KR20120062149A - Refrigerant cycle of air conditioner for vehicles - Google Patents

Abstract

PURPOSE: A cooling cycle of an air conditioner for a vehicle is provided to improve condensing efficiency by using cooling water supplied from a low-temperature radiator at a condensing area and using refrigerants exhausted from an evaporator at an over-cooling area. CONSTITUTION: A cooling cycle of an air conditioner for a vehicle comprises a compressor, a condenser(1), an expansion valve, and an evaporator. The compressor compresses a first heat exchange medium. The condenser condenses the compressed first heat exchange medium. The expansion valve throttles the condensed first heat exchange medium. The evaporator evaporates the first heat exchange medium flowing from the expansion valve.

Description

Refrigerant cycle of air conditioner for vehicles

The present invention relates to a refrigeration cycle of a vehicle air conditioner, and more particularly, in the refrigeration cycle, a condenser is configured of a water-cooled condenser in which a plurality of plates are stacked to alternately flow a first heat exchange medium and a second heat exchange medium. Cooling water supplied from the low-temperature radiator is used as the second heat exchange medium in the condensation area of the heat exchanger. In the subcooling area, the first heat exchange medium is cooled by using the refrigerant at the outlet of the evaporator, thereby increasing the supercooling temperature to improve condensation performance. A refrigeration cycle of a vehicle air conditioner.

In a refrigeration cycle of a typical vehicle air conditioner, the actual cooling action is caused by an evaporator in which the liquid heat exchange medium absorbs the amount of heat as vaporized heat from the surroundings and vaporizes. The heat exchange medium in the gas state flowing from the evaporator to the compressor is compressed at high temperature and high pressure in the compressor, and liquefied heat is released to the surroundings in the process of liquefying the compressed gas heat exchange medium through the condenser. As the medium passes through the expansion valve again, it becomes a low-temperature and low-pressure wetted vapor state, and then flows into the evaporator to evaporate to form a cycle.

That is, the condenser is a high-temperature, high-pressure gaseous refrigerant flows into the liquid state while releasing the liquefied heat by heat exchange, and is discharged. Can be.

The air-cooled condenser is configured to exchange heat with air introduced through an opening in the front of the vehicle, and is fixed to the front side of the vehicle in which the bumper beam is formed for smooth heat exchange with the air.

However, since the air-cooled condenser is formed at the rear end of the bumper beam when a vehicle accident occurs, the impact force applied to the pedestrian may be increased, and the heat exchanger configuration also has a high risk of being damaged by the impact, and accordingly, a repair cost is expected accordingly. There is a problem that the premium calculation standard can be raised.

As shown in FIG. 1, the water-cooled condenser 10 may use a plate heat exchanger in which a plurality of plates 20 are stacked.

The water-cooled condenser has a plurality of plates 20 are stacked to form a first flow portion 21 and a second flow portion 22 through which the first heat exchange medium and the second heat exchange medium flow, respectively, and the first heat exchange medium Inlet / outlet first inlet pipe 31 and first outlet pipe 32, second heat exchange medium inlet / outlet second inlet pipe 41 and second outlet pipe 42, the first heat exchange medium And a gas-liquid separator 50 for separating the gas-phase heat exchange medium and a liquid heat exchange medium, a first connection pipe 51 connecting the condensation region of the first flow unit 21 and the gas-liquid separator 50, and the gas-liquid separator. It is formed including a second connecting pipe 52 for connecting the subcooling region of the first flow portion (21).

In the water-cooled condenser 10, a first heat exchange medium introduced through the first inlet pipe 31 flows through the condensation region of the first flow unit 21, and through the first connection pipe 51. After moving to the gas-liquid separator 50 and again flowing the subcooling region of the first flow part 21 through the second connecting pipe 52, it is discharged through the first outlet pipe 32.

At this time, the second heat exchange medium flows through the second inlet pipe 41 and flows through the second flow part 22 formed alternately with the first flow part 21. To cool.

When the first heat exchange medium flowing in the water-cooled condenser in the form of a plate heat exchanger as described above is a refrigerant and the second heat exchange medium is a coolant, the coolant passes through a low-temperature radiator before entering the condenser and the refrigerant is lowered in temperature. Heat exchange with.

However, since the temperature of the cooling water passing through the low temperature radiator is about 50 to 60 ° C. when evaluating the actual vehicle at an outdoor temperature of 45 ° C., it is difficult to drop the temperature of the refrigerant discharged from the condenser below 50 ° C. There is a problem that this can be degraded.

