KR20110034172A - A water cooling type condenser - Google Patents

Abstract

PURPOSE: A water cooling type condenser is provided to prevent the deformation of a case due to the temperature or pressure change of coolants by combining a condenser with a case through a combination protrusion and a combination groove. CONSTITUTION: A water cooling type condenser includes a lower case(10), an upper case(20), and a condenser(30). A first heat exchange medium flows in a body(11). A first inlet pipe(12) is formed on the body. The first heat exchange medium is discharged through a first outlet pipe(13). A combination groove(15) is vertically formed on the body. The upper case is combined with the lower case. An upper tank(30a) and a lower tank(30b) are inserted into the body of the lower case. A tube(31) is fixed to the upper tank and the lower tank. A combination protrusion(35) corresponds to the combination groove.

Description

Water Cooling Type Condenser

The present invention relates to a condenser for a vehicle, and more particularly, to a water-cooled condenser by improving the air-cooled condenser by water-cooling condensation, thereby reducing the size of the condenser itself to increase the space utilization of the engine room, as well as improving the heat exchange performance. will be.

Various heat exchangers are used for the purpose of reusing thermal energy or lowering or increasing the temperature according to the use, and various heat exchangers are also provided in automobiles. A condenser is a type of heat exchanger, and is a cooling device for supplying cool air to a vehicle interior by exchanging heat with external air as a component provided inside the automotive air conditioner. The condenser is a device in which the refrigerant is introduced and the introduced refrigerant is moved to the tube to cool the tube to dissipate heat of the refrigerant to condense.

1 is an exploded perspective view of a conventional general air-cooled capacitor.

As shown, the conventional condenser 200 includes a plurality of tubes 110 are arranged side by side stacked at a predetermined interval; A plurality of fins 120 interposed between the tubes 110; And a header tank (150) comprising a header (130,130 ') at which both ends of the tube are inserted and fixed, and a tank (140,140') coupled to the header (130,130 ') to form a refrigerant flow path. It is made, including.

Since the condenser having the above configuration is heat exchanged through external air, there is a problem that the size of the condenser is increased and the heat exchange efficiency is also reduced to increase the heat exchange area. Of course, in order to increase the heat exchange efficiency, there is a case where a fan forcibly blowing air is installed, but this is also a problem in the engine room limited by the limited space.

In order to solve this problem, the development of a water-cooled condenser using heat exchanger has been attempted, but the size is relatively small compared to the air-cooled condenser. Is stored and the case in which the condenser is accommodated may be deformed by the coolant that is changed to a state of high temperature and high pressure after heat exchange, and thus, it is urgent to develop a technology for improving the case.

The present invention has been made to solve the above problems, an object of the present invention is to make the heat exchange method of the condenser water-cooled, and to make the condenser and the case coupled through the coupling protrusion and the coupling groove is small in size, heat exchange efficiency The present invention also provides a water-cooled condenser that prevents deformation due to cooling water.

In the water-cooled condenser of the present invention, a first heat exchange medium flows therein and a main body 11 having an upper side opened and a first inlet pipe formed at one side of the main body 11 to introduce the first heat exchange medium ( 12), a lower case 10 forming a first outlet pipe 13 through which the first heat exchange medium is discharged, and a coupling groove 15 formed in the height direction in the main body 11; An upper case 20 coupled to an open upper side of the lower case 10 to seal the lower case 10; The upper tank 30a and the lower tank 30b inserted into the main body 11 of the lower case 10 and spaced apart by a predetermined distance from each other, and the upper and lower tanks 30a and 30b at both ends. A tube 31 fixed to form a second heat exchange medium flow path, a second inlet pipe 33 connected to the upper or lower tanks 30a and 30b, into which a second heat exchange medium flows, and the upper or lower tank A coupling protrusion connected to the second outlet pipe 34 and the tube 31 through which the second heat exchange medium is discharged and connected to the coupling holes 30a and 30b and protruding to correspond to the coupling groove 15 to the outside. It characterized in that it comprises a; condenser 30 to form (35).

In addition, the upper case 20, a predetermined area is formed to extend upward to discharge the internal air of the lower case 10, characterized in that the reservoir tank 23 for receiving the first heat exchange medium overflows is formed. It is done.

In addition, the reservoir tank 23, the inlet 22 for replenishing the cooling water is characterized in that it is formed.

