KR20150146203A - Measurement Apparatus of the Insulation to Measure Thermal Insulation Performance - Google Patents

Abstract

The present invention relates to an insulation performance measurement device for an insulation material, and an insulation performance measurement method using the same capable of measuring a performance of insulation by placing an insulation material to surround a liquefied natural gas (LNG) carrier or an LNG transfer pipe in an extremely low environment. According to the present invention, the insulation performance measurement device for an insulation material comprises: a sample container having an insulation material charging part having a cylindrical shape with an opened upper and lower surfaces filled with an insulation material to be measured, a lower plate formed of a heat conductive material to close the lower part of the insulation material charging part, and an upper plate formed of a heat conductive material to close the upper part of the insulation material charging part; a cooling container having a cylindrical shape with an opened upper surface wherein the sample container is inserted through the opened upper surface such that the upper surface can be closed by the sample container; support members to support the sample container in a state where the sample container is separated from the lower surface of the cooling container at a predetermined distance; a refrigerant supply unit to supply cooling fluid to a space between the cooling container and the sample container; and a temperature measurement unit being in contact with the upper plate of the sample container to measure a temperature.

Description

TECHNICAL FIELD The present invention relates to an apparatus for measuring the thermal insulation performance of a thermal insulation material,

The present invention relates to an apparatus and a method for measuring the heat insulating performance of a heat insulating material, and more particularly, to an apparatus and a method for measuring a heat insulating performance by inserting a heat insulating material surrounding an LNG carrier or a liquefied natural gas transfer pipe into a cryogenic environment And a method for measuring the heat insulating performance using the same.

Generally, LNG (Liquefied Natural Gas) is compressed and cooled to -163 ℃ for convenience of transportation and storage, and the volume is reduced to 1 / 600 < / RTI > These liquefied natural gas are more popular as alternative energy sources because of their superior calorific value.

 In order to deal with liquefied natural gas cooled at -163 ° C, it is necessary to protect both piping and storage tanks to which liquefied natural gas is transported with excellent insulation. As a result, research and technology development for pipe insulation and tank insulation rapidly .

In order to measure the performance of the developed insulation, a technique for measuring and comparing the thermal efficiency of the insulation should be inevitably performed. In particular, the insulation used for transporting and storing the liquefied natural gas, which is in a cryogenic condition, .

However, conventional devices for measuring the performance of insulation in a cryogenic environment are expensive and require a lot of cost in the measurement test, and the measurement process is also very troublesome.

Registered Patent No. 10-1163070 (Registered Date June 29, 2012) "Cryogenic Thermal Conductivity and Thermal Expansion Coefficient Measuring Device and Method for Simultaneously Measuring Thermal Conductivity and Thermal Expansion Coefficient Using the Device" Registered Patent No. 10-0520895 (registered October 05, 2005) "Insulation and Cooling Performance Measurement System"

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a heat insulation property of a heat insulation material which is made of a simple structure and which can measure heat insulation performance by measuring thermal conductivity of the insulation material in a low- And a method for measuring the heat insulation performance using the same.

According to another aspect of the present invention, there is provided an apparatus for measuring a heat insulating performance of a heat insulating material, the apparatus comprising: a heat insulating material charging unit having a tubular shape with an upper surface and a lower surface opened to fill the heat insulating material to be measured; A sample container including a lower plate of a thermally conductive material to be closed and an upper plate of a thermally conductive material for closing an upper portion of the heat insulating material charging unit; A cooling container having an upper surface opened in a cylindrical shape, the upper surface being closed by the sample container while the sample container is inserted through the opened upper surface; A support member for supporting the sample container such that the sample container is supported at a predetermined distance from the lower surface of the cooling container; A refrigerant supply means for supplying a cooling fluid to a space between the cooling vessel and the sample vessel; And a temperature measuring unit installed to be in contact with the upper plate of the sample vessel and measuring the temperature.

A method for measuring an adiabatic performance using an adiabatic performance measuring apparatus according to the present invention comprises the steps of: filling a measured adiabatic material inside a sample vessel; Inserting the sample container through the open upper portion of the cooling vessel and placing it on the support member; Supplying a cooling fluid to the inside of the cooling vessel; And measuring the temperature of the upper plate of the sample container.

According to the present invention, the thermal conductivity through the heat insulating material can be measured by supplying the cryogenic cooling fluid such as liquefied nitrogen to the inside of the cooling vessel and measuring the temperature of the upper plate of the sample vessel containing the heat insulating material. Therefore, the performance of the heat insulating material can be easily and accurately measured with a simple structure.