The present invention has been made to solve the above problems, an object of the present invention is to provide a second plate in the condensation region of the water-cooled condenser in which a plurality of plates are stacked to alternately flow the first heat exchange medium and the second heat exchange medium, respectively. By using the cooling water supplied from the low-temperature radiator as the heat exchange medium and cooling the first heat exchange medium by using the refrigerant at the outlet side of the evaporator in the subcooling area, the refrigeration cycle of the vehicle air conditioner can increase the supercooling temperature to improve the condensation performance. To provide.

In addition, the object of the present invention is heat exchanged by a water-cooled method, the amount of air required compared to the conventional air-cooled heat exchanger is not required to be mounted on the front of the vehicle because the vehicle air conditioner including a water-cooled condenser that is not limited to the engine room mounting position To provide a refrigeration cycle.

The refrigeration cycle of the vehicle air conditioner of the present invention comprises a compressor (4) for sucking and compressing the first heat exchange medium; The first flow exchanger 110 and the second flow condensing the first heat exchange medium compressed by the compressor 4, the plurality of plates 100 are stacked to alternately flow the first heat exchange medium and the second heat exchange medium, respectively. The heat exchanger 120 is formed, the condensation region 220 is formed in a predetermined region of the first flow portion and the second flow portion 120, the sub-cooling region 210 is formed in the sub-cooling of the remaining constant region A condenser 1 comprising a portion 200; Expansion valve (2) for throttling the first heat exchange medium condensed in the condenser (1); An evaporator (3) for evaporating the first heat exchange medium flowing from the expansion valve (2); In the refrigeration cycle of a vehicle air conditioner, the condenser (1) is a 2-1 heat exchange medium and the second oil in which a second heat exchange medium flows in the condensation region 220 of the second flow unit 120 It consists of a 2-2 heat exchange medium flowing in the subcooled zone of the eastern portion 120, characterized in that the 2-1 heat exchange medium and the 2-2 heat exchange medium are different fluids.

In addition, the condenser 1 includes a first inlet pipe 310 into which a first heat exchange medium flows into the heat exchange part 200 and a first outlet pipe 320 discharged; A second inlet pipe 410 into which the 2-1 heat exchange medium is introduced into the heat exchange part 200 and a second outlet pipe 420 discharged; A third inlet pipe 510 into which the second-2 heat exchange medium flows into the heat exchange part 200 and a third outlet pipe 520 discharged; A receiver 600 for separating the gas phase heat exchange medium and the liquid heat exchange medium of the first heat exchange medium; The first connection pipe 610 connecting the condensation region 220 and the receiver 600 of the first flow unit 110 and the subcooling region of the receiver 600 and the first flow unit 110. A second connection pipe 620 for connecting 210; And is formed to include a plurality of protrusions.

In addition, the condenser 1 is a first heat exchange medium introduced through the first inlet pipe 310 flows through the condensation region 220 of the first flow unit 110, the first connection pipe 610 After moving to the receiver 600, and again flowing the subcooling region 210 of the first flow unit 110 through the second connecting pipe 620, the first outlet pipe 320 Characterized in that it is discharged through.

In addition, the condenser 1 is characterized in that the second inlet pipe 410 and the second outlet pipe 420 is connected to a cooling water circulation line 8 including a water pump 7 and a low temperature radiator 6. It is done.

In addition, in the refrigeration cycle of the vehicle air conditioner, the first inlet pipe 310 is connected to the outlet side refrigerant line 5 of the compressor 4, and the first outlet pipe 320 is the expansion valve 2. The third inlet pipe 510 is connected to the outlet side refrigerant line 5 of the evaporator 3, and the third outlet pipe 520 is connected to the compressor (5). It is characterized in that it is connected to the inlet side refrigerant line (5) of 4).

In addition, the plate 100 is hollow so that the first flow portion 110 is communicated in the stacking direction of the plate 100 and the first junction 710 is formed around the protruding in the upper or lower direction is formed The first communication hole 810 to the fourth communication hole 840; And a second joint part 720 formed to be hollow so that the second flow part 120 communicates in the stacking direction of the plate 100, and a circumference thereof protrudes in a direction opposite to the protrusion direction of the first joint part 710. A fifth communication hole 850 and a sixth communication hole 860; It is characterized in that it is formed.

In addition, the condenser 1 may be configured such that the first heat exchange medium and the second heat exchange medium do not communicate with each other in a stacking direction in an area where the condensation area 220 and the subcooling area 210 of the heat exchange part 200 are separated. The first communication hole 810 to the sixth communication hole 860 is characterized in that the closing plate 103 is all closed.

