KR101771145B1 - Condenser - Google Patents

Abstract

The present invention relates to a condenser, and more particularly, to a downflow type condenser in which a receiver is disposed at a lower end of a condenser, and a heat exchange medium And a communication hole is formed in the body of the receiver so that the flow path of the gas-liquid separator is formed in the longitudinal direction and the bottom of the receiver is hollowed in the height direction. So that the medium can be easily transferred to the supercooled region of the core on the upper side of the receiver.

Description

Condenser

The present invention relates to a condenser, and more particularly, to a downflow type condenser in which a receiver is disposed at a lower end of a condenser, and a heat exchange medium And a communication hole is formed in the body of the receiver so that the flow path of the gas-liquid separator is formed in the longitudinal direction and the bottom of the receiver is hollowed in the height direction. So that the medium can be easily transferred to the supercooled region of the core on the upper side of the receiver.

A heat exchanger is a device that absorbs heat from one side to the other and dissipates heat to the other side. It is a cooling system that absorbs heat from the room and emits it to the outside. It will act as a heating system. Basically, the heat exchanger consists of an evaporator that absorbs heat from the surroundings, a compressor that compresses the refrigerant, a condenser that releases heat to the surroundings, and an expansion valve that expands the refrigerant.

In the cooling apparatus, the actual cooling action is caused by the evaporator in which the liquid refrigerant absorbs the heat amount equivalent to the evaporation heat in the surroundings and is vaporized. The refrigerant gas in the gaseous state flowing into the compressor from the evaporator is compressed to a high temperature and a high pressure in the compressor and the condensed gas is discharged through the condenser, Passes again through the expansion valve, becomes a low-temperature and low-pressure wetted vapor state, and then flows into the evaporator again to be vaporized to form a cycle.

As described above, the refrigerant in a gaseous state at a high temperature and a high pressure flows into the condenser 1 and is condensed into a liquid state while being discharged by heat exchange, and then discharged.

The condenser 1 may be installed as a cross flow type as shown in FIG. 1 or as a down flow type as shown in FIG. 2 depending on the vehicle.

As shown in Fig. 1, in the cross-flow type, a pair of header tanks 2, 3 are spaced apart in the width direction, and a plurality of tubes 4 connecting the pair of header tanks 2, So that the refrigerant flows in the width direction of the condenser 1.

As shown in FIG. 2, in the downflow type, a pair of header tanks 2 and 3 are spaced apart in the height direction, and a plurality of tubes 4 connecting the pair of header tanks 2 and 3 are also arranged in the height direction So that the refrigerant flows in the height direction of the condenser 1.

The baffle 5 provided in the pair of header tanks 2 and 3 causes the refrigerant introduced into the condenser 1 to flow in a zigzag manner through the plurality of tubes 4, , A condensing region (A1) and a supercooled region (A2) in which the refrigerant that has passed through the condensing region (A1) is cooled again.

A receiver (6) is installed on the refrigerant channel of the condenser (1), that is, the receiver (6) is connected to one side of any one of the pair of header tanks (2, 3) And supplies a complete liquid refrigerant with a valve (not shown), and a desiccant (not shown) is sealed therein to absorb moisture contained in the refrigerant.

The upper portion of the vertically installed receiver 6 communicates with the condensing region A1 of the condenser 1 and the lower portion communicates with the supercooled region A2 of the condenser 1, The liquid refrigerant in the refrigerant flowing into the interior of the receiver 6 is positioned at the lower portion of the receiver 6 by gravity and the gaseous refrigerant that has not yet been liquefied is positioned at the upper portion of the receiver 6, Only the liquid phase refrigerant is supplied to the supercooled region A2 of the condenser.

On the other hand, in a defrosting process in which a frost generated in an external heat exchanger, that is, a condenser, which acts as an evaporator, is defrosted during operation of a heat pump of a vehicle, the conventional cross flow type pin / And the frost which melted was frozen again.

