KR100936368B1 - Receiver drier of one unit with condenser - Google Patents

Abstract

The present invention relates to a condenser integrated receiver dryer, in which a receiver dryer body (110) is temporarily assembled in one side tank (T) of the condenser, and is brazed in a furnace. The connection bracket 120 having the inlet and the refrigerant outlet formed therein is coupled to the tank T, and is brazed in the furnace. A filter seat 124a is formed at the refrigerant outlet of the connection bracket 120. The part has a structure in which the filter assembly 140 is coupled. According to this structure, the number of parts can be reduced, the assembly process can be simplified, and the thickness of the body for assembling the filter can be reduced, so that the heat balance of the condenser and the receiver dryer part during brazing improves the brazing property and the weight. This reduces the manufacturing cost.

Description

Receiver drier of one unit with condenser

The present invention relates to a condenser integrated receiver dryer, and more particularly, to a condenser integrated receiver dryer which connects the body of the receiver dryer and the tank of the condenser with a connection bracket and brazes and integrates the furnace.

In general, the condenser of the air conditioner is a heat exchanger in which a refrigerant compressed at high temperature and high pressure in a compressor flows into the liquid refrigerant by exchanging heat with surrounding air.

A receiver drier is installed between the condenser and the expansion valve to temporarily store the liquid refrigerant flowing from the condenser to supply the necessary amount to the evaporator according to the cooling load, and at the same time supply the complete liquid refrigerant to the expansion valve and the condenser. It serves to remove foreign substances such as moisture or bubbles contained in the refrigerant to absorb moisture in the gaseous state that is not condensed from the refrigerant.

The conventional condenser 1 has a first and a second tank (2) (3), which are installed to face each other as shown in Figure 1, and a plurality of tubes (4) for communicating the tank (2) (3) and And heat dissipation fins 5 interposed between the tubes 4, inlet and outlet pipes 6 and 6 ′ installed in the first tank 2, and installed in the tanks 2 and 3. It comprises a baffle (7), and a receiver dryer (10) in communication with the second tank (3) integrated with the condenser.

The receiver dryer 10 integrated with a condenser includes a receiver tank 11 communicating with the second tank 3, and an upper and lower caps 12 sealing upper and lower ends of the receiver tank 11 ( 13) and a desiccant 14 and a filter 15 installed in the receiver tank 11.

The high temperature and high pressure refrigerant introduced through the inlet pipe 6 in the condenser 1 configured as described above exchanges heat with the outside air while zipping the tubes 4 by the baffle 7, which is a partition means, and then receives the receiver dryer. It is discharged through the outlet pipe 6 'via (10).

In the manufacture of the condenser 1 integrated with the receiver dryer 10 having such a configuration, the receiver tank is brazed in a furnace in a state in which the receiver dryer 10 is temporarily assembled to the tank 3 of the condenser. After inserting the desiccant 14 and the filter 15 into the interior of the (11), the lower cap 13 is coupled to the lower end of the receiver tank 11 to seal the completion.

The present invention improves the assembly structure of the filter of the receiver dryer which is integrated by brazing in a furnace by condenser, thereby reducing the number of parts, simplifying the assembly process, and improving the thickness of the receiver dryer body for assembling the filter. The purpose of the present invention is to provide a condenser integrated receiver dryer which reduces the manufacturing cost by improving the brazing property and reducing the weight by forming a thermal balance between the condenser and the receiver dryer part during brazing.

The condenser integrated receiver dryer according to the present invention for achieving the above object is a condenser integrated receiver dryer in which a receiver dryer body is assembled in one tank of the condenser and brazed in a furnace. Is connected to the coupling bracket formed in the tank is brazed in the furnace, the refrigerant outlet of the connection bracket is formed with a filter seat, characterized in that the filter assembly is coupled to the filter seat.

The connecting bracket may include a connecting body portion having the refrigerant inlet and the refrigerant outlet formed therein, a first flange portion formed at one side of the connecting body portion to cover the outer peripheral surface of the tank, and a portion of the receiver dryer body. And a second flange portion formed at the other side of the connecting body portion, and a protrusion projecting toward the receiver dryer body to form the filter seating portion.

