KR100450123B1 - Sub cool condenser for airconditioner - Google Patents

Abstract

The present invention relates to a sub-cooling condenser for an air conditioner, and a main object of the present invention is to assemble the upper and lower half parts of the receiver tank separately and to assemble the advantages of the integrated type and the separate type to improve the productivity. To further go out, to form a plurality of two or more passages up and down to reduce the passage resistance, to stabilize the refrigerant pulsation.

A characteristic configuration of the present invention for achieving the above object is a pair of header pipes (1a) (1b) arranged in parallel with each other, a plurality of tubes (3) connecting between the header pipes, and After the cooling fins 4 are filled in between, the baffles 1c provided in the header pipes 1a and 1b guide the flow path of the refrigerant to the zigzag along the tubes 3. The receiver tank 5 is provided next to the header pipe 1a on one side, and flows in through the refrigerant inflow passage 51, and then only the liquid refrigerant through the refrigerant outlet passage 52 is located at a lower subcool zone ( 10. In the sub-cooling condenser to increase the cooling efficiency, the receiver tank (5) has an upper end cap (58) and an upper half with a bracket, and brazing welding with the one side header pipe (1a) The lower half part is made of the clad aluminum material pipe 5a to fix. The extruded aluminum material pipe 5b is to be bonded to each other, which is embedded in the above-mentioned receiver tank 5 and can be inserted from below, and the lower end of the above-mentioned receiver tank 5. It is composed of a plug (7) for sealing, but easy to assemble bonsai, and a filter (8) for assembling on the upper side of the plug (7) to filter foreign matter in the refrigerant.

Description

SUB COOL CONDENSER FOR AIRCONDITIONER

The present invention relates to a sub-cooling condenser for an air conditioner, comprising a receiver for sending only a liquid refrigerant to a sub-cooling zone under the core constituting the condenser, wherein the structure of the receiver tank, the desiccant pack therein, It is characterized by improving the structure of the filter and the plug.

In general, the air conditioner of the vehicle includes an air conditioner to supply cold air or remove moisture to the interior of the vehicle, and the air conditioner is provided by connecting a condenser that radiates heat while condensing the compressor to compress and supply the refrigerant. The condenser is connected to a capillary tube and an evaporator to perform a heat exchange action, and to supply the cool air generated by the heat exchange action to the interior of the vehicle to use as a cooling device of the vehicle, and to remove moisture from the refrigerant. In order to improve the cooling efficiency, a receiver drier was installed, and a sub cooling capacitor was provided.

Such a conventional subcooled condenser is a separate type in which the condenser assembly 1 and the receiver tank 2 are separated as shown in FIG. 1, and the condenser assembly 1 and the receiver tank as shown in FIG. 2. There is a receiver integrated type in which (2a) is integrated.

In the former case, the condenser is attached in a separate process after the core of the condenser is welded. The processability is good, but after preparing the parts necessary for manufacturing the condenser, the condenser is attached in the final finishing process of condenser production. Disadvantages such as weakness in vibration durability, inconvenient installation in the vehicle because it occupies a relatively large amount of space, a problem that takes a lot of passage resistance because it is connected separately, and the problem that the manufacturing cost increases.

In the latter case, there is a cylindrical type made of one part and an assembly type made of two parts, and it is not vulnerable because brazing welding is performed by assembling the receiver tank on the opposite side of the header pipe into which the tube is inserted. However, clad material should be used, and it is difficult to embed a pack or plastic cartridge containing a desiccant at the bottom, and to seal it, a sealing structure must be formed on the receiver body. Therefore, the aluminum material is difficult to manufacture.

The present invention has been made to solve the conventional problems as described above to solve the above problems, the main object of the invention is to configure the upper half and the lower half of the receiver tank separately, so as to assemble the integral and separate type It is intended to improve the productivity by combining the advantages, and further to form a plurality of two or more passages, up and down to reduce the passage resistance, to stabilize the refrigerant pulsation.

A characteristic configuration of the present invention for achieving the above object consists of a pair of header pipes arranged side by side, a plurality of tubes connecting between the header pipes, and a cooling fin filled between the tubes. And a baffle provided in the header pipe to guide the coolant flow path to the zigzag along the tubes, and include a receiver tank next to the header pipe on one side, and flows through the coolant inflow passage. In the sub-cooling condenser to improve the cooling efficiency by sending only the liquid refrigerant to the sub-cooling zone through the outflow passage, the receiver tank has a top end cap and the upper half of the bracket, the one side header pipe and brazing Clad aluminum material is fixed by welding, and the lower half is extruded aluminum material and joined together. It is to be built in the above-mentioned receiver tank, the desiccant pack that can be inserted from the bottom, and the lower end of the receiver tank, the plug easy to assemble bonsai, and assembled on the top of the plug refrigerant It is composed of a filter for filtering foreign substances in the inside.

