RU59833U1 - DEVICE FOR MEASURING THERMOPHYSICAL VALUES - Google Patents

Abstract

The utility model relates to construction equipment and can be mainly used to measure the thermal values of various building structures, for example, walls, ceilings, floors, various bulkheads, partitions, ceilings, etc. The objective of the utility model is to increase consumer properties by increasing accuracy and reliability. The solution to this problem is provided by using a storage tank in which a constant level of coolant is maintained using a drain pipe, as a result of which the mass flow rate of the coolant in the heat exchanger becomes constant, as well as using a heating tank, which ensures a constant temperature of the coolant at the inlet of the heat exchanger. Determination of the beginning of the temperature rise on the inner surface of the investigated object is carried out by a contact temperature meter. Determination of the moment the temperature rises on the external or lateral surface of the object under study is carried out by a thermal imager.

Description

The utility model relates to construction equipment and can be mainly used to measure the thermophysical values of various building structures, for example, walls, ceilings, floors, bulkheads, ceiling, etc.

A device for drilling wells [1], which allows to obtain samples of materials from various depths. By measuring the parameters of these samples, one can obtain information on the physical and chemical properties and configuration of the deep layers. A disadvantage of the known device is that it does not provide non-destructive testing of the studied object.

Numerous versions of devices for ultrasonic flaw detection are known, for example, [2, 3], which make it possible to determine the presence of inhomogeneities in various structures and the configuration of these inhomogeneities, however, devices of this kind do not allow the measurement of thermophysical quantities of the materials under study, in particular, thermal resistance.

Numerous variants of devices for measuring the thermal resistance of various electronic devices are known, for example, a device for measuring the thermal resistance of transistors described in [4]. A disadvantage of the known technical solution lies in a narrow scope: it can only be used to measure the thermal resistance of transistors.

Known is described in [5] a device for determining the characteristics of materials containing a source of pulse heating, a thermocouple

and an electronic processing unit. A thermocouple is located on the surface of the test sample. The output of the thermocouple is connected to the input of the electronic processing unit. The main disadvantage of the known device is that when using pulsed heating requires complex processing of the measurement results, which requires sophisticated equipment. This leads to a significant increase in the cost of measurements. In addition, the great complexity of processing the measurement results leads to a decrease in their accuracy and reliability.

The closest in technical essence to the claimed technical solution is a device for measuring thermal characteristics [6], comprising a heat exchanger, an inlet pipe, an outlet pipe, a contact temperature meter, a thermal imager, thermal insulation, the outer surface of the heat exchanger is provided with thermal insulation except adjacent to the inner surface of the object under study the outer surface of the heat exchanger, the output of the heat exchanger is connected to the inlet of the outlet pipe, a contact meter pace perature is placed between the inner surface of the test object and the outer surface of the heat exchanger. The moment the temperature rises at a given point on the inner surface of the object under study is carried out by a contact temperature meter. The moment of the beginning of the temperature rise on the outer surface of the investigated object or on the side surface of the studied object is carried out by a thermal imager.

The known device has low consumer properties. This is due to the need to maintain a constant value of the flow of coolant and a constant temperature of the coolant at the inlet of the heat exchanger to ensure high accuracy and high reliability of the measurements. If these parameters of the coolant are unstable in time, then the known device does not allow to achieve high

accuracy and high reliability of measurements, as a result of which consumer properties are low.

The objective of the utility model is to increase consumer properties by increasing the accuracy and reliability of measurements.

The solution of the problem in accordance with claim 1 of the utility model formula is ensured by the fact that in the known device comprising a heat exchanger, an inlet pipe, an outlet pipe, a contact temperature meter, a thermal imager, thermal insulation, the outer surface of the heat exchanger is provided with thermal insulation except adjacent to the inner surface of the investigated object of the outer surface of the heat exchanger, the output of the heat exchanger is connected to the inlet of the outlet pipe, a contact temperature meter is located between the inside the following surface improvements and the external surface of the heat exchanger made the following improvements: it additionally contains a supply tank, a heating tank, a first pipe, a second pipe, a heating tank equipped with a heating element, the output of the input pipe is connected to the input of the supply tank, the output of the supply tank is connected to the input of the first pipeline, the output of the first pipeline is connected to the inlet of the heating tank, the output of the heating tank is connected to the inlet of the second pipeline, and Exit second conduit connected to the inlet of the heat exchanger.

The use of a consumable tank in the claimed device ensures a constant time value of the heat carrier flow in the heat exchanger, and the use of a heating tank equipped with a heating element ensures a constant time temperature of the heat carrier at the inlet of the heat exchanger. Thus, the heat carrier enters the heat exchanger inlet, the flow rate and temperature of which are constant in time, as a result of which the accuracy and

reliability of measurements. This leads to an increase in consumer properties of the claimed device compared to the prototype.