The lower part of the receiver dryer body has a burring groove formed by burring is formed by protruding into the receiver dryer body so as to be in close contact with the protrusion.

On the outer surface of the end of the protrusion, a locking protrusion is formed so that the protrusion is caught by the burring groove when the connecting bracket is temporarily assembled. A plurality of ribs protrude from the end edge of the protrusion to coke and fix the filter assembly seated on the filter seat.

According to the condenser integrated receiver dryer according to the present invention, it is possible to reduce the number of parts and simplify the assembly process, and to reduce the thickness of the receiver dryer body for assembling the filter to achieve thermal equilibrium between the condenser and the receiver dryer during brazing. It has the effect of reducing manufacturing costs by improving the properties and reducing the weight.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 and 3 is an exploded perspective view and an assembled sectional view showing the condenser integrated receiver dryer according to the present invention. As illustrated, the receiver dryer body 110 is temporarily assembled to one side tank T of the condenser by brazing in the furnace.

The receiver dryer body 110 is a cylindrical body whose upper end is blocked and its lower end is open, and is temporarily assembled to the tank T via the connecting bracket 120, and then inside the receiver dryer body 110. After the desiccant is embedded, its lower end is sealed by the cap 130.

As shown in (a) to (c) of Figure 4, the lower portion of the receiver dryer body 110 is projected into the receiver dryer body 110 so as to be fitted in close contact with the protrusion of the connection bracket 120 to be described later Square burring grooves 112 are formed.

On the lower side of the burring groove 112, a locking protrusion 113 is formed along the inner circumferential surface of the receiver driver body 110 so as to catch the upper end of the cap 130, the lower inner circumferential surface of the locking protrusion 113 There is a stop groove 114 is fitted with a stop ring to be described later so that the cap 130 is fixed without being separated. The stop groove 114 is an embossed belt in which the inner peripheral surface of the receiver dryer body 11 is recessed and the outer peripheral surface protrudes.

The connection bracket 120 has a coolant inlet 121a and a coolant outlet 121b communicating with the inlet and outlet of the tank T. The coolant inlet 121a and the coolant outlet 121b are formed. A first flange portion 122 having two body portions 121 and two flanges 122a and 122b formed on one side of the connection body portion 121 so as to be wrapped in close contact with a portion of the outer circumferential surface of the tank T; A second flange portion 123 having two flanges 123a and 123b formed on the other side of the connecting body 121 so as to be wrapped in close contact with a part of the receiver dryer body 110 and the burring groove 112. It consists of a protrusion 124 formed to protrude toward the receiver dryer body side between the two flanges of the second flange portion 123 to be fitted in close contact with the inner surface of the (see Figure 5).

5 and 6, the protrusion 124 is formed with a filter seating portion (124a), the filter seating portion (124a) is a filter assembly 140 is assembled and brazed integrally in the furnace, The refrigerant outlet 121b of the connection bracket 120 is formed with a space portion 121c extended to reach the filter seating portion 124a.

A locking protrusion 124b is formed on an outer surface of the end of the protrusion 124 so that the protrusion 124 is caught by the burring groove 112 when the connection bracket 120 is temporarily assembled. In addition, a plurality of ribs 124c protrude from the end edge of the protrusion 124 to coke and fix the filter assembly 140 seated on the filter seat 124a.

2 and 3, a plurality of O-rings 132 are fitted to the outer circumferential surface of the cap 130 to be in close contact with the lower inner circumferential surface of the receiver dryer body 110 to be sealed. In order to prevent the cap 130 from being separated, the stop ring 134 is fitted to the stop groove 114 of the body 110 at the lower side of the cap 134. The lower end of the cap 130 has a female screw (130a) is coupled to the bolt to be easily separated when the cap 130 is separated. A handle may be formed in place of the female screw 130a.