1 is a cross-sectional view of the main part showing a conventional receiver separate sub-cooling capacitor

2 is a sectional view showing main parts of a conventional receiver integrated subcooled capacitor.

3 is a front view showing a subcooling capacitor of the present invention;

4 is a sectional view of main parts of the present invention;

Figure 5 is a cross-sectional view showing only the receiver tank of the present invention

6 is an exemplary view showing a desiccant pack of the present invention

7 is a cross-sectional view showing a filter and a plug of the present invention.

<Code Description of Main Parts of Drawing>

5: receiver tank 5a: clad aluminum material pipe

5b: extruded aluminum pipe 6: desiccant pack

7: plug 8: filter

51: refrigerant inlet passage 52: refrigerant outlet passage

53: expansion inner diameter 54: insertion end

55: introverted part 56: female thread part

57: straight inner diameter 58: stopper

59: welding protrusion 70: seating portion

71: O-ring 72: screw

73: flange 74: O-ring groove

81: mesh 82: expansion jaw

83: reduction

Hereinafter, the configuration and operation of the present invention will be described in detail with reference to the accompanying drawings.

3 is a front view showing the capacitor of the present invention, Figure 4 is a cross-sectional view of the main part of the present invention.

As shown in the drawing, the subcool condenser 100 includes a pair of header pipes 1a and 1b arranged in parallel with each other, a plurality of tubes 3 connecting between the header pipes, and between the tubes. After the cooling fins 4 are filled in between, the baffles 1c provided in the header pipes 1a and 1b guide the flow path of the refrigerant to the zigzag along the tubes 3. The receiver tank 5 is provided next to the header pipe 1a on one side, and flows in through the coolant inflow passage 51, and then only the liquid refrigerant through the coolant outlet passage 52 is located at the bottom of the subcool zone 10. Is supposed to be sent.

At this time, in the present invention, the above-mentioned receiver tank 5 is integrally configured with one side header pipe 1a, the upper part is made of clad aluminum material pipe 5a, and the lower part is made of extruded aluminum material pipe 5b. To combine with each other.

That is, the upper clad aluminum material pipe (5a) is formed in the lower end of the expansion inner diameter portion 53, the extruded aluminum material pipe (5b) is formed by inserting the end portion 54 on the upper end of the fitting method Assemble

And the clad aluminum material pipe (5a) is provided with a top end cap 58 and a bracket, in particular, the braided welding material (CLAD) for brazing welding should be applied so as to enable brazing welding with one side of the header pipe (1a).

When the bonding material is applied, the bonding material CLAD is also applied to the expanded inner diameter portion 53 of the clad aluminum material pipe 5a, and when the insertion end 54 of the extruded aluminum material pipe 5b is brazed, Confidentiality can be maintained.

In addition, the extruded aluminum material pipe 5b is at least one refrigerant inlet passage 51 communicating with the lower end of one header pipe 1a, and a refrigerant outlet passage communicating with the subcool zone 10 of one header pipe 1a. 52).

In addition, between the refrigerant inlet passage 51 and the refrigerant outlet passage 52 is provided with an inwardly annular annulus portion 55 having an arbitrary inner diameter D on its inner circumferential surface, and at its lower inner diameter a female screw portion 56. And a straight inner diameter portion 57 thereunder.

The desiccant pack 6 is formed by forming a bag of woven fabric paper through which a refrigerant can pass, and then sealing the desiccant therein.

On the other hand, the extruded aluminum material pipe (5b) can be sealed with a plug 7, the lower end of the built-in filter (8).

At this time, the plug 7 is composed of a threaded portion 72, a plurality of O-rings 71 fitted into the O-ring groove 74 thereunder, and a flange portion 73 below the screw portion as shown in FIG. When 72 is screwed into the female screw portion 56 of the extruded aluminum material pipe 5b, the O-ring 71 is brought into close contact with the linear inner diameter portion 57 below it so that airtightness is maintained.

In addition, the filter 8 has an outer circumferential surface mainly made of a net body 81, has an expansion jaw 82 at an upper end thereof, and a lower reduction part 83 is fitted to a seating part 70 of an upper surface of the plug 7 to be assembled. In particular, the height (H) of the filter (8) should be such that the height except for the lower portion 83 is the same dimension as the upper surface of the plug (7) and the bottom surface of the inward annulus (55). .

That is, the expansion jaw 82 of the filter 8 must be in close contact with the inwardly annular annulus 55 so that the refrigerant passing through the desiccant pack 6 flows only through the filter 8.

