KR19980037824A - Condenser - Google Patents

Abstract

The present invention discloses a condenser.

According to the present invention, first and second header pipes through which a refrigerant passes are provided, and a plurality of tubes are installed in the first and second header pipes in a cross-sectional direction, and fins for promoting heat dissipation are provided between the tubes. . In the condenser having a refrigerant inlet through which a refrigerant flows in and a refrigerant outlet through which the refrigerant flows out, the first header pipe divides the internal space of the first header pipe into subdivisions in a cross-sectional direction inside the first header pipe. A plurality of baffles having holes are formed, and a pipe connecting the holes of the baffles is provided to allow the refrigerant to pass through the intermediate space first and flow into the upper and lower spaces to increase the condensation efficiency of the refrigerant, thereby greatly increasing the cooling efficiency of the air conditioner. The effect can be obtained.

Description

Condenser

The present invention relates to an air conditioner, and more particularly to the internal structure of a condenser header pipe.

In general, an air conditioner using a refrigerant cycle liquefies a refrigerant compressed in a compressor in a condenser, and then vaporizes it in an evaporator through an expansion valve to cool the room by the heat of vaporization. Device.

As shown in FIG. 1, the condenser installed in the air conditioner is provided with first and second header pipes 10 and 20 formed by clogging both sides and having a plurality of holes 21. 10, a coolant inlet 11 through which the coolant flows in and a coolant outlet 12 through which the coolant flows out are assembled.

In addition, a baffle 13 for dividing the internal space into two parts is provided between the refrigerant inlet 11 and the refrigerant outlet 12 in the first header pipe 10.

Meanwhile, a plurality of tubes 25 connecting the first and second header pipes 10 and 20 are provided, which are sequentially arranged from the first hole to the last hole of the first and second header pipes 10 and 20. Is inserted. Then, corrugated fins 26 are installed between these tubes 25.

After applying the brazing weldment to the preassembled condenser, the brazing weldment is melted through a brazing furnace, not shown, and then dried to form a complete condenser.

In FIG. 2, the high temperature and high pressure steam refrigerant flowing into the refrigerant inlet 11 of the condenser passes through the tubes installed between the upper end of the first header pipe 10 and the baffle 13, and then the second header pipe 20. After passing through the tube, it passes through the tubes 11 installed from the baffle 13 to the lower end of the first header pipe 10 and is liquefied with a low temperature and high pressure liquid refrigerant. And the liquefied low temperature high pressure liquid refrigerant is introduced into the expansion valve (not shown) through the refrigerant outlet (12).

However, such a conventional condenser passes through the refrigerant outlet 12 in a state where the high temperature and high pressure steam refrigerant passing through the refrigerant inlet 11 and the upper tube 11 is not completely changed to the low temperature and high pressure liquid refrigerant. The problem of low efficiency appears.

An object of the present invention is to provide a structure of a condenser that can smoothly change the state of the refrigerant to solve such a conventional problem.

Figure 1 is an exploded perspective view showing a partially cut in the conventional condenser

2 is a schematic diagram showing the flow of refrigerant in a conventional condenser

Figure 3 is an exploded perspective view showing a condenser according to the present invention

Figure 4 is a partial cutaway view showing a header pipe is installed baffle according to the present invention

5 is a schematic diagram showing the flow of refrigerant in a condenser according to the invention

<Description of the code | symbol about the principal part of drawing>

50: tube 55: fin

60 (70): header pipe 62: refrigerant inlet

64: refrigerant outlet 65: pipe

66 (67): bafflle

In order to achieve the above object, the present invention provides a first and second header pipe through which the refrigerant passes, a plurality of tubes installed in the cross-sectional direction on the first and second header pipes, and pins provided between the tubes. And a refrigerant inlet provided in the first header pipe and a refrigerant outlet provided in the first header pipe, wherein the condenser is installed in the cross section of the first header pipe in the cross-sectional direction to upper and lower the inside of the first header pipe. A plurality of baffles divided into subdivided spaces and intermediate spaces, the holes being formed; Characterized in that the tube is provided to connect the holes.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In FIG. 3, a plurality of flat tubes 50 are provided, and corrugated fins 55 are provided between the tubes 50.

Then, both ends of the tubes 50 are assembled with cylindrical first and second header pipes 60 and 70, both ends of which are clogged. The outer peripheral surfaces of the first and second header pipes 60 and 70 have a cross section. A plurality of insertion holes 80 are formed in the direction to allow the tubes 50 to be inserted.