On the other hand, the downflow type condenser is formed such that the frost which flows down as the general evaporator for commercial use flows downward, thereby improving the drainage performance and improving the defrosting mode efficiency of the heat pump.

However, in the conventional downflow type condenser, the receiver is constructed inside or outside the condenser in the direction of gravity like the cross flow type due to the characteristics of the liquid refrigerant that has already been condensed by gravity and the gaseous refrigerant that has not yet condensed, In this case, the structure is complicated, which makes it difficult to manufacture and manage.

Therefore, it is necessary to develop a receiver structure suitable for a downflow type condenser in order to solve the above problems.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a downflow type condenser in which a liquid receiver is formed at a lower end, , A communication hole is formed in the body of the receiver so that the flow path of the heat exchange medium discharged into the supercooled region becomes a double pipe shape and a communication hole in which a predetermined area of the bottom surface is hollowed in the height direction is formed, To a supercooled region of a core disposed on the upper side of the receiver, in which a liquid state heat exchange medium separated by gas-liquid separation by gravity is easily conveyed.

The condenser of the present invention includes an upper header tank 110 and a lower header tank 120 which are spaced apart from each other by a predetermined distance in the height direction . A first pipe 210 and a second pipe 220 formed in the upper header tank 110 and through which the heat exchange medium is introduced or discharged ; A plurality of tubes (300) having both ends fixed to the upper header tank (110) and the lower header tank (120) to form a heat exchange medium flow path ; A plurality of pins (400) interposed between the tubes (300 ); A baffle (500) provided inside the upper header tank (110) and the lower header tank (120) to regulate the heat exchange medium flow ; A cylindrical body 610 provided at a lower side of the lower header tank 120 and communicated with the connection portion 700 to separate the gaseous heat exchange medium from the liquid phase heat exchange medium and extending in the width direction, A sealing cap 630 sealing the opening 611 formed at one end of the body 610 and including a filter unit 620 disposed inside the body 610 to filter foreign substances contained in the heat exchange medium; ) and a heat exchanging medium flows into the first connection portion 710 and the connecting portion (700 consisting of the second connection portion 720 which is the heat exchange medium discharged from the body 610 that is), which is discharged to the second connection portion 720 sap that passage of the heat exchanging medium is formed, including the insertion tube 800 that is a communication hole 810 side inserted in the longitudinal direction inside the body 610 and the bottom in the height direction of the predetermined area in which a hollow is formed to be a double tube type (600); And the second electrode is formed.

The first connection part 710 may be formed to have a condensing area A1 so that the heat exchange medium flowing through the first connection part 710 is separated from the heat exchange medium into the body 610, And a liquid heat exchange medium settled on the bottom surface of the body 610 passes through the communication hole 810 through the filter unit 620 and then passes through the second connection unit 720, The filter portion 620 is inserted into the insertion tube 800 to flow into the region A2 and the insertion tube 800, the filter portion 620 and the second connection portion 720 are inserted into the subcooled region A2 And is formed on the side where it is formed.

The insertion tube 800 is formed in a cylindrical shape corresponding to the outer circumferential surface of the filter unit 620 so that the filter unit 620 is inserted and fixed. A protruding portion 820 protruding inward is formed in a certain region of the inner circumferential surface of the insertion tube 800 so that one end portion of the insertion tube 800 is fixedly supported and the other end portion of the insertion tube 800 is fitted to the inner circumferential surface of the body 610 The protruding portion 830 is formed.

The filter unit 620 and the first connection unit 710 are arranged in the condensing region 620 so that the heat exchange medium flowing through the first connection unit 710 passes through the filter unit 620. [ A1 is formed on the bottom surface of the body 610. A liquid heat exchange medium sinking on the bottom surface of the body 610 flows into the insertion tube 800 and passes through the communication hole 810, And the insertion tube 800 and the second connection portion 720 are installed on the side where the super-cooled region A2 is formed so as to flow into the supercooled region A2 through the first and second connection portions 720 and 720, respectively.

