RU85659U1 - INSTALLATION FOR DETERMINING THE HEAT CONDUCTIVITY OF GLASS CONTAINERS - Google Patents

Abstract

Installation for determining the thermal conductivity of glass containers, containing a thermocouple connected to the registration unit, a thermostat with a trellised shelf on which the test sample is located, characterized in that the installation is additionally equipped with a rubber suction cup and a telescopic lock, which are fixed inside the test sample, with a telescopic lock at one end connected to the rubber suction cup, and the other end in contact with the wall of the test sample to hold the rubber suction cup, lubricated With vacuum oil, thermocouples of the thermocouple are fixed in a rubber suction cup, electrically connected between each other and in contact with one end with the inner wall of the test sample, covered with a lid on top, and a heat insulator is installed on the base of the rubber suction cup and on the cover of the test sample to maintain a constant temperature inside the test sample.

Description

The proposed utility model relates to the field of thermal tests, namely to the field of measurements of solid samples made from various types of glass, for example, special household glass, crystal glass, sodium-calcium silicate glass, low-lead crystal, lead crystal, barium crystal used in household and catering for cooking, drinks and table setting.

There are a huge number of devices for determining the thermal conductivity of solid materials using various measurement methods.

To measure the thermal conductivity of solid materials, a device is known that contains cylindrical thermoelectrodes inside which an electrically isolated linear heat source is placed connected to a power source (see author's certificate No. 1221567, IPC G01N 25/18, Bull. No. 12.1986) .

However, this device is mainly used to determine the thermal conductivity of bulk building materials and is not intended for the study of containers made of glass.

A device for measuring thermal conductivity is known, which measures the temperature difference in a flat sample by means of temperature meters in contact with the surfaces (see ed. Certificate No. 1561025, IPC G01N 25/18, Bull. No. 16, 1990).

However, this device is not used to determine the coefficient of thermal conductivity of materials used in the manufacture of containers made of glass, which is intended for food, medicine, drinks and other products.

The IT-1 installation for determining the thermal conductivity of solid materials is also known, consisting of two thermostatically controlled upper and lower metal plates measuring 250 * 250 mm, a heat flow meter (heat meter) located between the sample and the lower thermostated plate of the set and temperature control unit, clamp unit sample and heat-insulating casing The sample is placed on the heat meter and tightly pressed with a thermostated plate. Depending on the set test temperature, the temperature of the upper and lower thermostatically controlled plates is set. The heat-insulating casing ensures the elimination of heat loss through the end faces of the sample (see the passport to the installation for testing samples of building materials for thermal conductivity IT-1, MB and SSORF, VSTI, 1989).

The disadvantage of the IT-1 installation is that this device is mainly used to study building materials with a flat surface and cannot be used to determine the thermal conductivity of solid containers made of various types of glass and having different surfaces.

The closest technical solution to the utility model is an installation for determining the thermal conductivity of a container, containing a means for determining the thermal conductivity connected to the registration unit, a test sample, a power supply, and a thermostat. The installation is additionally equipped with a refrigerator with a lid mounted on the lattice shelf of the thermostat, and a thermoconverter made in the form of a flat plate electrically connected to the power supply was used as a means for measuring thermal conductivity, on one side the thermoconverter is fixed to the refrigerator, in which a constant temperature of about 0 ° C, the other side of the thermal converter is placed on the inner surface of the test sample placed on the lattice shelf of the thermostat, when changing the temperature at which measurements were taken, continuously recorded on a chart tape of the recording device of the registration unit, and a load was installed on the lid of the refrigerator (see utility model patent No. 75748, IPC G01N 25/18, Bull. No. 23, published on 08.20.2008 .).

However, this device is used only to determine the coefficient of thermal conductivity of containers and is not used to study containers made of various types of glass, since the installation for determining the thermal conductivity of containers uses such samples so that the inner surface is flat.

The technical task of the proposed utility model is to create a device that allows to study the thermal conductivity of containers made of various types of glass used for storing food, medicine, drinks and other products, to conduct research experiments and laboratory work on thermophysical measurements with the possibility of automatic recording of results and apply the data for research purposes.

The technical result of the utility model is relatively fast and accurate in obtaining data on the thermal conductivity of glass containers made of various types of glass, for example, special household glass, crystal glass, sodium-calcium silicate glass, low-lead crystal, lead crystal, barium crystal used in household and catering for cooking, drinks and table setting.

The specified technical result is achieved by the fact that in the installation for determining the thermal conductivity of glass containers containing a thermocouple connected to the registration unit, the thermostat with a trellised shelf on which the test sample is located, according to a utility model, the installation is additionally equipped with a rubber suction cup and a telescopic lock, which are fixed inside the test sample, and the telescopic lock at one end is connected to the rubber suction cup, and the other end is in contact with the wall of the test a thermocouple thermocouple, electrically connected to each other and in contact with one end with the inner wall of the test sample, covered with a lid on top, is fixed to the rubber suction cup, lubricated with vacuum oil, with a heat insulator for maintaining a constant temperature inside the test sample.

New elements in the installation for determining the thermal conductivity of glass containers made from various types of glass are:

- installation of a thermocouple inside the test sample, consisting of two thermocouples electrically connected among themselves, which are at one end in contact with the inner wall of the test sample, provides a measure of the heat flux passing through the wall thickness of the test sample of glass containers made of various types of glass, while being measured data is recorded automatically;

- the installation inside the test sample of a rubber suction cup, lubricated with vacuum oil, into which the thermocouples of the thermocouple are electrically connected, ensures the contact of the thermocouples with the wall of the test sample, eliminates the probability of errors and gives the most accurate measurement of thermal conductivity;

- the installation inside the test sample of a telescopic lock, which is connected to the rubber suction cup at one end and contacts the wall of the test sample with the other, ensures that the rubber suction cup adheres and makes the rubber suction cup sealed against the wall of the test specimen;

- the installation of a rubber suction cup on the base and on the cover of the test sample of the heat insulator provides control to maintain a constant temperature inside the test sample.

