KR101513930B1 - Installing Structure of Filter in Receiverdrier Manufacturing Method of Receiverdrier - Google Patents

Abstract

The present invention relates to a filter coupling structure of a receiver drier and a manufacturing method of a receiver drier, in which a first and a second insertion grooves are formed on an inner peripheral surface of a receiver dryer tank, And a manufacturing method of the receiver drier.

A filter coupling structure of a receiver dryer of the present invention includes: a receiver dryer tank having a cylindrical shape with an opening at a lower end thereof and a communication hole communicating with a header tank of a condenser at an outer side; A filter inserted into the receiver dryer tank to filter foreign matter; A lower cap supporting the filter and coupled to an opening of the receiver dryer tank; Wherein the first and second insertion grooves are formed in the inner circumferential surface of the receiver dryer tank so as to be perpendicular to the longitudinal direction of the receiver dryer tank.

Since the first and second insertion grooves are formed by cutting the inner peripheral surface of the receiver dryer tank, the amount of cutting of the receiver dryer tank can be minimized, There is an effect of preventing the waste of.

In addition, since the filter and the lower cap are fixed by the snap ring, there is an effect of preventing the resin sealing member or the filter from being damaged due to the heat transfer during the brazing process of the lower cap as in the conventional case.

Receiver dryer, filter, insert groove, snap ring

Description

Technical Field [0001] The present invention relates to a filter coupling structure of a receiver drier and a manufacturing method of a receiver drier,

The present invention relates to a filter coupling structure of a receiver drier and a manufacturing method of a receiver drier, in which a first and a second insertion grooves are formed on an inner peripheral surface of a receiver dryer tank, And a manufacturing method of the receiver drier.

The cooling system of the vehicle compresses the refrigerant, which performs heat exchange with the outside air, from the compressor to a high-temperature / high-pressure gas state and then sends it to a condenser. The condenser converts the gaseous refrigerant into a liquid state To the expansion valve. The expansion valve expands the refrigerant to a low-temperature / low-pressure state and sends it to an evaporator. The evaporator causes the low-temperature / low-pressure refrigerant to perform heat exchange with the indoor air of the vehicle to cool the interior of the vehicle.

In order for the refrigerant circulating through the above-mentioned path to absorb heat of the outside air, the refrigerant should be in a liquid state when it is condensed in the condenser, but a part of the refrigerant remains in a gaseous state and passes through the condenser.

Therefore, when the refrigerant in which the liquid phase and the vapor phase coexist is heat exchanged in the evaporator, the refrigerant in the gaseous state can hardly absorb the heat of the room air and thus the cooling efficiency is lowered.

To solve the above problem, a receiver drier is installed between a condenser and an expansion valve. The receiver dryer separates / removes gaseous refrigerant that has not been liquefied in the condenser or absorbs moisture contained in circulating refrigerant Thereby increasing the cooling efficiency.

1, the receiver drier is attached to one side header tank 102 of the condenser 100. The structure of the receiver drier is similar to that of the receiver dryer tank 104, A lower cap 110 having a filter portion 116 is installed in the tank 104 to remove impurities mixed in a working fluid having a moisture absorbent 108 for removing a working fluid, As shown in Fig.

2 and 3, the lower cap 110 includes a body portion 112 having a thread 114 formed on an outer circumferential surface thereof, and a filter portion 116 for removing impurities from the operating oil. The lower cap 110 is screwed to the lower portion of the receiver dryer tank 104 through the thread 114 of the body portion 112 and the lower portion of the sealing member insertion groove 118 formed in the outer peripheral surface of the body portion 112 As the body portion 112 rotates, the coupled sealing member 120 is pressed against the inner peripheral surface of the receiver dryer tank 104 to form a bonding surface. The filter portion 116 is in contact with the latching jaw 106 inside the receiver dryer tank 104 to prevent the filter portion 116 from moving inside the receiver dryer tank 104, There is a problem in that the coupling jaw 106 must be formed inside the pipe formed by the bumping process in order to form the locking jaw 106 in the receiver dryer tank 104 with the structure that is formed by extrusion. In the bumping process, the pipe formed by the extrusion is inserted into the mold, and the pressure is applied at both ends of the pipe to shorten the length of the pipe, thereby increasing the thickness of the pipe. The production cost is greatly increased due to the additional production facility for the bumping process . In addition, after the bumping process, the inner periphery of the pipe must be formed with a thread through a cutting process, so that waste of the material is worsened and productivity is lowered due to an increase in production time.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a receiver dryer tank in which first and second insertion grooves are formed in an inner circumferential surface of a receiver dryer tank, And a manufacturing method of the receiver drier.