As shown in FIGS. 7A and 7B, the filter assembly 140 includes a flat plate 142 having a filter unit 142a having a mesh hole, and the flat plate 142. A top and bottom seating ring 144 is fixed to the plate along the edge of the) and seated on the filter seat 124a. The area of the filter portion 142a is preferably 1.5 to 8 times the coolant outlet 121b.

On the other hand, as shown in Figure 8 (a) to (b), the filter assembly 240 is a convex plate-like plate 242 having a filter portion 242a with a mesh hole formed, and the edge of the convex plate-shaped plate Therefore, it may be a top and bottom mounting ring 244 is fixed to the plate seated on the filter seat 124a (an alternative embodiment). The filter part 242a is fixed to the lower end of the main mesh part 242a-1 and the main mesh part 242a-1 so as to increase the rigidity of the filter part 242a, and the main mesh part 242a-1. ) Is made of an auxiliary mesh portion 242a-2 having a larger mesh hole. This configuration has an effect of further increasing the area of the filter mesh portion when the size of the connection bracket 120 is limited.

The filter assemblies 140 and 240 are made of a metal having a higher melting point than that of the receiver dryer body 110, so that the filter assemblies 140 and 240 are not damaged even when the filter assembly 140 and 240 are put into the high temperature brazing furnace together with the receiver dryer body 110.

In the condenser integrated receiver dryer according to the present invention configured as described above, the refrigerant liquefied in the condenser and containing the liquid phase and the gaseous phase, through the inlet of the tank (T) and the refrigerant inlet (121a) of the connecting bracket 120, the receiver dryer. An expansion valve (not shown) that flows through the lower side of the condenser through the refrigerant outlet 121b of the connection bracket 120 through the desiccant pack (not shown) and through the desiccant pack (not shown). Flows to

The condenser integrated receiver dryer of the present invention is preassembled except for the desiccant pack (not shown) and the cap 130, while preassembled to one side tank (T) of the condenser via the connecting bracket 120, the brazing in the furnace After the integration, the desiccant pack is inserted into the receiver dryer body 120 and then sealed by the cap 130 to be completed.

At this time, the connecting bracket 120 is coated with a brazing sheet or aluminum molten clad metal during assembly with the receiver dryer body 110, and then press-fits the protrusion 124 into the burring groove 112, and preassembled. The engaging protrusion 124b formed on the outer surface of the end of the protrusion 124 is caught by the end of the burring groove 112 so that the connection bracket 120 does not fall out. Then, the rib 124c formed at the end edge of the protrusion 124 is caulked to fix the filter assembly 140.

The condenser integrated receiver dryer according to the present invention configured as described above improves the assembly structure of the filter of the receiver dryer, thereby reducing the number of parts, simplifying the assembly process, and reducing the flesh thickness of the receiver dryer body for assembling the filter. The heat balance between the condenser and the receiver dryer can improve the brazing and reduce the weight, thereby reducing the manufacturing cost.

9 is a graph showing the results of evaluating the filter clogging and the pressure drop in the area of the filter portion 142a of the same area as the refrigerant outlet 121b of the connecting bracket of the present invention. As indicated, it can be seen that the filter must be blocked by 50% or more when the driving distance is 30,000 km or more, and the pressure drop by 50% or more when the driving distance is 20,000 km or more. The area of the filter portion can be further increased to further improve the clogging of the filter and reduce the pressure drop.

1 is a configuration diagram showing a general condenser in which the receiver dryer is integrated;

2 is an exploded perspective view of a condenser integrated receiver dryer according to the present invention;

3 is an assembled cross-sectional view of a condenser integrated receiver dryer according to the present invention;

Figure 4 (a) is a cross-sectional view showing the lower part of the receiver dryer body in Figure 3,

Figure 4 (b) is an elevation view as seen from A of Figure 4 (a),

4C is a cross-sectional view taken along the line B-B in FIG. 4A,

Figure 5 is a cross-sectional view of the connection bracket assembly state in the receiver dryer body in the present invention,

Figure 6 (a) is an elevation view of the filter assembly coupled to the connecting bracket in the present invention,

Figure 6 (b) is a cross-sectional view taken along the arrow line C-C in Figure 6 (a),

7 (a) and 7 (b) are a plan view and a sectional view of the filter assembly of the present invention;

8 (a) and 8 (b) are a plan view and a sectional view showing another example of the feature assembly of the present invention;

9 is a graph showing the results of evaluating the filter clogging and the pressure drop in the filter area of the same area as the outlet of the connecting bracket of the present invention.