In addition, the upper case 20 or the lower case 10, characterized in that the through-hole 21 through which the second inlet pipe 33 and the second outlet pipe 34 is formed.

In addition, the upper case 20 or the lower case 10, the leakage for preventing the leakage of cooling water in the connection portion of the through-hole 21, the second inlet pipe 33 and the second outlet pipe 34 Preventing means 24 is characterized in that it is provided.

In addition, the first inlet pipe 12 is in communication with the upper side of the lower case 10, the first outlet pipe 13 is characterized in that it is in communication with the lower side of the lower case (10).

In addition, the condenser 30 is characterized in that it comprises a pin (32) interposed between the tube (31).

In addition, the lower case 10 is characterized in that the drain pipe 14 for discharging the cooling water to the outside is in communication with each other.

The water-cooled condenser of the present invention having the above-described configuration frees the design of the limited engine room because the size of the condenser is small, and the heat exchange efficiency is increased, thereby providing an excellent cooling performance to the user.

In addition, by coupling the condenser and the case through the coupling protrusion and the coupling groove there is an effect of preventing the deformation of the case due to the temperature change or pressure of the cooling water flowing into the case to improve the pressure resistance of the case.

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

Figure 2 is an exploded perspective view of the water-cooled condenser of the present invention, Figure 3 is a plan view of the lower case of the present invention. Figure 4 is a plan view of the lower case in which the condenser of the present invention is built, Figure 5 is a perspective front view of the water-cooled condenser structure of the present invention.

Referring to FIG. 2, the water-cooled condenser of the present invention includes a lower case 10, an upper case 20, and a condenser 30. Here, the cooling water is referred to as a first heat exchange medium, and the configuration in which the cooling water flows is also referred to as first. In addition, the refrigerant flowing into the condenser is hereinafter referred to as a second heat exchange medium, and the configuration in which the refrigerant flows is also referred to as second.

2 to 5, the lower case 10 includes a main body 11, a first inlet pipe 12, a first outlet pipe 13, a drain pipe 14, and a coupling groove 15. Can be.

The main body 11 may be formed by opening the upper side in the form of a housing. The first heat exchange medium may flow inside the main body 11. The condenser for heat exchange with the first heat exchange medium may be inserted into the main body 11.

When the lower left side of the illustrated perspective is defined as the front, and the upper right side is defined as the rear, the first inlet pipe 12 may be formed in communication with the upper side of the rear side of the lower case 10. The first inlet pipe 12 communicates with a radiator (not shown), one side of which communicates with the main body 11 and the other side of which heat exchanges the first heat exchange medium having a high temperature and high pressure at low temperature and low pressure. It serves to circulate to the main body (11).

The first outlet pipe 13 may be formed in communication with the front side lower side of the lower case 10. The first outlet pipe 13 communicates with a radiator (not shown), one side of which communicates with the main body 11 and the other side of which heat exchanges the first heat exchange medium having a high temperature and high pressure to a low temperature and low pressure to exchange the first heat exchange medium having a high temperature and high pressure. It serves to circulate to the radiator.

For reference, the radiator is a radiator separate from the existing radiator for the engine, whereas the operating temperature of the radiator for the engine is 110 to 120 degrees Celsius, whereas the radiator should be maintained at the operating temperature of 60 to 70 degrees Celsius. In the terminology, the radiator is referred to as a low temperature radiator (LTR).

A drain pipe 14 may communicate with a lower surface of the lower case 10. One side of the drain pipe 14 communicates with the bottom surface of the main body 11 and the other side is exposed to the outside, so that the drain pipe 14 is stored inside the main body 11 for replacement of the first heat exchange medium or repair of the lower case 10. It is formed for forcibly discharging the first heat exchange medium. As shown in FIG. 5, a valve 14a for opening and closing the drain pipe 14 may be provided on the drain pipe 14.

Coupling grooves 15 may be symmetrically formed on the front and rear sides of the lower case 10. The coupling groove 15 may be formed in a vertical direction. The coupling groove 15 may be spaced apart from the left and right by a predetermined distance, and may include a protrusion 15a protruding toward the inner side of the lower case 10 along an up and down height, and the protrusions 15a may have ends facing each other. A bent portion 15b that is bent toward may be formed. The coupling groove 15 is a configuration for fitting coupling of the capacitor 30 to be described later, the coupling structure for this will be described in detail when explaining the configuration of the capacitor 30.

