KR200259605Y1 - Integral Condenser - Google Patents

Abstract

The present invention relates to a condenser integrated with a receiver, wherein a connector tank 4 having a refrigerant inlet pipe and an outlet pipe at upper and lower portions thereof is arranged parallel to the connector tank 4 and the upper and lower diameters are equally expanded. The return tank (5), the tube (2) connected in communication with the connector tank and the return tank and the corrugated pin (3) alternately installed between the tube, and the inside of the connector tank and the return tank are divided into refrigerant A plurality of baffles (8-10) for U-turning, a partition plate (11) having at least one distribution hole (12) formed on a wall of the lower space of the return tank, and embedded in an upper portion of the return tank; Including a desiccant 13, and a filter 14 built into the lower portion of the return tank, the liquid is performed in the return tank during the flow of the refrigerant, and then the pure refrigerant separated from the water while flowing to the connector tank By heat exchange again, the heat exchange amount can be increased.

Description

Integral condenser

The present invention relates to a receiver integrated condenser in the vehicle air conditioner, which can also function as a receiver in the return tank of the condenser.

The vehicle refrigeration cycle forms a refrigerant circuit in which a compressor, a condenser, a receiver, an expansion valve, and an evaporator are sequentially connected. The refrigerant circulates along the refrigerant circuit, and cools the air while exchanging heat with external air during this circulation process.

The receiver is to separate the phase-converted refrigerant from the condenser to gas-liquid, so that only the liquid refrigerant flows into the expansion valve, but is separated from the condenser. Is being presented.

For example, Japanese Unexamined Patent Application Publication No. 3-31266 increases the diameter of the longitudinal header on the refrigerant outlet side of the condenser, and incorporates a desiccant in the header having the larger diameter to maintain the fluid receiver function and at the same time the fluid function. Is performed at the end of the heat exchange path.

However, the receiver performs the purpose of gas-liquid separation of the two-phase refrigerant and the purpose of removing the water mixed in the refrigerant at the same time, the above-mentioned design performs the fluid function in the final stage of the refrigerant heat exchange, so that the water contained during the heat exchange Since the refrigerant flows, the amount of heat exchange is reduced by the moisture contained therein.

The present invention has been made in view of this point, and an object of the present invention is to provide a receiver integrated condenser that can perform a fluid function on a refrigerant induction path flowing in the condenser.

Another object of the present invention is to provide a receiver integrated condenser that can increase the amount of heat exchange by heat exchange only the pure liquid refrigerant in a state in which water contained in the refrigerant is removed.

The receiver integrated condenser of the present invention for achieving this purpose is a connector tank having a refrigerant inlet pipe and an outlet pipe at the top and bottom, respectively, and having a diameter larger than the diameter of the connector tank are parallel and vertically spaced A return tank, a tube connected in communication with the connector tank and the return tank, a cooling fin installed alternately between the tube, a plurality of baffles for partitioning the inside of the connector tank and the return tank to turn a refrigerant, and the return It is characterized in that it comprises a plate which divides the lower space of the tank and at least one distribution hole is formed on the wall, a desiccant embedded in the upper portion of the return tank, and a filter embedded in the lower portion of the return tank.

According to such a configuration, the amount of heat exchange can be increased by performing a fluid function in the return tank while the refrigerant flows, and then exchanging the pure refrigerant with water separated therein while flowing into the connector tank.

1 is a front view of a condenser according to the present invention,

Figure 2 is a sectional view of the main part showing a return tank having a receiver function;

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a cross-sectional view taken along the line B-B of FIG.

5 and 6 are cross-sectional view showing another embodiment of the return tank,

7 to 9 are cross-sectional views for explaining the positional relationship between the filter and the desiccant,

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

1; condenser 2; tube

3; corrugated pin 4; connector tank

5; return tank 6; inlet pipe

7; outlet pipe 8-10; baffle

11; split plate 11a; horizontal section

11b; vertical 12; distribution hole

13; desiccant 14; filter

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

1 is a front view of the receiver integrated condenser according to the present invention, Figure 2 is an enlarged cross-sectional view showing the main portion of the return tank with the receiver, Figure 3 and Figure 4 shows a planar cross-sectional view of the return tank.

The condenser, shown in its entirety by reference numeral 1, is laminated between the plurality of tubes 2 via a corrugated fin 3. Each end of the tube 2 is inserted in communication with the connector tank 4 and the return tank 5 facing each other. The inlet pipe 6 and the outlet pipe 7 are coupled to the upper and lower portions of the connector tank 4, and a plurality of baffles 8-10 are provided in each tank to coolant flow in a zigzag.

