KR20050030351A - The refrigerator for improvement on heat exchange efficiency - Google Patents

Abstract

A refrigerator improving heat exchange efficiency is provided to prevent external air sucked into a machine chamber from flowing into a compressor through a space of a rear wall of the machine chamber without completing heat exchange with a condenser, thereby improving performance of a refrigerator. A compressor, a condenser(160) and a cooling fan are sequentially installed inside a machine chamber(70) having an inner rear wall inclined at a predetermined angle. The machine chamber is hermetically sealed by a machine chamber cover(80). A rear of the condenser is formed in the same shape as the tilt angle of the rear wall of the machine chamber inside so that the inside of the machine chamber is completely filled with the condenser.

Description

Refrigerator with improved heat exchange efficiency

The present invention relates to a refrigerator, and more particularly, the outside air sucked into the inside of the machine room through the suction action of the cooling fan flows to the compressor side through the empty space of the rear wall of the inside of the conventional machine room which is inclined at a predetermined angle without achieving complete heat exchange with the condenser. In order to prevent the condenser is formed in the rear shape of the same as the rear wall inclination angle of the inside of the machine room relates to a refrigerator having improved heat exchange efficiency is configured to completely fill the inside of the machine room by the condenser.

In general, the refrigerator lowers the temperature in the refrigerator through the cold air generated by the refrigeration cycle consisting of the compressor 50, the condenser 60, the expansion valve (not shown), and the evaporator (not shown) to freeze food or the like. It is intended for refrigeration, and in particular, in the machine room 70 located at the lower rear side of the refrigerator, as shown in FIG. 1, the refrigerant evaporated from the evaporator to a low temperature low pressure gas phase is pressurized to a high temperature high pressure gas phase A condenser 60 is connected to the compressor 50 and the compressor 50 to condense the refrigerant pressurized from the compressor 50 into a liquid phase at room temperature and high pressure. The compressor 50 and the condenser 60 are provided. Machine room cover 80 is installed outside the machine room 70 to protect the refrigerator machine room 70 is installed.

Reference numeral 65 is a cooling fan 65 for cooling the compressor 50 and the condenser 60, 82 is a through hole 82 of the machine room cover (80).

On the other hand, the condenser 60 installed in the machine room 70 heats the condensation heat of the refrigerant through heat exchange with the external air introduced into the machine room 70, the structure for this is as shown in Figure 2, A bending pipe (Bending) in the form of a continuously repeated in parallel in the form of a steel pipe (bend), and then bends itself again in multiple stages, the refrigerant pipe 61 of the overall outer shape to form a rectangular parallelepiped shape; The plurality of heat dissipation fins 62 are bonded to the outer circumferential surface of the coolant tube 61 at predetermined intervals to dissipate heat of the coolant flowing along the coolant tube 61 to the outside.

At this time, the heat dissipation fin 62 has a circular cross-sectional shape, and is bonded to the outer circumferential surface of the coolant pipe 61 at predetermined intervals by spot welding.

However, in the case of the condenser 60, as described above, after bending a straight steel pipe in parallel to a continuously repeated sand-shape, and then bending itself again in multiple stages, The condenser is formed in a rectangular parallelepiped shape when the external air sucked into the machine chamber 70 by the cooling fan 65 is blown to the condenser 60 through the blowing action of the cooling fan 65. Due to the structure of 60, that is, the structure in which the coolant pipes 61 are densely arranged, the coolant flowing in the coolant pipe 61 is prevented from allowing the air blown to the condenser 60 to freely pass through the condenser 60. There was a big problem that the heat exchange with the outside air is not made smoothly.

In the case of the condenser 60, when the refrigerant pipe 61 is densely bent in multiple stages and the overall outer shape is installed in the machine room 70 in a rectangular parallelepiped structure having a predetermined volume, the internal shape of the machine room 70 is 3 is installed in a state in which the rear wall of the machine room 70, which is inclined at a predetermined angle, is excluded from the machine room 70, as shown in FIG. The empty space (A) is formed, the external air sucked into the machine room 70 during the blowing operation by the cooling fan 65 in the above state does not completely heat exchange with the condenser 60, Some of the external air flows directly into the compressor 50 through the empty space A formed on the rear wall of the machine room 70 to cool the compressor 50 and the compressor 50 and then to the outside of the machine room 70. The condensation, There was also a big problem that the heat exchange efficiency with the outside air in the plane (60) is greatly reduced.

Furthermore, the rear wall of the machine room 70 is prevented through the empty space A formed on the rear wall of the machine room 70 to prevent the external air from flowing directly to the compressor 50 without making heat exchange with the condenser 60. When the guide is installed on the rear wall of the machine room 70, a guide member for improving heat exchange efficiency of the condenser 60 is installed on the rear wall of the machine room 70. As a result, there was also a big problem that the manufacturing process and manufacturing time is increased accordingly.

