KR101282726B1 - Method of monitering vacuum of vacuum insulation material - Google Patents

Abstract

PURPOSE: A vacuum condition monitoring method of a vacuous insulator is provided to apply simple external impact such as air pressure and to measure a phenomenon that a thin outer wall unit is temporarily bent or vibrated by the external impact, thereby simply checking a vacuum condition of the vacuous insulator. CONSTITUTION: A vacuum condition monitoring method of a vacuous insulator is as follows. External impact inducing the temporary transformation of an outer wall unit is applied. A change of the outer wall unit according to the external impact is checked. A vacuum condition of the vacuous insulator is monitored through the change of the outer wall unit which becomes different according to the destruction of the vacuum condition of a vacuum space (112).

Description

How to monitor vacuum condition of vacuum insulator {METHOD OF MONITERING VACUUM OF VACUUM INSULATION MATERIAL}

The present invention relates to a vacuum state monitoring method of a vacuum insulation material that can check the vacuum state of the vacuum insulation material.

Energy efficiency of home appliances is becoming more and more important in terms of energy saving, and according to this trend, it is required to improve the insulation performance of refrigerators, thermal insulation cold containers, etc., and it is recognized that high performance of insulation material is essential for energy saving. .

General insulation is manufactured using materials with low thermal conductivity such as styrofoam, but when the insulation using styrofoam is applied to the refrigerator, the thickness of the insulation itself is thick, which reduces the internal capacity of the refrigerator and relatively increases the overall volume of the refrigerator. This is being pointed out. In order to solve such a problem, a vacuum insulator is used, and for example, a vacuum insulator can be obtained by sealing the inside of a container such as metal or plastic after reduced pressure. In the case of the vacuum insulator, the thermal conductivity of the vacuum insulator is significantly lower than that of the insulator using the low thermal conductivity material, and thus the energy efficiency is very excellent. It can also assist.

However, in the case of the vacuum insulator, if the vacuum degree of the container itself is damaged due to the breakage of the container, the thermal insulation performance may be greatly reduced, and in this case, there is a risk that the article stored therein is rapidly exposed to heat.

Therefore, in the case of a device using such a vacuum insulator, it is recognized as a key to quickly check the vacuum state of the vacuum insulator and to quickly cope with the economic loss due to the breakdown of the vacuum insulator.

In addition, in the assembly process of home appliances using a vacuum insulator, for example, a refrigerator, there is a problem that the degree of vacuum of the vacuum insulator decreases due to a mechanical impact or a bonding process. A complex and very time consuming inspection process is required.

The present invention provides a vacuum state monitoring method of a vacuum insulator capable of checking a vacuum state therein.

According to an exemplary embodiment of the present invention, a vacuum state monitoring method of a vacuum insulator including an inner vacuum space and a sealed outer wall portion defining a vacuum space, includes: providing an external shock to induce a temporary deformation of the outer wall portion; Checking the change of the outer wall portion corresponding to the external impact; And monitoring the vacuum state of the vacuum insulator through the change of the outer wall portion corresponding to the breakdown of the vacuum state of the vacuum space.

In the present invention, the outer wall portion of the vacuum insulator may be formed using a variety of materials capable of forming an enclosed space, such as metal or plastic, for example, thin film of thin aluminum or stainless steel or other alloys. It can be manufactured, and the outer wall portion can be provided through lamination of a thin metal and a plastic such as polyimide or polyethyleneterephthalate. In some cases, glass fibers may be disposed in the vacuum insulator to maintain its shape. The method of manufacturing a heat insulating material having a glass fiber is already widely disclosed, and in particular, reference may be made to Patent Publication 2011-0103970.

As described above, the vacuum insulator may be provided in a variety of materials, it is possible if the appearance can be temporarily changed by an external physical impact. More specifically, the vacuum insulator may have a degree of elasticity or restoring force such that the appearance may be temporarily distorted or vibrated by an impact such as wind or sound waves.

In addition to the wind and sound waves mentioned above, the external shock may be an air-borne indirect shock such as air injection, resonance phenomena or sound pressure, or in some cases, a direct shock that directly hits the vacuum insulator. It may be.

The above-described shocks may be provided intermittently or continuously, induce air flow by using a sound wave generator, an air compressor or a fan or an air pump, and an air regulator. ), It is possible to provide a continuous or intermittent break in the flow of air, and to control the air pressure.

