SU1599739A1 - Apparatus for determining heat-moisture protective properties of footwear - Google Patents

Abstract

The invention relates to experimental thermal physics and can be used in light industry to determine the thermophysical properties of footwear. The purpose of the invention is to increase the reliability of the determination of the desired characteristics by approximating the experimental conditions to the natural conditions of shoe use. The device contains a camera in which the sample of the shoe is located on a stand. The support is made in the form of a measuring unit containing a capillary-porous soil simulator with a thermo-regulating device. The surface of the simulator with a sample of the shoe is enclosed in a casing with a duct placed on its surface, which is hydraulically connected with the internal cavity of the casing. The heat carrier in the form of metal shot and a fixed source of heating, made in the form of a set of pipes connected to each other by means of flexible elements made of heat-conducting material, are placed in the internal cavity of the shoe sample. Each nozzle is equipped with an independent heating element, a means for changing its flow area, and humidity and temperature sensors located inside the nozzles. 1 il.

Description

The invention relates to experimental thermophysics and can be used in light industry to determine the thermophysical characteristics of footwear as indicators of its heat and moisture protection properties. .

The purpose of the invention is to increase the reliability of the determination of the desired characteristics by approximating the conditions

experiment to the natural conditions of shoe use.

FIG. 1 shows the proposed device, the cross section; in fig. 2 - fixed heat source installed in the internal cavity of the sample.

The device contains a chamber 1, at the base of which a measuring unit 2 is located, containing a capillary-and-ary simulator 3 of the soil (reference material). In the lower part of the unit 2, a thermopile A is installed with a sensor 5 at the surface temperature and a Water heat exchanger 6, the Thermocouple 4 is connected to the software device 7, and the heat exchanger 6 is connected with a cooling unit 8. The near-surface layer of the capillary Porous Simulator 3 is equipped with a diffusion-permeable heat massometer 9, and on the surface of simulator 3 a sample of 10 shoes is installed, which is fixed to this surface by means of manipulators 11. At the same time, the surface of Measuring unit 2 Cover in the form of a cap 12, On the side surface of the cap 12 is screwed perforated inside: The cap tube 13 connected to the automatic system 14 to maintain the specified thermal and moisture parameters of the binary mixture in chamber 1 and under the cap 12. In addition, in the upper part of the cap 12 installed locking valve 15.

The heat and moisture parameters in the process of the experiment vary with the Yostia of radiant heaters 16, fan 17 and are monitored by temperature sensors 18 and humidity 19 connected to the secondary device 20 In the cavity of sample 10 of the shoe, the source 21 is heated and filled in the form of an air duct with a perforation: on the lateral surface and with a Pristinianist equipped with clamps-22. A warm-up source 21 is connected with a binary mixture preparation unit 23, as well as with a switching unit 24 of a heating source 21 and secondary measuring equipment. On the inner surface of the shoe sample, overhead sensors 25 of temperature and humidity are installed, equipped with a safe perforated screen 26, the cavity of the shoe sample 10 is filled with heat carrier ™ 27 in the form of lead shot. The overhead temperature and humidity sensors 25 are connected to a combined recording device 28 and a digital-to-print device 29,

The fixed heating source 21 contains (FIG. 2) a perforated tube made in the form of separate nozzles 30 connected to each other.

by means of elastic elements 31 of heat-conducting material (corrugation of metal foil). In addition, each of the perforated pipes is provided with a heating element 32 with a temperature sensor 33 installed in a highly thermally conductive perforated screen 34. A means 35 is installed in each pipe to change its cross section, made in the form of a slider gate, allowing the binary mixture in the sample cavity to vary shoes, as well as humidity sensors 36 and temperature 37.

The device works in the following way.

On the inner surface of the material of the sample 10 footwear, in place and zones (sole, foot), overhead temperature and humidity sensors 25 are installed, equipped with a perforated screen 26. A sectional source of heating 21 is introduced into the cavity of the sample 10 footwear and fixed in axial position clamps 22. Then the free volume of the sample cavity 10 is filled with coolant 27 in the form of lead shot.