In addition, the condenser 10 is connected to the first pipe 210 and the second pipe 220 through the first pipe 210 and the second pipe 220, Both ends of the insertion tube 800 to be inserted into the first connection portion 710 and the insertion tube 800 to be inserted into the second connection portion 720 side are formed so as to be formed on the side where the second connection portion 720 is installed, And extend inward to form an integral body.

In the condenser of the present invention, in order to transfer the liquid-state heat exchange medium collected on the bottom surface of the inside of the receiver body to the core in the downflow type condenser having the receiver at the lower end thereof, the flow path of the heat- A liquid-state heat exchange medium, which is liquid-phase separated by gravity, is installed in the receiver, and the liquid- To the supercooled region of the core on the upper side of the core.

In addition, the condenser of the present invention is capable of forming a liquid receiver at the lower end of the condenser in parallel with a pair of header tanks spaced apart in the height direction and allowing the liquid heat exchange medium to smoothly flow into the supercooled region, And it is advantageous in that it is convenient to manufacture and control compared to the conventional downflow type condenser.

Further, the condenser of the present invention is a downflow type condenser in which the refrigerant flows smoothly between the receiver and the core of the condenser, and the drainage of the melted water is improved in the defrosting process, so that the efficiency of the defrosting mode can be improved when the heat pump operates.

1 is a front view showing a conventional cross-flow type condenser.
2 is a front view showing a conventional downflow type condenser;
3 is a partial cross-sectional view of a condenser according to the present invention.
4 is a partially exploded perspective view of a condenser according to the present invention.
5 is a partial cross-sectional view of another condenser according to the present invention.
6 is a perspective view showing the insertion tube of the condenser shown in Fig.
7 is a side sectional view showing the receiver of the condenser shown in Fig.
8 is a perspective view showing another insertion tube of the condenser according to the present invention.
9 is a partially exploded perspective view showing another condenser according to the present invention.
FIG. 10 is a partial cross-sectional view of the condenser of FIG. 9, showing a flow of a heat exchange medium in operation of a heat pump.
FIG. 11 is a partial cross-sectional view of the condenser of FIG. 9, showing a flow of a heat exchange medium during operation of an air conditioner.

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

FIG. 3 is a partial cross-sectional view of a condenser according to the present invention, FIG. 4 is a partially exploded perspective view showing a condenser according to the present invention, FIG. 5 is a partial cross-sectional view showing another condenser according to the present invention, 7 is a side sectional view showing the receiver of the condenser shown in Fig. 5, Fig. 8 is a perspective view showing another insertion tube of the condenser according to the present invention, and Fig. 9 is a perspective view showing the insertion tube of the condenser shown in Fig. FIG. 10 is a partial cross-sectional view of the condenser of FIG. 9, and FIG. 11 is a partial cross-sectional view of the condenser of FIG. Is a flowchart showing the flow of the heat exchange medium when the air conditioner operates.

The condenser 10 according to the present invention is configured as a down flow type so that the refrigerant flows in a height direction (longitudinal direction).

The condenser 10 includes an upper header tank 110 and a lower header tank 120 which are spaced apart from each other by a predetermined distance in the height direction and a lower header tank 120 which is formed in the upper header tank 110, A plurality of tubes 300 each having a first pipe 210 and a second pipe 220 and both ends fixed to the upper header tank 110 and the lower header tank 120 to form a heat exchange medium flow path; And a heat dissipation fin 400 interposed between the heat dissipation fin 400 and the heat dissipation fin 400 to enhance the heat exchange performance.

A baffle 500 is provided inside the upper header tank 110 and the lower header tank 120 to regulate the flow of the heat exchange medium and the heat exchange medium introduced into the condenser 10 by the baffle 500 includes a plurality It is possible to flow the tubes 300 in a zigzag fashion.

