KR100606265B1 - Heat leakage protecting device for a piping of kimchi refrigerator - Google Patents

Abstract

The present invention installs an insulating connector made of a material having high heat resistance in a part of the evaporator tube connected between the evaporator outlet and the compressor inlet to prevent heat from being transferred to the inner container along the evaporator tube to minimize heat loss. It relates to a heat conduction blocking device of the evaporation tube for kimchi storage to increase the efficiency. The thermal conductivity blocking device connects the first evaporator tube connected to the evaporator pipe side, the second evaporator tube connected to the compressor side, the first evaporator tube and the second evaporator tube, and has a small coefficient of thermal conductivity, engineering plastics, rubber tubes, And a heat insulating connector having heat insulating means made of any one selected from non-metallic materials.

  Kimchi storage, evaporation tube, heat conduction blocker.

Description

Heat conduction blocking device of evaporation tube for kimchi storage {HEAT LEAKAGE PROTECTING DEVICE FOR A PIPING OF KIMCHI REFRIGERATOR}             

1 is a cross-sectional view schematically showing the internal structure of a kimchi storage in general.

Figure 2 is a schematic cross-sectional view showing the internal structure of the kimchi storage installed heat loss blocking device of the present invention.

Figure 3 is a cross-sectional view showing the configuration of a heat insulating connector which is a heat conduction blocking device according to an embodiment of the present invention.

Figure 4 is a cross-sectional view showing the configuration of a heat insulating connector which is a heat conduction blocking device according to another embodiment of the present invention.

Figure 5 is a cross-sectional view showing the configuration of a heat insulating connector which is a heat conduction blocking device according to another embodiment of the present invention.

♣ Explanation of symbols for main part of drawing ♣

 2: storage room 10: inner container

12: Insulation material 14: Outer container

16: Evaporator 18: Door

20: bulkhead 22: machine room

26: Compressor 30, 40, 50: Insulation connector

31, 31 ', 41, 41', 51, 51 ': Evaporator 34: Heat insulation plate

38, 58: O-ring 42, 52: Cap

44: insulation tube 54: insulation body

The present invention relates to a heat conduction blocking device for a kimchi storage evaporation tube, and more particularly, a part of the pipe connected between the evaporator outlet and the compressor inlet to install a heat insulation connector made of a material having a high heat resistance to heat the high temperature of the machine room. The present invention relates to a heat conduction blocking device of a kimchi storage evaporation tube that can increase energy efficiency by preventing heat transfer to the inner container along the evaporation tube.

In the case of general refrigerators that are used at home frequently, the kimchi is gradually rancidized in the process of frequently opening and closing, so that the ripe taste cannot be maintained as it is and freshness is lowered. In order to compensate for these problems, kimchi storage that can preserve kimchi's taste for a long time by aging kimchi appropriately according to seasons and preferences and then cooling it at low temperature is widely used.

An internal structure of a kimchi storage that is generally used will be described with reference to FIG. 1. 1 is a cross-sectional view schematically showing the internal structure of the kimchi storage in general. Looking at the overall configuration of the kimchi storage, the outer container 10 is provided on the outside of the inner container 10 via the inner container 10 and the heat insulating material 12 to provide a storage compartment (2) for putting kimchi, vegetables, fruits, etc. The container 14, the door 18 mounted on the upper part of the main body so as to be opened and closed by a hinge to open the storage compartment 2, and the partition 4 are disposed below the main body of the kimchi storage, Compressor 26, a condenser, a cooling fan, etc. are installed in the machine room 22.

On the outer circumferential surface of the inner container 10, an evaporator pipe 16 through which a refrigerant flows is stored for refrigeration of kimchi, including a heater for ripening kimchi. The outlet of the evaporator pipe 16 is connected to the compressor 26 via an evaporator tube (hereinafter referred to as an evaporator tube) 28 so that the refrigerant that cools the storage compartment 2 and flows out is evaporated tube 28. Is returned to the compressor 26.

In the heat loss generated in the kimchi storage of this configuration, the heat from the inner container 10 in which the evaporator pipe 16 is wound is partially directed toward the body along the arrow direction Q1, and the other part is the arrow direction Q2. Along with the loss due to the heat flux passing through the heat insulating material 12 in the process of being discharged toward the door 18 along the direction of the arrow (Q3) in the evaporation tube 28 made of copper or aluminum, which is a very good thermal conductivity material. There is a heat loss that is transferred along.