In the particular case, in accordance with paragraph 2 of the formula of the utility model, the inlet pipe is equipped with a valve. This allows you to adjust the amount of coolant flow passing through the inlet pipe.

In the particular case, in accordance with paragraph 3 of the utility model formula, the first pipeline is equipped with a second valve. This allows you to adjust the amount of coolant flow passing through the first pipeline.

In the particular case, in accordance with paragraph 4 of the formula of the utility model, the supply tank is equipped with a drain pipe. If the parameters of the claimed device are selected in such a way that the amount of coolant flow in the first pipeline is less than the minimum possible amount of coolant flow in the inlet pipe, then part of the coolant leaves all the time through the drain pipe, as a result of which a constant level of coolant in the supply tank is ensured. This leads to a constant flow of heat carrier in the heat exchanger.

In a particular case, in accordance with paragraph 5 of the utility model formula, the claimed device contains a storage tank and a drain tank, the output of the storage tank is connected to the input of the inlet pipe, the output of the output pipe is connected to the first input of the drain tank, and the output of the drain pipe is connected to the second input of the drain tank . This embodiment of the design of the claimed device allows you to reuse the same coolant due to its transportation from the drain tank to the storage tank.

In the particular case, in accordance with paragraph 6 of the utility model formula, the optical axis of the thermal imager is directed to the outer surface of the subject

object. This embodiment of the inventive device provides a fixation of the start time of the temperature rise at a given point located on the outer surface of the investigated object.

In the particular case, in accordance with paragraph 7 of the utility model formula, the optical axis of the thermal imager is directed to the side surface of the object under study. This embodiment of the inventive device provides a fixation of the start time of the temperature rise at a given point located on the side surface of the investigated object.

The essence of the utility model is illustrated by a description of a specific embodiment of the claimed device and drawings, in which:

- figure 1 shows a diagram of the device corresponding to items 1-6 of the formula of the utility model;

- figure 2 shows a view in axonometric projection of the device corresponding to items 1-6 of the formula of the utility model;

- figure 3 shows a diagram of the device corresponding to items 1-5 and 7 of the formula of the utility model;

- figure 4 shows a view in axonometric projection of the device corresponding to claims 1-5 and 7 of the formula of the utility model.

A device for measuring thermophysical quantities contains a heat exchanger 1, an inlet pipe 2, an output pipe 3, a contact temperature meter 4, a thermal imager 5, thermal insulation 6, the outer surface of the heat exchanger 1 is provided with thermal insulation 6 except for the outer surface of the heat exchanger 1 adjacent to the inner surface 7 of the test object 8 , the output of the heat exchanger 1 is connected to the input of the output pipe 3, a contact temperature meter 4 is placed between the inner surface 7 of the test object 8 and the external surface heat exchanger 1. It also contains

a supply tank 9, a heating tank 10, a first pipe 11, a second pipe 12, a heating tank 10 is provided with a heating element, the output of the input pipe 2 is connected to the input of the supply tank 9, the output of the supply tank 9 is connected to the input of the first pipe 11, the output of the first pipe 11 is connected with the input of the heating tank 10, the output of the heating tank 10 is connected to the input of the second pipe 12, and the output of the second pipe 12 is connected to the input of the heat exchanger 1. The input pipe 2 is provided with a valve 13, the first pipe 11 is equipped with wives a second valve 14, and the supply tank 9 is equipped with a drain pipe 15. The device for measuring thermophysical quantities further comprises a storage tank 16 and a drain tank 17, the output of the storage tank 16 is connected to the input of the input pipe 2, the output of the output pipe 3 is connected to the first input of the drain tank 17, and the outlet of the drain pipe 15 is connected to the second inlet of the drain tank 17. The optical axis 18 of the thermal imager 5 is directed either to the outer surface 19 of the investigated object 8, or to the side surface 20 of the studied object and 8.

The direction of movement of the coolant is shown by the arrows, indicated by 21 in the drawings. As a heating element, a converter of electrical energy into thermal energy can be used. The terminals to which an external source of electrical energy is connected are indicated at 22 in the drawings.

The change in the mass flow rate of the coolant through the heat exchanger 1 is usually carried out by changing the height of the supply tank 9 above the heat exchanger 1. In this case, the storage tank 16 should be located, as a rule, above the supply tank 9, and the heating tank 10 should be located, as a rule, below the supply tank 9 and above the heat exchanger 1. The storage tank 16 may be filled from

tap water, in this case, the role of the coolant is tap water.

The coolant accumulated in the drain tank 17 can be reused by transporting it from the drain tank 17 to the storage tank 16 (this path in Fig. 1 and Fig. 3 is indicated by an arrow with an intermittent line and indicated by 23) using any pipeline equipped with a pump (compressor) or by transporting the liquid coolant from the drain tank 17 to the storage tank 16 using any containers, for example, buckets.