The change in the outer wall part may include a change in the position where the outer wall part vibrates or bends due to the external impact mentioned above, and the change of the outer wall part may be measured by using a measuring device disposed outside the outer wall part. .

The measuring apparatus may measure a change in the position of the outer wall using light, and specifically, emit light toward the outer wall and receive the reflected light to measure that the phase of the outer wall changes.

The measuring device for measuring the change of position using light is already a commonly used device, for example, a thickness measuring device using a laser to measure the thickness of the thin film may be used as it is. The apparatus disclosed in 10-2009-0097938, the measurement window disclosed in registered patent 10-0486751, and the like.

The vacuum state monitoring method of the vacuum insulator of the present invention provides a simple external shock such as pneumatic pressure, and by measuring the phenomenon in which the thin outer wall part is temporarily vibrated or bent, it is possible to simply check the vacuum state of the vacuum insulator.

1 is a partial perspective view of a refrigerator to which a vacuum insulator according to an embodiment of the present invention is applied.
FIG. 2 is an exploded perspective view of a part of the refrigerator illustrated in FIG. 1.
3 is a cross-sectional view taken along the AA direction of FIG. 1.
4 is a cross-sectional view of the measuring device and the outer wall portion capable of confirming the vibration state of the outer wall portion of the vacuum insulator.
5 is a cross-sectional view of a vacuum insulator for explaining another embodiment to which the method of checking the vacuum degree of the vacuum insulator according to the present invention can be applied.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments. For reference, the same numbers in this description refer to substantially the same elements and can be described with reference to the contents described in the other drawings under these rules, and the contents which are judged to be obvious to the person skilled in the art or repeated can be omitted.

1 is a partial perspective view of a refrigerator to which a vacuum insulator according to an embodiment of the present invention is applied, FIG. 2 is an exploded perspective view of a part of the refrigerator shown in FIG. 1, and FIG. .

1 to 3, a refrigerator 1 is generally illustrated for storing food at low temperature, and the refrigerator 1 may include a case forming a storage space 20 such as a refrigerator compartment or a freezer compartment for storing food. 10), a door (not shown) that opens and closes the refrigerating compartment and the freezing compartment, and a mechanical part (not shown) configured to maintain the stored food at a low temperature.

In general, the refrigerator is filled with a heat insulating material between the outer surface forming the outer shape in the case and the inner surface forming the storage space, the polyurethane foam liquid is injected between the inner surface and the outer surface of the case in the assembled state. It was then formed by heating and foaming. However, the heat insulating material formed by foaming polyurethane is limited in improving heat insulation performance due to the incorporation of heat-transfer air and the heat conduction property of the polyurethane itself. There was a problem of increasing volume.

Therefore, in recent years, the refrigerator 1 often uses a vacuum insulator 100 that can effectively reduce the thermal conductivity by maintaining the inside thereof in a vacuum, and the vacuum insulator has a large volume when compared with a conventional foam insulator. It can be reduced, which in turn is very effective in reducing the volume of the refrigerator 1 itself.

The vacuum insulator itself may determine the appearance of the refrigerator, but as in this embodiment, a separate case 10 is attached to the outer surface of the vacuum insulator 100 so that the case 10 forms an inner surface or an outer surface of the refrigerator 1. You can also do that. Specifically, in the present embodiment, the inner case 12 constituting the inner surface of the refrigerator 1 and the outer case 14 constituting the outer surface of the refrigerator 1 are attached to both surfaces of the vacuum insulator 100.

Specifically, as shown in FIG. 2, in the state where the vacuum insulator 100 provided in the form of a rectangular parallelepiped is disposed between the inner case 12 and the outer case 14 forming one surface of the refrigerator 1, the inner surface By combining the case 12 and the outer case 14, the case 12 and the outer case 14 may be disposed between the inner case 12 and the outer case 14. Of course, different vacuum insulators 100 are disposed on different sides of the refrigerator 1. That is, the other surfaces of the refrigerator 1 may also arrange the vacuum insulator 100 on the respective surfaces by disposing different vacuum insulators between different inner and outer cases. For reference, the vacuum insulator 100 is inserted into the groove 15 provided inside the outer case 14 to accommodate the vacuum insulator 100. Of course, in some cases, the vacuum insulator may be provided in a bent form to constitute a plurality of surfaces of the refrigerator, and one vacuum insulator may be provided to form one storage space in the form of an open rectangular parallelepiped.

