DE102011052327A1 - WATER-COOLED CONDENSER - Google Patents

Abstract

A water-cooled condenser is provided which is reduced in size and improved in cooling efficiency thanks to a simple structure, the condenser comprising: a main heat dissipation unit (1) where a refrigerant discharged from a compressor exchanges heat with a cooling water; and a supercooling core unit (5) where a coolant discharged from a receiver dryer (2) exchanges heat with a cooling water, the main heat dissipation unit (1) and the supercooling core unit (5) having separate cooling circuits and being integrated into one unit, a second Cooling water inflow pipe (6b) through which the cooling water flows into the supercooling core unit (5) diverges from a first cooling water inflow pipe (5a) through which the cooling water flows into the main heat dissipation unit (1), and wherein the cooling water flowing in the supercooling core unit (5) flows, is mixed via an internal connecting line (7a) with the cooling water in the main heat dissipation unit (1) and discharged.

Description

The present application claims priority to Korean Patent Application Number 10-2010-0122874 filed on Dec. 3, 2010, the entire contents of which are incorporated herein by this reference.

The present invention relates to a water-cooled condenser, and more particularly, to a water-cooled condenser in which a main heat-emitting core unit and a subcool core unit have separate cooling circuits and are integrally mounted with a cooling water flowing into, merging into, and subsequently into the main heat-discharging unit and the sub-cooling core unit is removed from it.

In general, capacitors are devices that condense and liquefy a gaseous coolant of high temperature and high pressure, which is discharged from a compressor by heat emission of the gaseous refrigerant to the air and / or the cooling water. Depending on the type of cooling, condensers are classified into air-cooled and water-cooled condensers.

Air-cooled condensers used for vehicles are cooled by cooling wind (or cooling air) that flows inward via a bumper or grille at the front of an engine compartment. The system configuration is relatively simple, but the cooling efficiency is unsatisfactory.

Water-cooled capacitors have been increasingly developed despite their complicated structure as compared with that of the air-cooled condensers due to an electric water pump, a storage tank, and a low-temperature radiator because their cooling efficiency is higher than that of the air-cooled condensers.

A known structure of a water-cooled condenser comprises: a separate-type heat exchanger having a main heat-emitting core unit exchanging heat with a wet-vapor refrigerant, and a sub-cooling core unit exchanging heat with a liquid refrigerant, the units being separated from each other. In the heat exchanger, a coolant and a cooling water flow into the main heat emitting unit and exchange heat there. The refrigerant that has exchanged heat in the main heat emitting unit flows into a receiver dryer where the liquid refrigerant is separated from the gaseous refrigerant, and separately flows into the subcool core unit while the cooling water drains from the main heat output unit is discharged outside. In the same way, a specific cooling water also flows into the subcool core unit, exchanges heat with the coolant in the subcool core unit, and is then discharged from the subcool core unit.

Furthermore, another structure has been proposed in which a main heat emitting unit and a subcooling core unit have separate cooling circuits and integrated into one unit. A refrigerant flows into the main heat-discharging unit and is led out of the sub-cooling core unit after passing through a collector-drier. A cooling water flows into the main heat emitting unit and is then discharged outside via the subcool core unit.

The information disclosed herein in the context of the general background of the invention is merely for the better understanding of the general background of the invention and should not be taken as an acknowledgment or any form of indication that this information represents a prior art well known to those skilled in the art.

Various aspects of the present invention provide a water-cooled condenser whose size is small thanks to a simple structure and whose cooling efficiency is improved.

One aspect of the present invention provides a water-cooled condenser in which a main heat-discharging unit where a refrigerant discharged from a compressor exchanges heat with a cooling water and a sub-cooling core unit where a coolant discharged from a header dryer exchanges heat with a cooling water separate cooling circuits and are integrated into a single unit, wherein a second cooling water inflow pipe through which the cooling water flows into the subcool core unit diverges from a first cooling water inflow pipe through which the cooling water flows into the main heat radiating unit, and the cooling water flowing in the subcool core unit passes over an internal connection pipe is mixed with the cooling water in the main heat output unit and then discharged.

Preferably, a cooling water inlet and a cooling water outlet of the main heat emitting unit and a cooling water inlet of the subcooling core unit are disposed on the one side of the integrated unit, and a coolant inlet of the main heat emitting unit Coolant outlet of the subcooling core unit arranged on the other side of the integrated unit.