The plurality of tubes 300 constitute a condensing region A1 and a subcooling region A2. That is, the gaseous heat exchange medium flowing into the condenser 10 flows through the plurality of tubes 300 while cooling The region where the liquid phase refrigerant is phase-changed by the liquid phase heat exchange medium is referred to as a condensation region A1 and the region where the liquid phase refrigerant having passed through the condensation region A1 flows again through the plurality of tubes 300 is called a supercooled region.

The condenser 10 may be installed in the upper header tank 110 and the lower header tank 120 to change the position or the number of baffles 500 installed in the upper header tank 110 and the lower header tank 120, May be variously changed.

The upper header tank 110 and the lower header tank 120 may have a single pipe structure and may include a header (not shown) to which both ends of the plurality of tubes 300 are coupled, Tank.

The first pipe 210 and the second pipe 220 are formed in the condenser 10. The first pipe 210 and the second pipe 220 are connected to the heat exchanging medium, Are formed in the upper header tank 110.

At this time, generally, any one of the first pipe 210 and the second pipe 220 into which the heat exchange medium is introduced is formed on the upper header tank 110 side communicating with the condensation region A1, And the remaining one is formed on the upper header tank 110 side communicating with the subcooled region A2.

The downflow type condenser 10 according to the present invention has a structure in which the lower header tank 120 is arranged long in the width direction So that the receiver 600 is also installed in the width direction.

The receiver unit 600 is installed on the lower side of the lower header tank 120 and communicates with the connection unit 700. The liquid receiver 600 is separated from the gaseous heat exchange medium and the liquid heat exchange medium and has a cylindrical body 610 ).

At this time, the body 610 has both side ends opened in the width direction, one of which is sealed by the sealing cap 630, and the sealing cap 630 is provided inside the body 610 And a filter unit 620 for filtering foreign substances contained in the heat exchange medium. In addition, the opening 611 formed on the other side is sealed by the stopper 650.

A desiccant 640 is accommodated in the body 610. The desiccant 640 absorbs and removes moisture contained in the heat exchange medium.

The condenser 10 according to the present invention includes a first connection portion 710 and a second connection portion 720 in which the lower header tank 120 and the body 610 are formed to communicate with each other, .

The first connection portion 710 is a passage through which the heat exchange medium is introduced into the receiver 600 and the second connection portion 720 is a passage through which the heat exchange medium is discharged from the receiver 600.

Particularly, the receiver 600 of the condenser 10 according to the present invention is inserted longitudinally into the body 610 such that the flow path of the heat exchange medium discharged to the second connection portion 720 is a double pipe, And an insertion tube 800 in which a communication hole 810 in which a predetermined region of the bottom surface is hollow is formed.

3, the receiver 600 includes a first connection part 710 for condensing the heat exchange medium introduced through the first connection part 710 into the body 610, And is provided on the side where the region A1 is formed.

The liquid receiver 600 may be configured such that a liquid heat exchange medium submerged on the bottom surface of the body 610 passes through the communication hole 810 through the filter unit 620 and then passes through the second connection unit 720, The filter unit 620 is inserted into the insertion tube 800 so as to flow into the supercooled region A2 through the first and second connection portions 620 and 620. The insertion tube 800, A2 may be formed.

The insertion tube 800 may be formed into a cylindrical shape corresponding to the outer circumferential surface of the filter unit 620 so that the filter unit 620 is inserted and fixed. The protruding portion 820 may be formed to protrude inwardly of a certain region of the inner circumferential surface of the insertion tube 800 so that the right end of the filter portion 620 is fixedly secured to one end of the filter portion 620 in FIG.

In addition, tight fitting portions 830 and 830 may be formed so that both end portions of the insertion tube 800 protrude outward so as to be in close contact with the inner circumferential surface of the body 610.

Therefore, since the clearance between the contact portions 830 and 830 of the insertion tube 800 and the inner circumferential surface of the body 610 are tightened, no gap is generated between the contact portions 830 and 830 of the insertion tube 800, All of the heat exchange medium may be introduced into the insertion tube 800.