A filter coupling structure of a receiver dryer of the present invention includes: a receiver dryer tank having a cylindrical shape with an opening at a lower end thereof and a communication hole communicating with a header tank of a condenser at an outer side; A filter inserted into the receiver dryer tank to filter foreign matter; A lower cap supporting the filter and coupled to an opening of the receiver dryer tank; Wherein the first and second insertion grooves are formed in the inner circumferential surface of the receiver dryer tank so as to be perpendicular to the longitudinal direction of the receiver dryer tank.

And the distance between the first insertion groove and the second insertion groove is formed to match the distance between the filter and both ends of the lower cap assembly.

And a snap-ring is fixedly inserted into the first insertion groove and the second insertion groove, respectively.

A method of manufacturing a receiver dryer of the present invention includes the steps of: a) an extruding step of extruding a receiver dryer tank having a hollow interior; b) an insertion groove forming step in which an annular first insertion groove and a second insertion groove are formed in an inner peripheral surface of the extruded receiver dryer tank, respectively; c) a snap ring insertion step in which a snap-ring is inserted into the first insertion groove; d) a filter inserting step in which a filter is inserted into the receiver dryer tank and the upper end of the filter is fixedly supported by the snap ring; And e) a lower cap inserting step in which the lower cap is inserted into the receiver dryer tank so as to contact the lower end of the filter so as to fix and hold the filter, and then the snap ring is inserted into the second insertion groove and the lower cap is fixedly supported; And a control unit.

Wherein the step b) includes the steps of: forming a communication hole at one side of the receiver dryer tank, the communication hole communicating with the header tank of the condenser; And further comprising:

Wherein the step (e) includes the steps of: inserting a moisture absorbing material into the receiver dryer tank; and closing the upper end of the moisture absorbing material by the upper cap; And further comprising:

Since the first and second insertion grooves are formed by cutting the inner peripheral surface of the receiver dryer tank, the amount of cutting of the receiver dryer tank can be minimized, There is an effect of preventing the waste of.

In addition, since the filter and the lower cap are fixed by the snap ring, there is an effect of preventing the resin sealing member or the filter from being damaged due to the heat transfer during the brazing process of the lower cap as in the conventional case.

Hereinafter, the filter coupling structure of the receiver dryer of the present invention and the method of manufacturing the receiver dryer will be described in detail with reference to the accompanying drawings.

5 is a cross-sectional view of the receiver dryer tank of the present invention. Fig. 6 is an exploded perspective view of the filter and the lower cap of the present invention. Fig. 7 is a cross- FIG. 8 is a flow chart showing a method of manufacturing the receiver drier of the present invention. FIG.

4 to 5, the filter coupling structure of the receiver dryer of the present invention includes a receiver drier 26 having a cylindrical shape with an opening at its lower end and a communication hole 26 communicating with the header tank 12 of the condenser 10, A tank 20; A filter 30 inserted into the receiver dryer tank 20 to filter foreign substances; And a lower cap (40) supporting the filter (30) and coupled to an opening of the receiver dryer tank (20); The receiver dryer tank 20 includes a first insertion groove 22 and a second insertion groove 22 which are formed on an inner circumferential surface of the receiver dryer tank 20 so as to be perpendicular to the longitudinal direction of the receiver dryer tank 20, 24 are formed by being inserted into each other.

