KR20020052606A - Condenser of refrigerator - Google Patents

Abstract

PURPOSE: A condenser for refrigerator is provided to make manufacturing process easier and to improve efficiency of condensing refrigerant. CONSTITUTION: A condenser(50) includes a plurality of heat exchanging fins(52) made of aluminum, laminated, arranged in rows and having penetrating holes(53), around which burrs(54) are formed to be closed, attached on a periphery of a refrigerant pipe(51) formed thereon; and the refrigerant pipe made of fine and long aluminum pipe whose inner diameter is 4.5-7.0mm, penetrating the heat exchange fins through the penetrating holes and is bent at regular intervals so that the heat exchange fins form groups and is layered on each other.

Description

Condenser for refrigerator

The present invention relates to a condenser for a refrigerator, and more particularly, to a condenser for a refrigerator, which is mounted in a machine room of a refrigerator and condenses a high temperature, high pressure refrigerant discharged from a compressor.

In general, a condenser for a refrigerator is disposed between a compressor and an expansion device forming a refrigeration cycle, and is a device that condenses the refrigerant discharged at a high temperature and high pressure from the compressor to the expansion device.

A conventional refrigerator condenser having such a function is mounted in a machine room formed under the cabinet of the refrigerator. As shown in FIG. 1, a refrigerant tube 1 having a predetermined length bent several times in a “U” shape and a refrigerant tube ( 1) A plurality of wire pins 2 arranged in parallel on the outside are provided.

One end 1a of the refrigerant pipe 1 is connected to an outlet end (not shown) of the compressor, and the other end 1b is connected to an expansion mechanism (not shown).

The wire fins 2 are a kind of heat exchange fins arranged in the refrigerant pipe 1 to form a plurality of layers. That is, each wire pin (2) is made of thin wire, usually about 1.6mm in diameter, is mounted through the welding means perpendicular to the direction of the refrigerant pipe (1) while maintaining a constant distance from the neighboring ones.

However, in such a conventional refrigerator condenser, the wire pins 2 are made of wire, so that corrosion is easily progressed, and a high cost coating process is required to prevent this.

In addition, by connecting the wire pin (2) made of wire to the refrigerant pipe (1) through the welding means one by one, there is a problem that the work process is difficult and the manufacturing cost due to this also increases.

The present invention is to solve this problem, an object of the present invention is to improve the structure of the refrigerant pipe and the heat exchange fin disposed therein to facilitate the manufacturing process, and to provide a condenser for a refrigerator that can improve the refrigerant condensation efficiency. It is.

1 schematically shows a condenser for a conventional refrigerator.

Figure 2 shows the machine room structure of the refrigerator to which the present invention is applied.

3 is a perspective view showing an extract of a condenser for a refrigerator according to the present invention.

Figure 4 is a block diagram showing a manufacturing step of the condenser for a refrigerator according to the present invention.

* Description of symbols on the main parts of the drawings *

Machine room 20. Compressor

50. Condenser 51. Refrigerant line

52. Heat exchange pin 53. Through hole

54..Bur

The present invention for achieving this object is;

In the refrigerator condenser mounted in the machine room of the refrigerator,

A plurality of heat exchanger fins are arranged in parallel and the through-holes perforated, and through the through-holes through the heat exchanger fins and bent at regular intervals, the heat exchanger fins as a group characterized in that it comprises a refrigerant pipe to arrange the layer Configuration.

In addition, the heat exchange fin is made of a thin aluminum plate, the refrigerant pipe is a configuration characterized in that made of an elongated aluminum tube having an inner diameter of 4.5 to 7.0mm.

In addition, the periphery of the through-hole of the heat exchange fin is characterized in that the bur is formed in close contact with the outer circumference of the refrigerant pipe.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings. 2 briefly illustrates the structure of a machine room of a refrigerator to which the present invention is applied, and FIGS. 3 and 4 schematically show a condenser for a refrigerator and a manufacturing step thereof according to the present invention.

Referring to FIG. 2, the refrigerator to which the present invention is applied is provided with a machine room 11 behind the cabinet 10 on the enclosure, and includes a refrigeration cycle such as a compressor 20, a condenser 50, and a cooling fan 30. Urea and various electrical appliances are installed.

The compressor 20 serves to compress and compress the refrigerant which has been evaporated in the evaporator (not shown) disposed in the storage compartment to a high temperature and high pressure state, and the condenser 50 is discharged from the compressor 20. It condenses the refrigerant at a high temperature and high pressure to serve as an expansion mechanism (not shown). In addition, the cooling fan 30 is disposed between the compressor 20 and the condenser 50, and sucks external air to condense the condenser 50 and simultaneously cools the compressor 20. Unexplained reference numeral 40 denotes a machine room cover covering the machine room 11 opening.