According to the receiver of the present invention configured as described above, the refrigerant enters the receiver tank 5 through the refrigerant inlet passage 51, and then the water is removed while passing through the desiccant pack 6, the extruded aluminum material thereunder The pipe 5b flows downward through the inwardly annular frame 55 of the pipe 5b, and foreign matter is filtered out of the filter, and then liquefied and then moved to the subcool zone 10 through the refrigerant outlet passage 52.

On the other hand, when the desiccant pack 6 is to be replaced, the lower plug 7 of the receiver tank 5 is disassembled, and then the filter 8 is temporarily taken out and taken out through the inwardly annular annulus 55. .

At this time, the desiccant pack (6) is slightly larger than the inner diameter (D) of the inwardly facing annulus portion 55, it is convenient to take out using a separate tong tool.

And again when the new desiccant pack (6) is inserted through the inner diameter (D) of the inwardly annulus part 55 forcibly inserted.

The present invention as described in detail above constitutes a receiver tank, the upper half of the clad aluminum material pipe, the lower half of the extruded aluminum material structure is assembled to each other, so when the receiver tank is assembled in the header pipe cladding the upper half By using an aluminum material pipe, it can be assembled by the method of brazing welding like the conventional one-piece type, and productivity is greatly improved.

In addition, since the desiccant pack inside is made of fabric paper, it is easy to manufacture and greatly reduce the cost, and in particular, since the receiver tank can form two or more passages, the passage resistance is reduced, It has several advantages, such as the ability to stabilize refrigerant pulsations.

Claims (8)

After a pair of header pipes (1a) (1b) arranged in parallel with each other, a plurality of tubes (3) connecting between the header pipes, and the cooling fins (4) filled between the tubes, The baffles 1c provided inside the header pipes 1a and 1b guide the flow path of the refrigerant to the zigzag along the tubes 3, and the receiver tank next to the header pipe 1a. And a subcooling condenser provided with a coolant inflow passage 51 to send only the liquid refrigerant to the lower subcooling zone 10 through the coolant outlet passage 52 to increase cooling efficiency. To The receiver tank 5 is provided with a top end cap 58 and an upper half bracket, and made of a clad aluminum material pipe 5a fixed to the one side header pipe 1a by brazing welding, and the lower half is extruded aluminum. It is assumed that the material pipes 5b are joined to each other. A desiccant pack (6) embedded in the receiver tank (5), which can be inserted from below; Sealing the lower end of the receiver tank (5), and easy to assemble bonsai 7, An air conditioner subcooled condenser, characterized in that the filter (8) is assembled to the upper side of the plug (7) to filter foreign matter in the refrigerant. The method of claim 1, The upper clad aluminum material pipe (5a) of the receiver tank (5) is characterized in that the brazing welding bonding material (CLAD) is coated to enable brazing welding with the one side header pipe (1a) Subcool condenser. The method of claim 1, The upper clad aluminum material pipe 5a of the receiver tank 5 forms an extended inner diameter 53 at its lower end, and the extruded aluminum material pipe 5b has an insertion end 54 formed at its upper end. The sub-cooling condenser for air conditioners, characterized in that the assembly by fitting to each other. The method of claim 1, The clad aluminum material pipe 5a of the receiver tank 5 forms a welding protrusion 59 at an upper end thereof, and the extruded aluminum material pipe 5b is in communication with at least one lower end of one header pipe 1a. A refrigerant inflow passage 51, a refrigerant outlet passage 52 in communication with the subcool zone 10 of the one side header pipe 1a, and an inward ring having an arbitrary inner diameter D formed at a position therebetween; Sub air condenser for air conditioner characterized in that it comprises a te (55). The method of claim 1, The desiccant pack (6) is a subcooled condenser for air conditioning, characterized in that the bag is formed of woven fabric paper so that the refrigerant can pass through, and containing the desiccant therein sealed. The method of claim 5, wherein When the desiccant pack 6 is filled with a desiccant, the circumference of the desiccant pack 6 has a dimension slightly larger than the inner diameter D of the inwardly annular annulus 55 so that the desiccant pack can be forcibly inserted and removed. Subcool condenser. The method of claim 1, The filter 8 has an outer circumferential surface mainly made of a net body 81, has an expansion jaw 82 at an upper end thereof, and a lower reduction part 83 may be fitted to a seating part 70 of an upper surface of the plug 7. The sub-cooling condenser for air conditioners, characterized in that. The method of claim 1, The air filter subcooled condenser is characterized in that the height (H) excluding the reduction portion (83) is the same as the upper surface of the plug (7) and the bottom surface of the inwardly annular ring (55). .