The receiver dryer tank 20 is a metal pipe formed by extruding a predetermined length, and first and second insertion grooves 22 and 24 are formed in an inner peripheral surface thereof. The first and second insertion grooves 22 and 24 are annularly formed along the inner circumferential surface perpendicular to the longitudinal direction of the receiver dryer tank 20. The first and second insertion grooves 22 and 24 are formed in a rectangular cross section as shown in FIG. 5, but are not limited thereto. The first and second insertion grooves 22 and 24 may have a rectangular cross- It is preferable to form it so as to coincide with the outer end surface of the snap ring 50. [

The shortest distance between the first insertion groove 22 and the second insertion groove 24 is a distance between the lower end of the filter 30 and the lower end of the filter of the assembled assembly Is formed to be equal to the distance. Therefore, the snap ring 50 is inserted into the first and second insertion grooves 22 and 24, and the filter 30 and the lower cap 40 can be completely fixed without flowing.

A snap ring (50) is inserted into the first and second insertion grooves (22, 24). The snap ring 50 is widely used, and a tool insertion hole 52 is formed in which an annular annular ring having a central portion is perforated, a part of which is cut, one side is opened, and tools are inserted at both ends thereof. The outer diameter L1 of the snap ring 50 is formed to be larger than the inner diameter of the first and second insertion grooves 22 and 24. The tool is inserted into the tool insertion hole 52 of the snap ring 50, The outer diameter L1 of the snap ring 50 is reduced and the insertion into the receiver dryer tank 20 becomes possible.

The filter 30 and the lower cap 40 inserted into the receiver dryer tank 20 may have a single structure or may be formed separately as shown in FIG. The filter 30 is inserted into the receiver dryer tank 20 to filter foreign matter in the refrigerant circulating through the cooling system of the vehicle. An upper flange 32 having an outer diameter equal to the inner diameter of the upper receiver dryer tank 20 is formed at an upper end of the filter 30 to prevent the filter 30 inserted into the receiver dryer tank 20 from flowing And a filter screen 34 for filtering foreign substances in the refrigerant flowing inside the receiver dryer tank 20 is formed at the center.

The lower cap 40 is fitted to the lower end of the receiver dryer tank 20 to fix and support the lower end of the filter 30 and to seal the lower end of the receiver dryer tank 20 to prevent the refrigerant from leaking. A sealing member 42 made of resin is inserted into the outer periphery of the lower cap 40 to close the contact surface between the lower cap 40 and the receiver dryer tank 20. [

Assembly of the receiver dryer having the above-described structure will be described in detail with reference to Figs. 7 to 8. Fig. A tubular receiver dryer tank 20 is formed through extrusion. The receiver dryer tank 20 can be manufactured by various methods, but it is preferable to use the extrusion with the highest productivity. The inner circumferential surface of the receiver dryer tank 20 is cut to form the first and second insertion grooves 22 and 24. At this time, a communication hole (26) communicating with the header tank (12) of the condenser (10) is formed on the outer peripheral surface of the receiver dryer tank (20). The filter 30 and the lower cap 40 are inserted into the receiver dryer tank 20 in which the communication holes 26 and the first and second insertion holes 22 and 24 are formed by the cutting process as described above. A tool (not shown) is inserted into the tool insertion hole 52 of the snap ring 50 to reduce the distance between the tool insertion holes 52 to reduce the overall outer diameter L1 of the snap ring 50, The snap ring 50 is returned to its original outer diameter by the elasticity of the snap ring 50 itself and the first insertion groove 22 ). Since the inner diameter of the snap ring 50 fitted and fixed to the first insertion groove 22 is smaller than the inner diameter of the receiver dryer tank 20, the snap ring 50 protrudes into the receiver dryer tank 20, . The upper flange 32 of the filter 30 inserted into the receiver dryer tank 20 is fixedly supported by the snap ring 50. After the insertion of the filter 30 is completed, the lower cap 40, into which the sealing member 42 is inserted, is inserted into the receiver dryer tank 20. The upper end of the lower cap 40 comes into contact with the lower end of the filter 30 to fix the filter 30 and the same snap ring 50 as the snap ring 50 inserted into the first insertion groove 22 has the same method And the lower end of the lower cap 40 is firmly fixed and supported. A moisture absorbent material 16 for removing moisture from the refrigerant into the receiver dryer tank 20 during the insertion process of the filter 30 and the lower cap 40 may be disposed above the upper portion of the receiver dryer tank 20 And the upper end of the receiver dryer tank 20 is sealed by the upper cap 18. Since the upper cap 18 is in contact with the upper end of the moisture absorber 16 and is not firmly supported, The receiver dryer 14 is connected to the header tank 12 at one side of the condenser 10 through a communication hole 26. [

