KR20040027069A - Condensor for airconditioner - Google Patents

Abstract

PURPOSE: A condenser for an air conditioner is provided to discharge only a liquefied refrigerant by returning gaseous refrigerant to a refrigerant passage, thereby improving the performance of an air conditioner. CONSTITUTION: A condenser is formed of left and right header pipes(11,12), a plurality of tubes(13) connecting the header pipes with each other, fins(14) interposed between the tubes, and a receiver tank(20) installed on a side of the right header pipe. Baffles(15) are installed in the header pipes. A refrigerant flows in the plurality of tubes in zigzags by the baffles, and then is discharged by a refrigerant outlet port(17) through a sub-cool zone(10a) via the receiver tank. A return path(18) is formed over the refrigerant outlet port to flow the gas refrigerant which is not liquefied to the receiver tank.

Description

Condenser for air conditioner {CONDENSOR FOR AIRCONDITIONER}

The present invention relates to a condenser for an air conditioner, and is characterized in that only the liquid refrigerant can be discharged by flowing the vapor refrigerant that has not condensed into the liquid phase to the receiver again through the return passage just before the outflow.

In general, the refrigerant condenser used in the air conditioner serves to reduce the high-temperature / high pressure refrigerant vapor sent from the compressor to the liquid refrigerant, and a conventional general condenser can be seen in FIGS. 1 and 2.

The condenser of FIG. 1 is a gravity type, and is composed of a plurality of tubes 13 between the header pipes 11 and 12 on both the left and right sides, and fins 14 filling the spaces between the tubes. Numeral 16 is connected to the upper end of the header pipe 11 on one side, and the refrigerant outlet 17 is connected to the lower end of the header pipe 11, respectively.

Therefore, after the refrigerant flows through the refrigerant inlet 16, the partition baffle 15 provided in the left and right header pipes 11 and 12 moves to the left and right jig zags to radiate heat gradually. The liquefied liquid, which is liquefied, is sent from the lower half to the receiver 20 provided at one side thereof, and then to the subcool zone 10a capable of dissipating only the liquefied refrigerant. It exits to the refrigerant outlet 17.

On the other hand, the condenser of Figure 2 is a liquid refrigerant separation type, consisting of a plurality of tubes (13) between the header pipes (11, 12) on both the left and right sides, and pins (14) between the tubes, In order to allow the refrigerant to flow into the heat exchanger, the refrigerant inlet 16 is connected to the middle of the header pipe 11, and the refrigerant outlet 17 is connected to the lower end.

At this time, the refrigerant introduced into the refrigerant inlet 16 allows gaseous refrigerant to flow upward and liquefied refrigerant to flow downward, and each of these refrigerants is again inside the receiver 20 at one side of the header pipe 12. In this case, the sufficiently liquefied refrigerant is sent to the subcool zone 10a and then exits to the refrigerant outlet 17.

However, in the conventional condenser shown in FIGS. 1 and 2 as described above, the refrigerant exiting the refrigerant outlet 17 through the subcool zone 10a does not completely change into a liquid refrigerant, and some gaseous refrigerant flows out together. It did not help to improve the air conditioning performance.

Therefore, the present invention is devised to compensate for the above-mentioned conventional shortcomings, the main object of the invention is to pass through the refrigerant flow path inside the condenser, after converting to the liquid phase in the receiver, to be passed through the sub-cooling zone, Partial gaseous refrigerant remaining in the liquefied refrigerant is returned to the refrigerant flow path of the condenser so that only the liquid phase refrigerant can flow out. Further, the content of the refrigerant in the gaseous state can be reduced to improve the air conditioner performance. It is.

A characteristic configuration of the present invention for achieving the above object is a left and right header pipe, a plurality of tubes connected between the header pipes, a pin interposed between the tubes and the one of the header pipe It consists of a receiver provided next to the refrigerant flows into the refrigerant inlet due to the baffle installed in the interruption of the header pipes zigzag through a plurality of tubes, the refrigerant flows out through the sub-cooling zone through the receiver In the air conditioner condenser to be discharged to the sphere, in the sub-cool zone provided in the lower half of the condenser so that the refrigerant in the gaseous state that could not be converted to the liquid phase flows toward the receiver again It has a return passage.