In addition, the condenser 1 has a first plate 101 having the first junction 710 formed in an upward direction and a second junction 720 formed in a downward direction, and the first junction 710 having a lower side. Direction and the second plate 102 having the second junction portion 720 formed in an upward direction are alternately stacked, and the first plate 101 and the second plate 102 are adjacent to the first junction portion 710. ) And the second bonding portion 720 are bonded to each other.

In addition, the condenser 1 has the first inlet pipe 310 and the first connection pipe 610 is formed above the one end of the heat exchange unit 200, the first outlet pipe (below the other end) 320 and a second connection pipe 620 are formed, the second inlet pipe 410 and the second outlet pipe 420 is formed above or below the other end, and the second inlet pipe 410 and The third inlet pipe 510 and the third outlet pipe 520 are formed above or below the other end portion of which the second outlet pipe 420 is not formed.

In addition, the condenser 1 is connected to any one of the first inlet pipe 310 and the first connection pipe 610 of the first communication hole 810 of the condensation region 220, the condensation The second communication hole 820 of the region 220 is connected to the other of the first inlet pipe 310 and the second connection pipe 620 on the upper side, the first communication hole 810 of the subcooling region 210. ) Is connected to any one of the first outlet pipe 320 and the second connection pipe 620 at the lower side, the second communication hole 820 of the subcooling region 210 is the first outlet pipe ( 320 and the second connection pipe 620, the fifth communication hole 850 of the condensation region 220 of the second inlet pipe 410 and the second outlet pipe 420 of the upper side. The sixth communication hole 860 of the condensation region 220 is connected to any one of the second inlet pipe 410 and the second outlet pipe 420 from the upper side, and the subcooling region ( The fifth communication hole 850 of the 210 is connected to any one of the third inlet pipe 510 and the third outlet pipe 520 from the lower side, and the sixth communication hole 860 of the condensation region 220. Is connected to the other one of the third inlet pipe 510 and the third outlet pipe 520 at the lower side.

In addition, the plate 100 has the first flow portion 110 or the second flow portion 120 in the width direction in the region where the first communication hole 810 to the sixth communication hole 860 is not formed Separated portion 140 is formed to protrude in the longitudinal direction up or down so that the first passage 131 and the second passage 132 is formed, one end portion in the longitudinal direction of the partition 140 It is characterized in that the extension is formed between the third communication hole 830 and the fourth communication hole (840).

In addition, the plate 100 is characterized in that the stepped portion 150 is formed so that the circumferential surface protrudes in the upper or lower direction so that a plurality can be stacked.

The refrigeration cycle of the vehicle air conditioner of the present invention uses the cooling water supplied from the low-temperature radiator as the second heat exchange medium in the condensation zone of the water-cooled condenser in which a plurality of plates are stacked and the first heat exchange medium and the second heat exchange medium flow alternately. In the subcooling region, the first heat exchange medium is cooled by using a refrigerant on the outlet side of the evaporator, thereby increasing the subcooling temperature to improve condensation performance.

In addition, the refrigeration cycle of the vehicle air conditioner of the present invention has the advantage that it is possible to improve the supercooling efficiency without additional space by receiving the refrigerant from the evaporator included in the prior art without additional equipment.

In addition, since the water-cooled condenser included in the refrigeration cycle of the vehicle air conditioner of the present invention is heat-exchanged by the water-cooling method, the amount of air required is smaller than that of the existing air-cooled heat exchanger, so the engine room mounting position is limited. There is an advantage that is not.

1 is an exploded perspective view showing a conventional water-cooled condenser.
2 is a system diagram showing a refrigeration cycle of a vehicle air conditioner including a water-cooled condenser according to the present invention.
3 is a perspective view showing a water-cooled condenser according to the present invention.
Figure 4 is an exploded perspective view showing a water-cooled condenser according to the present invention.
5 is a perspective view showing a plate of the water-cooled condenser according to the present invention.
6 is a view showing a first heat exchange medium flow of the water-cooled condenser shown in FIG.
7 and 8 show the flow of the second heat exchange medium of the water-cooled condenser shown in FIG.

Hereinafter, the refrigeration cycle of the vehicle air conditioner of the present invention as described above will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing a conventional water-cooled condenser, Figure 2 is a system diagram showing a refrigeration cycle of a vehicle air conditioner including a water-cooled condenser according to the present invention, Figure 3 is a perspective view showing a water-cooled condenser according to the present invention, Figure 4 is an exploded perspective view showing a water-cooled condenser according to the present invention, Figure 5 is a perspective view showing a plate of the water-cooled condenser according to the invention, Figure 6 shows a first heat exchange medium flow of the water-cooled condenser shown in FIG. 7 and 8 are views showing the flow of the second heat exchange medium of the water-cooled condenser shown in FIG.