Next, the heat exchange medium passes through the filter unit 620 by the protrusion 820, passes through the communication hole 810 through the filter unit 620, 7 along the space between the double pipes formed between the bodies 610 and can be discharged to the supercooled region A2 through the second connection portion 720. [

5, the receiver 600 includes a filter unit 620 and a first filter unit 620 so that the heat exchange medium introduced through the first connection unit 710 passes through the filter unit 620, The connection portion 710 may be provided on the side where the condensation region A1 is formed.

The receiver 600 may be configured such that a liquid heat exchange medium sinking on the bottom surface of the body 610 flows into the insertion tube 800 and passes through the communication hole 810, And the second connection portion 720 may be installed on the side where the subcooled region A2 is formed to flow into the supercooled region A2 through the first and second connection portions 720 and 720. [

3, the insertion tube 800 may be formed with a tightly coupled portion 830 that protrudes outward so that both end portions of the insertion tube 800 closely contact the inner circumferential surface of the body 610 have.

Therefore, the receiver unit 600 can be easily inserted into the first connection unit 710 because the tight fitting unit 830 of the insertion tube 800 and the inner circumferential surface of the body 610 are in close contact with each other, The heat exchange medium passing through the inlet tube 620 may be introduced into the insertion tube 800.

Next, the heat exchange medium passes through the communication hole 810 formed in the lower side of the insertion tube 800, and then, along the space between the double tubes formed between the insertion tube 800 and the body 610, And can be discharged to the subcooled region A2 through the second connection portion 720. [

The communication hole 810 formed in the insertion tube 800 may be formed by hollowing a certain region of the lower outer circumferential surface of the insertion tube 800 as shown in FIG. 6, and the communication hole 810 may be formed as shown in FIG. And may extend to one end of the insertion tube 800 so that a predetermined region of the outer circumferential surface of the end portion is opened.

8, when the body 610 and the second connection portion 720 are assembled first, the side where the communication hole 810 is formed faces the upper side when the receiver 600 is assembled So that the protruded portion of the second connection portion 720 is not caught, and then the communication hole 810 is rotated and assembled so as to be positioned on the floor.

9, the condenser 10 is connected to the inlet pipe 800 through the first pipe 210 and the second pipe 220, (800) inserted into the first connection part (710) so that both the first connection part (710) and the second connection part (720) are formed, and the second connection part Both ends of the insertion tube 800 to be inserted into the insertion tube 800 may extend in the inward direction and be integrally formed.

In this case, the condenser 10 is applied to a heat pump system that simultaneously performs cooling and heating using one refrigerant. Since the refrigerant is moved in the opposite direction in cooling and heating, The second pipe 220 may or may not be provided with the heat exchange medium.

As shown in FIG. 11, the heat exchange medium may be introduced through the first pipe 210 and the heat exchange medium may be discharged through the second pipe 220 during cooling.

At this time, the heat exchanging medium flows into the condenser 10 through the first pipe 210, flows in a staggered manner along the condensing region A1 by the baffle 500, and then flows through the first connecting portion 710 To the receiver (600).

Next, the heat exchange medium flows along the double pipe through the filter unit 620, passes through the communication hole 810 of the insertion pipe 800 positioned at the second connection unit 720 side, And is discharged to the subcooled region (A2) through the second connection portion (720) by being lifted along the space between the double pipe formed between the body (800) and the body (610). The supercooled heat exchange medium through the supercooled zone (A2) is discharged through the second pipe (220).

As shown in FIG. 10, when heating, the heat exchange medium is discharged through the first pipe 210, and the heat exchange medium may be introduced through the second pipe 220.

At this time, the heat exchanging medium flows into the condenser 10 through the second pipe 220, and then flows into the receiver 600 through the first connecting part 710.

