SU580487A1 - Instrument for determining thermal resistance of materials - Google Patents

Description

one

The invention relates to the field of measurement technology and is intended to determine the thermal resistance of easily deforming materials of flat formations, for example, textile materials, by the method of regular operation under the conditions that most closely simulate the operation of clothing.

A device for determining the resistance of textile materials and packages of them is known, which contains a supporting table, a hollow cylinder with clamps for a sample, inside of which is a heater that can be moved along the axis of the cylinder using an apparatus for creating an air gap between the test sample and the heater. This device allows one to determine the thermal resistance of textile materials and packages of them only in a static state, i.e., fixedly mounted on the support table of the device, which does not correspond to the actual conditions of operation of clothing.

Also known is a device for determining the heat-shielding properties of woven and non-woven materials, fur, leather and izdalyy them, i.e. the method of regular thermal conditions, a flat bicalorimeter which is equipped with a cassette with the installation mechanism and mounted vertically on the rotary table in front of the wind tunnel. Device design

allows to determine the heat-shielding properties of both cut samples, and without cutting them under conditions close to the actual conditions of service of clothes, for

an account of the use of a rotary table with a calorimeter, by means of which the angle of attack of the air flow 2 is established.

the device also allows testing it in a static condition that does not provide an accurate and objective assessment of the heat-shielding properties of clothes.

The most advanced known device is a device for determining thermal resistance of materials, such as textiles, containing a working cylinder, a sample clamp, a core with grooves to create convective air flows through the sample, and an actuator for reciprocating the core, a heater, and a temperature sensor 3. However This device does not allow to determine the thermal resistance of textile materials and packages of them with

given the dynamic effort. Dynamic forces significantly change the structural characteristics of materials, especially materials, which are easily deformed (articles made of knitted fabrics, elastic, etc.),

for example, a density negative pressure due to an increase in Marcf cells (ala when stretched, which causes an increased air duct of the latter and, consequently, a change in their heat-shielding properties.

To improve the accuracy of determining the thermal coherence by bringing the test conditions to real, the proposed device has a loaded, ayi sleeve, concentrically mounted on the working cylinder with the possibility of reciprocating mixing, and the associated mechanism for specifying loading forces, A sample clamp is mounted on a loading sleeve. In addition, the load force setting mechanism is connected to the drive and contains contacts for controlling the drive motor and a bracket with elastic shelves, one of which is rigidly connected to one of the contacts and the loading sleeve, and the other KJiHe is connected to the other contact and to the drive motor .

The drawing schematically shows the proposed device.

The device contains an operating cylinder 1, on which a loading sleeve 2 with clamps 3 for fastening the sample 4 is concentrically mounted with the possibility of reciprocating motion. The loading sleeve is connected by means of strain gauge 5 to the force setting mechanism.

The latter contains contacts 6, 7 for controlling the drive motor 8 and the clamp 9 with elastic shelves 10, 11 made, for example, in the form of springs. The knob 10 is rigidly connected to the scale 12 carrying the contact 6 and through cable 5 to the loading sleeve 2, and the shelf I is kinematically connected to contact 7 through the arrows 13 and to the drive engine 8 via the gear 14 and screw 15 mechanisms.

The motor 8 is reversible, in connection with which the chord 12 has an additional contact 16. The gap between the contacts (electric contact) 6 and 16 can be adjusted to vary the loading forces and deformations of the material.

The device also has a measuring circuit containing a reohord 17 for measuring deformations, a loading force sensor in the form of strain gauges 18, an amplifier 19, a recorder 20 and a drive 21 for reciprocating movement of the core.

The core itself with grooves for creating convective air flows through the sample, as well as the heater and temperature sensor are similar to the corresponding elements of the device and are not shown in the drawing.

The heat-shielding properties of the materials on the proposed instrument are determined as follows.

The test sample 4 is fastened on the loading sleeve 2 by clamp 3. By moving the electrical contacts 6 and 16, a given loading value is set on a scale 12 and a reversible electric motor 8 is turned. Rotation of the shaft of the latter through a gear 14 and screw 15 mechanisms is converted into reciprocating movement of the bracket 9 and , thereby loading sleeve 2 with sample 4.

The elastic shelves 10, 11 are deformed in proportion to the magnitude of the forces stretching the sample 4, which are recorded through the amplifier 19 by the recorder 20.

When the sample is stretched and the shelves 11 are deformed, the arrow 13 contacts with the appropriate electrical contact, and the engine 8 reverses. The magnitude of the deformation of the specimen, corresponding to the magnitude of the stroke of the loading sleeve 2, is recorded using a reichord 17 included in the measuring circuit of the amplifier 19 and a self-pioneer 20.

In the case of testing the sample under static load and achieving the specified deformations or stresses, the reversing motor 8 is turned off.

The proposed device allows to measure the heat-shielding properties of easily deforming materials of flat formations, such as knitted fabric, rubber, elastics, etc., as well as packages of them, taking into account their dynamic state.

Claims (3)

1. An instrument for determining the resistance of materials, such as textiles, containing a working cylinder, a clamp for the sample, a core with grooves for creating convective air flows through the sample, a drive for reciprocating movement of the core, a heater and a temperature sensor, characterized in that improving the accuracy of determining thermal resistance due to approaching the test conditions to real ones, it has a loading sleeve concentrically mounted on the working cylinder with the possibility of returning the displacement mechanism, and the associated mechanism for setting the loading forces, with the sample clamp mounted on the loading sleeve. 2. The apparatus according to claim 1, characterized in that the mechanism for setting the loading forces It is connected with the drive and contains contacts for controlling the drive motor and the bracket with elastic shelves, one of which is rigidly connected to one of the contacts and the loading sleeve, and the other is kinematically connected to the other contact and to the drive motor. Sources of information taken into account in the examination 1- USSR Copyright Certificate №217011, cl. G OIN 25/18, 1965. 2. USSR author's certificate No. 347645, cl. G 01N 25/20, 1971. 3. USSR author's certificate number 425093, cl. G 01N 25/18, 1972.