KR100512245B1 - Multi path structure for heat transfer of condensor - Google Patents

Abstract

The multi-layer flow path structure for heat dissipation of the condenser according to the present invention relates to heat dissipation of the condenser in the machine room, and more particularly, to a heat dissipation and flow path for improving heat dissipation to the condenser in a built-in type refrigerator. A multi-layer flow path structure for heat dissipation of a condenser includes: a refrigerator having a machine room at a lower end of a main body, the refrigerator comprising: a heat dissipation space located at a lower end of the machine room for a flow path of hot air; A partition wall dividing the heat dissipation space up and down; A condenser fixed to an upper side of the partition wall; Located in the rear of the partition wall is characterized in that consisting of a cooling fan for forced circulation of the air at the bottom of the partition to the top of the partition wall.

The multi-layer flow path structure for heat dissipation of the condenser according to the present invention has the effect of sufficiently and effectively discharging high temperature air generated from the condenser of the refrigerator to the outside of the refrigerator.

Description

Multi path structure for heat transfer of condensor

The present invention relates to a heat dissipation and a flow path for improving heat dissipation for a condenser of a built-in type refrigerator. In general, a refrigerator obtains low temperature cold air in the course of completing a compression refrigeration cycle, but at the same time, It must be maintained to cool the condenser so that the refrigerator can continue to perform its desired performance, in order to release hot air from the condenser to the outside of the refrigerator.

1 is a view showing a schematic position of the main engine of the compression refrigeration cycle in a typical refrigerator, Figure 2a is a view showing the noise generating element of the refrigerator actually installed in the vicinity of the wall in Figure 1 and the adjacent interior around the machine room, FIG. 2B shows the main engines in the machine room in FIG. 2A.

Referring to these drawings, the refrigerator exerts its function by cold air generated by a compression refrigeration cycle, that is, a compressor 5 in which a low temperature low pressure gas refrigerant is converted into a high temperature high pressure gas refrigerant, and the high temperature high pressure gas. A condenser 1 in which a refrigerant is converted into a liquid refrigerant of medium temperature and high pressure, an expansion tube 4 in which the liquid refrigerant of medium temperature and high pressure is converted into a liquid refrigerant of low temperature and low pressure, and the liquid refrigerant of low temperature and low pressure are converted into a gas refrigerant of low temperature and low pressure. The compressed refrigeration cycle is completed by the evaporator (3).

Here, elements of some of the engines that complete the compression refrigeration cycle are located in the machine room 7 located at the bottom of the refrigerator, such as the condenser 1, the compressor 5, the cooling fan 2, and the like. In order to discharge hot air from the machine room 7 to the outside, the refrigerator is generally used at a distance (A) away from the wall surface, which is required for the refrigerator to discharge a sufficient amount of hot air from the machine room to the outside. Because it can exert.

FIG. 3A is a perspective view illustrating a state in which heat of the condenser is released through the machine room cover in FIG. 2A, and FIG. 3B is a side view illustrating heat radiation through the machine room cover in FIG. 2A.

Referring to these drawings, the heat dissipation of the condenser is made through a machine room cover located at the bottom rear of the refrigerator, and relatively low-temperature air outside the refrigerator is introduced through the intake hole 10 formed at one side of the machine room cover 9. The air changed to high temperature by the condenser 1 is discharged to the outside of the refrigerator through an exhaust hole 11 formed opposite the intake hole 10, and at this time, a certain amount of air is discharged from the wall to discharge hot air from the machine room. Refrigerators installed spaced apart by the distance (A), even if spaced apart from the wall in order to release a sufficient amount of hot air from the machine room, considering the space utilization and balance with other furniture, etc. It can not be enlarged unconditionally. Therefore, sufficient heat dissipation is not achieved well.

In order to improve this problem, conventionally, a separate space for heat dissipation is provided under the machine room, and condenser is installed in the heat dissipation space, thereby making efforts to improve heat dissipation efficiency.

Figure 4a is a perspective view of the heat dissipation through the heat dissipation space of the lower portion of the machine room according to the prior art, Figure 4b is a side view showing the heat dissipation through the heat dissipation space of the lower portion of the machine room in Figure 4a.

Referring to these drawings, a heat dissipation space for dissipating the condenser 18 is provided on a lower side of a conventional machine room, and in particular, a condenser 18 is disposed on an upper wall of the heat dissipation space, and below the condenser 18 in a front-rear direction. It has a partition 16 that crosses, the front of the heat dissipation space has a front vent cover 17 and the front vent cover 17 has an intake hole 13 and an exhaust hole 14 for the flow of air, respectively Is installed.

Looking at the heat dissipation process according to the above configuration in detail, in the upper side of the heat dissipation space provided in the lower side of the machine room, the condenser 18 is installed and operated separately from the machine room in this process, the heat dissipation space inside is maintained at a high temperature. A relatively low temperature air outside the refrigerator is introduced through an intake hole 13 formed at one side of the front vent cover 17 on the front side of the heat dissipation space, and a cooling fan installed at the rear of the partition 16. The cold air forcedly circulated by the cooler is cooled by contact with the condenser 18 and then discharged to the outside of the refrigerator through the exhaust hole 14 formed opposite the intake hole 13. It will act as a heat radiation for (18).

However, in the heat dissipation structure as described above, heat dissipation is insufficient because a condenser is installed on the upper side of the heat dissipation space and cold air from the outside of the refrigerator flows into the side and is discharged to the other side, so that the air circulation effect by convection is not shown. As well as

Problems such as high temperature heat of the condenser is transferred back to the inside of the refrigerator by heat conduction through the upper surface of the heat dissipation space.