2 and 5, the upper case 20 may include a through hole 21 and a leak preventing means.

The upper case 20 may be formed in a plate shape. The upper case 20 is shown that the inner periphery of the plate is formed to extend downward to be coupled to the upper end of the lower case 10, but simply the side end of the plate and the upper end of the lower case 10 It may be welded and joined. In addition, if the configuration for sealing the lower case 10, any shape or coupling method will be possible.

The upper case 20 has a through hole 21 through which the second inlet pipe 33 and the second outlet pipe 34 to be described later are formed. The through-holes 21 are formed in a pair and a sealing member is provided on a coupling surface to which the through-holes 21 and the second inlet or the second outlet pipes 33 and 34 are coupled to leak the first heat exchange medium. Can be prevented.

The through hole 21 is illustrated as being formed in the upper case 20, but may be formed in the lower case 10. That is, the upper case 20 may be formed or the lower case 10 may be formed.

A leakage preventing means 24 may be provided at a coupling surface to which the through hole 21 and the second inlet or the second outlet pipe 33 and 34 are coupled.

The leakage preventing means 24 may include a screw portion 24a, a sealing portion 24b, and a nut portion 24c. The leakage preventing means 24 may be provided in each of the through holes 21 coupled to the second inlet or the second outlet pipes 33 and 34.

The screw portion 24a may be formed to extend a predetermined distance upward from a circumferential surface of the through hole 21. A thread for screwing the nut portion 24c may be formed on an outer circumferential surface of the screw portion 24a. Grooves may be formed in the upper inner circumferential surface of the screw portion 24a to allow the sealing portion 24b to be seated. The sealing portion 24b may be an O-ring of a resin material. The sealing portion 24b is inserted into a groove formed at a portion where the outer circumferential surface of the second inlet or the second outlet pipe 33 and 34 and the upper inner circumferential surface of the screw portion 24a contact, that is, the upper inner circumferential surface of the screw portion 24a. It serves to prevent leakage of the first heat exchange medium. The nut part 24c may be a general nut having a screw thread formed on an inner circumferential surface thereof so as to be screwed to the outer circumferential surface of the threaded part 24a. However, when the upper portion of the nut portion 24c is formed to allow the second inlet or the second outlet pipe 33 and 34 to pass therethrough, and the nut portion 24c is coupled to the screw portion 24a. An upper inner surface may be formed to seal the pressing portion 24b.

2, 4 and 5, the configuration of the capacitor 30 is a conventional capacitor is applied as it will be briefly described only the configuration.

As shown, the condenser 30 according to the present invention is fixed to both ends of the upper tank 30a and the lower tank 30b and the upper and lower tanks 30a and 30b provided side by side with a predetermined distance. It consists of a plurality of tubes 31 arranged side by side to form a refrigerant flow path, and a plurality of fins 32 interposed between the tubes 31.

The tubes 31 are arranged side by side to form a plurality of flow paths for the second heat exchange medium. In addition, a pin 32 is interposed between the respective tubes 31.

The upper tank 30a and the lower tank 30b are formed with a plurality of tube insertion holes (not shown) in which both ends of the tube 31 are inserted and fixed together with the upper tank 30a and the lower tank 30b. The flow path of the second heat exchange medium is formed.

At the side end of the upper tank 30a, a second inlet pipe 33 for introducing the second heat exchange medium may be installed to communicate with the inside of the upper tank 30a. In addition, a second outlet pipe 34 for discharging the second heat exchange medium may be installed at a side end of the upper tank 30a so as to communicate with the inside of the upper tank 30a.

At this time, the second inlet pipe 33 and the second outlet pipe 34 are in communication on the upper tank (30a), one side of the flow path of the second heat exchange medium is in communication with the second inlet pipe 33, the second heat exchange medium The other side of the flow path is in communication with the second outlet pipe. The second inlet pipe 33 serves to introduce a second heat exchange medium into the condenser 30, and the second outlet pipe 34 serves to discharge the heat exchanged second heat exchange medium from the condenser 30. Do it.

The second inlet pipe 33 and the second outlet pipe 34 are shown to be connected to the upper tank 30a, but may also be connected to the lower tank 30b. That is, the second inlet pipe 33 and the second outlet pipe 34 may be connected to the upper tank 30a or to the lower tank 30b.

