermocouple electrodes. Measuring Equipment and Metrology, 70, 110-117.  Vasylkiv, N., Kochan, O., Kochan, V. (2009). The method of heterogeneity thermocouple error correction. Ukraine Patent no. 92192.  Kohan, O., Kohan, R. Thermocouplesensor. Ukraine Patent no. 97464.  Krose, B., van der Smagt, P. (1996). An Introduction to Neural Networks. University
velocity corresponds to 1 m/s. The measuring equipment consisting of a heating plate, the constant surface temperature of which is ensured using a simple regulation circuit with a thermocouplesensor at the value of 35 ± 1°C, is placed into the air-conditioning chamber. The tested sample, edges of which are fixed by a frame, is placed onto the heating plate. Thermal resistance R ct is determined on the basis of sensing the sample surface temperature on both fabric sides of the fabric and the quantity of heat flowing through the fabric measured by a thermal flux sensor