The vacuum insulator 100 includes a sealed outer wall portion 110 defining a vacuum space 112 and a vacuum space 112 therein, and the outer wall portion 110 of the vacuum insulator 100 is made of metal or plastic. It may be formed using a variety of materials that can form a closed space therein, the glass fiber 120 may be disposed inside the vacuum space 112 of the interior defined by the outer wall portion 110. The glass fiber 120 maintains the shape of the outer wall portion 110, which may be provided as a very thin thin metal, and may prevent the shape of the outer wall portion 110 from being distorted inward due to the internal pressure in a vacuum state. have.

The outer wall portion 110 of the above-described vacuum insulator 100 is possible if the appearance can be temporarily changed by the physical impact of the outside. More specifically, the vacuum insulator 100 may have a certain elasticity or restoring force that may temporarily distort or vibrate the appearance of impact such as wind or sound waves, and most preferably, in the present embodiment, a thin metal Is provided.

Wind or sound waves may be used as an external impact, and may be provided intermittently or continuously to induce temporary deformation of the outer wall portion 110.

A device capable of externally impacting may include a sound wave generator, and in brief, an air fluting device 300 capable of generating a flow of air, such as an air compressor or a pen or an air pump, as in the present embodiment. May be used, and a nozzle for air injection may be provided at the tip of the air fluting device 300. Induces a flow of air using the air fluting device 300 that can change the pneumatic pressure, in some cases, can be provided by continuously or intermittently cutting off the flow of air, and may adjust the pressure of the air .

In the present embodiment, the change of the outer wall portion 110 may be a change in the position where the outer wall portion 110 vibrates or bends due to an external impact, that is, a change in pneumatic pressure, and the change of the outer wall portion 110 may be The measurement may be performed using the measuring apparatus 200 disposed outside the outer wall unit 110.

In the present embodiment, the measuring device 200 may measure a change in position of a specific point of the outer wall portion 110 using light, and specifically, emits light toward the outer wall portion 110 and receives the reflected light. The positional change of one point of the outer wall portion 110 can be observed.

The measuring device 200 for measuring a change in position using light is already a commonly used device. For example, a thickness measuring device using light such as a laser may be used as it is to measure the thickness of a thin film. For example, such a device may include a device disclosed in Korean Patent Laid-Open Publication No. 10-2009-0097938, a measurement device disclosed in Korean Patent No. 10-0486751, or a measurement device disclosed in Korean Patent No. 10-0490325.

Referring to FIG. 4, a measuring device 200 capable of measuring vibration of the outer wall part 110 is disposed outside the outer wall part 110.

The measuring device 200 shown in FIG. 4 is a device for measuring thickness and refractive index of a thin film layer, which is widely used these days, and is based on a reflectometry. In the present embodiment, the measuring device 200 is not used to measure the thickness of the layer, but may be used to check the position change of a specific point so as to calculate the vibration period or amplitude of the outer wall part 110. . Specifically, the light starting from the light source 201 is reflected by the light splitter 202 and is incident on the outer wall part 110 through the objective lens 204. Part of the light projected on the outer wall part 110 is reflected on the surface of the outer wall part 110, and then is again detected through the objective lens 204 at the center of the light splitter 202 and the reflecting plate 218. After projecting to the spectroscope 230 through 220, the spectroscope 230 analyzes the projected reflected light to obtain the intensity of the reflected light as a function of light wavelength. This result can confirm the movement of the position of the specific point of the outer wall portion 110 through the numerical converter 232 and the information processor 234, based on this, it is possible to calculate the measurement value, such as the vibration width or period.

In the present embodiment, since the vibration period, amplitude, or magnitude of the phase change at a specific point observed by the measuring device 200 may vary depending on whether the vibration state inside the outer wall part 110 is different, the vacuum may be obtained by using the above equipment. The vacuum of the heat insulating material 100 can be confirmed. For example, when the air is blown with the aforementioned air fluting device, the vibration period or amplitude at a specific point is measured in advance according to the degree of vacuum, and the wind is blown at a specific point at any time. The degree of vacuum can be checked by measuring the period and amplitude.

