KR100493697B1 - The refrigerator for improvement on heat exchange efficiency - Google Patents

Abstract

The present invention relates to a refrigerator having improved heat exchange efficiency, wherein the first condenser and the second condenser using a screw refrigerant pipe constituting the heat exchanger of the screw heat exchanger formed to increase heat transfer area in contact with air to improve heat exchange efficiency. By forming a cooling fan between the first condenser and the second condenser, by the continuous forced convection from the second condenser to the first condenser by the external air due to forced suction and forced air of the cooling fan There is an excellent effect that can maximize the heat transfer efficiency by maximizing the heat dissipation performance of the condenser, such as to uniformly radiate heat from the entire condenser.

In addition, by installing the first condenser and the second condenser in a form in which the flow direction of the external air introduced into the machine room by the cooling fan and the longitudinal direction of the screw refrigerant pipe are perpendicular to each other, the flow of the external air (blowing) The space and the direction of the length of the refrigerant pipe can be significantly reduced compared to the conventional condenser that was installed in the same direction, there is also an excellent effect that can use the reduced condenser space as the interior space (volume) of the refrigerator as described above.

Description

Refrigerator with improved heat exchange efficiency

The present invention relates to a refrigerator, and more particularly, a first condenser and a second condenser using a screw refrigerant pipe constituting the heat exchanger of the screw heat exchanger formed to increase heat transfer area in contact with air to improve heat exchange efficiency. And by installing a cooling fan between the first condenser and the second condenser, the forced air convection is continuously performed from the second condenser to the first condenser by the external air caused by forced suction and forced blowing of the cooling fan. The present invention relates to a refrigerator having improved heat exchange efficiency to maximize heat transfer efficiency by maximizing heat dissipation performance of the condenser, such as to uniformly radiate heat from the entire 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 bent coolant tube 61 is densely arranged, the air blown toward the condenser 60 does not freely pass through the condenser 60 and flows through the coolant tube 61. Heat exchange between the refrigerant and the outside air is not performed smoothly.

In more detail, the external air blown to the condenser 60 by the blowing action of the cooling fan 65 may pass through the refrigerant pipe 61 located in the front portion of the condenser 60. When a large amount of external air flows to improve the heat transfer efficiency through a smooth heat exchange with the refrigerant, when the external air passes through the refrigerant pipe 61 located in the middle of the condenser 60, the condenser 60 Since the refrigerant pipe 61 constituting the () is densely arranged, the flow resistance of the outside air is generated on the condenser 60, less than when passing through the first row of the condenser 60 As the outside air flows, the heat transfer efficiency through heat exchange with the refrigerant is reduced.

Furthermore, when the external air reaches the refrigerant pipe 61 located at the rear portion of the condenser 60, the condenser 60 has a larger flow resistance of the external air due to the densely arranged condenser 60 structure. The heat transfer efficiency in the rear portion of the condenser 60 is reduced by the amount of heat exchange with the refrigerant in an amount less than the amount of external air passing through the middle portion of the condenser 60. There was a big problem, such as to be reduced more than the middle and middle).

In the case of the condenser 60, the refrigerant pipe 61 is densely bent in multiple stages, and the overall outline is formed into a rectangular parallelepiped shape having a certain volume. In particular, the condenser 60 formed as described above is a machine room 70. Since a large amount of space is occupied in the system, the internal space of the machine room 70 is reduced by the size of the space of the condenser 60, and the compressor 50 and the cooling fan 65 together with the condenser 60 are reduced. In order to install in the machine room 70, there was a big problem such as the need to enlarge the internal space of the machine room 70.

In addition, when the internal space of the machine room 70 is enlarged in order to install the condenser 60 and the compressor 50, the cooling fan 65, etc., which are formed in a rectangular parallelepiped shape having a predetermined volume as described above, the enlarged machine room ( There was also a big problem that the internal space (volume) of the refrigerator cannot be utilized as much as the space size of 70).

The present invention has been made in order to solve the above problems, the first condenser and the second using a screw refrigerant pipe constituting the heat exchanger of the screw heat exchanger formed to increase the heat transfer area in contact with air to improve the heat exchange efficiency By forming a condenser and installing a cooling fan between the first condenser and the second condenser, continuous air convection from the second condenser to the first condenser is performed by external air caused by forced suction and forced blowing of the cooling fan. The purpose of the present invention is to maximize heat dissipation performance of the condenser by maximizing heat dissipation from the entire condenser while being made.