On the other hand, since the outlet of the evaporator tube 28 wound on the inner container 10 is continuously connected to the compressor 26 of the machine room 22, the outlet of the evaporator pipe 16 wound on the inner container 10. The temperature difference between the temperature of the evaporation tube 28 and the evaporation tube led to the machine room 22 becomes large. The temperature of the last evaporation tube wound on the inner container 10 is approximately 0 ° C., but the temperature of the evaporation tube drawn out to the machine room 22 to send the refrigerant to the compressor 26 is usually higher than the temperature of the outside air.

Therefore, there is a problem that the high temperature heat emitted from the machine chamber 22 is transferred along the evaporation tube to the inner container 10. As a result of actual experiments and computational analysis to test the factors of heat loss generated in the Kimchi storage, heat loss due to the heat flux passing through the heat insulator 12 is about 40-50% of the total power consumption, and heat through the evaporator tube The loss was found to be 10-20%.

Therefore, in order to obtain a high-efficiency product, it remains a problem to block heat transfer through an evaporator tube in which heat loss of 10 to 20% occurs.

The present invention to solve this problem prevents the high temperature heat generated in the machine room of the kimchi storage to be transferred to the inner container by the evaporator tube to fundamentally block the heat loss of the kimchi storage Kimchi storage that can increase the overall thermal efficiency It is an object of the present invention to provide a heat conduction blocker of a solid solution evaporator tube.

In order to achieve the above object, the heat conduction blocking device of the evaporator tube for kimchi storage of the present invention has an evaporator pipe wound around the outer circumferential surface of the inner container providing a storage compartment, and the refrigerant flowing out of the evaporator pipe is supplied to the compressor of the machine room through the evaporator tube. In the incoming kimchi reservoir, by connecting the first evaporator pipe connected to the evaporator pipe side, the second evaporator pipe connected to the compressor side, the first evaporator pipe and the second evaporation pipe, engineering plastics having a small coefficient of thermal conductivity, And a heat insulating connector having a heat insulating means made of any one selected from a rubber tube and a non-metallic material.

According to one embodiment of the present invention, the thermal insulation connector is composed of a body coupled to the evaporation tube of any one of the first evaporation tube and the second evaporation tube, the insulation plate is fixed to the body by fasteners such as screws.

According to another embodiment of the present invention, the ends of the first evaporation pipe and the second evaporation pipe are provided with a threaded threaded portion, and the thermal insulation connector has a female thread that is engaged with the male thread of the threaded portion, and has a predetermined interval therebetween. It consists of a pair of caps arranged, and a heat insulating tube which is fastened by a pair of caps to connect the first evaporation tube and the second evaporation tube.

According to still another embodiment of the present invention, a heat insulation connector has a cross-shaped heat insulation body having a threaded portion having male threads at both ends extending in the longitudinal direction, a through hole formed extending in the longitudinal direction inside the threaded portion, and one end of the first heat insulating connector. It is fixed to the ends of the evaporation tube and the second evaporation tube, respectively, the other end is composed of a cap that is fastened to both ends of the heat insulating body through the female screw formed on the inner peripheral surface.

Hereinafter, with reference to the accompanying Figures 2 to 5 will be described in detail with respect to the heat conduction blocking device of the kimchi storage evaporation tube according to a preferred embodiment of the present invention.

Figure 2 is a cross-sectional view schematically showing the internal structure of the kimchi storage is installed a heat conduction cutoff device of the present invention, Figures 3 to 5 are each of the thermally conductive cut-off connector according to the first to third embodiments of the present invention It is sectional drawing which showed the composition. In the following description, the same parts as the structure of the conventional kimchi storage described in FIG. 1 will be described with reference to the same reference numerals.

As described in detail with reference to FIG. 1, the kimchi reservoir consists of a storage chamber 2 disposed at an upper portion and a machine chamber 22 disposed at a lower portion of the partition wall 4. An evaporator pipe 16 for cooling is wound around the outer circumferential surface of the inner container 10 providing the storage compartment 2, and the outer container 14 is disposed on the outside via an insulating material 12 to form a body. In the upper part of the storage chamber 2, the door 18 is attached so that opening and closing is possible by a hinge. In addition, the machine room 22 includes a compressor 26 for compressing a refrigerant, a condenser, a cooling fan, and the like for cooling the refrigerant compressed by the compressor.