5 is a cross-sectional view of a vacuum insulator for explaining another embodiment to which the method of checking the vacuum degree of the vacuum insulator according to the present invention can be applied.

In this embodiment, the vacuum insulator 400 may include a glass fiber 420 used as an inner core material and an outer wall portion 410 provided on a film on which aluminum is deposited.

On the other hand, a getter may be inserted into the heat insulator, and the getter for absorbing moisture, nitrogen, or other gas remaining in the heat insulator to lower or maintain the vacuum degree may be provided in the getter accommodating part 440 in the form of a bag. Can be provided soaked.

The type of getter can be selected by using desiccant such as CaO or BaO which is effective for water absorption, or cobalt oxide (Co ₃ O ₄ ) which can remove hydrogen or other organic gas inside vacuum insulator. The shape of the accommodation portion is not determined, and in this embodiment, the plate 430 having a flat outer surface is padded outside the getter accommodation portion 440.

In general, the inner core material used for the vacuum insulator 400, that is, the stainless steel ultra-thin plate (STS) provided on the glass fiber 420 to form the outer wall portion 410 is very thin, about 50 ~ 80㎛ thickness of the inner The outer wall part 410 has an uneven surface by the filling material.

If the outer surface is not so flat, it may be difficult to accurately measure the vibration state of the outer wall portion by the measuring device described in the previous embodiment.

However, in the present invention, by providing a flat surface on the surface of the outer wall portion can minimize the measurement error according to the surface roughness of the outer wall portion, specifically, by laying a flat plate 430 as in this embodiment, by depositing aluminum When the outer wall portion 410 of the heat insulating material is formed, the outer wall portion 410 of the portion corresponding to the flat plate 430 on the getter receiving portion 440 has a flat surface than other portions.

That is, by attaching a flat plate to the getter receiving portion that enters the inside of the outer wall portion to make the surface state of the outer wall portion 410 flat, measurement that may occur when measuring through the measuring device according to the surface roughness of the outer wall portion The error can be minimized.

For reference, the flat plate 430 may be selectively attached to the inner surface or the outer surface of the getter receiving portion, and, unlike the present embodiment, the flat plate 430 is padded on the glass fiber as the inner filling material so that the outer wall is flat. It may be to have a flat outer surface in the portion corresponding to the, and the surface of the outer wall portion formed thereon may be flattened by making the getter receiving portion surface itself flat.

As described above, although described with reference to the preferred embodiment of the present invention, those skilled in the art various modifications and variations of the present invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

1: Refrigerator 12: Inner case
14: Outer case 100: Vacuum insulation material
112: vacuum space 200: measuring device
300: air fluting device

Claims (7)

A vacuum state monitoring method of a vacuum insulator comprising an inner vacuum space and a sealed outer wall portion defining the vacuum space,
Providing an external impact that induces temporary deformation of the outer wall portion;
Checking a change in the outer wall portion corresponding to the external impact; And
Monitoring the vacuum state of the vacuum insulator through the change of the outer wall portion corresponding to the breakdown of the vacuum state of the vacuum space;
Vacuum state monitoring method of the vacuum insulation material comprising a. The method of claim 1,
The external shock is any one of a continuous or intermittent air blowing, sound waves, resonance phenomena, sound pressure, and physical blown delivered to the outer wall portion, the vacuum state monitoring method of the vacuum insulator. The method of claim 1,
The change of the outer wall portion is a vacuum state monitoring method of the vacuum insulator, characterized in that the change in the vibration or position of the outer wall portion. The method of claim 1,
The external shock may be generated by inducing the flow of air by using any one of a sound wave generator, an air compressor, a fan, and an air pump. Way. The method of claim 1,
The change of the outer wall portion is measured by using a measuring device disposed outside the outer wall portion to receive the light emitted from the outer wall portion and the light reflected from the outer wall portion. The method of claim 1,
Providing a flat surface on the surface of the outer wall portion to minimize the measurement error due to the surface roughness of the outer wall portion. The method according to claim 6,
And a flat plate attached to a getter accommodating part inside the outer wall part to make the surface state of the outer wall part flat, thereby minimizing a measurement error due to the surface roughness of the outer wall part.

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