In addition, a coolant inlet 62 is assembled at an intermediate portion of the first header pipe 60, and a coolant outlet 64 is assembled at a lower end thereof.

On the other hand, in Fig. 4, according to the feature of the present invention, a tube 65 is provided axially inserted into the first header pipe 60, and the first and second baffles 66 and 67 are provided at both ends of the tube 65. In the center of the first baffle 66, a first hole 68 having the same diameter as the inner diameter of the tube 65 is formed, and the center of the second baffle 67 is formed of the tube 65. The second hole 69 having the same diameter as the outer diameter is formed so that the end of the tube 65 is assembled to protrude outward from one side of the second baffle 67.

The assembled first baffle 66 is located between the refrigerant inlet 62 and the refrigerant outlet 64, and the second baffle 67 is located between the refrigerant inlet 62 and the upper end of the first header pipe 60. Located. Therefore, the interior of the first header pipe 60 is divided into subdivisions of the upper space 63a, the intermediate space 63b, and the lower space 63c.

The number of tubes 50 located in these spaces 63a to 63c is equal to the number of tubes 50 located in the intermediate space 63b and the tubes located in the upper and lower spaces 63a and 63c. The number of the 50 is the same as the sum, and the number of tubes 50 located in the upper space 63a is assembled relatively more than the number of tubes 50 located in the lower space 63c.

After applying the brazing weldment to the preassembled condenser, the brazing welder is melted through a brazing furnace (not shown). When the melted state is dried, the parts are joined to form a complete condenser.

In the condenser according to the present invention, the vapor refrigerant compressed at high temperature and high pressure in a compressor (not shown) as shown in FIG. 5 is introduced into the intermediate space 63b through the refrigerant inlet 62, and the first and second baffles 66 and 67 are formed. The state change is made through a plurality of tubes (50) installed between the) and the liquid refrigerant of low temperature and high pressure.

At this time, although not shown, in general, as the heat dissipation fan installed in the central portion of the condenser intensively cools the intermediate space 63b, the high temperature and high pressure steam refrigerant initially passing through the intermediate portion 63b is initially heated to a high temperature. Compared with the conventional condenser which passes the high pressure steam refrigerant to the upper end, the efficiency is relatively high.

Meanwhile, among the refrigerants introduced into the second header pipe 70, the state change is relatively less, and thus the refrigerant in the vapor state flows into the plurality of tubes 50 installed in the upper space 63a. Since the heat exchange is required, the liquid is smoothly converted into a low-temperature, high-pressure liquid refrigerant while passing through the tubes 50 installed in the upper space 63a more than the number of tubes 50 installed in the lower space 63c. The less refrigerant is introduced into the plurality of tubes 50 installed in the lower space 63c.

Subsequently, the refrigerant passing through the upper space 63a of the first header pipe 60 flows into the lower space 63c through the tube 65 and passes through the tubes 50 installed in the lower space 63c. Joined with the refrigerant is introduced into the expansion valve (not shown) through the refrigerant outlet (64).

Thus, in the present invention, the heat dissipation effect of the high temperature and high pressure refrigerant passing through the inside of the condenser is provided by installing the first and second baffles 66 and 67 and the tube 65 inside the first header pipe 60. The efficiency is higher than that.

As described above, the condenser according to the present invention has a high heat dissipation efficiency, thereby improving the cooling efficiency of the air conditioner and greatly improving the reliability of the product compared to the conventional product.

Claims (3)

First and second header pipes through which the refrigerant passes, a plurality of tubes installed in the cross-sectional direction on the first and second header pipes, pins disposed between the tubes, and refrigerants installed in the first header pipe. In the condenser consisting of an inlet and a refrigerant outlet provided in the first header pipe, It is installed in the cross section direction inside the first header pipe 60 and divides the inside of the first header pipe 60 into the details of the upper and lower spaces 63a, 63c and the intermediate space 63b. A plurality of baffles (66) (67) in which (68) (69) are formed; And a tube (65) connecting the holes (68) (69). The method of claim 1, The refrigerant inlet (62) is a condenser, characterized in that provided between the plurality of baffles (66) (67). The method of claim 1, Condenser characterized in that the number of tubes (50) installed in the upper space (63a) is greater than the number of tubes () installed in the lower space (63c).