KR20010080791A - Air flow structure in machine room for refrigerator - Google Patents

Abstract

PURPOSE: An air flow structure is provided to achieve an improved operating efficiency of refrigerator by allowing smooth air flow in the machinery chamber and effectively releasing the heat generated from the compressor and condenser. CONSTITUTION: An air flow structure comprises a machinery chamber(30) where a variety of components for driving the refrigerator are installed; a blower fan(36) installed inside of the machinery chamber, and which radiates heat from the machinery chamber; and a rear cover(40) having an air inlet opening(43) and an air outlet opening(45) for air flow throughout the machinery chamber, and which protects the machinery chamber from outside. The rear cover has a recessed portion(42) which is formed by recessing the rear cover toward the machinery chamber, and the air inlet opening of the rear cover is formed at the recessed portion. The distance between the machinery chamber and the air inlet opening of the rear cover is reduced due to the recessed portion, heat radiation is performed in an effective manner.

Description

Air flow structure in machine room for refrigerator

The present invention relates to a refrigerator, and more particularly, to a machine room air flow structure of a refrigerator for producing an air flow for heat dissipation of components installed inside the machine room of the refrigerator.

1 is a plan view showing a machine room of a conventional refrigerator. According to this, the machine room 3 is formed at the rear of the lower end of the refrigerator body 1.

The machine room 3 is provided with components constituting the refrigeration cycle of the refrigerator. That is, a compressor 4 is provided at one side of the machine room 3 to compress the refrigerant into a high pressure liquid state.

In addition, a condenser 5 for dissipating heat of a refrigerant that has become relatively high by heat exchange in an evaporator (not shown) is installed at one side of the compressor 4. In addition, although not shown in the drawings, a defrost container for collecting the defrost water generated in the evaporator is also installed in the machine room. In general, the defrost container is installed at the bottom of the machine room corresponding to the lower part of the condenser (5).

On the other hand, a blowing fan 6 for dissipating heat generated from the components installed in the machine room 3 is installed on one side of the machine room 3 to be driven by the air circulation motor 7.

In addition, a rear cover 10 for protecting the parts by blocking the parts installed in the machine room 3 from the outside is installed on the back of the machine room (3). The rear cover 10 has an air inlet 11 for sucking outside air by driving the blower fan 6 at one end of the rear cover 10 corresponding to the position of the blower fan 6. Is formed.

In addition, an air discharge port 12 is formed in the rear cover 10 through which air, which flows inside the machine room 3 and absorbs heat emitted from the parts, is discharged to the outside of the machine room 3. The air outlet 12 is formed on the rear cover 10 on the opposite side where the air inlet 11 is formed.

At this time, the portion of the air inlet 11 and the air outlet 12 is bent inclined to form a predetermined gap between the refrigerator main body 1 and the adjacent wall surface (W) to intake and discharge the air To be done.

In the prior art having such a configuration, when the refrigeration cycle is operated to generate cold air, the compressor 3 is driven to generate a lot of heat, and the condenser 5 releases heat from the refrigerant.

In order to discharge the heat generated as described above, the air circulation motor 7 is driven. That is, when the blowing fan 6 is rotated by the air circulation motor 7, outside air is sucked through the air inlet 11 of the rear cover 10, as indicated by the arrow in FIG. . The air sucked in this way receives heat generated by the condenser 5 and the compressor 3 in order, and is transferred to the outside of the machine room 3 through the air discharge port 12.

However, the prior art as described above has the following problems.

That is, when the refrigerator main body 1 is installed in close contact with the wall surface (W) as shown in FIG. 1, the rear cover (10) is covered on the wall surface (W) so that the air inlet (11) and the air outlet ( 12) is less exposed to the outside air flow into the machine room 3 is not smooth, in particular the condensation capacity of the condenser 5 is lowered, the operating efficiency of the refrigerator is reduced.

In the related art, when the flow path from the air inlet 11 to the condenser 5 is relatively long, the flow resistance becomes large, and when the blower fan 6 is not operated, external air is transferred to the condenser 5. There is also a problem that the heat exchange efficiency is relatively low since it is not easy to be.

In such a state, in order to smoothly discharge the heat from the condenser 5 to the outside, there is a method of increasing the rotation speed of the air circulation motor 7, in which case the noise in the air circulation motor 7 This occurs a lot, the load of the blower fan 6 is increased, too, a lot of noise is generated.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, and to make the air flow into and out of the machine room of the refrigerator more smoothly.

Another object of the present invention is to minimize the noise generated in the machine room of the refrigerator.

1 is a plan view showing a machine room air flow structure of a refrigerator according to the prior art.

Figure 2 is a plan view showing a machine room air flow structure of the refrigerator according to the present invention.

Explanation of symbols on the main parts of the drawings

20: refrigerator body 30: machine room

34: compressor 35: condenser

36: blower fan 37: air circulation motor

40: back cover 42: depression

43: air inlet 45: air outlet

W: wall panel

According to a feature of the present invention for achieving the object as described above, the present invention provides a machine room in which various parts for driving a refrigerator are installed, and a blower fan installed in the machine room to form an air flow for radiating heat inside the machine room. And a rear cover having an assembly and an air flow port for distributing air into and out of the machine room, and shielding the machine room from the outside, wherein the air flow port recesses an end of the back cover to be adjacent to a heat source. To form.