When the second inlet pipe 33 and the second outlet pipe 34 are connected to the upper tank 30a, the through hole 21 may be formed in the upper case 20, the second inlet pipe When the 33 and the second outlet pipe 34 are connected to the lower tank 30b, the through hole 21 may be formed in the lower case 10.

Since the condenser 30 is inserted into the lower case 10 and sealed by the upper case 20, the second inlet and the second outlet pipes 33 and 34 are through holes of the upper case 20. It communicates with the outside through 21.

At least one coupling protrusion 35 corresponding to the coupling groove 15 may be formed at the front and rear sides of the condenser 30. The coupling protrusion 35 is sandwiched between the pins 32 so that one side protrudes on the front side and the other side protrudes on the rear side, and the body 35a and plate shape are fixed by welding with the pin 32. It may be made of a fitting plate (35b) which is respectively coupled to both side ends of the body (35a).

The body 35a is sandwiched between the bent portions 15b, and the inner surface of the fitting plate 35b contacts the inner surface of the bent portion 15b and slides from the top of the coupling groove 15. Can lose. The coupling protrusion 35 may be formed in plural in the vertical height direction corresponding to the vertical height direction of the coupling groove 15. The condenser 30 and the lower case 10 may be coupled through the coupling protrusion 35 and the coupling groove 15 to prevent the front and rear sides of the lower case 10 from being opened due to internal pressure. Will be. That is, the coupling prevents the deformation of the combined upper case 20 and the lower case 10 according to the temperature change or pressure of the first heat exchange medium flowing into the combined upper case 20 and the lower case 10. The upper case 20 and the lower case 10 has the effect of improving the pressure resistance.

Hereinafter, a second embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

6 is an exploded perspective view of a water-cooled condenser of a second embodiment of the present invention, FIG. 7 is a perspective view of a water-cooled condenser of a second embodiment of the present invention, and FIG. 8 is a plan view of a water-cooled condenser of a second embodiment of the present invention.

In the water-cooled capacitor of the second embodiment of the present invention, only the configuration of the first embodiment and the upper case 20 is different, and detailed descriptions of the remaining components will be omitted.

6 to 8, a through hole 21, an injection port 22, and a reservoir tank 23 may be formed in the upper case 20.

The upper case 20 may be formed in a plate shape. The upper case 20 is shown that the inner periphery of the plate is formed to extend downward to be coupled to the upper end of the lower case 10, but simply the side end of the plate and the upper end of the lower case 10 It may be welded and joined. In addition, if the configuration for sealing the lower case 10, any shape or coupling method will be possible.

The upper case 20 has a through hole 21 through which the second inlet pipe 33 and the second outlet pipe 34 described above in the first embodiment pass. The through-holes 21 are formed in a pair and a sealing member is provided on a coupling surface to which the through-holes 21 and the second inlet or the second outlet pipes 33 and 34 are coupled to leak the first heat exchange medium. Can be prevented.

In more detail, a leakage preventing means 24 may be provided at a coupling surface to which the through hole 21 and the second inlet or the second outlet pipe 33 and 34 are coupled.

A reservoir tank 23 may be formed on an upper surface of the upper case 20. The reservoir tank 23 may be opened in a lower shape and communicate with the lower case 10, and an injection hole 22 may be formed on an upper surface thereof. The reservoir tank 23 is formed higher than the water level in which the first heat exchange medium is stored to serve to receive the first heat exchange medium that overflows. The injection port 22 may be opened and closed through a cap 22a having an upper portion communicating with the outside. The inlet 22 is formed to replenish the first heat exchange medium.

At this time, an overflow tube 22b may be formed on the side surface of the injection hole 22. The overflow pipe 22b is formed so that one side is in communication with the side surface of the inlet, the other side is exposed to the outside, to discharge the internal air of the lower case 10, the first heat exchange medium is the reservoir tank (23) If it exceeds the level of), it serves as a forced discharge.

Hereinafter, a third embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

9 is a perspective front view of a water-cooled condenser of a third embodiment of the present invention.

The water-cooled condenser of the third embodiment of the present invention differs only in the configuration of the first embodiment and the condenser 30, and thus detailed descriptions of the remaining components will be omitted.

As shown in the condenser 30 according to the third embodiment of the present invention, the upper tank 30a and the lower tank 30b and the upper and lower tanks 30a and 30b which are provided side by side at a predetermined distance apart from each other. It is composed of a plurality of tubes 31 are arranged side by side so that both ends are fixed to form a refrigerant passage.