As shown in Figure 2, the refrigeration cycle of the vehicle air conditioner according to the present invention by connecting the compressor (4)-> condenser (1)-> expansion valve (2)-> evaporator (3) to the refrigerant line (5) In the refrigerating cycle configured to circulate the first heat exchange medium, different fluids flow in the condensation zone 220 and the subcooling zone 210 of the compressor 4, respectively.

In the refrigeration cycle of the vehicle air conditioner, the compressor 4 sucks and compresses the first heat exchange medium, and the condenser 1 condenses the first heat exchange medium compressed by the compressor 4 and expands the expansion. The valve 2 throttles the first heat exchange medium condensed in the condenser 1, and the evaporator 3 evaporates the first heat exchange medium flowing from the expansion valve 2.

3 and 4, the condenser 1 has a configuration in which heat exchange occurs while the first heat exchange medium and the second heat exchange medium alternately flow, and a plurality of plates 100 are stacked to form the first heat exchange medium. And a heat exchanger 200 in which a first flow unit 110 through which flow is performed and a second flow unit 120 through which the second heat exchange medium flows are alternately formed.

In addition, the condenser 1 is formed to include a receiver 600 for separating the gas phase heat exchange medium and the liquid phase heat exchange medium of the first heat exchange medium.

The first flow unit 110 is formed to be alternating with the second flow unit 120, a predetermined region is the condensation region 220 and the remaining region the sub-cooling of the first heat exchange medium is condensed The subcooling region 210 is formed, and the condensation region 220 is formed on the upper side, and the subcooling region 210 is formed on the lower side.

In this case, the first heat exchange medium and the second heat exchange medium flowing through the respective spaces of the first flow part 110 and the second flow part 120 are respectively flowed and exchanged and not mixed with each other. The detailed configuration of 100 will be described again below.

Particularly, in the condenser 1 of the refrigeration cycle of the vehicle air conditioner of the present invention, the second heat exchange medium and the subcooling in which the second heat exchange medium flows to the second flow part 120 of the condensation zone 220 are used. It consists of a 2-2 heat exchange medium flowing in the second flow section 120 of the region 210, characterized in that the 2-1 heat exchange medium and the 2-2 heat exchange medium are different fluids.

As described above, the condenser 1 has a second heat exchange medium consisting of the 2-1 heat exchange medium and the 2-2 heat exchange medium and the first heat exchange medium flows therein, so that each heat exchange medium flows in. And inlet and outlet pipes that can be discharged.

3 and 4, the condenser 1 includes a first inlet pipe 310 into which a first heat exchange medium flows into the heat exchange part 200 and a first outlet pipe 320 discharged thereto; A second inlet pipe 410 into which the second-1 heat exchange medium flows into the heat exchange part 200 and a second outlet pipe 420 discharged from the second heat exchange part 200, and a second-2 heat exchange medium flows into the heat exchange part 200; The third inlet pipe 510 is formed and the third outlet pipe 520 is discharged.

Meanwhile, the receiver 600 separates the gas phase heat exchange medium and the liquid heat exchange medium of the first heat exchange medium passing through the condensation region 220 of the first flow unit 110 separately from the heat exchange part 200. As the condensation region 220 and the receiver 600 are connected by a first connection pipe 610, the receiver 600 and the subcooling region 210 are connected through a second connection pipe 620. do.

That is, in the condenser 1 of the present invention, the first heat exchange medium is introduced through the first inlet pipe 310 to pass through the condensation region 220 of the first flow unit 110, and thus the first connection pipe 610. The first outlet pipe 320 is moved to the receiver 600 and flows to the subcooling region 210 of the heat exchange part 200 again through the second connection pipe 620. Is discharged through.

The condenser 1 is connected to the cooling water circulation line 8 in which the second inlet pipe 410 and the second outlet pipe 420 include a water pump 7 and a low temperature radiator 6. Obtain a heat exchange medium.

At this time, the second inlet pipe 410 is connected to the inlet side cooling water circulation line 8 of the water pump 7, and the second outlet pipe 420 is the outlet side cooling water of the low temperature radiator 6. It is connected to the circulation line (8).