The present invention has been made in view of the above problems, and has an object of transmitting heat of a condenser by a heat sink having a large area, and moreover, efficiently dissipating heat transferred by heat conduction to the outside of the refrigerator as described above.

According to an aspect of the present invention, there is provided a multi-layer flow path structure for dissipating a condenser, the refrigerator including a machine room at a lower end of a main body, the heat dissipation space being located at a lower end of the machine room for a flow path of hot air; A partition wall dividing the heat dissipation space up and down; A condenser fixed to an upper side of the partition wall; Located in the rear of the partition wall is characterized in that consisting of a cooling fan for forced circulation of the air at the bottom of the partition to the top of the partition wall.

Hereinafter, a preferred embodiment of a multilayer flow path structure for heat dissipation of a condenser according to the present invention will be described with reference to the accompanying drawings.

Figure 5a is a perspective view showing the heat discharge of the condenser through the multi-layer flow path structure in accordance with the present invention, Figure 5b is a side view showing the heat discharge of the condenser through the multi-layer flow path structure in Figure 5a.

Referring to these drawings, a heat dissipation space for dissipating the condenser 18 is provided on the lower side of the machine room, and a heat dissipation plate 19 for dividing the heat dissipation space up and down is installed in the center of the heat dissipation space, and the heat dissipation plate 19 The upper side of the) is fixed while the condenser is in contact with the rear of the heat dissipation plate 19 is provided with a cooling fan forcibly circulating the air at the bottom of the heat dissipation plate 19 to the top of the heat dissipation plate (19).

Looking at the heat dissipation process of the condenser using the multi-layer flow path by the above components, the heat dissipation space provided on the lower side of the machine room is divided into two up / down by the heat dissipation plate 19, the condenser on the upper side of the heat dissipation plate 19 The heat dissipation plate 19 is made of a metal plate having excellent thermal conductivity such as an iron plate, and the like. The purpose is to maximize the heat dissipation efficiency of the condenser by being able to be easily transferred to the heat dissipation plate 19 by.

As described above, relatively cold air outside the refrigerator flows into the metal heat dissipation plate 19 having excellent thermal conductivity, and the air thus absorbed heat primarily by contact with the heat dissipation plate 19. Afterwards, it is forced to be circulated by the heat radiating fan 20 located at the rear of the heat radiating plate 19, wherein the air moved to the upper layer of the heat radiating plate 19 and the air above the heat radiating plate 19 warmed by the condenser. Once in contact, the internal heat is taken away and released to the outside of the refrigerator.

Here, the inflow of outside air is made through an intake hole 13 formed at one side of the front vent cover 17 installed at the front of the heat dissipation space, and discharge of hot air from the inside of the refrigerator to the outside of the heat dissipation space. It is made through the exhaust hole 14 formed on the other side of the front vent cover 17 installed in.

As described above, the heat dissipation of the condenser using the multi-layer flow path structure of the present invention is primarily conducted from the condenser fixed in contact with the metal heat dissipation plate 19, and cold external air introduced into the lower part of the heat dissipation plate 19 is introduced. After absorbing heat by the contact with the heat radiating plate 19 is forced to circulate to the top of the heat radiating plate 19 by the heat radiating fan, and once again absorbs heat from the hot air on the top of the heat radiating plate 19, In addition to heat dissipation due to heat dissipation and forced circulation, heat dissipation efficiency is maximized by using heat dissipation due to convection.

The multi-layer flow path structure for heat dissipation of the condenser according to the present invention has the effect of sufficiently and effectively discharging high temperature air generated from the condenser of the refrigerator to the outside of the refrigerator.

1 is a view showing a schematic position of main engines of a compression refrigeration cycle in a general refrigerator.

FIG. 2A shows the noise generating element of the refrigerator actually installed in the vicinity of the wall in FIG. 1 and the adjacent interior around the machine room. FIG.

FIG. 2B shows the main organs in the machine room in FIG. 2A; FIG.

Figure 3a is a perspective view showing the heat discharge of the condenser through the machine room cover in Figure 2a.

Figure 3b is a side view showing the heat dissipation through the machine room cover in Figure 2a.

Figure 4a is a perspective view of the heat dissipation through the heat dissipation space of the lower part of the machine room according to the prior art viewed from the bottom.

Figure 4b is a side view showing the heat dissipation through the heat dissipation space in the lower part of the machine room in Figure 4a.

Figure 5a is a perspective view showing a state in which heat of the condenser is discharged through a multi-layer flow path structure according to the present invention.

FIG. 5B is a side view illustrating a state in which heat of the condenser is discharged through the multilayer flow path structure in FIG. 5A; FIG.

<Description of Symbols for Main Parts of Drawings>

1: condenser 2: cooling fan 3: evaporator

4: expansion tube 5: compressor 6: refrigerator

7: Machine Room 8: Fan Motor 9: Machine Room Cover

10 intake hole 11 exhaust hole 12 door

13 intake hole 14 exhaust hole 15 condenser

16: bulkhead 17: front vent cover 18: condenser

19: heat dissipation plate 20: heat dissipation fan

Claims (3)

compressor; A machine room provided below the refrigerator to place the compressor; A heat dissipation space formed at a lower side separated from the machine room; A heat dissipation plate having a heat dissipation space divided into upper and lower parts and a rear part to be opened; A condenser formed on the heat dissipation plate to transmit heat to the heat dissipation plate; Located in the rear of the heat dissipation space, the cooling fan for forced circulation of air from the lower portion of the heat dissipation plate to the upper portion of the heat dissipation plate; An intake hole formed at a lower side of the front portion of the heat dissipation space to allow air to flow into a lower portion of the heat dissipation plate; And And an exhaust hole formed at an upper side of the front portion of the heat dissipation space to allow air to flow through the upper portion of the heat dissipation plate. delete delete