The essence of the proposed utility model is illustrated by drawings, where Fig. 1 shows a schematic diagram of an apparatus for determining the thermal conductivity of glass containers, Fig. 2 shows the result of measuring thermal conductivity in the form of a diagram.

The proposed installation for determining the thermal conductivity of glass containers (see figure 1) consists of a thermal converter 1 and a registration unit 2, which can be used TM 902 C, having a measurement error of not more than ± 0.5.

The thermocouple 1 is electrically connected to the registration unit 2 and consists of two electrically connected thermocouples 3. Thermocouples 3 are mounted in a rubber suction cup 4, which is lubricated with vacuum oil, and are located so that the ends of two thermocouples 3 are in contact with the inner wall of the test sample 5. Rubber suction cup 4 and the thermocouples 3 of the thermocouple 1 fixed in it are placed in the test sample 5, and the test sample 5 is placed on the trellis shelf 6 of the working chamber of the thermostat 7, which maintains the required temperature automatically eski and allows you to ensure that the heat flux flows uniformly over the entire area of the test sample 5. The rubber suction cup 4 installed inside the test sample 5 is held with a telescopic lock 8, the latter is also installed inside the test sample 5 and fixed so that it connects to the rubber at one end suction cup 4, and the other end is in contact with the inner wall of the test sample 5. On the basis of the rubber suction cup 4 and on the cover 9 of the test sample 5, a heat insulator 10 is tightly installed, which allows you to ensure a constant temperature inside the test sample 5. On the thermostat 7 is the front panel of the control panel 11. On the front panel of the control panel 11 there is a toggle switch 12, which sets the desired temperature in the working chamber of the thermostat 7, controlling it according to the readings of digital indicator 13. Also on the front The panel of the control panel 11 has an LED 14 that lights up continuously when the thermostat 7 enters the heating mode.

The proposed installation for determining the thermal conductivity of glass containers works as follows.

On the front panel of the control panel 11 of the thermostat 7, turn on the toggle switch 12 for turning on the network, then press the “MODE” button and set the required temperature in the working chamber of the thermostat 7, controlling it according to the readings of the digital indicator 13. After setting the necessary thermostat temperature, which must be remembered, press on the “RECORD” buttons, then “STOP”, and then press the “START” button. The thermostat 7 goes into heating mode and while maintaining the set temperature, the LED 14 of the control panel 11 is constantly on. On the lattice shelf 6 of thermostat 7, a prepared test sample 5 of a container made of glass is placed, inside which a rubber suction cup 4 is fixed, lubricated with vacuum oil, supported by a telescopic lock 8. The telescopic lock 8 is installed inside the test sample 5 and fixed so that one end it connects to the rubber suction cup 4, and the other end is in contact with the inner wall of the test sample 5 of the glass container. A thermocouple 1 is fixed in the rubber suction cup 4, consisting of two electrically coupled thermocouples 3. Thermocouples 3 are in contact with the inner wall of the test sample 5. The test sample 5 is closed by a cover 9. A heat insulator 10 is tightly mounted on the cover 9 and on the base of the rubber suction cup 4, which allows supporting constant temperature. The heat flux in the working chamber of the thermostat 7 passes through the entire thickness of the test sample 5, and the thermocouple 1 captures the thermoelectromotive force (TEMF), the value of which depends on the internal temperature in the working chamber of the thermostat 7. The recording unit 2 records the data of the study of the test sample 5 from glass containers .

According to the calculated, well-known formula, the values of the thermal conductivity of the test sample 5 are derived from glass containers.

Studies are carried out using test samples of 5 different thicknesses from various types of glass.

Figure 2 shows a diagram of the result of an experiment obtained on the proposed utility model for a single sample of a glass jar with a capacity of 1 l, which indicates that the inventive installation provides satisfactory data on the thermal conductivity of the studied samples made of various types of glass.

The proposed installation for determining the thermal conductivity of glass containers in comparison with the prototype (see patent for utility model No. 75748, IPC G01N 25/18, Bull. No. 23, publ. 08/20/2008) can be used in practice in the field of thermophysical measurements for research thermal conductivity of various types of glass, of different thicknesses and surfaces, has increased accuracy in obtaining data on the thermal conductivity of glass containers and can be used to study the thermal conductivity of unexplored materials.

The utility model can be used in conducting research experiments and laboratory work on thermophysical measurements of the thermal conductivity of solid, various thicknesses and surfaces of glass samples, glass products and apply the obtained data for research purposes.

Claims (1)

Installation for determining the thermal conductivity of glass containers, containing a thermocouple connected to the registration unit, a thermostat with a trellised shelf on which the test sample is located, characterized in that the installation is additionally equipped with a rubber suction cup and a telescopic lock, which are fixed inside the test sample, with a telescopic lock at one end connected to the rubber suction cup, and the other end is in contact with the wall of the test sample to hold the rubber suction cup, lubricated With vacuum oil, thermocouples of the thermocouple are fixed in a rubber suction cup, electrically connected between each other and in contact with one end with the inner wall of the test sample, covered with a lid on top, and a heat insulator is installed on the base of the rubber suction cup and on the cover of the test sample to maintain a constant temperature inside the test sample.