SU1518752A1 - Apparatus for thermophysical measurements - Google Patents

Abstract

The invention relates to the field of thermal testing, namely, devices for measuring the thermophysical properties of substances. The purpose of the invention is to simplify the device and extend the temperature range of the test. The device includes a Dewar vessel filled with a refrigerant, a housing placed inside the Dewar vessel, a measuring cell and a heat pipe. The heat pipe is made in the form of an articulated high-heat-conducting glass and a cylindrical element of low heat-conducting material, which extends the wall of the glass. The free end of the cylindrical element is fixed on the lid of the body and is open for connection with the internal volume of the Dewar vessel. The measuring cell is attached to the bottom of the glass. Inside the cylindrical element is placed a piston with the possibility of longitudinal movement. The depth of the glass exceeds the thickness of the piston. Changing the position of the piston changes the thermal resistance between the measuring cell and the refrigerant. When the piston is lowered to the bottom of the glass, the refrigerant is in direct contact with the highly heat-conducting glass. The wide range of variation of thermal resistance provides an extension of the temperature range of the test at a fixed refrigerant temperature. A simplification of the device is also achieved by reducing the number of elements carrying out the thermal coupling of the measuring cell and the refrigerant.

Description

one

(21) 4384759 / 31-25

(22) 02.29.88

(46) 10/30/89. Bup. No. 40

(71) Kharkiv State University named after AM Gorky

(72) B.A. Merisov, A.A. Zavgorodniy, O.A. Gavrenko and G.M. Zlobintsev

(53) 536.2 (088.8)

(56) Eine Apparatur for cliessungen von War mekepazitaten zwischen, 2 und 30 K - Expic mentelle Technik der Physik, 1977, No. 4, pp.300-304.

USSR Author's Certificate No. f092395, cl. G 01 N 25/18, 1983.

(54) DEVICE FOR TESHEUPHYSICAL MEASUREMENTS

(57) The invention relates to the field of thermal testing, namely, devices for measuring the thermal properties of substances. The purpose of the invention is to simplify the device and extend the temperature range of the test. The device includes a Dewar vessel, a refrigerant filled with a housing placed inside the Dewar vessel, a measuring cell and a heat pipe. The heat pipe is made in the form of articulated high-heat-conducting glass and a cylindrical element of low heat-conducting material, which extends the wall of the glass. The free end of the cylindrical element is fixed on the lid of the body and is open for connection with the internal volume of the Dewar vessel. The measuring cell is attached to the bottom of the glass. Inside the cylindrical element is placed a piston with the possibility of longitudinal movement. The depth of the glass exceeds the thickness of the piston. Changing the position of the piston changes the thermal resistance between the measuring cell and the refrigerant. When the piston is lowered to the bottom of the glass, the refrigerant is in direct contact with the highly heat-conducting glass. The wide range of variation of thermal resistance provides an extension of the temperature range of the test at a fixed refrigerant temperature. A simplification of the device is also achieved by reducing the number of elements carrying out the thermal coupling of the measuring cell and the refrigerant.

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The invention relates to thermal tests, namely, devices for measuring the thermophysical properties of substances.

The purpose of the invention is to simplify the device and extend the temperature range of the test.

The drawing shows a diagram of the proposed device.

The device contains a heat pipe consisting of a cup 1 made of a material with high thermal conductivity, such as copper and a tubular element 2 connected to the glass, made of a material with low thermal conductivity, such as stainless steel, a piston 3 installed in the tubular element 2

longitudinal movement by means of a pull, vacuum housing 4, in which the heat conductor and the cell meter are mounted, the cell includes sample 5, furnaces 6 and 7, thermometers 8, as well as protective shields 1-1, not shown). All the device is clearly in the 9 Dewar vessel. The upper part of the Dewar vessel, containing devices for pouring gels and pumping its vapors, withdrawal, measuring procedures and other things in the drawing, is not even. Piston 3 can be made of material with any coefficient of thermal conductivity: copper, stainless steel, fluoroplastic, etc. The diameter of the piston must ensure free grinding of the pipe in element 2 pipe. Depth of the glass; 1 °; 1 exceed the piston 3. The inner cavity of the tubular element 2 on the sides of its free end is connected to the cavity of the Dewar vessel 9 which is a coolant tank. The pipe element must be firmly gripped in the bore of glass 1 with tightness. The vacuum in the housing 4 is provided by vacuuming (not shown) through the tube 10. The device works next to it;

The Dewar vessel 9 is filled with a cryogenic liquid so that its level is above the upper level of the tubular element 2. The piston 3 is in the tubular element 2. In the lower position of the piston 3, i.e. when it is in the recess of the cup 1, the refrigerant fills the entire volume 1 of the spiked element 2 above the piston 3. In this case, the refrigerant contacts the material of the cup 1 protruding above the piston 3 and cools it to its own temperature i.e. to, 2 K in case of gels. The temperature of the liquid (e 4.2 K (up to 1.5 K) is achieved by pumping out vapors of the helium above the surface of the liquid. To carry out measurements in the prescribed temperature range, the piston 3 is moved by means of a pull along a tubular element, fixing it in the given positions. due to the gap between the piston 3 and the element 2, a small amount of refrigerant penetrates into the space between the piston and the cylindrical element;

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fills up the volume formed during the lift and prevents the coolant from entering there. The gas pressure in the volume is equal to the pressure of the refrigerant column above the plug.

Moving the piston 3 through the tubular element 2 sets the heat resistance value between the refrigerant and the glass 1, which is realized by the material of the walls of the tubular element. By changing the heat resistance, the temperature of the cold end of sample 5, which is in direct contact with glass 1, is changed. A finer adjustment of the temperature of the sample is carried out by means of an electronic thermostat, of which furnace 6 is an element.

Example. The inner diameter of the tubular element 2, made of stainless steel, is 20 mm, the length is 60 mm. The piston 3 is made of fluoroplast 5 mm thick. Depth of a glass is 8 mm. 2.5 liters of liquid helium is poured into the Dewar 9 for measurements. The measurement process does not differ from the measurements on the device prototype.

Compared with the known device, the structure is significantly simplified by eliminating a long and complex heat conductor and a cap in the form of a Dewar vessel, and the reliability of the device is also improved by eliminating the heat conductor assembly (hood), and its weight and dimensions are reduced. Due to the wider range of variation of the thermal resistance of the heat conductor, the temperature range of the tests is extended.

With the same measuring cell and refrigerant volume, the temperature range of measurements in the proposed device using only liquid gels is expanded to 1.5-150 K compared to 1.5-80 K for a known device.

Claims (2)

1. A device for thermophysical measurements containing a heat pipe. a bonding test object with a coolant tank, made in the form of a cup of highly heat-conducting material and a tubular element connected to it, made of a material with low thermal conductivity, conjugated with the side wall of the cup, characterized by in order to simplify the thickness of the piston, and expanding the temperature range of the test, a piston is placed in the tubular element with the possibility of its longitudinal movement. 2. The device according to claim 1, characterized in that the depth of the inner cavity of the glass exceeds