KR100482423B1 - Receiver Dryer Integrated Condenser - Google Patents

Abstract

The present invention allows the working fluid discharged to the bottom of the condenser header tank to flow into the upper part of the receiver dryer tank so as to pass a large amount of the absorbent stored up to the receiver dryer tank to sufficiently remove the moisture mixed in the working fluid. A receiver dryer-integrated condenser which increases the heat exchange effect by allowing the working fluid to pass through the large amount of the moisture absorbent, and its configuration is such that the working fluid discharged through the outlet of the header tank can be introduced into the receiver dryer tank. A guide flow path is formed in the receiver dryer tank.

Description

Receiver dryer integrated condenser

The present invention relates to a receiver dryer integrated condenser, and in particular, the working fluid flowing downward of the header tank is introduced into the receiver dryer tank upward, thereby allowing a large amount of the absorbent stored up to the receiver dryer to pass through a sufficient amount of moisture removal. By providing a purer working fluid it is possible to increase the heat exchange efficiency.

A condenser is a type of heat exchanger of a cooling system, and its typical configuration is provided with a header tank with baffles for zigzagly controlling the flow of working fluid at both ends of a plurality of tubes, and a heat transfer area between each tube. Corrugated pins are inserted to help widen the heat transfer.

Accordingly, the condenser is passed through the working fluid compressed in the gas state in the compressor by the baffle to the tube and both header tanks in a zigzag manner to exchange heat with the outside air to change the phase into a liquid state and then discharge it.

However, as described above, the working fluid discharged after the heat exchange in the condenser is mixed with water so that the working fluid containing the moisture is compressed to high temperature and high pressure through the compressor through the evaporator and discharged again to the condenser.

However, when the working fluid containing water is compressed in the compressor as described above, the moisture is hardly compressed and the compressor compressing the water has a problem of being damaged when the life of the compressor is shortened or the load is severely received.

In order to prevent the load of the compressor, the moisture contained in the working fluid is removed from the receiver dryer containing the absorbent, which is installed between the condenser and the expansion valve in the flow path of the cooling system to provide only the pure working fluid. Done.

However, in the related art, the condenser and the receiver dryer are separately installed, but there is a disadvantage in that the manufacturing and installation are cumbersome. In recent years, as shown in FIG. 1, the so-called receiver dryer integrated condenser is manufactured by integrally configuring the receiver dryer on one side of the header tank of the condenser. It is becoming.

As described above, when the working fluid flow path in the condenser, in which the receiver dryer is integrally formed, the working fluid flowing into the one side header tank 20 and the outer inlet 21 of the condenser 10 is inside both header tanks 20, Zigzag flows in a zigzag manner by the baffle 22 located in the direction of the arrow, and then flows into the receiver dryer through the outlet 23 of the header tank 20 and the inlet 31 of the receiver dryer tank 30. At this time, the working fluid still contains water.

In this state, the working fluid passes through the moisture absorbent 40 contained in the receiver, and then the water is removed. Then, the receiver dryer outlet 32, the inlet 24 of the header tank 20, the tube 11 and It is discharged to the expansion valve through the outer outlet 25 provided in the other header tank (20).

However, it passes through the inlet, outlet 23, 24, 31, 32 through which the working fluid passes through the lower portion of the header tank 20 and the receiver dryer tank 30 of the condenser 10, respectively. One working fluid is passed from below the central portion of the absorbent 40 has passed through a small amount of the absorbent 40 has a disadvantage that does not completely remove the moisture contained therein.

Accordingly, the present invention is to solve the conventional problems as described above, the technical problem is that the working fluid discharged to the bottom of the header tank of the condenser is introduced into the receiver dryer tank upper portion of the large amount of the absorbent stored up to the receiver dryer top It is to provide a receiver dryer integrated condenser that passes through the water to completely remove the moisture to increase the heat exchange efficiency of the working fluid.

The configuration of the present invention is characterized in that the guide flow path is provided so that the working fluid discharged from the header tank at the receiver dryer tank predetermined position can be introduced into the receiver dryer tank.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the embodiment of the present invention. Figure 3 is a front sectional view showing a receiver dryer integrated condenser of the present invention, Figures 4 to 5 is an exploded perspective view according to the present invention, Figure 6 is an enlarged cross-sectional view showing the integrated condenser header tank and the receiver dryer of the present invention.

Receiver condenser integrated condenser to which the present invention is applied is a condenser header tank through which the entrance and exit spaced to allow the working fluid to enter and exit the receiver dryer tank at a predetermined position of the body as usual, and the working fluid discharged to the outlet of the header tank It is composed of a receiver dryer tank through which the inlet and outlet through the predetermined position of the body to accommodate the inside to liquefy it and discharged to the inlet of the condenser.

In the receiver dryer integrated condenser, the present invention allows the working fluid discharged through the outlet 210 of the header tank 200 to be introduced into the receiver dryer tank 300 as shown in FIG. 300, the guide flow path 400 is formed at a predetermined position.

The guide flow path 400 has a predetermined width and length in front of the receiver dryer tank 300 in contact with the header tank 200 and is introduced into the inside of the receiver dryer tank 300. A passage 410 is perforated to flow therein. The lower end portion of the guide passage 400 extends to the lower end position of the outlet 210 so as to accommodate the working fluid discharged through the outlet 210 of the header tank 200 therein, and the upper end portion of the guide passage 400 is inserted therein. Receiver dryer tank 300 extends to the upper end.

Therefore, since the passage 410 of the guide flow path 400 is formed through the upper portion, the moisture absorbent 40 embedded in the receiver dryer tank 300 can be accommodated near the passage 410, thereby increasing the amount of the moisture absorbent 40. Will be available.

