KR20120061534A - Water-cooled condenser - Google Patents

Abstract

PURPOSE: A water-cooled condenser is provided to improve cooling efficiency and increase flow quantity through reducing coolant flow resistance by flowing the coolant supplied from a radiator into a major heat radiation core unit and a super cooling core unit. CONSTITUTION: A water-cooled condenser comprises a major heat radiation core unit(1) and a super cooling core unit(5). The major heat radiation core unit operates the heat exchanging of the coolant discharged form a compressor and cooling water. The super cooling core unit operates the heat exchanging of the coolant discharged form a receiver driver and cooling water. The coolant circuit comprises the major heat radiation core unit and super cooling core unit separately. A first coolant inflow pipe(6) and a second coolant inflow pipe(7) are connected to the major heat radiation core unit and super cooling core unit respectively and the coolant supplied to the major heat radiation core unit and super cooling core unit is vented through being mixed each other.

Description

Water-cooled condenser

The present invention relates to a water-cooled condenser, in particular, the kitchen heat core portion and the subcooling core portion having a cooling circuit that is separated from each other while the cooling water is introduced into the kitchen heat core portion and the subcooling core portion at the same time, the water-cooled Relates to a condenser.

In general, the condenser (condenser) is a high temperature discharged from the compressor. Condensation by dissipating heat from a high pressure gas refrigerant into air and / or cooling water. It is a liquefaction equipment, which is divided into air-cooled condenser and water-cooled condenser according to the cooling method.

The air-cooled condenser used in the vehicle cools the condenser with the cooling air flowing through the foremost bumper or radiator grille in the engine room. The system configuration is relatively simple but the cooling efficiency is not satisfactory.

The water-cooled condenser requires an electric water pump, a reservoir tank, a low-temperature radiator, etc., compared to the air-cooled condenser.

The known water-cooled condenser structure is a separate heat exchanger in which the kitchen heat core portion for exchanging the wet steam refrigerant and the subcooling core portion for exchanging the liquid refrigerant are separated from each other, and the refrigerant and the coolant are introduced into the kitchen heat core to exchange heat with each other. Refrigerant heat exchanged in the kitchen heat core portion is introduced into the receiver dryer after the gas-liquid is separated into the sub-cooling core portion while the cooling water is discharged from the kitchen heat core portion to the outside, and also in the subcooled core portion There is a structure in which a separate cooling water is introduced and heat exchanged with the refrigerant introduced into the subcooling core part and then discharged to the outside from the subcooling core part.

In addition, the kitchen heat core portion and the subcooling core portion are integrated into a single body with a cooling circuit separated from each other, and the refrigerant flows into the kitchen heat core portion and then passes through a receiver dryer, and then is discharged to the outside through the subcooling core portion, and the coolant is There is also a structure that is introduced into the kitchen heat core portion and then discharged to the outside via the subcooled core portion.

It is an object of the present invention to provide a water-cooled condenser that can simplify the structure to reduce its size and improve its cooling efficiency.

In order to achieve the above object, the present invention provides a kitchen circuit core unit for receiving heat from the compressor and exchanging heat with the cooling water, and a cooling circuit having a subcooling core unit for exchanging the refrigerant discharged from the receiver dryer with the cooling water. The second cooling water inlet pipe which is integrated into a single body and allows the cooling water to flow into the subcooling core part is branched to the first cooling water inflow pipe which allows the cooling water to flow into the kitchen heat core part, and the cooling water introduced into the subcooling core part is connected internally. It is configured to be discharged by combining with the cooling water of the kitchen heat core portion through a line.

Preferably, the kitchen heat core part cooling water inlet and the outlet and the cooling water inlet of the subcooling core part are disposed on one side of the unitary body, and the kitchen heat core part refrigerant inlet and the refrigerant outlet of the subcooling core part are disposed on the other side opposite to the single body. It is characterized by.

In addition, the present invention is integrated into a single unit having a cooling circuit separated from each other the kitchen heat core unit for receiving the refrigerant discharged from the compressor and heat exchange with the cooling water and the supercooling core unit for heat exchange the refrigerant discharged from the receiver dryer with the cooling water, the kitchen heat A second coolant inlet pipe for allowing coolant to flow into the subcooled core part is branched to a first coolant inlet pipe for allowing coolant to flow into a core part, and a second coolant outflow of the subcooled core part is discharged to a first coolant outlet pipe for the kitchen heat core part. It is characterized in that the pipe is connected.

According to the water-cooled condenser according to the present invention, as the kitchen heat core portion and the subcooled core portion have a cooling circuit separated from each other and have an integrated structure as a single body, the structure is simplified and the size is reduced, which is advantageous in layout. As the incoming cooling water flows into the kitchen heat core part and the subcooling core part, respectively, the flow rate is increased by decreasing the cooling water flow resistance, thereby improving cooling efficiency.

1 is a cooling circuit and a structural diagram of a water-cooled condenser according to an embodiment of the present invention,
2 is a cooling circuit and a structural diagram of a water-cooled condenser according to an embodiment of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will now be described in detail with reference to the accompanying drawings.