Another aspect of the present invention provides a water-cooled condenser in which a main heat-discharging unit where a refrigerant discharged from a compressor exchanges heat with a cooling water and a sub-cooling core unit where a coolant discharged from a header dryer exchanges heat with a cooling water separate Cooling circuits are integrated into a single unit, wherein a second cooling water inflow pipe through which the cooling water flows into the subcooling core unit diverges from a first cooling water inflow pipe through which the cooling water flows into the main heat releasing unit, and a second cooling water outlet pipe of the subcooling core unit with a first cooling water outlet pipe the main heat emitting unit is connected.

According to various aspects of the present invention, since the main heat emitting unit and the subcooling core unit have separate cooling circuits and integrated into one unit, the structure is simplified and the size reduced, which is advantageous in terms of layout. Further, the cooling water discharged from a radiator (or a radiator) separately flows into the main heat emitting unit and the subcool core unit, so that the flow resistance of the cooling water decreases and, accordingly, the flow rate (flow rate) increases, thereby improving the cooling efficiency.

The methods and apparatus of the present invention have further features and advantages, as will become apparent in detail from the appended and the following detailed descriptions, which are incorporated herein and together serve to explain certain principles of the present invention.

1 shows a refrigeration cycle and the structure of an exemplary water-cooled condenser according to the present invention.

2 shows a refrigeration cycle and the structure of an exemplary water-cooled condenser according to the present invention.

It should be understood that the appended drawings are not necessarily to scale, presenting merely a simplified representation of the various features in accordance with the principles of the invention. The particular design features of the present invention as disclosed herein, including, for example, particular dimensions, orientations, locations and outlines, will be determined in part by a particular intended application and use environment.

Reference will now be made in detail to the various embodiments of the present invention, examples of which are illustrated in the accompanying drawings. While the invention will be described in conjunction with the embodiments, it is to be understood that the present description is not intended to limit the invention to those exemplary embodiments. On the other hand, it is intended that the invention not only cover the exemplary embodiments, but also various alternatives, modifications, equivalents, and other embodiments that fall within the spirit and scope of the invention as defined in the appended claims.

1 shows the structure and a circuit of a water-cooled condenser according to various embodiments of the present invention, in which an outlet of a main heat-emitting unit 1 (or a main heat output core unit), which is connected to a compressor (not shown) and gives off the heat of a wet steam refrigerant of high temperature and high pressure, which is discharged from the compressor, via a first connecting pipe 3 with a collector-dryer 2 communicates, leaving a coolant in the main heat output unit 1 has exchanged heat with a cooling water, over the outlet of the main heat emitting unit 1 and over the first connecting pipe 3 into the inlet of the collector-dryer 2 flows in and in the collector-dryer 2 into a gas (gaseous refrigerant) and a liquid (or liquid refrigerant) is separated.

The outlet of the collector-dryer 2 is via a second connecting pipe 4 with the inlet of the supercooling core unit 5 connected so that the coolant in the collector dryer 2 has been separated into a gas and a liquid, via the second connecting pipe 4 and over the inlet of the subcooler core unit 5 into the subcooler core unit 5 flows in and there exchanges heat with the cooling water.

The collector-dryer 2 can with the main heat emitting unit 1 and the subcool core unit 5 be integrated in a unit or provided separately.

As the main heat emitting unit 1 and the subcooler core unit 5 have separate cooling circuits and are integrated into one unit, the structure is simple and the size (or component size) is small.

Further, a cooling water inflow pipe 6 provided by the cooling water through different channels both in the main heat emitting unit 1 and into the subcooler core unit 5 may flow in, so that the cooling water, which has been cooled by a low-temperature radiator (or a low-temperature radiator, not shown), via the Kühlwassereinströmrohr 6 into the main heat emitting unit 1 and into the subcooler core unit 5 can flow in and exchange heat with the coolant.

The cooling water inflow pipe 6 has a second cooling water inflow pipe 6b through which the cooling water into the supercooling core unit 5 can flow in and that of a first cooling water inflow pipe 6a diverges, through which the cooling water into the main heat output unit 1 can flow in, with the pipes 6 . 6a and 6b together form a T-shape or a Y-shape.

Since the cooling water through separate channels in the main heat output unit 1 and into the subcooler core unit 5 can flow in and exchange heat with the coolant, the flow resistance of the cooling water is reduced and thus improves the cooling performance.

Meanwhile, the cooling water entering the subcool core unit 5 and into the main heat emitting unit 1 has flowed through a cooling water inlet pipe 7 that with the main heat output unit 1 connected, led out. A connection line 7a that the main heat emitting unit 1 and the subcooler core unit 5 interconnecting is so transverse (or crossing) to the main heat emitting unit 1 and the subcool core unit 5 arranged that in the supercooling core unit 5 flowing cooling water up into the main heat output unit 1 moved, then mixed and then together with that in the main heat output unit 1 flowing cooling water is led out.