Condenser 50 according to the present invention of the refrigeration cycle components as shown in Figure 3, the heat exchange fin 52 is composed of a kind of split fin type heat exchanger consisting of a plurality of thin plates.

That is, the condenser 50 for a refrigerator according to the present invention is disposed in parallel and is bent such that heat is passed through a plurality of heat exchange fins 52 made of rectangular thin plates and a plurality of heat exchange fins 52 are arranged in layers. A coolant pipe 51 is provided.

The thin plate heat exchange fins 52 are divided into a plurality of groups and arranged in a layered layer, and their pin pitches are uniformly arranged. In addition, three through-holes 53 are formed in the heat exchange fins 52 so as to pass through the coolant tube 51, and are spaced a predetermined distance apart, and the burrs 54 and Burr are formed in the periphery of the through-holes 53 through burring. ) Is provided. The burrs 54 are in surface contact with the outer circumference of the refrigerant pipe 51 passing through the through hole 53 to further improve the condensation efficiency.

And the refrigerant pipe 51 extending in a predetermined length is inserted in the through-hole 53 of the heat exchange fin 52 is arranged in parallel to form a plurality of rows. At this time, if the inner diameter of the refrigerant pipe 51 is larger than 7 mm, the volume inside the refrigerant pipe 51 increases, and there is a possibility that a part of the refrigerant pipe 51 will evaporate in the process of condensing the refrigerant at a high temperature and high pressure. Therefore, in order to prevent such a phenomenon, it is preferable to use an inner diameter of the refrigerant pipe 51 of 4.5 mm to 7.0 mm. In this embodiment, an inner diameter of the refrigerant pipe 51 is used of 4.8 mm. In addition, one end 51a of the refrigerant pipe 51 is connected to the compressor 20, and the other end 51b thereof is connected to an expansion mechanism (not shown).

A method of manufacturing a condenser for a refrigerator using the refrigerant pipe 51 and the heat exchange fins 52 will be described with reference to FIGS. 3 and 4 as follows.

The method of manufacturing a condenser for a refrigerator according to the present invention includes a preparation step (S1) of preparing a refrigerant pipe (51) and a heat exchange fin (52), and a heat exchange fin by inserting a refrigerant pipe (51) into a plurality of heat exchange fins (52). Heat exchange fin arrangement step (S2) for arranging (52) in a plurality of groups, refrigerant pipe expansion step (S3) for expanding the refrigerant pipe 51 inserted into the heat exchange fin (52), and arranged in parallel in a plurality of groups And a refrigerant pipe bending step (S4) of bending the refrigerant pipe 51 such that the heat exchange fins 52 form a layer.

In the preparation step (S1), a plurality of heat exchange fins 52 made of a refrigerant pipe 51 extending to a predetermined length and a rectangular aluminum sheet and having a through hole 53 are prepared. At this time, the coolant tube 51 is prepared as an aluminum elongate tube having an inner diameter of 4.8 mm. In addition, the through-hole 53 is drilled in the heat exchange fin 52 so that the refrigerant pipe 51 before expansion can be inserted in a relaxed manner, and the periphery of the through-hole 53 is formed by a burring process. To form.

The heat exchange fin arrangement step S2 is to pre-assemble the heat exchange fins 52 and the refrigerant pipe 51 provided in the preparation step S1 to arrange the heat exchange fins 52 into a plurality of groups. That is, after the heat exchange fins 52 are arranged in parallel to form a plurality of groups by using a jig device (not shown), the elongated refrigerant pipe 51 is inserted to penetrate the through hole 53. At this time, the heat exchange fins 52 are preferably arranged closely at intervals such that they are not blocked by dust and the like, and the heat exchange fins 52 are arranged such that a predetermined interval is maintained between the groups.

In addition, the refrigerant pipe expansion step (S3) is an expansion tool having a steel ball (not shown) provided at one end of the steel wire (not shown) after the heat exchange fin arrangement step S2 in which the heat exchange fins 52 form heat. By expanding the refrigerant pipe 51 therein through (not shown), the outer circumference of the refrigerant pipe 51 and the surface of the burr 54 is a step. That is, when the steel wire is inserted into one end of the refrigerant pipe 51 and pulled out by force from the other end side, the steel ball is forced through the refrigerant pipe 51. Accordingly, the refrigerant pipe 51 is plastically deformed and is expanded from the inside to the outside to be in close contact with the burr 54 around the through hole 53. At this time, the diameter of the steel ball is preferably made only slightly larger than the inner diameter of the refrigerant pipe (51).