Figure 1 shows the structure and circuit of the water-cooled condenser according to an embodiment of the present invention bar, the high temperature discharged from the compressor connected to the compressor. The outlet of the kitchen heat core part 1 for dissipating the high-pressure wet steam refrigerant is connected to the inlet of the receiver dryer 2 through the first connection pipe 3, and the cooling water in the kitchen heat core part 1 is connected to the outlet of the kitchen heat core part 1. The heat-exchanged refrigerant is introduced into the inlet of the receiver dryer 2 through the first connecting pipe 3 to separate the gas liquid from the inside of the receiver dryer 2.

The outlet of the receiver dryer 2 is connected to the inlet of the subcooling core part 5 through the second connecting pipe 4, and the refrigerant from which the gas liquid is separated from the receiver dryer passes through the second connecting pipe 5. Through the inlet of the subcooled core portion 5 is introduced into the subcooled core portion to exchange heat with the cooling water.

The receiver dryer 2 may be integrated into a single body of the kitchen heat core part 1 and the subcooling core part 5 and may be installed separately.

Since the kitchen heat core part 1 and the subcooling core part 5 have a cooling circuit separated from each other and have a structure integrated into a single body, the structure is simplified and the size is reduced.

In addition, a cooling water inflow pipe 6 is installed in the kitchen heat core part 1 and the subcooling core part 5 to allow cooling water to flow in different paths, respectively, which is cooled in a low temperature radiator through the cooling water inflow pipe. Cooling water flows into the kitchen heat core part and the subcooled core part to exchange heat with the refrigerant.

The cooling water inflow pipe 6 is a second cooling water inflow pipe 6b for allowing the cooling water to flow into the subcooling core part to the first cooling water inflow pipe 6a through which the cooling water flows into the kitchen heat core part 1. Since it has a branched form at, it generally has a T or Y shape.

As described above, as the coolant flows through the respective paths, the kitchen heat core part and the subcooling core part exchange heat with the refrigerant, thereby reducing the cooling water flow resistance and improving the cooling efficiency.

Meanwhile, the cooling water introduced into the subcooling core part 5 and the kitchen heat core part 1 is discharged through the cooling water outlet pipe 7 installed in the kitchen heat core part 1, and the subcooling core part 5 The cooling water flowing into the kitchen heat core part 1 is connected to the kitchen heat core part and the supercooling core part so as to rise toward the kitchen heat core part 1 so as to be combined with the cooling water of the kitchen heat core part. Connected across wealth.

The refrigerant inlet in the kitchen heat core part 1 and the refrigerant outlet in the subcooling core part 5 are arranged to be opposite to the cooling water inlet and outlet.

2 shows the structure and circuit of the water-cooled condenser according to the second embodiment of the present invention. The difference from the first embodiment lies in the configuration of the cooling water outlet pipe 17, and the rest of the configuration is the same.

That is, the cooling water outlet pipe 17 includes a first cooling water outlet pipe 17a for allowing the cooling water to flow out from the kitchen heat core part 1 and a second cooling water outlet pipe for allowing the cooling water to flow out from the subcooling core part 5 ( 17b) are separated separately and merged into one.

In the second embodiment, since the kitchen heat core part 1 and the subcooling core part 5 have separate cooling circuits and have a structure integrated into a single body, the structure is simplified and the size is reduced. Through the cooling water inflow pipe and the cooling water outlet pipe, the kitchen heat core part and the subcooling core part are introduced and discharged through the respective paths, thereby reducing the cooling water flow resistance and improving the cooling efficiency as they exchange heat with the refrigerant.

1-Kitchen Heat Core 2-Receiver Drier
3,4-connected pipe 5-subcooled core
6-Chilled Water Inlet Pipe 7-Cooled Water Outlet Pipe

Claims (4)

The kitchen heat core unit for receiving the refrigerant discharged from the compressor and exchanging heat with the cooling water and the supercooling core unit for exchanging the refrigerant discharged from the receiver dryer with the cooling water are integrated into a single body with separate cooling circuits. A second cooling water inflow pipe is introduced into the first cooling water inflow pipe to allow the cooling water to flow into the subcooling core part, and the cooling water introduced into the subcooling core part is discharged by being combined with the cooling water of the kitchen heat core part through an internal connection line. Water cooled condenser. The cooling water inlet and the outlet of the kitchen heat core part and the cooling water inlet of the subcooling core part are disposed on one side of the unitary body, and the kitchen heat core part refrigerant inlet and the refrigerant outlet of the subcooling core part are opposite to each other in the single body. A water-cooled condenser, characterized in that disposed in. The kitchen heat core unit for receiving the refrigerant discharged from the compressor and exchanging heat with the cooling water and the supercooling core unit for exchanging the refrigerant discharged from the receiver dryer with the cooling water are integrated into a single body with separate cooling circuits. A second cooling water inlet pipe for allowing coolant to flow into the subcooling core part is introduced into the first cooling water inflow pipe to be introduced, and a water cooling type in which the second cooling water outlet pipe of the subcooling core part is connected to the first cooling water outlet pipe of the kitchen heat core part. Condenser. The cooling water inlet of the kitchen heat core part and the outlet and the cooling water inlet of the subcooling core part are disposed on one side of the unitary body, and the kitchen heat core part refrigerant inlet and the refrigerant outlet of the subcooling core part are opposite to each other in the single body. A water-cooled condenser, characterized in that disposed in.

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