The return tank 5 is larger than the diameter of the connector tank 4, and preferably has a diameter of about 1.2-3 times the diameter of the connector tank 4. A split plate 11 is provided below the baffle 9, and the split plate 11 is bent by a press to form a horizontal portion 11a and a vertical portion 11b. The outer periphery of the split plate 11 is formed with a plurality of distribution holes 12, may be formed in the horizontal portion (11a) and the vertical portion (11b), and the bottom of the return tank (5) for possible gas-liquid separation It is good to form in close proximity. The distribution holes 12 have a diameter of approximately 3-16 mm and are independent of the number of distribution holes when the refrigerant passage area is the same.

In the embodiment, the return tank 5 is formed in the shape of a pipe by extrusion, but may be manufactured by combining a plurality of plates as shown in FIGS. 5 and 6, which is a header 5a into which the tube 2 is inserted. And a tank 5b that is combined with the header 5a to form a refrigerant flow path, and the same result as in the embodiment can be obtained by brazing the plate 5c inside the return tank 5. .

Meanwhile, the present invention has a desiccant 13 built in the lower part of the return tank 5 around the baffle 9 to remove moisture mixed in the refrigerant, and a filter 14 is installed in front of the split plate 11. Doing. In the embodiment, the desiccant 13 is embedded in the upper portion of the return tank 5, but may be embedded in the lower portion of the return tank 5, as shown in FIGS. 7 to 9, and the positions of the desiccant 13 and the filter 14 are shown. May be reversed with respect to the refrigerant flow direction.

The filter 14 has an installation position determined according to the position of the distribution hole 12 formed in the split plate 11. For example, the distribution hole 12 is formed in both the horizontal portion 11a and the vertical portion 11b. If the filter 14 is installed horizontally on the upper surface of the horizontal portion (11a), if the distribution hole 12 is formed in the vertical portion (11b) it is installed vertically in front of the distribution hole (12).

In addition, the desiccant 13 may be located at the rear end of the filter with respect to the direction of the refrigerant path, or may be located together with the filter 14 under the return tank 5.

According to the present invention, the high temperature and high pressure air refrigerant compressed by the compressor flows to the return tank 5 through the upstream tube through the inlet pipe 6 coupled to the upper portion of the connector tank 4, and then the baffle 10 U-turn and flows back to the connector tank (4) through the upstream tube. The refrigerant flowing into the return tank 5 is in a state in which water is removed by the desiccant 13, and the present invention can increase heat exchange efficiency by flowing the pure refrigerant in which water is removed.

Then, the refrigerant flowing into the connector tank 4 flows to the lower part of the return tank 5 while the path is switched by the baffle 9, passes through the filter 14, and passes through the downstream tube 7 through the downstream tube 7. Will leak out.

At this time, the refrigerant introduced into the lower portion of the return tank 5 passes through the filter 14 to separate the gas-liquid by its own weight. That is, since the distribution hole 12 formed in the vertical portion 11b of the split plate 11 is close to the bottom surface of the return tank 5, a constant refrigerant storage space is formed.

Therefore, the gas refrigerant is located in the upper portion by its own weight, whereas the liquid refrigerant is located in the lower portion, so that only the liquid refrigerant can flow through the distribution hole 12 formed in the dividing plate 11.

Here, the present invention is to expand the diameter so that the return tank (5) to the sap function and to incorporate a desiccant and a filter therein, serves as a receiver on the flow path of the refrigerant, after which the pure water is removed By only exchanging the liquid refrigerant through the downstream tube again, complete phase conversion is possible and the amount of heat exchange can be increased to increase the cooling efficiency.

As described above, the present invention expands the return tank at a constant rate compared to the connector tank and allows the receiver to function as a receiver by incorporating a desiccant and a filter therein, thereby overcoming the space limitation of the engine room. In addition, since the liquid is performed on the heat exchange path of the refrigerant, only the pure liquid refrigerant can be heat-exchanged again through the downstream tube, thereby increasing the amount of heat exchange and increasing the cooling efficiency.

Claims (3)

A connector tank having upper and lower coolant oil in and out pipes; A return tank in which a spacing with the connector tank is maintained and installed in parallel, and a desiccant at the top and a filter at the bottom; A plurality of baffles for partitioning each of the insides of the connector tank and the return tank to allow the refrigerant to be turned; A split plate having a horizontal portion and a vertical portion to partially partition the lower space of the liter tank, and at least one distribution hole formed on a wall surface of either one of the horizontal and vertical portions; And It includes a filter installed in front of the split plate, Here, the liquid receiver integrated condenser characterized in that to achieve the gas-liquid separation through the distribution hole of the split plate. The receiver integrated condenser of claim 1, wherein a desiccant is embedded in a lower portion of the return tank, and a filter is installed in a vertical portion of the split plate. 2. A receiver integrated condenser as set forth in claim 1, wherein a filter is provided on an upper surface of the horizontal portion of said dividing plate, and a desiccant is built into a rear end of said filter.