Further, the first condenser and the second condenser are installed in such a manner that the flow direction of the external air introduced into the machine room by the cooling fan and the longitudinal direction of the refrigerant pipe are perpendicular to each other, thereby the flow direction of the external air. And the space direction of the refrigerant pipe can be significantly reduced compared to the conventional condenser installed in the same direction, and there is another purpose to utilize the reduced condenser space as the interior space (volume) of the refrigerator as described above. .

The object of the present invention is to form a first condenser and a second condenser using a screw refrigerant pipe formed with a heat sink fin in the form of a screw on the outer peripheral surface of the tube type heat exchanger, and between the first condenser and the second condenser The bar can be solved by the improved heat exchange efficiency of the installation of the present invention will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view showing a planar state of a refrigerator machine room to which the condenser of the present invention is applied, and FIG. 4 is a perspective view and a detailed view of the condenser according to the present invention.

The refrigerator having an improved heat exchange efficiency according to the present invention includes a compressor in which a compressor 50, a condenser, a cooling fan, and the like are sequentially installed in a machine room 70, and the machine room 70 is sealed by a machine room cover 80. To;

The first condenser 160 and the second condenser 160a are formed using a screw refrigerant pipe 161 having a heat dissipation fin 162 formed in a screw shape on the outer circumferential surface of the tube to increase heat transfer area in contact with air, thereby improving heat exchange efficiency. A cooling fan 165 is installed between the first condenser 160 and the second condenser 160a so that external air caused by forced suction and forced blowing of the cooling fan 165 is discharged from the second condenser 160a. The first condenser 160 is configured to continuously perform forced convection.

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 is a conventional condenser in which the heat transfer efficiency of the conventional condenser 60 formed to have a rectangular parallelepiped shape of a predetermined volume by bending the refrigerant pipe 61 in multiple stages, that is, the heat exchange with the external air is smooth. To prevent heat transfer efficiency in the middle portion or the rear portion compared to the front portion of the (60), as well as to ensure a uniform heat dissipation from the entire condenser 160 to maximize the heat transfer efficiency In order to form a first condenser 160 and a second condenser 160a using a screw refrigerant pipe 161 having a heat dissipation fin 162 formed in a screw shape on the outer circumferential surface of the tube, the first condenser 160 and the second condenser are formed. Cooling fan 165 is installed between the 160a to allow forced air convection from the second condenser 160a to the first condenser 160 due to forced suction and forced blowing of the cooling fan 165. As will be made, 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, as shown in Figs. 3 and 4, the machine room 70 of a predetermined space formed at the bottom of the refrigerator; A compressor (50) fixed in the machine room (70) for pressurizing the refrigerant evaporated from the evaporator to a low temperature low pressure gas phase in a high temperature high pressure gas phase; A first condenser (160) and a second condenser (160a) for condensing the refrigerant pressurized from the compressor (50) through a heat exchange with external air introduced into the machine room (70) in a liquid state at room temperature and high pressure; It is installed between the first condenser 160 and the second condenser 160a, and is forced to convection external air to the second condenser 160a and the first condenser 160 through the suction and blowing action while being rotated by the motor drive. Cooling fan 165 to be; 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 first condenser 160, the cooling fan 165, and the second condenser 160a are installed. It is.

The first condenser 160 and the second condenser 160a have a heat exchanger fin formed on the outer circumferential surface of the refrigerant pipe 161 in the form of a screw in order to increase the heat transfer area in contact with air to improve heat exchange efficiency. (Utility Model Registration No. 20-228935), the screw-type heat exchanger, as shown in Figure 4, the heat dissipation fin 162 on the outer circumferential surface of the refrigerant pipe is formed in the screw refrigerant pipe 161 in the form of a screw It is formed in a rectangular parallelepiped shape of a certain volume bent in multiple stages, in particular, the screw refrigerant pipe 161 after cutting a portion of the pipe to be inclined, and then set up the heat radiation fin 162 larger than the outer diameter of the refrigerant pipe 161. The heat dissipation fin 162 is integrally protruded from the outer circumferential surface of the refrigerant pipe 161, and the heat dissipation fin 162 is formed in a continuous spiral shape.

As described above, the heat dissipation fin 162 is formed in a continuous spiral shape on the outer circumferential surface of the refrigerant pipe 161, and thus the heat exchange efficiency is greatly increased.