2 and 3, in the refrigeration cycle of the vehicle air conditioner, the first inlet pipe 310 of the condenser 1 is connected to the outlet side refrigerant line 5 of the compressor 4, and The first outlet pipe 320 is connected to the inlet refrigerant line 5 of the expansion valve 2, and the third inlet pipe 510 is connected to the outlet refrigerant line 5 of the evaporator 3. The third outlet pipe 520 may be connected to the inlet refrigerant line 5 of the compressor 4.

The condenser 1 is connected to the outlet side refrigerant line 5 of the evaporator 3 through the third inlet pipe 510 to receive a second heat exchange medium, which is then supplied. Since the heat exchange medium has a temperature much lower than the 2-1 heat exchange medium supplied from the low temperature radiator 6 at a temperature of about 10 ° C., the heat exchange efficiency with the first heat exchange medium in the subcooling zone 210 is improved, so that the subcooling is performed well. You can lose.

Accordingly, the 2-1 heat exchange medium flowing in the second flow part 120 of the condensation area 220 is supplied from the low temperature radiator 6 and is supplied to the second flow part 120 of the subcooling area 210. The flow of the second-2 heat exchange medium may be supplied through the refrigerant line 5 on the outlet side of the evaporator 3.

On the other hand, as shown in Figures 4 and 5, the plate 100 forming a plurality of heat exchanger 200 of the condenser 1 is stacked in a hollow so that the first flow unit 110 in communication with the stacking direction And a first communication hole 810 to a fourth communication hole 840 having a first junction 710 protruding upward or downward in a circumference thereof, and the second oil in a stacking direction of the plate 100. The fifth communication hole 850 and the sixth communication hole, in which the eastern part 120 is hollow and the circumference thereof is formed with a second joint part 720 protruding in a direction opposite to the protruding direction of the first joint part 710. 860 is formed.

In FIG. 5, the plate 100 has the fifth communication hole 850, the third communication hole 830, the fourth communication hole 840, and the sixth communication hole 860 from the rear side to the front side on the left side. It is formed sequentially, an example in which the first communication hole 810, and the second communication hole 820 is formed on the right side from the rear side to the front side.

That is, in the same plate 100, the fifth communication hole 850 and the sixth communication hole 860 are formed with a second joint portion 720 in the same direction, and the first communication hole 810 to the fourth communication. The hole 840 is formed with a first junction 710 opposite to the second junction 720.

As shown in FIG. 5, in the basic plate 100 constituting the heat exchange part 200, the first junction part 710 is formed in an upward direction, and the second junction part 720 is formed in a downward direction. The first plate 101 and the first junction 710 is formed in the downward direction and the second plate 102 having the second junction 720 in the upward direction is used, and the first plate 101 and the first plate are used. The two plates 102 are alternately stacked, and at this time, neighboring joining portions are joined to each other.

That is, when the first plate 101 and the second plate 102 are stacked, and the first plate 101 is positioned above the second plate 102, the first plate 101 is located below. ) And the space formed by the second plate 102, the first junction 710 protruding upward of the first plate 101 and the first junction protruding downward of the second plate 102. 710 may communicate with each other so that the first heat exchange medium may move vertically through the space, and a second flow part 120 through which the second heat exchange medium flows is formed in the remaining space except for the bonded portion. .

At this time, since the first plate 101 and the second plate 102 are alternately stacked, the first flow unit 110 through which the first heat exchange medium flows on the upper and lower sides of the second flow unit 120. ) Is formed.

As shown in FIG. 5, the condenser 1 has a second fluid and a second heat exchange medium, respectively, which are different fluids in the second flow part 120 of the condensation area 220 and the subcooling area 210. The first communication hole to allow the second heat exchange medium to flow, and to flow the first heat exchange medium of the liquid phase separated through the receiver 600 to the first flow unit 110 of the subcooling region 210. 810 to 6th communication hole 860 may be formed including a closed plate 103 all closed.

That is, the closed plate 103 in which the first communication hole 810 to the sixth communication hole 860 are all closed is an area in which the condensation area 220 and the subcooling area 210 of the heat exchange part 200 are separated. The first heat exchange medium and the second heat exchange medium may be provided so as not to communicate in the stacking direction.

The condenser 1 has the first inlet pipe 310 and the first connection pipe 610 is formed above the one end of the heat exchange unit 200, the first outlet pipe 320 below the other end. And a second connection pipe 620, and the second inlet pipe 410 and the second outlet pipe 420 are formed above or below the other end, and the second inlet pipe 410 and the second outlet pipe 410 are formed. The third inlet pipe 510 and the third outlet pipe 520 may be formed above or below the other end portion where the outlet pipe 420 is not formed.