The refrigerant pipe bending step S4 is a step of bending the refrigerant pipe 51 between the groups of the heat exchange fins 52 and the group after the refrigerant pipe expansion step S3 to force alignment. That is, when the refrigerant pipe 51 between the groups of heat exchange fins 52 is bent, a layer layer of the heat exchange fins 52 group is disposed, thereby completing the condenser 50 for the refrigerator.

As described above, the condenser 50 according to the present invention is configured by bending the refrigerant pipe 51 after passing the refrigerant pipe 51 through the thin plate heat exchange fins 52, thereby welding the heat exchange fin made of wire. The manufacturing process is made easier than the conventional one to be bonded one by one. In addition, since both the heat exchange fins 52 and the refrigerant pipe 51 are made of aluminum, a separate coating process is not required, and thus the overall manufacturing cost is also reduced.

Next, the operation and effect of the condenser 50 manufactured through this series of processes will be described in an example in which the refrigerator is installed in the machine room 11.

First, when power is applied to the refrigerator, the compressor 20 and the cooling fan 30 installed in the machine room 11 are driven. Therefore, the vaporized refrigerant, which has been evaporated in the evaporator (not shown), is sucked into the compressor 20, is compressed to high temperature and high pressure, and is supplied to the condenser 50.

In addition, the refrigerant sent to the condenser 50 side is heat-exchanged with the external air sucked by the operation of the cooling fan 30 while flowing along the refrigerant pipe 51, and condensed, and is then sent to the evaporator side through an expansion mechanism (not shown) Create

At this time, the refrigerant passing through the condenser 50 is conducted along the refrigerant pipe 51 and the heat retained is conducted to the refrigerant pipe 51 and the heat exchange fins 52. . This is because the outer circumference of the refrigerant pipe 51 and the heat exchange fins 52 are in surface contact with the burr 54.

In fact, the present inventors applied the condenser 50 to the refrigerator and operated it, and as a result, the overall efficiency of the refrigeration cycle was improved, and thus, it was found that there was an effect such as reducing the consumption input of the refrigerator. With reference to Table 1, the effects of the present invention will be described once again.

TABLE 1 Test results of a refrigerator to which a conventional condenser is applied and a refrigerator to which a condenser according to the present invention is applied

division Refrigerator with conventional condenser Refrigerator to which the condenser according to the invention is applied Power Consumption (kwh / month) (30 ℃, 75% Humidity) 47.4 42.5 (10.3% ↓) Cooling rate freezer / freezer (min) 96.4 / 94.5 86.0 (9.6min ↓) / 88.0 (6.5min ↓) Minimum temperature freezer / freezer (℃) -30.6 / -0.9 -31.9 (1.3 ℃ ↓) / -1.1 (0.5 ℃ ↓)

As shown in the above [Table 1], the power consumption at the condition of 30 ℃, 75% humidity is 47.4 (kwh / month) in the refrigerator with a conventional condenser made of wire heat exchange fins, while the condenser according to the present invention ( When 50) is applied, it can be seen that the power consumption is reduced by about 10.3% as 42.5 (kwh / month).

In addition, the cooling rate can also be seen that up to 10 minutes faster when the present invention is applied compared to the prior art, the condensing efficiency of the condenser 50, the minimum temperature of the freezer compartment is lowered to more than 1 degree can be seen that the cooling capacity is improved. have.

As described in detail above, according to the condenser for a refrigerator according to the present invention, a plurality of heat exchange fins arranged in parallel and through holes are perforated thin plate heat exchange fins, and bent at regular intervals through the heat exchange fins through the through holes. This group consists of an elongated coolant tube allowing the layers to be arranged. As a result, the heat exchange area is significantly increased compared to the prior art, so that the refrigerant condensation efficiency is improved, as well as a separate coating process is not required, thereby reducing the overall manufacturing cost.

Claims (3)

In the refrigerator condenser mounted on the machine room 11 of the refrigerator, A plurality of heat exchanger fins 52 are arranged in parallel and the through-holes 53 are perforated thin plate, The refrigerator comprises a refrigerant pipe 51 penetrating the heat exchange fins 52 through the through holes 53 and bent at regular intervals so that the heat exchange fins 52 form a group and a layer layer is arranged. Condenser. The method of claim 1, The heat exchange fin 52 is made of a thin aluminum plate, The refrigerant pipe 51 is a condenser for a refrigerator, characterized in that made of an elongated aluminum tube having an inner diameter of 4.5 to 7.0mm. The method according to claim 1 or 2, Condenser for refrigerator, characterized in that the burr (54) is formed in close contact with the outer periphery of the through-hole (53) of the heat exchange fin (52).