Then, the heat exchange medium passes through the filter unit 620 along the double pipe, and the gaseous heat exchange medium and the oil, which are separated from the filter unit 620, are passed through the communication hole 810, And then discharged through the second connection part 720, and then finally discharged through the first pipe 210. The first pipe 210 and the second pipe 210 are connected to each other through a pipe (not shown).

10 and 11, the insertion tube 800 includes an insertion tube 800 inserted into the first connection portion 710 and an insertion tube 800 inserted into the second connection portion 720 side. And the extended portion may be formed so as to be in close contact with the inner circumferential surface of the body 610 like the tightly coupled portion 830 of the insertion tube 800. [

At this time, the desiccant 640 is inserted into the insertion tube 800 to be received in the receiver 600.

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.

110: upper header tank 120: lower header tank
210: inlet pipe 220: outlet pipe
300: tube
400: pin
500: Baffle
600: Receiver
610: Body 611:
620: Filter part 630: Sealing cap
640: desiccant 650: cap
700: Connection
710: first connection part 720: second connection part
800: Insertion tube
810: communication hole 820: protrusion
830:
A1: condensation region A2: supercooled region

Claims (5)

An upper header tank 110 and a lower header tank 120 that are spaced apart from each other by a predetermined distance in the height direction ;
A first pipe 210 and a second pipe 220 formed in the upper header tank 110 and through which the heat exchange medium is introduced or discharged ;
A plurality of tubes (300) having both ends fixed to the upper header tank (110) and the lower header tank (120) to form a heat exchange medium flow path ;
A plurality of pins (400) interposed between the tubes (300 );
A baffle (500) provided inside the upper header tank (110) and the lower header tank (120) to regulate the heat exchange medium flow ; And
A cylindrical body 610 disposed at a lower side of the lower header tank 120 and communicated with the connection portion 700 to separate the gaseous heat exchange medium from the liquid phase heat exchange medium and extending in the width direction, A sealing cap 630 that hermetically closes the opening 611 formed at one end of the body 610 and includes a filter unit 620 disposed inside the body 610 to filter foreign substances contained in the heat exchange medium, a connection portion consisting of the first connection portion 710 and the second connecting portion 720 where the heat exchange medium discharged from the body (610) where the heat exchange medium inlet 700, a heat exchange medium discharged from the second connection portion 720 the receiver of the flow path is formed including the insertion tube 800 that is a communication hole 810 side inserted in the longitudinal direction inside the body 610 and the bottom in the height direction of the predetermined area in which a hollow is formed to be a double tube form ( 600); ≪ / RTI >
The receiver (600)
The first connection part 710 is installed on the side where the condensation area A1 is formed so that the heat exchange medium flowing through the first connection part 710 is separated into gas and liquid and is received in the body 610,
A liquid heat exchange medium that has settled on the bottom surface of the body 610 passes through the communication hole 810 through the filter portion 620 and flows through the second connection portion 720 to the subcooled region A2, The filter unit 620 is inserted into the insertion tube 800 and the insertion tube 800 and the filter unit 620 and the second connection unit 720 are installed on the side where the subcooled region A2 is formed Lt; / RTI >
delete The method according to claim 1,
The insertion tube (800)
The filter unit 620 has a cylindrical shape corresponding to the outer circumferential surface of the filter unit 620,
A protrusion 820 is formed in which a certain region of the inner circumferential surface of the insertion tube 800 projects inward so that one end of the filter unit 620 facing the inside of the body 610 is fixedly secured,
And a tight fitting portion (830) protruding outward so that both end portions of the insertion tube (800) are in close contact with the inner circumferential surface of the body (610).
delete 4. The method according to any one of claims 1 to 3,
The condenser (10)
Both the first pipe 210 and the second pipe 220 are connected to the first pipe 210 and the second pipe 220,
An insertion tube 800 inserted into the first connection part 710 such that both the first connection part 710 and the second connection part 720 are formed by the insertion tube 800, And both ends of the insertion tube (800) inserted into the second connection portion (720) side extend inward to form an integral body.

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