The first inlet pipe 310, the first outlet pipe 320, the first connection pipe 610, and the second connection pipe 620 are the second inlet pipe 410, the second outlet pipe 420, and the first outlet pipe 310. The third inlet pipe 510 and the third outlet pipe 520 are formed on the other side, and the first inlet pipe 310 and the first connection pipe 610 are formed on the upper side where the condensation region 220 is formed. The first outlet pipe 320 and the second connection pipe 620 are formed at a lower side where the subcooled region 210 is formed, and the first heat exchange medium having a low temperature passing through the receiver 600 is introduced. It is preferable to make it possible to improve cooling performance more by making it possible.

At this time, the first communication hole 810 of the condensation region 220 is connected to any one of the first inlet pipe 310 and the first connection pipe 610 from the upper side, The second communication hole 820 is connected to the other of the first inlet pipe 310 and the second connection pipe 620 from the upper side, the first communication hole 810 of the subcooling region 210 is the lower side It is connected to any one of the first outlet pipe 320 and the second connection pipe 620, the second communication hole 820 of the subcooling region 210 is the first outlet pipe 320 and the second from the lower side. It is connected to the rest of the connection pipe 620.

In addition, the fifth communication hole 850 of the condensation region 220 is connected to any one of the second inlet pipe 410 and the second outlet pipe 420 from the upper side, and the fifth communication hole 850 of the condensation region 220. The six communication hole 860 is connected to the other one of the second inlet pipe 410 and the second outlet pipe 420 from the upper side, the fifth communication hole 850 of the subcooling region 210 is the lower side It is connected to any one of the third inlet pipe 510 and the third outlet pipe 520, the sixth communication hole 860 of the condensation region 220 is the third inlet pipe 510 and the third from the lower side It is connected to the other one of the outlet pipe 520.

As shown in FIG. 5, the plate 100 has the first flow part 110 or the second in an area where the first communication holes 810 to the sixth communication holes 860 are not formed in the longitudinal direction. A partition 140 protruding upward or downward may be further formed to divide the flow part 120 into left and right directions so that the first flow path 131 and the second flow path 132 are formed.

In the present invention, the first flow passage 131 and the second flow passage 132 are portions forming the first row and the second row, respectively, in the drawing, and are formed in the front and rear rows partitioned by the partition unit 140. Means.

In this case, as shown in FIG. 6, the condenser 1 is disposed such that the first heat exchange medium does not flow in the width direction at the side where the third communication hole 830 and the fourth communication hole 840 are located. One end portion in the longitudinal direction of the partition 140 extends between the third communication hole 830 and the fourth communication hole 840, and the first communication hole 810 to the fourth communication hole 840. One or more of the communication holes may be closed to control the flow thereof.

In addition, the plate 100 may be easily stacked together with the partition 140 and a stepped portion 150 having a circumferential surface protruding upward or downward in order to increase sealing performance may be formed. A bead 160 protruding in the upper or lower direction of the first passage 131 and the second passage 132 may be formed to increase the heat exchange area of the heat exchange medium and the second heat exchange medium.

At this time, the bead 160 is preferably formed to be opposite to the forming direction of the partition portion 140.

Referring to Figures 6 to 8 illustrating the flow of the first heat exchange medium and the second heat exchange medium in the condenser 1 according to the present invention,

The first heat exchange medium flows in through the first inlet pipe 310 and moves vertically through the first communication hole 810 to the fourth communication hole. The first of the first flow part 110 is formed alternately. It flows along the flow path 131 and the second flow path 132 and passes through the condensation region 220 to the receiver 600 through the first connection pipe 610.

After the gas-liquid separation, the first heat exchange medium in the liquid state is again flowed through the second connection pipe 620 to the subcooling area 210 of the heat exchange part 200 and then discharged through the first outlet pipe 320. do.

The 2-1 heat exchange medium is introduced through the second inlet pipe 410 and vertically moved through the fifth communication hole 850 or the sixth communication hole 860, and is alternated in the condensation region 220. After flowing along the first flow path 131 and the second flow path 132 of the second flow portion 120 to be formed, it is moved vertically through the fifth communication hole 850 or the sixth communication hole 860 again. And is discharged through the second outlet pipe 420.

The second-2 heat exchange medium flows in through the third inlet pipe 510 and moves vertically through the fifth communication hole 850 or the sixth communication hole 860 and is alternated in the subcooling area 210. After flowing along the first flow path 131 and the second flow path 132 of the second flow portion 120 to be formed, it is moved vertically through the fifth communication hole 850 or the sixth communication hole 860 again. And is discharged through the third outlet pipe 520.