1 is a configuration diagram showing a conventional capacitor

2 is a configuration diagram showing another conventional capacitor

3 is a configuration diagram showing a capacitor of the present invention

<Code Description of Main Parts of Drawing>

10: condenser 10a: subcool zone

11, 12: header pipe 13: tube

14 pin 15 baffle

16: refrigerant inlet 17: refrigerant outlet

18: return passage 20: receiver

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

3 is a configuration diagram showing a condenser 10 of the present invention, wherein the condenser includes left and right header pipes 11 and 12, a plurality of tubes 13 connected between the header pipes, and It consists of the pin 14 which intervened in between, and the receiver 20 provided beside the one side header pipe 12 mentioned above.

After the refrigerant entering the refrigerant inlet 16 is zigzag through the plurality of tubes 13 due to the baffle 15 installed at the middle of the header pipes 11 and 12, the receiver 20 The bar exits to the refrigerant outlet 17 through the sub-cool zone 10a at the bottom, which is similar to the prior art.

At this time, in the present invention, in the subcool zone 10a provided in the lower half of the condenser, a gaseous refrigerant that cannot be converted into a liquid phase is further toward the receiver 20 in the upper side of the side having the refrigerant outlet 17. It is characterized by having a return passage 18 so as to flow.

In the condenser according to the present invention configured as described above, only the refrigerant flowing out through the refrigerant outlet 17 may be almost liquid.

This causes the refrigerant to dissipate while flowing in both the header pipes 11 and 12 and the tubes 13 therebetween, and flows into the receiver 20 in the lower half, and in the receiver the dryer ( (Not shown), the liquid refrigerant that accumulates downward by its own weight flows into the subcool zone 10a below the condenser.

The liquid refrigerant is further cooled out in the subcool zone 10a and exits to the refrigerant outlet 17. At this time, in the present invention, a gaseous refrigerant that has not been liquefied is upper part of the refrigerant outlet 17. It is introduced into the return passage 18 provided in the return passage 18 is connected to the receiver 20 again, so that after fully liquefied, it is guided to pass through the sub-cool zone (10a).

Since the return passage 18 is located above the sub cool zone 10a immediately before the coolant outlet 17, it is easy to return the light gas refrigerant that has not been dropped.

According to the present invention as described above in detail, after passing through the refrigerant passage inside the condenser, converting to a liquid phase in the receiver, and then to flow out through the subcool zone, some of the gaseous refrigerant remaining in the liquefied refrigerant is again condenser Since the refrigerant flow path is returned to the receiver and the receiver, the refrigerant exiting the refrigerant outlet through the repetition of the above operation is almost the liquid phase refrigerant.

Therefore, since the refrigerant content in the gaseous state is greatly reduced, there is an advantage that the performance of the air conditioner is further improved.

Claims (2)

Left and right header pipes 11 and 12, a plurality of tubes 13 connected between the header pipes, a pin 14 interposed between the tubes, and the header pipe 12 described above. ) And the refrigerant entering the refrigerant inlet 16 due to the baffle 15 installed at the middle of the header pipes 11 is formed in the plurality of tubes 13. In the air conditioner condenser which flows through the jig zag, and exits through the receiver 20 through the lower sub-cool zone (10a) to the refrigerant outlet (17), In the sub-cool zone (10a) provided in the lower half of the condenser, the return passage so that the gaseous refrigerant which cannot be converted into the liquid phase flows to the receiver 20 again above the side where the refrigerant outlet 17 is provided. A condenser for air conditioners, characterized by comprising (18). The method of claim 1, The return passage 18 is a condenser for an air conditioner, characterized in that composed of two or more tubes (13).