A device for measuring thermophysical quantities works as follows. The coolant from the storage tank 16 through the inlet pipe 2 enters the consumable tank 9, and from it through the first pipe 11 enters the heating tank 10, where it is heated by the heating element. Then, the heated coolant through the second pipe 12 enters the heat exchanger 1. The working temperature of the coolant at the inlet of the heat exchanger 1 must be higher than the maximum possible temperature of the coolant at the inlet of the heating tank 10. When the temperature of the coolant entering the inlet pipe 2 changes, the temperature at the inlet of the heat exchanger 1 is constant. the operation of the heating element. In the heat exchanger 1, the heat carrier transfers thermal energy to the test object 8 through a portion of the inner surface 7 of the test object 8 adjacent to the outer surface of the heat exchanger 1. The contact temperature meter 4 records the moment of the temperature rise in the contact area of the outer surface of the heat exchanger 1 with the inner surface 7 of the test object 8. The thermal imager 5 captures the moment the temperature rises at a given point. In accordance with paragraph 6 of the utility model formula, a given point is selected on the outer surface 19 of the investigated object 8. In accordance

from clause 7 of the utility model formula, a given point is selected on the lateral surface 20 of the investigated object 8. The calculation of the thermophysical quantities of the studied object is carried out by a known method described, for example, in [6].

INFORMATION SOURCES

1. Sukhov R.I., Lebedkin Yu.M., Kuznetsov V.G. and others. A method of drilling wells and a device for its implementation. RF patent for invention No. 2237148, prior. 1999.10.06, publ. 2001.07.20, IPC7 E 21 V 6/02, E 21 V 7/00, E 21 V 10/36.

2. Pilin B.P., Markov A.A., Molotkov S.L. The method of ultrasonic inspection and a device that implements it. RF patent for the invention No. 2131123, prior. 1996.01.12, publ. 1999.05.27, IPC6 G 01 N 29/04.

3. Bobrov V.T., Tarabrin V.F., Ordynets S.A., Kuleshov R.V. Ultrasonic flaw detector "Swallow". RF patent for invention No. 2231783, prior. 2001.08.09., Publ. 2003.07.10, IPC7 G 01 N 29/04.

4. Sergeev V.A. Device for measuring the thermal resistance of transistors. Application for a patent of the Russian Federation for invention No.2000127414 / 09, prior. 2000.10.31, publ. 2002.10.10, IPC7 G 01 R 31/26.

5. Medvedev VV, Troitsky O.YU. Device for determining the characteristics of materials. RF patent for invention No. 2212653, prior. 2002.05.28, publ. 2003.09.20, IPC7 G 01 N 25/18.

6. Abramova E.V., Epiphany A.I., Isakov P.G., Lapovok E.V., Khankov S.I. etc. A device for measuring thermophysical characteristics (options). RF patent No. 54193 for utility model, priority 12/19/2005, publ. 06/10/2006, IPC G 01 N 25/18 (2006.01).

Claims (7)

1. A device for measuring thermophysical quantities, comprising a heat exchanger, an inlet pipe, an outlet pipe, a contact temperature meter, a thermal imager, thermal insulation, the outer surface of the heat exchanger is provided with thermal insulation except for the outer surface of the heat exchanger adjacent to the inner surface of the test object, the outlet of the heat exchanger is connected to the inlet of the outlet pipe , a contact temperature meter is placed between the inner surface of the test object and the outer surface t an exchanger, characterized in that it further comprises a supply tank, a heating tank, a first pipe, a second pipe, a heating tank equipped with a heating element, the output of the input pipe is connected to the input of the supply tank, the output of the supply tank is connected to the input of the first pipe, the output of the first pipe is connected to the input of the heating tank, the output of the heating tank is connected to the input of the second pipeline, and the output of the second pipe is connected to the input of the heat exchanger. 2. A device for measuring thermophysical quantities according to claim 1, characterized in that the inlet pipe is equipped with a valve. 3. A device for measuring thermophysical quantities according to claim 1, characterized in that the first pipeline is equipped with a second valve. 4. A device for measuring thermophysical quantities according to claim 1, characterized in that the supply tank is equipped with a drain pipe. 5. The device for measuring thermophysical quantities according to claim 1, characterized in that it further comprises a storage tank and a drain tank, the output of the storage tank is connected to the input of the input pipe, the output of the output pipe is connected to the first input of the drain tank, and the output of the drain pipe is connected to the second inlet of the drain tank. 6. A device for measuring thermophysical quantities according to claim 1, characterized in that the optical axis of the thermal imager is directed to the outer surface of the object under study. 7. A device for measuring thermophysical quantities according to claim 1, characterized in that the optical axis of the thermal imager is directed to the side surface of the object under study.