In order to solve the above problems, the present invention is configured to form the rear shape of the condenser installed in the machine room equal to the rear wall inclination angle inside the machine room, so that the inside of the machine room is completely filled by the condenser, so that the suction of the cooling fan This function prevents external air sucked into the machine room from flowing directly to the compressor through the empty space of the rear wall of the inside of the machine room, which is inclined at a predetermined angle, without making a complete heat exchange with the condenser, thereby preventing the heat exchange efficiency of the condenser from being lowered. Its purpose is to.

In addition, the heat exchange efficiency of the condenser is improved through the complete heat exchange effect between the condenser installed in the machine room 70 in which the inner rear wall is inclined at a predetermined angle as described above and the outside air sucked into the machine room. Another purpose is to improve the performance (freezing and refrigeration capacity) of the refrigerator according to the improvement.

The object of the present invention can be solved by the refrigerator having improved heat exchange efficiency of the present invention configured to form a rear shape of the condenser installed in the machine room equal to the rear wall inclination angle inside the machine room so that the inside of the machine room is completely filled by the condenser. Will be described in detail below with reference to the accompanying drawings.

Figure 4 shows a schematic structural diagram of the machine room according to the present invention, Figure 5 shows a side cross-sectional view of the machine room and the condenser according to the present invention.

In the refrigerator having improved heat exchange efficiency of the present invention, a compressor 50, a condenser, a cooling fan 65, and the like are sequentially installed in a machine room 70 having an inner rear wall inclined at a predetermined angle, and the machine room cover 80 provides a machine room. In the refrigerator having a structure in which the 70 is sealed;

The rear shape of the condenser 160 is formed to be equal to the rear wall inclination angle of the inside of the machine room 70 so that the inside of the machine room 70 is completely filled by the condenser 160.

Hereinafter, the refrigerator having an improved heat exchange efficiency will be described in detail.

The refrigerator having an improved heat exchange efficiency according to the present invention includes a conventional machine room 70 in which external air sucked into the machine room 70 through a suction action of the cooling fan 65 does not form a complete heat exchange with the condenser 60 and is inclined at a predetermined angle. The heat exchange efficiency of the condenser 60 can be improved by preventing the flow of the gas directly into the compressor 50 through the empty space A of the inner rear wall and through the complete heat exchange with the external air sucked into the machine room 70. In order to be able to do so, the rear shape of the condenser 160 installed in the machine room 70 is formed to be equal to the rear wall inclination angle of the inside of the machine room 70 so that the inside of the machine room 70 is completely filled by the condenser 160. As such, the present invention will be described in detail. The same reference numerals will be applied to the same configurations as those of the present invention and the conventional art described above.

Referring to the refrigerator machine room structure to which the condenser of the present invention is applied, which is formed at the bottom of the refrigerator as shown in FIGS. 4 and 5, the machine room 70 of a predetermined space in which an inner rear wall is inclined at a predetermined angle; A compressor (50) fixed in the machine room (70) to pressurize the refrigerant evaporated from the evaporator (not shown) to a low temperature low pressure gas phase in a high temperature high pressure gas phase; A condenser (160) positioned behind the compressor (50) and condensing the refrigerant pressurized from the compressor (50) through a heat exchange with external air introduced into the machine room (70) into a liquid phase at room temperature and high pressure; A cooling fan 65 that rotates through a motor drive and allows external air to flow into the machine room 70; It consists of a machine room cover 80 fixed to the machine room 70 to protect the machine room 70 in which the compressor 50, the condenser 160, and the cooling fan 65 are installed.

At this time, the condenser 160 according to the present invention increases the heat transfer area in contact with the air to increase the heat dissipation performance, that is, heat exchange efficiency, the refrigerant pipe provided with a spiral protrusion (heat dissipation fin) 162 along the inner / outer circumferential surface of the tube It is configured by bending in multiple stages using (161), the condenser is applied to the refrigerator condenser (Application No. 10-1999-2485) structure previously filed by the applicant.

Particularly, in the case of the condenser 160, a condenser located at the rear of the condenser 160, that is, at the rear wall of the machine room 70 so as to fill the empty space A of the rear wall of the machine room 70 inclined at a predetermined angle ( The rear of the 160 is formed to be equal to the rear wall inclination angle of the inside of the machine room 70. The structure thereof will be described in more detail in front of the condenser 160, that is, the condenser located at the inlet side of the machine room 70 ( The front of the 160 is vertically up and down, but the rear of the condenser 160 is adapted to the angle of inclination of the rear wall inside the machine room 70 when bending the refrigerant pipe 161 in which the spiral protrusion (heat radiating fin) 162 is formed. As bent, the rear shape of the condenser 160 is formed in a trapezoidal shape inclined at a predetermined angle.

Next, the condensation process of heat exchange between the outside air introduced into the machine room 70 through the suction action of the cooling fan 65 and the condenser 160 installed to the rear wall of the inside of the machine room 70 will be described.

