RU2568983C1 - Method to determine coefficient of heat conductivity of liquid heat insulation in laboratory conditions - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: determination, using a meter, of heat conductivity of equivalent coefficient of heat conductivity of a flat three-layer sample of square cross section, consisting of two identical heat-conductive reference standards of available thickness with available coefficient of heat conductivity of material and layer of fluid heat insulation of available thickness arranged between reference standards. Using available values of heat conductivity coefficients of the flat three-layer sample and heat conductive reference standards, thicknesses of separate layers of the flat three-layer sample (reference standards and liquid heat insulation) they calculate using a special calculation formula the coefficient of heat conductivity of liquid heat insulation.

EFFECT: increased accuracy of determination of liquid heat insulation heat conductivity coefficient under laboratory conditions.

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Description

The invention relates to stationary methods for determining the coefficient of thermal conductivity of liquid heat-insulating materials. The developed method can be used in construction and power engineering to study in laboratory conditions the heat-conducting qualities of ultrathin liquid heat-insulating coatings.

A known method for determining the coefficient of thermal conductivity of liquid substances by the method of coaxial cylinders. A cylindrical gap formed by two coaxially arranged cylinders is filled with the investigated liquid substance. The layer of liquid substance is limited by an inner cylinder with a known outer diameter and length and an outer cylinder with a known inner diameter. A main heater with a known heat output is placed in the inner cylinder. To exclude end heat losses from the inner cylinder, safety cylinders with security heaters are provided in the device system. The working temperature difference of the surfaces of the cylinders adjacent to the liquid substance is measured by thermocouples. The thermal conductivity coefficient of the investigated liquid substance is determined by the heat equation for a single-layer cylindrical wall under stationary thermal conditions [1].

The disadvantages of this method include the technical complexity of the installation for implementing the method, which includes two cylinders between which the test liquid is located, guard cylinders designed to eliminate end heat loss from the inner cylinder, and thermocouples mounted on the outer surface of the inner cylinder and inner surface outer cylinder.

A known method for determining the coefficient of thermal conductivity of thin-walled heat-resistant coatings, carried out in two stages. At the first stage, with the help of a constant temperature heater, the entire external surface of the sample is heated uniformly over a distance without a heat-shielding coating, while cooling the reverse side of the sample with an air flow moving in a heat-insulated ventilation duct. In the second stage, a heat-shielding coating is applied to the external surface of the sample, repeatedly conducting the same tests. According to the results of non-contact thermographs measuring the temperature fields of the sample surfaces before and after applying a heat-shielding coating to one of its sides, as well as the temperature of the cooling air, the thermal conductivity coefficient of the heat-shielding coating is calculated using special calculation formulas [2].

The disadvantages of this method include the duration of the experiment (in two stages) and a rather complicated calculation procedure (determination of the heat transfer coefficient by the results of the first stage of the measurements according to the heat balance equation, finding of the temperature at the interface between the sample and the heat-shielding coating according to the results of the second stage, the final calculation local and average values of the coefficient of thermal conductivity of the heat-shielding coating).

Closest to the claimed invention is a method for determining the thermal conductivity of ultrathin liquid thermal insulation coatings, carried out in two stages. At the first stage, the lower surface of a plane-parallel wall, consisting of two layers of the same thickness and with an equal coefficient of thermal conductivity of the material, is heated using a thermally controlled heat source and the temperature of the outer surface of the upper layer is measured. At the second stage, on the outer surface of the plane-parallel wall, a metal plate of known thickness and thermal conductivity coefficient is fixed with an ultra-thin liquid heat-insulating coating applied to its outer surface and the same tests are repeated, measuring the contact surface temperature of the upper layer of the plane-parallel wall and a metal plate with an ultra-thin liquid heat-insulating coating . Using the special calculation formula, the thermal conductivity coefficient of the liquid heat-insulating coating is calculated [3].

The disadvantages of this method include the duration of the experiment (in two stages), the use of a large number of elements (a thermally controlled heat source, two layers of a plane-parallel wall, a metal plate and an ultrathin liquid thermal insulation coating) and contact temperature meters that distort the temperature field of a stationary thermal process. The initial equations for deriving the final calculation formula to some extent do not correspond to the classical laws of heat transfer.

The aim of the invention is to simplify the method and improve the accuracy of determining the coefficient of thermal conductivity of liquid thermal insulation in laboratory conditions.

This goal is achieved in that a heat conductivity meter determines the equivalent heat conductivity coefficient of a flat three-layer sample of square cross section, consisting of two identical heat-conducting standards of known thickness with a known coefficient of thermal conductivity of the material and a layer of liquid thermal insulation of known thickness located between the standards. Using the known values of the thermal conductivity coefficients of a flat three-layer sample and heat-conducting standards, the thicknesses of individual layers of a flat three-layer sample (standards and liquid thermal insulation), the thermal conductivity coefficient of liquid thermal insulation is calculated using a special calculation formula.

In FIG. 1 shows a schematic diagram of the implementation of a method for determining the coefficient of thermal conductivity of liquid thermal insulation.