Using the manipulators 11, the shoe sample 10 is placed in a predetermined position under the cap 12, while the valve 15 is in the closed position. At the base of the chamber 1 hermetically sealed. The measuring unit 2 is tanned, its measuring means are connected to the secondary equipment (not shown in Fig. 1). The software device 7 is turned on and the temperature change program on the thermal surface of the iso-, thermal surface 4 is dialed in accordance with the work plan. A water heat exchanger 6 is connected to the refrigeration unit 8. Thereafter, the temperature of the thermocouple 4 is monitored by sensor 5. According to the indications of the diffusion permeable heat mass meter 9, the specified mech values of heat and mass transfer coefficients from the surface of the capillaries of the L-porous simulator 3 are determined. At the same time, information on the characteristics of external heat and mass transfer from the surface of the measuring unit 2 in the chamber 1 and under the cap 12 are created and maintained by the automatic system 14

15

20

25

These thermal and moisture parameters of the binary mixture. The valve 15 in this case is shifted to the open position. The control over the parameters of the binary budget coming under the cap through the perforations in the tube 13 is carried out using temperature sensors 18 and

19 connected to the secondary device 20.

At the same time air washes the surface of the sample shoe and measuring

Kppts. using the fan 17, and the temperature is changed due to the radiant heaters 16. Then the heating source 21 is connected to the power source through the switching unit 24 and connected to the binary mixture preparation unit 23.

In accordance with the size and shape of the shoe sample pad, the required number of perforated nipples 30 is drawn using elastic elements 31. The heating elements 32 nipples 30 are connected to the switching unit 24, and the humidity and temperature sensors are connected to the combined recording device 28. Then, according to the experimental plan fixes the position of the means 35 for changing the flow area of the pipes 30. Using a flexible air duct, connect the channel of the sectional source of the fixed heating with

block 23 preparation of the binary mixture.

After that, the sectional source 21 of fixed heating is installed in the cavity of the sample of the shoe being investigated and includes secondary measuring equipment, differentiated heating and moistening of the heat transfer fluid and the binary mixture in the cavity of the shoe sample.

In accordance with the experiment plan, at the first stage of the work, experiments were carried out to determine the heat and moisture protection properties of the footwear when the sample 10 of the shoe was above the measuring unit 2. At the second stage, the experiments were carried out when the sample 10 was installed directly on the surface of the block 2

In the first and second stages, the temperature of the surface of the sectional heater, and accordingly the heat carrier 27, monotonously increases from 55 initial average integrated temperature to a given temperature (for example, j 15 37.0-Or). Simultaneously., With heating medium coolant 27 in

50

30 35

40 45

five

cavity sample 10 shoes using. The preparation unit 23 arrives in a certain amount of a binary mixture with a given temperature of 1-ura and relative humidity.

By varying these parameters, it is possible to simulate certain heat and humidity conditions on the inner surface of the sample in its various zones. They are monitored using temperature and humidity sensors 25 provided with perforated screens. The mean temperature of the coolant 27 at a fixed time instant is equal.

t under + t b + t x

t

 -sr

where t

under 6

t "the temperature of the sole, the top and around the heel.

In addition, the values of the dense :: heat flux temperature t p- from the surface of the measuring unit, as well as the air flow temperature and relative humidity of the air are recorded by sensors 18 and 19 and the heat mass meter 9.

The criterion for assessing the joint heat and moisture transfer across the surface of the sample of the shoe is the total thermal resistance and moisture conductivity. The statement of the experiment and the processing of measurement results are carried out by mathematical methods of planning a multifactor experiment.

The use of the proposed device for determining the heat and moisture protection properties of shoes and a sectional source of fixed heating allows, compared with the existing ones, to significantly increase the reliability of the results of measurements of heat and moisture properties of shoes by approximating the experiment that is important in the subsequent assessment of the hygienic developed models of samples of shoes.

Claims (1)

Invention Formula A device for determining the heat and moisture protection properties of a shoe, comprising a chamber with a test sample filled with coolant located on the stand, a source of fixed heating in the form of an electric heating element placed in the internal cavity of the sample, as well as means for measuring the temperature of the coolant and the environment, which is different the fact that, in order to increase the reliability of the determination of the desired characteristics by approximating the experiment to the natural conditions of exploitation footwear, the stand is made in the measuring unit, containing a capillary-porous hf simulator with a thermal and moisture regulating device () m, the surface of the simulator with a sample of the shoe is encased with a duct hydraulically connected to BHyt on its surface - a housing cavity, and a source of fixed heating is performed in the form of a set of perforated patrols, interconnected by means of elastic elements made of heat conductive material, with each nozzle provided with a separate heater ny element, a means for {changing its flow area and temperature and humidity sensors located inside the nozzles. Rf