Figure 6 shows a state in which the external air introduced by the blowing fan drive is discharged to the outside of the refrigerator via the condenser of the present invention.

As shown in FIG. 6, the refrigerant pressurized in the gaseous state at high temperature and high pressure by the compressor 50 flows into the condenser 160 installed up to the rear wall of the inside of the machine room 70, and thus inside the refrigerant pipe 161 of the condenser 160. When the air flows, the outside air sucked through the through-hole 82 of the machine room cover 80 which seals the machine room 70 by the driving of the cooling fan 65 is blown through the air blow of the cooling fan 65. As it is forced convection to the entire condenser 160 installed to the rear wall inside the machine room 70 as described above, a uniform heat dissipation is performed from the entire condenser 160 through heat exchange, and thus the refrigerant is phase-changed to a liquid state at room temperature and high pressure. The following describes the process in more detail.

As described above, the external air introduced into the machine room 70 through the suction operation of the cooling fan 65 is forcedly blown to the condenser 160 installed to the rear wall of the inside of the machine room 70 through the blowing operation of the cooling fan 65. When the outer air passes through the condenser 160, a part of the outside air flows along the shape of the protrusion formed in a spiral shape on the outer circumferential surface of the refrigerant pipe 161, that is, the heat radiation fin 162, and the outer circumferential surface of the refrigerant pipe 161. Heat exchange with the refrigerant is formed in the form of enclosing the outside air, that is, the temperature of the outside air, ie, hot air, whose temperature is increased through heat exchange with the refrigerant in the condenser 160 as described above, is blown to the compressor 50 to overheat the compressor 50 and the compressor ( 50) After cooling the ambient temperature, it is discharged to the outside through the through hole 82 of the machine room cover (80).

In particular, when exchanging heat with the outside air through the condenser 160 installed to the rear wall inside the machine room 70 as described above, the outside air directly through the empty space (A) of the rear wall inside the machine room 70 as in the prior art ( Since it does not flow to 50, and heat exchanges with the entire condenser 160 installed up to the rear wall inside the machine room 70, the characteristic effect that the heat exchange efficiency of the condenser 160 is improved accordingly occurs.

In the case of the condenser 160 configured as described above, as well as a top-type refrigerator applied as an embodiment in the present invention, the refrigerator-type is located at the top and the freezer is located at the bottom. Note that the refrigerator and the freezer and the refrigerating compartment may be applied to a side by side type refrigerator located at the left / right side of the main body.

The refrigerator having improved heat exchange efficiency according to the present invention forms a rear shape of the condenser installed in the machine room in the same manner as the rear wall inclination angle inside the machine room, so that the inside of the machine room is completely filled by the condenser, and the machine room is sucked by the cooling fan. The external air sucked into the inside flows directly to the compressor through the empty space of the rear wall of the inside of the conventional machine room which is inclined at a predetermined angle without being completely heat exchanged with the condenser, thereby preventing the deterioration of the heat exchange efficiency of the condenser. .

In addition, the heat exchange efficiency of the condenser is improved through the complete heat exchange effect between the condenser installed in the machine room in which the inner rear wall is inclined at a predetermined angle and the outside air sucked into the machine room, and the heat exchange efficiency of the condenser is improved. Refrigerator performance (freezing and refrigeration) also has an excellent effect that can be improved.

1 is a partial cross-sectional view showing a machine room structure of a conventional refrigerator.

2 is a perspective view of a condenser installed in a conventional refrigerator machine room.

3 is a side cross-sectional view of a machine room in which a conventional condenser is installed.

4 is a schematic structural diagram of a machine room according to the present invention;

5 is a side cross-sectional view of a machine room and condenser in accordance with the present invention.

6 is a state in which the external air introduced by the blowing fan drive is discharged to the outside of the refrigerator via the condenser of the present invention.

Explanation of symbols on the main parts of the drawings

50. Compressor 60, 160. Condenser

61, 161. Refrigerant line 62, 162. Heat dissipation fin

65. Cooling fan 70. Machine room

80. Machine room cover A. Empty space in back wall of machine room

Claims (2)

A refrigerator having a structure in which a compressor, a condenser, a cooling fan, and the like are sequentially installed in a machine room in which an inner rear wall is inclined at a predetermined angle, and the machine room is closed by a machine room cover; And a rear shape of the condenser is formed to be equal to a rear wall inclination angle of the inside of the machine room so that the inside of the machine room is completely filled by the condenser. The heat exchanger according to claim 1, wherein the condenser is formed in the same shape as the inside of the machine room by using a screw refrigerant pipe in which a heat dissipation fin is formed in a screw shape on the outer circumferential surface of the tube so as to increase the heat transfer area in contact with air, thereby improving heat exchange efficiency. Refrigerator with improved efficiency.