The air outlet is formed in the entire recessed portion of the rear cover to face each other with the wall behind the refrigerator.

According to the airflow structure of the machine room of the refrigerator according to the present invention having such a configuration, the air inlet is formed to be adjacent to the heating source inside the refrigerator machine room, so that the air inflow into the inside is more smooth, and even if the refrigerator is closely attached to the wall, the inside and outside of the machine room are installed. The air flow to the furnace can be smoothly increased efficiency of the refrigeration cycle, there is an advantage that can minimize the noise and vibration of the refrigerator because a large load is not applied to the blower fan assembly.

Hereinafter, a preferred embodiment of a machine room air flow structure of a refrigerator according to the present invention as described above will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2, the machine room 30 is formed at the rear of the lower end of the refrigerator body 10. Various parts for the operation of the refrigerator are installed in the machine room 30.

First, a compressor 34 is installed at one side of the machine room 30 to compress a relatively low pressure refrigerant into a high pressure liquid refrigerant. In addition, a condenser 35 for dissipating heat from a refrigerant having a relatively high temperature by heat exchange with cold in an evaporator is installed side by side on the compressor 34.

Next, a blower fan 36 for discharging heat generated from the compressor 34 and the condenser 35 to the outside by transferring external air to the compressor 34 and the condenser 35 is an air circulation motor 37. It is installed to be driven by.

And a rear cover 40 is installed on the back of the machine room 30, which shields the inside and the outside of the machine room 30, the compressor 34, the condenser 35 and the blower fan 36 installed inside the machine room 30 To protect parts, etc.).

One side of the rear cover 40 forms a depression 42 recessed toward the inside of the machine room 30, as shown in FIG. In the recess 42, an air inlet 43 for sucking outside air into the machine room 30 is perforated. The air inlet 43 may have various shapes such as a circular hole or a slot. Such a depression 42 is formed to extend to a position adjacent to the condenser 35 which is a heat generating source in the inside of the machine room 30.

In addition, an air outlet 45 is formed at a portion of the rear cover 40 corresponding to the opposite side of the air inlet 43. The air discharge port 45 is a portion for discharging the air circulated in the machine room 30 to the outside. Such an air discharge port 45 may also be formed by forming a depression like the air inlet 43.

The operation of the machine room air flow structure of the refrigerator according to the present invention having such a configuration will be described in detail.

When the refrigerator is operated, a refrigeration cycle is operated to generate cold air. Accordingly, the compressor 34 performs a compression process of the refrigerant. In the operation of the compressor 34, a large amount of heat is generated in the compressor 34. In the condenser 35, since the heat of the refrigerant, which becomes relatively high in heat exchange with cold, is released, a lot of heat is generated.

The blower fan 36 is used to discharge heat generated as described above to the outside. That is, when the blower fan 36 is operated by driving the air circulation motor 37, outside air is introduced into the machine room 30 through the air inlet 43 of the rear cover 40.

At this time, the air inlet 43 is formed in the depression 42 of the rear cover 40, even if the rear surface of the refrigerator main body 20 is installed in close contact with the wall surface (W), the wall surface (W) It will not be blocked directly. Therefore, the air intake amount per unit time that can suck the air inlet 43 can be obtained a predetermined value or more, regardless of the installation state of the refrigerator main body 20.

On the other hand, the air sucked through the air inlet 43 is passed through the condenser 35 and the compressor 34 receives the heat generated from them. And it is discharged to the outside of the machine room 30 through the air discharge port 45 formed in the rear cover 40.

Here, even when the blower fan 36 is not operated, since the air inlet 43 is formed in the entire depression 42 formed by recessing toward the condenser 35, the outside of the condenser 35 and the machine room 30. Since the distance between them is close, heat release by natural convection can be achieved.

According to the machine room air flow structure of the refrigerator according to the present invention as described above in detail, a portion of the air inlet formed in the rear cover is formed by recessing the inside of the machine room so that external air can be introduced into the machine room. The air inlet portion is not blocked by the wall even when installed in close contact with the wall.

Therefore, regardless of the distance between the refrigerator body and the wall surface through the air inlet can be introduced into the machine room more than a certain amount of outside air. In this case, since the air flow inside the machine room is smooth, the heat generated from the compressor and the condenser can be effectively released, and thus the efficiency of the refrigerator can be expected to be improved.

In addition, the flow path from the air inlet to the heat generating source becomes relatively short, and the flow resistance becomes smaller as a whole, so that the air flow for heat dissipation is more smoothly performed.

Claims (2)

A machine room in which various parts for driving a refrigerator are installed, A blowing fan assembly installed inside the machine room and forming an air flow for radiating heat inside the machine room; It is configured to include a rear cover for shielding the machine room from the outside having an air flow port for distributing air to the inside and outside of the machine room, The air flow port is a machine room air flow structure of the refrigerator, characterized in that formed by recessing the end portion of the rear cover to be adjacent to the heat source. 2. The machine room airflow structure according to claim 1, wherein the air outlet is formed in the entire recessed portion of the rear cover so as to face the wall behind the refrigerator.