In the kimchi storage of this configuration, to prevent the high temperature heat generated in the machine room 22 is transferred to the inner container 10 via the evaporation tube to block the heat loss, in the present invention between the evaporator outlet and the compressor inlet By installing a thermal insulation connector made of a material having a high heat resistance in a part of the evaporation tube connected to the heat exchanger, the heat of the machine room 22 is prevented from being transferred to the inner container 10 along the evaporation tube to minimize heat loss.

Insulation connector employed in the present invention is provided with a heat insulating member made of engineering plastic, rubber tube, non-metallic material, etc. having a low coefficient of thermal conductivity, the high temperature heat generated in the machine room 22 is transferred to the inner container 10 along the evaporation tube. Do not

To this end, in the present invention, the evaporator tube is separated into a first evaporator tube 31 connected to the evaporator pipe 16 side and a second evaporator tube 31 'connected to the compressor 26 side. In addition, the first evaporation pipe 31 and the second evaporation pipe 31 'are connected by using an insulation connector 30 having a heat insulation member having a small thermal conductivity coefficient value, so that the high temperature heat generated in the machine room 22 is reduced. Blocking the transfer to the inner container 10 along the evaporation tube.

In the embodiment shown in Figure 3, the thermal insulation connector 30 of the present invention is an evaporation tube of any one of the first evaporation tube 31 and the second evaporation tube 31 ', e.g. It consists of a body 32 coupled to the tube 31 'and a heat insulating plate 34 fixed to the body 32 by fasteners such as screws 36 and the like. In this embodiment, the structure in which the heat insulating plate 34 is fixed to the body 32 by using the screw 36 is illustrated, but these components may be joined by other methods such as welding.

An enlarged diameter portion 31a is formed at the end of the evaporation tube (eg, 31) on the side inserted into the heat insulation plate 34 to increase the thermal contact area between the evaporation tube 31 and the heat insulation plate 34. The heat transferred through the evaporation tube 31 'is sufficiently transmitted to the heat insulating plate 34 through the enlarged diameter portion 31a. The other end of the evaporation tube 31 'is press-fitted to the end of the body 32 and then sealed by welding or the like to prevent the refrigerant from leaking.

In addition, an O-ring 38 for preventing leakage of the refrigerant is fitted along the outer periphery of the end of the side evaporation tube 31 inserted into the heat insulation plate 34.

Next, in the embodiment shown in Figure 4 illustrates an insulating connector 40 using a tube-shaped insulating member.

To this end, a male thread type thread portion 41a is formed at the end of the first evaporation pipe 41 connected to the outlet side of the evaporator pipe 16 and the second evaporation pipe 41 'connected to the inlet side of the compressor 26. It was. In addition, a pair of caps 42 are coupled to the male threads of the threaded portion 41a in a state in which the female threads formed on the inner circumferential surface thereof are disposed to face each other at a predetermined interval, and the insulating tube 44 is provided between the pair of caps 42. ) Is inserted.

Therefore, since the first evaporation pipe 41 and the second evaporation pipe 41 'are connected to each other by a heat insulation tube 44, which is a heat insulation member, the first evaporation pipe 41' is generated in the machine room 22 and the second evaporation pipe 41 'is generated. Most of the heat flowing in is blocked by the heat insulating tube 44 having a small thermal conductivity coefficient so as not to be transferred to the inner container 10.

On the other hand, an extension part 44a is formed at both ends of the heat insulation tube 44, and a locking part 42a to which the extension part 44a of the heat insulation tube 44 is engaged is formed at one end of the cap 42. . In addition, the first and second evaporation pipes 41 and 41 'are formed in a form in which the diameter of the screw portion 41a is also enlarged. Therefore, the thermal contact area with the heat insulation tube 44 is increased by these diameter expansion portions so that the heat introduced from the machine room 22 through the evaporation tube 41 'is not transmitted to the evaporation tube 41 as much as possible.

Next, Figure 5 is a cross-sectional view showing a heat insulation connector according to another embodiment of the present invention.