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

110: receiver dryer body 112: burring groove

120: connection bracket 124: protrusion

124a: filter seat 130: cap

140, 240: filter assembly

Claims (9)

delete In the condenser-integrated receiver dryer for temporarily brazing the receiver dryer body 110 in the tank T of the condenser in the furnace, A connection bracket 120 having a refrigerant inlet 121a and a refrigerant outlet 121b is coupled to a lower portion of the receiver dryer body 110 to be temporarily assembled in the tank to be brazed in a furnace, and a refrigerant outlet of the connection bracket 120 is provided. A filter seating portion 124a is formed at 121b, and filter assemblies 140 and 240 are coupled to the filter seating portion 124a. The connection bracket 120 includes the connection body 121 having the refrigerant inlet 121a and the refrigerant outlet 121b and a portion of the outer circumferential surface of the tank T so as to be wrapped in close contact with the connection body 121. A first flange portion 122 formed on one side of the second flange portion 123 formed on the other side of the connecting body portion 121 to be wrapped in close contact with a part of the receiver dryer body 110, and the filter seating Condenser integrated receiver dryer characterized in that it comprises a protrusion 124 protruding toward the receiver dryer body 110 so that the portion (124a) is formed. The method according to claim 2, Condenser integrated receiver dryer, characterized in that the lower portion of the receiver dryer body 110 is formed with a burring groove 112 is formed to protrude to the inside of the receiver dryer body 110 so that the protrusion (124) is fitted in close contact. The method according to claim 3, Condenser integrated receiver dryer, characterized in that the locking projection 124b is formed on the outer surface of the end of the protrusion 124 so that the protrusion 124 is caught in the burring groove 112 when the connection bracket 120 is temporarily assembled. . The method according to claim 3, A plurality of ribs 124c are formed at the end edge of the protrusion 124 so as to caulk and fix the filter assemblies 140 and 240 seated on the filter seat 124a. Dryer. In the condenser-integrated receiver dryer for temporarily brazing the receiver dryer body 110 in the tank T of the condenser in the furnace, A connection bracket 120 having a refrigerant inlet 121a and a refrigerant outlet 121b is coupled to a lower portion of the receiver dryer body 110 to be temporarily assembled in the tank to be brazed in a furnace, and a refrigerant outlet of the connection bracket 120 is provided. A filter seating portion 124a is formed at 121b, and filter assemblies 140 and 240 are coupled to the filter seating portion 124a. The filter assemblies 140 and 240 are fixed to the plates along the edges of the plates 142 and 242 having the filter holes 142a and 242a with mesh holes formed therein. It includes a seat ring 144, 244 seated on the filter seat 124a, The filter portion 242a is fixed to the lower end of the main mesh portion 242a-1 and the main mesh portion 242a-1 so as to increase the rigidity of the filter portion 242a and the main mesh portion 242a-. A condenser integrated receiver dryer, comprising an auxiliary mesh portion 242a-2 having a larger mesh hole than 1). The method according to claim 6, The filter unit (142a, 242a) has an area of 1.5 to 8 times the area of the refrigerant outlet (121b), the condenser integrated receiver dryer. delete The method according to claim 6, The filter assemblies 140 and 240 are made of a metal having a higher melting point than that of the receiver dryer body 110, so that the filter assemblies 140 and 240 are not damaged even when they are introduced into the high temperature brazing furnace together with the receiver dryer body 110. Integrated receiver dryer.

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