In the case of the first condenser 160 and the second condenser 160a of the present invention to which the screw heat exchanger is applied as described above, the refrigerant pressurized by the high temperature and high pressure from the compressor 50 is passed through the first condenser 160 through the second condenser 160. While flowing to the condenser (160a) is connected to a single condenser state through the connecting pipe 164 to achieve heat exchange with the external air introduced into the machine room 70 by the operation of the cooling fan 165.

At this time, the first condenser 160 and the second condenser 160a are formed in the same structure, which is a heat dissipation fin 162 on the outer circumferential surface of the tube formed in a continuous spiral form of the heat of the refrigerant flowing along the tube Screw refrigerant pipe 161 made to radiate heat to the outside; In order to prevent the flow of the screw refrigerant pipe 161 is composed of a bracket 163 fixed to both ends of the screw refrigerant pipe 161.

In addition, in the case of the first condenser 160 and the second condenser 160a, the external air introduced through the through-hole 82 of the machine room cover 80 that seals the machine room 70, the cooling fan 165 Forced suction and forced blowing of the air) uniformly radiates heat from the first and second condensers 160 and 160a while continuously forced convection from the second condenser 160a to the first condenser 160. In order to improve the heat dissipation performance of the cooling fan 165 is installed in a form perpendicular to the flow (air blowing) direction of the external air introduced into the machine room 70 and the longitudinal direction of the screw refrigerant pipe 161. In particular, when the first and second condensers 160 and 160a are installed in such a manner that the longitudinal direction of the flow (blowing) direction of the external air and the length of the refrigerant pipe 161 are perpendicular to each other, the flow (blowing) direction of the external air is provided. Compared with the conventional condenser 60 in which the longitudinal direction of the refrigerant pipe 161 is installed in the same direction. Along with the feature that the space is greatly reduced, the reduced condenser 160, 160a space as described above may be utilized as the internal space (volume) of the refrigerator.

In particular, in the case of the first condenser 160 and the second condenser 160a of the condenser structure of the present invention, the outside air sucked by the driving of the cooling fan 65 as in the conventional condenser 60 through the cooling fan 65 The external air sucked into the machine chamber 70 by the driving of the cooling fan 165 is not a method of mutual heat exchange with the refrigerant flowing in the external air and the condenser 60 while being forced to the side of the cooling fan 165. Forced convection by the forced suction is performed in the second condenser 160a through suction and blowing action of), and forced convection by the forced blow in the first condenser 160 while the first and second After the heat exchange with the refrigerant in the condenser (160) (160a), the first condenser (160) and the second condenser (160a) so that the heat exchanged to the outside of the machine room 70 through the compressor (50) is discharged The cooling fan 165 is provided in between.

In addition, when manufacturing the first and second condenser 160, 160a of the present invention using the screw refrigerant pipe 161, heat exchange efficiency by the screw refrigerant pipe 161 itself according to the increase in the heat transfer area in contact with air According to this improved characteristic, the conventional condenser 60 may be manufactured to about 60% of the length of the refrigerant pipe 61 constituting the condenser 60, thereby reducing the manufacturing costs of the condenser 160, 160a and the refrigerator.

Subsequently, the external air introduced into the machine room 70 by the driving of the cooling fan 165 installed between the first condenser 160 and the second condenser 160a causes suction and blowing of the cooling fan 165. The condensation process of exchanging heat with the refrigerant in the condenser 160 and 160a while being forced convection to the first and second condenser 160 and 160a will be described below.

Figure 5 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. 5, the first condenser of the first condenser 160 and the second condenser 160a interconnected with the refrigerant pressurized in a gaseous state of high temperature and high pressure in the compressor 50 through a connecting pipe 164. When flowing into the 160 and flowing inside the screw refrigerant pipe 161 of the first condenser 160 and the second condenser 160a, it is installed between the first condenser 160 and the second condenser 160a Forced convection by forced suction is performed in the second condenser 160a through the suction and blowing of the external air introduced into the machine room 70 by driving the cooling fan 165. In the first condenser 160 is forced convection by the forced blowing, and uniformly from the first and second condenser 160, 160a through heat exchange with the refrigerant in the first and second condenser 160, 160a. As the heat dissipation takes place, the refrigerant forms a phase change to a liquid state at room temperature and high pressure. Referring to the process for more detail as follows.