The difference between the condenser 30 of the third embodiment and the first embodiment is that the pins placed on the tube 31 are deleted.

The fin may be an essential configuration in the case of air-cooled condenser, but in the case of water-cooled condenser, heat exchange performance is superior to air-cooled, so the heat exchange performance is not largely reduced even if the fin is deleted.

The tubes 31 are arranged side by side to form a plurality of flow paths for the second heat exchange medium.

The upper tank 30a and the lower tank 30b are formed with a plurality of tube insertion holes (not shown) in which both ends of the tube 31 are inserted and fixed together with the upper tank 30a and the lower tank 30b. The flow path of the second heat exchange medium is formed.

As described above, the condenser 30 having the pins removed may be easily manufactured, and the manufacturing cost may be reduced.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention. Therefore, the embodiments described in the present specification and the configuration shown in the drawings are only the most preferred embodiments of the present invention, and do not satisfy all of the technical idea of the present invention, and various equivalents may be substituted for them at the time of the present application. It should be understood that there may be water and variations.

1 is an exploded perspective view of a conventional capacitor

Figure 2 is an exploded perspective view of the water-cooled condenser of the present invention

Figure 3 is a bottom plan view of the present invention

Figure 4 is a plan view of the lower case of the capacitor condenser of the present invention

5 is a perspective view of the water-cooled condenser structure of the present invention.

6 is an exploded perspective view of a water-cooled condenser of a second embodiment of the present invention.

7 is a perspective view of the water-cooled condenser of the second embodiment of the present invention.

8 is a plan view of a water-cooled condenser of a second embodiment of the present invention.

9 is a perspective view of the water-cooled condenser of the third embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: lower case 11: the body

12: first inlet pipe 13: first outlet pipe

14: drain pipe 15: coupling groove

20: upper case 21: through hole

22: injection hole 23: reservoir tank

24: leak prevention means

30 condenser 31 tube

32: pin 33: second inlet pipe

34: second outlet pipe 35: engaging projection

Claims (8)

The first heat exchange medium flows therein and the upper body is opened in the form of a main body 11, the first inlet pipe 12 is formed on one side of the main body 11, the first heat exchange medium is introduced, and the first A lower case 10 forming a first outlet pipe 13 through which one heat exchange medium is discharged, and a coupling groove 15 extending in the height direction in the main body 11; An upper case 20 coupled to an open upper side of the lower case 10 to seal the lower case 10; The upper tank 30a and the lower tank 30b inserted into the main body 11 of the lower case 10 and spaced apart by a predetermined distance from each other, and the upper and lower tanks 30a and 30b at both ends. A tube 31 fixed to form a second heat exchange medium flow path, a second inlet pipe 33 connected to the upper or lower tanks 30a and 30b, into which a second heat exchange medium flows, and the upper or lower tank A coupling protrusion connected to the second outlet pipe 34 and the tube 31 through which the second heat exchange medium is discharged and connected to the coupling holes 30a and 30b and protruding to correspond to the coupling groove 15 to the outside. A condenser 30 forming a 35; Water-cooled condenser comprising a. The method of claim 1, The upper case 20, A water-cooled condenser, characterized in that the reservoir tank (23) is formed to extend a predetermined area upward to discharge the internal air of the lower case (10) and to receive the overflowed first heat exchange medium. 3. The method of claim 2, On top of the reservoir tank 23, Water-cooled condenser, characterized in that the inlet 22 for replenishing the cooling water is formed. The method of claim 1, In the upper case 20 or the lower case 10, The water-cooled capacitor, characterized in that the through-hole 21 through which the second inlet pipe 33 and the second outlet pipe 34 passes. The method of claim 4, wherein In the upper case 20 or the lower case 10, Water-cooled condenser, characterized in that the leakage preventing means for preventing the leakage of cooling water is provided in the connection portion of the through hole (21) and the second inlet pipe (33) and the second outlet pipe (34). The method of claim 1, The first inlet pipe (12) is in communication with the upper side of the lower case (10), the first outlet pipe (13) is characterized in that in communication with the lower side of the lower case (10). The method of claim 1, The condenser (30) is a water-cooled capacitor, characterized in that it comprises a pin (32) interposed between the tube (31). The method of claim 1, Water cooling condenser, characterized in that the lower case 10 is formed in communication with the drain pipe 14 for discharging the cooling water to the outside.

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