A flat three-layer sample of square section, consisting of two identical heat-conducting standards 1 of thickness δ, each of them with a coefficient of thermal conductivity of the material λ, and a layer of liquid thermal insulation 2 of thickness δ _of , located between the standards 1, is located in the measuring cell of the thermal conductivity meter 3. Width and the heights of the individual layers of a flat three-layer sample are equal to each other and correspond to the sizes of a heater 4 and a refrigerator 5 of a heat conductivity meter 3. Adjacent surfaces of adjacent layers of a flat three-layer This sample fits snugly together. The front surfaces of the three-layer sample are adjacent to the front surfaces of the heater 4 and the refrigerator 5 of the thermal conductivity meter 3.

A device for implementing the proposed method works as follows (Fig. 1).

The meter of thermal conductivity 3 using a heater 4 and a refrigerator 5 creates a stationary heat flux passing through a flat three-layer sample. In terms of the heat flux density, the temperature of the opposite faces of a flat three-layer sample and its thickness, which is equal to the sum of the thicknesses of two heat-conducting standards 1 and a layer of liquid thermal insulation 2, i.e. 2δ + δ _of , the thermal conductivity meter 3 calculates the equivalent thermal conductivity coefficient of a flat three-layer sample λ _equiv .

The thermal conductivity coefficient of liquid thermal insulation λ _{of is} calculated by a special calculation formula:

,

,

where λ _EQ is the equivalent coefficient of thermal conductivity of a flat three-layer sample, determined by a thermal conductivity meter 3;

λ is the coefficient of thermal conductivity of the material of the heat-conducting standards 1;

δ is the thickness of one standard 1;

δ _of - the thickness of the layer of liquid thermal insulation 2.

The advantage of the proposed method is the conduct of thermophysical measurements in laboratory conditions in one step using a flat three-layer sample of square section. High accuracy of the results is achieved through the use of a specialized meter of thermal conductivity and the use of the only special calculation formula derived from the classical heat equation for a flat three-layer wall under stationary thermal conditions.

An example of a specific implementation of the method.

Let us determine the thermal conductivity coefficient of liquid thermal insulation in laboratory conditions using the example of Teplomett Standard paint with a thickness of δ _of = 2 · 10 ^-3 m located between two heat-conducting standards with a thickness of δ = 6 · 10 ^-3 m of each made of stainless steel with a coefficient thermal conductivity of the material λ = 50.2 W / (m · K). The width and height of a flat three-layer sample are 0.15 × 0.15 m.

According to the results of laboratory measurements with the ITS-1 "150" thermal conductivity meter, the equivalent thermal conductivity coefficient of a flat three-layer sample was λ _equiv = 0.0351 W / (m · K). Then the thermal conductivity coefficient of liquid thermal insulation Teplomett Standard according to a special calculation formula will be equal to:

.

.

The relative error of the entire measuring system is ± 5%.

The value of the thermal conductivity coefficient of Teplomett heat-insulating paint The standard obtained in laboratory conditions is comparable with the manufacturer's thermal conductivity coefficient of the material, equal to λ _of = 0.003 W / (m · K).

Bibliography

1. Heat power engineering and heat engineering. Theoretical foundations of heat engineering. Thermotechnical experiment: reference book / Under the general. ed. A.V. Klimenko and V.M. Zorina. - M.: Publishing House MPEI, 2007. - 421 p.

2. Pat. 2426106 Russian Federation, IPC G01N 25/18. A method for determining the coefficient of thermal conductivity of thin-walled heat-protective coatings and a device for its implementation / V.F. Yanishevsky, V.F. Krastyn, V.A. Kalutsky; Applicant and patent holder of FSUE Flight Research Institute named after MM Gromov. - No. 2009149671/28; declared 12/31/2009; publ. 08/10/2011. BI No. 22, 2011.

3. Pat. 2478936 Russian Federation, IPC G01N 25/18, G01N 25/20. The method for determining the coefficient of thermal conductivity of ultrathin liquid thermal insulation coatings / Yu.I. Pravnik, R.A. Sadykov, R.V. Ivanova, I.O. Maneshev, D.V. Krainov, E.V. Adaev; applicants and patent holders of Kazan State University of Architecture and Civil Engineering, R.A. Sadykov. - 2011145173/04; declared 11/07/2011; publ. 04/10/2013. BI No. 7, 2013.

Claims (1)

A method for determining the coefficient of thermal conductivity of liquid thermal insulation in laboratory conditions, including the use of a heater, two identical heat-conducting standards of known thickness with a known coefficient of thermal conductivity of the material and testing under stationary thermal conditions, characterized in that the layer of liquid thermal insulation of known thickness is placed between the heat-conducting standards, a heat conductivity meter determines the equivalent thermal conductivity of a flat three-layer Nogo sample liquid thermal insulation coefficient of thermal conductivity was calculated by the formula:

,
where δ _from - the thickness of the layer of liquid thermal insulation;
δ is the thickness of one standard;
λ _equiv - the equivalent coefficient of thermal conductivity of a flat three-layer sample, determined by the meter of thermal conductivity;
λ is the coefficient of thermal conductivity of the material of heat-conducting standards.