First, when the outside air introduced into the machine room 70 through the driving of the cooling fan 165 passes through the second condenser 160a by the forced suction force of the cooling fan 165 as described above, some air is A screw coolant tube 161 of the second condenser 160a, that is, the outer circumferential surface of the screw coolant tube 161 while flowing along the shape of the heat dissipation fin 162 continuously formed in a spiral form on the outer circumferential surface of the coolant tube 161 Heat exchange with the refrigerant in a wrapping form, and at the same time the external air heat exchanged with the second condenser (160a) as described above is interconnected with the second condenser (160a) through the forced blowing force of the cooling fan (165) 1 is forcedly blown to the condenser 160, which is also part of the outer air blown to the first condenser 160 is the same process as the above-described flow of the air, that is to be continuous in a spiral form on the outer peripheral surface of the refrigerant pipe 161 Along the shape of the formed heat radiation fins 162 While the heat exchange with the refrigerant in the form of surrounding the outer circumferential surface of the screw refrigerant pipe 161, such as a uniform heat dissipation effect is made from the first, second condenser 160, 160a, thereby condenser 160 The heat transfer efficiency in the 160a may be maximized.

On the other hand, in the case of hot air whose temperature is increased through heat exchange with the refrigerant while passing through the second condenser 160a and the first condenser 160 as described above, the air is blown by the cooling fan 165 toward the compressor 50. After cooling and cooling the surrounding temperature of the compressor 50 and the compressor 50, the air is discharged to the outside through the through hole 82 of the machine room cover 80.

In the case of the condenser 160, 160a configured as described above, not only the top-type refrigerator applied as an embodiment of the present invention, but also a bottom type in which a refrigerating chamber is located at the top and a freezing chamber is at the bottom. -Type refrigerators and freezers and refrigerators can also be applied to side by side-type refrigerators located on the left and right sides of the main body.

In the refrigerator having an improved heat exchange efficiency, the first condenser and the second condenser are formed by using a screw refrigerant pipe constituting the heat exchanger among the screw heat exchangers formed to increase the heat transfer area in contact with air to improve the heat exchange efficiency. By installing a cooling fan between the first condenser and the second condenser, by the continuous forced convection from the second condenser to the first condenser by the external air due to forced suction and forced air of the cooling fan as a whole condenser The heat dissipation performance of the condenser is maximized by maximizing the heat dissipation performance of the condenser.

In addition, by installing the first condenser and the second condenser in a form in which the flow direction of the external air introduced into the machine room by the cooling fan and the longitudinal direction of the screw refrigerant pipe are perpendicular to each other, the flow of the external air (blowing) The space and the direction of the length of the refrigerant pipe can be significantly reduced compared to the conventional condenser that was installed in the same direction, there is also an excellent effect that can use the reduced condenser space as the interior space (volume) of the refrigerator as described above.

In addition, when manufacturing the first and second condensers of the present invention by using the screw refrigerant pipe, according to the characteristic that the heat exchange efficiency is improved by the screw refrigerant pipe itself in accordance with the increase in the heat transfer area in contact with air, It can be produced about 60% of the length of the refrigerant pipe, there is also an excellent effect to reduce the manufacturing cost of the condenser and the refrigerator accordingly.

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 cross-sectional view showing a planar state of a refrigerator machine room to which the condenser of the present invention is applied.

4 is a perspective view and a detailed view of the condenser according to the invention.

5 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 main parts of drawing

50. Compressor 60. Condenser

61. Refrigerant line 62. Heat sink fin

65, 165.Cooling fan 70. Machine room

80. Machine room cover 160. First condenser

160a. Second condenser 161. Screw refrigerant tube

162. Heat Sink Fins 163. Bracket

164. Connector

Claims (3)

A refrigerator comprising a compressor, a condenser, a cooling fan, and the like sequentially installed in a machine room, and the machine room is sealed by a machine room cover; The first condenser and the second condenser are formed by using a screw refrigerant pipe in which the heat dissipation fin is formed in the form of a screw on the outer circumferential surface of the tube to increase the heat transfer area in contact with the air, and to cool the space between the first condenser and the second condenser. And a fan installed so that external air caused by forced suction and forced blowing of the cooling fan is continuously forced convection from the second condenser to the first condenser. The refrigerator of claim 1, wherein the first condenser and the second condenser are interconnected through a connecting pipe. The method of claim 1, wherein the first condenser and the second condenser are installed in such a manner that the direction of flow (blowing) of external air introduced into the machine room by the cooling fan and the longitudinal direction of the screw refrigerant pipe are perpendicular to each other. Refrigerator with improved heat exchange efficiency.