At this time, the first heat exchange medium flowing in the first flow unit 110 exchanges heat with the second heat exchange medium flowing in the neighboring second flow unit 120, and in the condensation region 220, the low temperature radiator ( The second-1 heat exchange medium supplied from 6) and the second-2 heat exchange medium supplied through the refrigerant line 5 at the outlet side of the evaporator 3 are exchanged in the subcooling region 210.

Accordingly, in the refrigeration cycle of the vehicle air conditioner of the present invention, the cooling water supplied from the low-temperature radiator as the second heat exchange medium in the condensation region of the water-cooled condenser in which a plurality of plates are stacked and the first heat exchange medium and the second heat exchange medium are alternately flowed. In the subcooling region, the first heat exchange medium is cooled by using a refrigerant on the outlet side of the evaporator, thereby increasing the subcooling temperature to improve condensation performance.

In addition, there is an advantage that it is possible to improve the subcooling efficiency without taking up additional space by receiving the refrigerant from the evaporator included in the prior art without adding a separate device.

In addition, since the water-cooled condenser included in the refrigeration cycle of the vehicle air conditioner of the present invention is heat-exchanged by the water-cooling method, the amount of air required is smaller than that of the existing air-cooled heat exchanger, so the engine room mounting position is limited. There is an advantage that is not.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

1: condenser 2: expansion valve
3: evaporator 4: compressor
5: refrigerant line 6: low temperature radiator
7: water pump 8: cooling water circulation line
100: plate
101: first plate 102: second plate
110: first flow part 120: second flow part
131: first euro 132: second euro
140: partition portion 150: stepped portion
160: Bead
200: heat exchanger
210: supercooled zone 220: condensed zone
310: first inlet pipe 320: first outlet pipe
410: second inlet pipe 420: second outlet pipe
510: third inlet pipe 520: third outlet pipe
600: Receiver
610: first connection pipe 620: second connection pipe
710: first joint portion 720: second joint portion
810 ~ 860: 1st ~ 6th Communication Hall

Claims (12)