According to the present invention constituted as described above, when the inlet 220 of the header tank 200 and the outlet 320 of the receiver dryer tank 300 coincide with each other, the outlet 210 of the header tank 200 is guided. It is accommodated in the flow path 400 to guide the flow of the working fluid.

Accordingly, the working fluid in the condenser 10 zigzags the tube 110 by the baffles 230 in both header tanks 200 and then moves the outlet 210 of the one side header tank 200 as shown in FIG. 6. It is discharged through the guide passage 400 through. Subsequently, the working fluid flows upward along the guide passage 400 and then flows into the receiver dryer tank 300 through the passage 410 and passes through the absorbent 40 stored near the passage 410. After the water mixed therewith is completely removed, it is discharged to the tube 110 through the outlet 320 of the receiver dryer tank 300 and the inlet 220 of the header tank 200 as usual, and then directed to the expansion valve. .

On the other hand, another embodiment of the present invention as shown in Figure 5 extends the upper portion of the guide flow path 400 of the working fluid to the top of the receiver dryer tank 300 and cut the end thereof through the passage 410. In addition, the outlet 320a and the inlet 220a are cut by matching the lower end of the receiver dryer tank 300 with the lower end of the corresponding header tank 200 so that the working fluid is discharged through the passage 410. Each will be formed.

Flow diagram of the working fluid in the embodiment The working fluid discharged to the outlet 210a of the header tank 200 moves upward along the guide flow path 400 in the same manner as in the previous embodiment, and the passage 410 at the end thereof. After the water is removed while entering the receiver dryer tank 300 through the absorbent 40, the tube 110 through the outlet 320a of the receiver dryer tank 300 and the inlet 220a of the header tank 200. Since it is discharged to) it is possible to achieve the object of the present invention.

As described above, the present invention has a purpose to remove the water while passing through the larger amount of the absorbent 40 by allowing the working fluid to flow into the receiver dryer tank 300, the guide flow path ( Although the 400 is formed to be inserted into the receiver dryer tank 300, the object of the present invention can be achieved, of course, even when the guide flow path 400 is formed in the header tank 200 in the opposite concept. Even if the flow path 400 is formed in each of the header tank 200 and the receiver dryer tank 300, the above object can be achieved.

In each of the above embodiments, for convenience of description, the header tank 200 includes two members (two-piece type) and the receiver dryer tank 300 includes one member (one-piece type), but the header tank 200 ) And the receiver dryer tank 300 may be variously manufactured with a plurality of members, and the guide flow path 400 is formed between the contact portions.

The present invention constituted as described above allows the working fluid discharged from the header tank 200 to flow into the upper portion of the receiver dryer tank 300 so as to pass through a larger amount of the absorbent 40 to completely remove moisture to exchange heat. There is an advantage to maximize the efficiency.

1 is a front sectional view showing a conventional receiver dryer integrated condenser;

2 is an enlarged cross-sectional view of the main part of FIG.

Figure 3 is a front sectional view showing a receiver dryer integrated condenser of the present invention.

4 is an exploded perspective view of the present invention;

5 is an exploded perspective view of another embodiment of the present invention;

Figure 6 is an enlarged cross-sectional view showing the integrated condenser header tank and the receiver dryer of the present invention.

※ Explanation of code for main part of drawing

200: header tank 300: receiver dryer tank

400: guided passage 410: passage

320,320a: Exit 220,220a: Entrance

Claims (4)

Condenser header tank through which the entrance and exit are spaced apart so that the working fluid can enter and exit the receiver dryer tank at a predetermined position of the body, and the working fluid discharged to the outlet of the header tank is accommodated therein and moisture is absorbed by the built-in absorbent. In the receiver dryer-integrated condenser comprising a receiver dryer tank through which the inlet and outlet through the predetermined position of the body to be removed and discharged to the condenser inlet, A guide flow path is formed between the header tank and the receiver dryer tank contact surface to allow the working fluid discharged through the outlet of the header tank to enter the receiver dryer tank and pass through the absorbent stored up to the tank. The flow path is recessed upwardly with a predetermined width and depth from the position at which the lower end receives the outlet of the header tank in front of the receiver dryer tank in contact with the header tank so that the working fluid is inside the receiver dryer tank at the predetermined position thereon. A receiver dryer integrated condenser, characterized in that the passage is through so that it can be introduced into the. Condenser header tank through which the entrance and exit are spaced apart so that the working fluid can enter and exit the receiver dryer tank at a predetermined position of the body, and the working fluid discharged to the outlet of the header tank is accommodated therein and moisture is absorbed by the built-in absorbent. In the receiver dryer-integrated condenser comprising a receiver dryer tank through which the inlet and outlet through the predetermined position of the body to be removed and discharged to the condenser inlet, A guide flow path is formed between the header tank and the receiver dryer tank contact surface to allow the working fluid discharged through the outlet of the header tank to enter the receiver dryer tank and pass through the absorbent stored up to the tank. The condenser integrated with the receiver is characterized in that the upper portion of the passage is extended to the top of the receiver dryer tank so that the passage is cut at the end thereof. The receiver dryer integrated condenser of claim 1 or 2, wherein the receiver dryer tank has an outlet cut inward from a lower end thereof to discharge the working fluid therein out of the condenser. 3. The integrated receiver dryer of claim 1, wherein the header tank has an inlet cut in a lower end portion corresponding to the outlet of the receiver dryer tank to allow a working fluid discharged from the receiver dryer tank to pass therethrough. Condenser.