That is, the thermal insulation performance measuring apparatus of the present invention can measure the thermal conductivity of the heat insulating material in the sample container by measuring the temperature of the sample container at room temperature without forming a cryogenic chamber having a large volume for forming a cryogenic environment There is an advantage that the configuration and operation of the apparatus can be greatly simplified.

1 is an exploded perspective view showing an apparatus for measuring a heat insulation performance of a heat insulating material according to an embodiment of the present invention.
Fig. 2 is a perspective view of the adiabatic performance measuring apparatus of Fig. 1. Fig.
3 is a sectional view of the adiabatic performance measuring apparatus of Fig.
4 is a perspective view showing a sample container of the adiabatic performance measuring apparatus of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4 show an embodiment of an apparatus for measuring the heat insulating performance of a heat insulating material according to the present invention. The apparatus for measuring the heat insulating performance of this embodiment includes a sample container 10 in which a measured thermal insulating material 1 is accommodated, A cooling container 20 in which a sample container 10 is accommodated and a cooling device 20 for cooling the cooling container 20 such that a lower surface of the sample container 10 and a lower surface of the cooling container 20 are spaced apart from each other by a predetermined distance, A coolant supply means for supplying a cooling fluid to a space between the cooling vessel 20 and the sample vessel 10 and a coolant supply means for supplying a cooling fluid to the space between the cooling vessel 20 and the sample vessel 10, And temperature measuring means 50 for measuring the temperature.

The sample container 10 has a tubular shape of a rectangular parallelepiped having open top and bottom surfaces and includes a heat insulating material charging part 11 filled with the thermal insulating material 1 to be measured and a heat insulating material charging part 11 closing the bottom of the heat insulating material charging part 11 A lower plate 12 made of a thermally conductive material and an upper plate 13 made of a thermally conductive material for closing the upper part of the heat insulating material charging part 11. [

The heat insulating material charging part 11 of the sample container 10 may be formed of a vacuum insulated panel having four sides of the sample container 10 and a vacuum process inside thereof, It may be.

The lower plate 12 and the upper plate 13 of the sample container 10 are made of a metal having excellent thermal conductivity, for example, stainless steel or aluminum.

The cooling container 20 is formed in a cylindrical shape having a rectangular parallelepiped having an open top surface and made of a metal such as stainless steel filled with foam. The sample vessel 10 is inserted through the open upper surface of the cooling vessel 20 and the upper surface of the cooling vessel 20 is closed by the sample vessel 10. A gasket 25 made of rubber or silicone may be installed around the upper end of the cooling container 20 so as to prevent the cooling fluid from leaking through the gap between the outer surface of the sample container 10 and the inner peripheral surface of the upper end of the cooling container 20 have.

A coolant inlet port 21 for supplying a cooling fluid such as liquefied nitrogen and a coolant outlet port 22 for discharging a coolant fluid in the coolant vessel 20 to the outside of the cooling vessel 20 As shown in Fig.

The support member supports the sample container 10 such that the sample container 10 inserted into the cooling container 20 is supported at a predetermined distance from the lower surface of the cooling container 20. In this embodiment, the support member is provided at each corner of the bottom surface of the cooling container 20 so as to extend upward and includes a plurality of support columns 30 supporting the lower surface of the sample container 10 ). When the sample container 10 is inserted into the cooling container 20, the lower surface of the sample container 10 is supported by the support column 30 and the lower surface of the sample container 10 and the cooling container 20 A predetermined space is formed.

When the sample vessel 10 is inserted into the cooling vessel 20 and supported by the support column 30, the upper plate 13 of the sample vessel 10 is constantly positioned above the upper end of the cooling vessel 20 So that the rim portion of the upper plate 13 does not come into contact with the cooling vessel 20 so that direct heat transfer between the cooling vessel 20 and the upper plate 13 can be prevented desirable.

The coolant supply means supplies the liquefied nitrogen as a cooling fluid to the space between the cooling vessel (20) and the sample vessel (10). The refrigerant supply means includes a refrigerant supply line 41 and a refrigerant discharge line 42 connected to the refrigerant inlet 21 and the refrigerant outlet 22 of the cooling vessel 20, A supply control valve 44 for controlling the supply of the cooling fluid through the coolant supply line 41 and a coolant supply line 42 for cooling the coolant through the coolant discharge line 42. [ And a discharge control valve 45 for controlling discharge of the fluid.

The temperature measuring means 50 is provided in contact with the upper plate 13 of the sample container 10 to measure the temperature. The temperature measuring means 50 may be a temperature sensor, a thermocouple, or the like.

A method of measuring the heat insulating performance of the heat insulating material using the above-described heat insulating performance measuring apparatus will be described below.