A compressor (4) for sucking and compressing the first heat exchange medium;
The first flow exchanger 110 and the second flow condensing the first heat exchange medium compressed by the compressor 4, the plurality of plates 100 are stacked to alternately flow the first heat exchange medium and the second heat exchange medium, respectively. The flow unit 120 is formed, the condensation region 220 is formed in a predetermined region of the first flow unit 110 and the second flow unit 120, and the subcooling region 210 in which subcooling is performed in the remaining constant region. A condenser 1 including a heat exchange part 200 formed;
Expansion valve (2) for throttling the first heat exchange medium condensed in the condenser (1);
An evaporator (3) for evaporating the first heat exchange medium flowing from the expansion valve (2); In the refrigeration cycle of the vehicle air conditioner comprising:
The condenser 1
A second heat exchange medium flowing in the condensation zone 220 of the second flow section 120, the second heat exchange medium and the sub-cooling zone 210 of the second flow section 120-2-2 Made of heat exchange medium,
And said 2-1 heat exchange medium and said 2-2 heat exchange medium are different fluids.
The method of claim 1,
The condenser 1
A first inlet pipe 310 into which the first heat exchange medium is introduced into the heat exchange part 200 and a first outlet pipe 320 discharged;
A second inlet pipe 410 into which the 2-1 heat exchange medium is introduced into the heat exchange part 200 and a second outlet pipe 420 discharged;
A third inlet pipe 510 into which the second-2 heat exchange medium flows into the heat exchange part 200 and a third outlet pipe 520 discharged;
A receiver 600 for separating the gas phase heat exchange medium and the liquid heat exchange medium of the first heat exchange medium;
The first connection pipe 610 connecting the condensation region 220 and the receiver 600 of the first flow unit 110 and the subcooling region of the receiver 600 and the first flow unit 110. A second connection pipe 620 for connecting 210; Refrigeration cycle of a vehicle air conditioner, characterized in that it comprises a.
The method of claim 2,
The condenser 1
The first heat exchange medium introduced through the first inlet pipe 310 flows through the condensation region 220 of the first flow unit 110 and the receiver 600 through the first connection pipe 610. And flows again to the subcooled region 210 of the first flow unit 110 through the second connection pipe 620, and is discharged through the first outlet pipe 320. Refrigeration cycle of vehicle air conditioner.
The method of claim 2,
The condenser 1
The second inlet pipe (410) and the second outlet pipe (420) is a refrigeration cycle of a vehicle air conditioner, characterized in that connected to the cooling water circulation line (8) including a water pump (7) and a low temperature radiator (6).
The method of claim 2,
The refrigeration cycle of the vehicle air conditioner
The first inlet pipe 310 is connected to the outlet side refrigerant line 5 of the compressor 4,
The first outlet pipe 320 is connected to the inlet refrigerant line 5 of the expansion valve 2,
The third inlet pipe 510 is connected to the outlet side refrigerant line 5 of the evaporator 3,
The third outlet pipe (520) is connected to the inlet refrigerant line (5) of the compressor (4).
The method of claim 1,
The plate 100 is
A first communication hole 810 to a first hole in which the first flow part 110 is hollow so as to communicate with each other in the stacking direction of the plate 100 and a first joining part 710 is formed to protrude upward or downward; Four communication holes 840; And
The second flow part 120 is hollow so as to communicate with each other in the stacking direction of the plate 100, and a second joint part 720 protruding in a direction opposite to the direction in which the first joint part 710 protrudes is formed. A fifth communication hole 850 and a sixth communication hole 860; Refrigeration cycle of a vehicle air conditioner characterized in that it is formed.
The method of claim 6,
The condenser 1
In the region where the condensation region 220 and the subcooling region 210 of the heat exchange unit 200 are divided
For the vehicle, characterized in that the first plate and the second heat exchange medium is provided with a closing plate 103 in which all of the first communication hole 810 to the sixth communication hole 860 is closed so as not to communicate in the stacking direction. Refrigeration cycle of air conditioner.
The method of claim 6,
The condenser 1
A first plate 101 in which the first junction part 710 is formed in an upward direction and the second junction part 720 is formed in a downward direction;
The first plate 710 is formed in the lower direction and the second plate 102 formed with the second bond portion 720 in the upward direction are alternately stacked,
The first plate (101) and the second plate (102) is a refrigeration cycle of a vehicle air conditioner, characterized in that the adjacent first bonding portion 710 and the second bonding portion 720 are bonded to each other.
The method of claim 2,
The condenser 1
The first inlet pipe 310 and the first connection pipe 610 are formed at an upper end of one end of the heat exchange part 200, and the first outlet pipe 320 and the second connection pipe (below the other end). 620 is formed,
The second inlet pipe 410 and the second outlet pipe 420 are formed above or below the other end,
The third inlet pipe 510 and the third outlet pipe 520 is formed on the upper side or the lower side of the other end where the second inlet pipe 410 and the second outlet pipe 420 is not formed. Refrigeration cycle of vehicle air conditioner.
The method of claim 6,
The condenser 1
The first communication hole 810 of the condensation region 220 is connected to any one of the first inlet pipe 310 and the first connection pipe 610 from the upper side, the second communication of the condensation region 220 The hole 820 is connected to the other of the first inlet pipe 310 and the second connection pipe 620 from the upper side,
The first communication hole 810 of the subcooling region 210 is connected to any one of the first outlet pipe 320 and the second connection pipe 620 at the lower side, the second communication of the subcooling region 210. The hole 820 is connected to the other of the first outlet pipe 320 and the second connection pipe 620 in the lower side,
The fifth communication hole 850 of the condensation region 220 is connected to any one of the second inlet pipe 410 and the second outlet pipe 420 from the upper side, and the sixth communication of the condensation region 220. The hole 860 is connected to the other of the second inlet pipe 410 and the second outlet pipe 420 from the upper side,
The fifth communication hole 850 of the subcooling region 210 is connected to any one of the third inlet pipe 510 and the third outlet pipe 520 at the lower side, and the sixth communication of the condensation region 220. The hole 860 is refrigerated cycle of the vehicle air conditioner, characterized in that connected to the other one of the third inlet pipe 510 and the third outlet pipe 520 at the lower side.
The method of claim 6,
The plate 100 is
The first flow path 110 or the second flow part 120 is separated in the width direction in an area where the first communication hole 810 to the sixth communication hole 860 are not formed, and thus the first flow path 131. And a partition 140 protruding upward or downward in the longitudinal direction to form the second flow path 132,
One end portion in the longitudinal direction of the partition portion 140 extends between the third communication hole (830) and the fourth communication hole (840).
The method of claim 1,
The plate 100 is
A refrigeration cycle of a vehicle air conditioner, characterized in that the stepped portion 150 is formed so that the circumferential surface protrudes in the upper or lower direction so that a plurality can be stacked.

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