Furthermore, the coolant inlet of the main heat emitting unit 1 and the coolant outlet of the supercooling core unit 5 arranged on a side opposite to the cooling water inlet and the cooling water outlet.

2 shows the structure and a circuit of a water-cooled capacitor according to various embodiments of the present invention, in which the configuration. a cooling water outlet pipe 17 different from that described above, with all other configurations being the same.

That is, the cooling water outlet pipe 17 a first cooling water outlet pipe 17a through which the cooling water from the main heat emitting unit 1 can be removed, and a second cooling water outlet pipe 17b through which the cooling water from the supercooling core unit 5 can be discharged, wherein the first and the second cooling water outlet pipe 17a . 17b are separate parts that are joined together.

As according to the illustrated embodiment, the main heat emitting unit 1 and the subcooler core unit 5 have separate cooling circuits and are integrated in one unit, the structure is simple and the size is reduced. Further, the cooling water separately flows over the cooling water inflow pipe 6 . 6a . 6b into the main heat emitting unit 1 and into the subcooler core unit 5 into and over the cooling water outlet pipe 17 . 17a . 17b out again, so that the flow resistance of the cooling water is reduced by the heat exchange of the coolant and, accordingly, the cooling performance is improved.

For purposes of explanation and detail of the appended claims, terms such as "front," "inner," and "outer," etc. are used to describe the features of the exemplary embodiments with respect to the features illustrated in the figures.

The foregoing descriptions of the specific exemplary embodiments of the present invention are for the purpose of illustration and description. They are not to be construed as exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teachings. The exemplary embodiments have been chosen and described to illustrate certain principles of the invention and their practical application, and to enable those skilled in the art to make and use the various embodiments of the present invention, as well as the numerous alternatives and modifications thereof. It is intended that the scope of the invention be defined by the appended claims and their equivalents.

Claims (4)

A water cooled condenser comprising: a main heat output unit ( 1 ), where a discharged from a compressor coolant exchanges heat with a cooling water; and a supercooling core unit ( 5 ), where one from a collector-dryer ( 2 ) discharged coolant exchanges heat with a cooling water; the main heat emitting unit ( 1 ) and the subcooling core unit ( 5 ) have separate cooling circuits and are integrated in one unit; wherein a second cooling water inflow pipe ( 6b ), through which the cooling water into the supercooling core unit ( 5 ) flows in from a first cooling water inflow pipe ( 6a ) diverges through which the cooling water into the main heat output unit ( 1 flows in; and wherein the cooling water contained in the supercooling core unit ( 5 ), via an internal connection line ( 7a ) with the cooling water in the main heat output unit ( 1 ) is mixed and discharged. The water-cooled condenser according to claim 1, wherein a cooling-water inlet and a cooling-water outlet of the main heat-emitting unit (FIG. 1 ) and a cooling water inlet of the supercooling core unit ( 5 ) are arranged on the one side of the integrated unit, and a coolant inlet of the main heat emitting unit (FIG. 1 ) and a coolant outlet of the supercooling core unit ( 5 ) are arranged on the other side of the integrated unit. A water cooled condenser comprising: a main heat output unit ( 1 ), where a discharged from a compressor coolant exchanges heat with a cooling water; and a supercooling core unit ( 5 ), where one from a collector-dryer ( 2 ) discharged coolant exchanges heat with a cooling water; the main heat emitting unit ( 1 ) and the subcooling core unit ( 5 ) have separate cooling circuits and are integrated in one unit; wherein a second cooling water inflow pipe ( 6b ), through which the cooling water into the supercooling core unit ( 5 ) flows in from a first cooling water inflow pipe ( 6a ) diverges through which the cooling water into the main heat output unit ( 1 flows in; and wherein a second cooling water outlet pipe ( 17b ) of the subcooler core unit ( 5 ) with a first cooling water outlet pipe ( 17a ) of the main heat emitting unit ( 1 ) connected is. The water-cooled condenser according to claim 3, wherein a cooling water inlet and a cooling water outlet of the main heat-emitting unit (FIG. 1 ) and a cooling water inlet of the supercooling core unit ( 5 ) are arranged on the one side of the integrated unit, and a coolant inlet of the main heat emitting unit (FIG. 1 ) and a coolant outlet of the supercooling core unit ( 5 ) are arranged on the other side of the integrated unit.

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