The lower plate 12 is installed in the lower part of the heat insulating material charging part 11 of the sample container 10 and then the measured heat insulating material 1 is filled in the space inside the heat insulating material charging part 11, The upper part of the charging part 11 is closed.

The sample container 10 filled with the measured thermal insulating material 1 is inserted through the open top of the cooling container 20 and placed on the support column 30. [ At this time, the upper plate 13 of the sample vessel 10 is exposed to the outside of the upper end of the cooling vessel 20, and the rim of the upper plate 13 is positioned above the upper end of the cooling vessel 20 And is not in direct contact with the cooling vessel 20.

The supply control valve 44 of the refrigerant supply means is opened and the cooling fluid is discharged from the refrigerant supply source 43 and injected into the cooling vessel 20 through the refrigerant supply line 41. [ The cooling fluid supplied to the space between the cooling vessel 20 and the sample vessel 10 through the refrigerant supply line 41 is cooled while contacting the lower plate 12 under the sample vessel 10.

At this time, the temperature measuring means measures the temperature of the upper plate 13 of the sample container 10. The temperature measured by the temperature measuring means is transmitted to the computer or the controller, and the computer or the controller analyzes the performance of the insulating material by the transmitted temperature information.

According to the present invention, the cryogenic cooling fluid such as liquefied nitrogen is supplied to the inside of the cooling vessel 20, and the temperature of the upper plate 13 of the sample vessel 10 is measured to measure the thermal conductivity through the heat insulating material 1 can do. Therefore, the performance of the heat insulating material 1 can be easily and accurately measured with a simple structure.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

1: Insulation material 10: Sample container
11: Insulating material charging part 12: Lower plate
13: upper plate 20: cooling container
21: Refrigerant inlet port 22: Refrigerant outlet port
30: Support column 41: Refrigerant supply pipe
42: Refrigerant discharge pipe 43: Refrigerant supply source
44: Supply control valve 45: Discharge control valve
50: Temperature measuring means

Claims (7)

A heat insulating material charging part 11 in which a top surface and a bottom surface are opened and filled with a measured thermal insulating material 1 and a thermally conductive lower plate 12 which closes the bottom of the thermal insulating material charging part 11, And a top plate (13) of a thermally conductive material for closing the upper part of the heat insulating material charging part (11);
A cooling container (20) having an upper surface opened in a cylindrical shape and having a top surface closed by the sample container (10) while the sample container (10) is inserted through an opened upper surface;
A support member for supporting the sample container 10 such that the sample container 10 is supported at a predetermined distance from the lower surface of the cooling container 20;
A refrigerant supply means for supplying a cooling fluid to a space between the cooling vessel (20) and the sample vessel (10);
And a temperature measuring means (50) installed to be in contact with the upper plate (13) of the sample container (10) and measuring the temperature. The support member according to claim 1, wherein the support member is provided at each corner of the bottom surface of the cooling container (20) so as to extend upward and includes a plurality of support columns (30) supporting the lower surface of the sample container support column for measuring the heat insulation performance of the heat insulating material. The apparatus according to claim 1, wherein the heat insulating material charging part (11) is made of a vacuum insulation panel whose inside is subjected to a vacuum treatment. The apparatus of claim 1, wherein the upper plate (13) of the sample vessel (10) is disposed at a position higher than the upper end of the cooling vessel (20) Wherein the heat insulating property measuring device is configured to measure the heat insulating performance of the heat insulating material. The gasket according to claim 1, wherein a gasket (25) is provided around the upper end of the cooling container (20) so that the cooling fluid does not leak through the gap between the outer surface of the sample container (10) and the inner peripheral surface of the upper end of the cooling container Characterized in that the heat insulating performance of the heat insulating material is measured. The refrigerant supply device according to claim 1, wherein the refrigerant supply means includes a refrigerant supply line (41) connected to a refrigerant inlet (21) and a refrigerant outlet (22) formed to communicate with the inside and the outside of the cooling container (20) A refrigerant supply line 43 for supplying a cooling fluid through the refrigerant supply line 41 and a supply control valve 43 for controlling the supply of the cooling fluid through the refrigerant supply line 41, 44), and a discharge control valve (45) for controlling discharge of the cooling fluid through the refrigerant discharge line (42). A method for measuring an adiabatic performance using the adiabatic performance measuring apparatus according to any one of claims 1 to 6,
Filling the inside of the sample container (10) with the measured thermal insulating material (1);
Inserting the sample container (10) through the open top of the cooling container (20) and placing it on the support member;
Supplying a cooling fluid into the cooling vessel (20);
And measuring the temperature of the upper plate (13) of the sample container (10).

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