As shown here, looking at the structure of the heat insulation connector 50 illustrated in the present embodiment, there is a threaded portion 54a having male threads formed at both ends extending in the longitudinal direction, and in the longitudinal direction inside the threaded portion 54a. The cross-shaped heat insulation body 54 having an extended through hole 54c, and one end is fixed to the ends of the first evaporation tube and the second evaporation tube, and the other end is the heat insulation body 54 through a female screw formed on the inner circumferential surface thereof. Cap 52 is fastened to both ends of the.

As such, the threaded portions 54a are formed at both ends of the heat insulation body 54 in the longitudinal direction, so that the two evaporation tubes 51 and 51 'can be easily connected by using the cap 52. The end 51a of the evaporation tube 51 is press-fitted to one end of the cap 52.

In addition, a groove 54b is formed in the heat insulating body 54, and an o-ring 58 is inserted into the groove 54b to prevent leakage of the refrigerant.

On the other hand, in the adiabatic body 54, the middle portion of the threaded portion 54a extending in the longitudinal direction is composed of an extension portion 54d extending at right angles to maximize the thermal contact area with the evaporation tube 51 '. It was. Therefore, the heat introduced from the machine room 22 through the evaporation tube 51 'is sufficiently blocked by the screw portion 54a and the extension portion 54d of the heat insulating body 54, and the internal container (e.g. 10) should not be delivered.

According to the present invention described above, by installing a heat insulation connector made of a material having a high heat resistance in a part of the evaporator tube connected between the evaporator outlet and the compressor inlet, the heat of the machine room is transferred along the evaporator tube to the inner container to prevent heat Minimizing losses can increase energy efficiency.

Claims (9)

In the outer circumferential surface of the inner container for providing a storage chamber, an evaporator pipe is wound, and the refrigerant flowing out of the evaporator pipe flows into the compressor of the machine room through the evaporator pipe. A first evaporator pipe connected to the evaporator pipe side; A second evaporation pipe connected to the compressor side; Connecting the first evaporation tube and the second evaporation tube, the evaporation tube for kimchi storage characterized in that it comprises a heat insulating connector having a heat insulating means made of any one selected from engineering plastics, rubber tube, non-metallic material having a small coefficient of thermal conductivity. Thermal conduction breaker. According to claim 1, wherein the thermal insulation connector for kimchi storage, characterized in that consisting of a body coupled to the evaporation tube of any one of the first evaporation tube and the second evaporation tube, the insulation plate fixed to the body by a fastener. Heat conduction blocker of evaporation tube. The method of claim 2, wherein the O-ring for preventing the leakage of the refrigerant is inserted along the outer periphery of the end of the evaporation tube inserted into the heat insulating plate of the evaporation tube for kimchi storage evaporation tube. According to claim 2 or claim 3, The heat conduction blocking device of the evaporation tube for kimchi storage, characterized in that the enlarged diameter portion is formed at the end of the side evaporation tube inserted into the insulating plate. According to claim 1, wherein the first evaporation tube and the end of the second evaporation tube is provided with a screw thread formed with a male screw, The insulating connector has a female screw that is coupled to the male screw of the screw portion, and a pair of caps disposed opposite to each other at a predetermined interval, The heat conduction blocking device of the Kimchi storage evaporator tube, characterized in that made of a heat insulating tube is fastened by the pair of caps connecting the first evaporator and the second evaporator. According to claim 5, wherein both ends of the heat insulation tube is formed expansion, the heat conduction blocking device of the evaporation tube for kimchi storage, characterized in that one end of the cap is formed with a engaging portion is engaged with the extension of the heat insulation tube. According to claim 1, The thermal insulation connector is a cross-shaped heat insulation body having a threaded portion formed with male threads at both ends extending in the longitudinal direction, and a through hole formed extending in the longitudinal direction inside the screw portion, One end is fixed to the ends of the first evaporation tube and the second evaporation tube, the other end of the heat conduction blocking of the evaporation tube for kimchi storage evaporation tube, characterized in that the cap is fastened to both ends of the heat insulating body through a female screw formed on the inner peripheral surface. Device. According to claim 7, wherein the heat insulating body is formed in the groove, the heat conduction blocking device of the evaporation tube for kimchi storage, characterized in that the groove is fitted with O-ring. The method according to claim 7 or 8, In the heat insulation body, the middle portion of the screw portion extending in the longitudinal direction is a heat conduction blocking device of the evaporation tube for kimchi storage, characterized in that the extending portion is formed extending at right angles.

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