Since the first and second insertion grooves 22 and 24 are formed by cutting the inner peripheral surface of the receiver dryer tank 20 formed by extrusion as described above, the amount of cutting of the receiver dryer tank 20 can be minimized, And productivity is improved.

The filter 30 and the lower cap 40 are fixed by the snap ring 50. This prevents the sealing member 42 or the filter 30 from being damaged due to heat transfer during the brazing process of the lower cap 50, Is prevented from being damaged.

1 is a cross-sectional view of a conventional condenser in which a receiver drier is formed;

2 is an exploded perspective view of a conventional filter unit.

3 is a cross-sectional view illustrating a structure of a filter portion of a conventional receiver drier;

4 is a cross-sectional view of a condenser incorporating a receiver dryer of the present invention;

5 is a cross-sectional view of a receiver dryer tank of the present invention.

6 is an exploded perspective view of the filter and the lower cap of the present invention.

7 is a cutaway perspective view showing a method of manufacturing the receiver dryer of the present invention.

8 is a flowchart showing a method of manufacturing a receiver dryer of the present invention.

DESCRIPTION OF REFERENCE NUMERALS

10: condenser 12: header tank

14: Receiver dryer

20: receiver dryer tank 22, 24: first and second insertion grooves

26: communication hole

30: filter 32: upper flange

34: Filter

40: lower cap 42: sealing member

50: snap ring 52: tool insertion hole

Claims (6)

A receiver dryer tank 20 in which an opening is formed at the lower end in a cylindrical shape and a communication hole 26 is formed in the outer side of the condenser 10 to communicate with the header tank 12; A filter 30 inserted into the receiver dryer tank 20 to filter foreign substances; And A lower cap (40) supporting the filter (30) and coupled to an opening of the receiver dryer tank (20); The filter fixing structure of the receiver dryer comprising: An annular first insertion groove (22) and a second insertion groove (24) are formed in the inner peripheral surface of the receiver dryer tank (20) so as to be perpendicular to the longitudinal direction of the receiver dryer tank (20) The upper end of the filter 30 is fixed through a snap ring 50 inserted into the first insertion groove 22 and the upper end of the filter 30 is inserted through the snap ring 50 inserted into the second insertion groove 24, And the lower end of the lower cap (40) is fixed. The method according to claim 1, Wherein a distance between the first insertion groove (22) and the second insertion groove (24) is formed to match the distance between the filter (30) and both ends of the lower cap (40) assembly . delete As a method of manufacturing the receiver dryer (14) a) an extrusion step (S1) in which an internally hollow receiver dryer tank (20) is extruded; b) an insertion groove forming step (S2) in which an annular first insertion groove (22) and a second insertion groove (24) are integrally formed on the inner peripheral surface of the extruded receiver dryer tank (20); c) a snap ring insertion step (S3) in which a snap ring (50) is inserted into the first insertion groove (22); d) a filter inserting step (S4) in which the filter (30) is inserted into the receiver dryer tank (20) and the upper end of the filter (30) is fixedly supported by the snap ring (50); And e) a lower cap 40 is inserted into the receiver dryer tank 20 so as to contact the lower end of the filter 30 to fix the filter 30, and then the snap ring 50 A lower cap inserting step (S5) in which the lower cap (40) is fixedly supported; , ≪ / RTI & The upper end of the filter 30 is fixed through a snap ring 50 which is inserted into the first insertion groove 22 and the upper end of the filter 30 is inserted through a snap ring 50 inserted into the second insertion groove 24, And fixing the lower end of the lower cap (40). 5. The method of claim 4, (B) forming a communication hole (S2-1) in which a communication hole (26) communicating with the header tank (12) of the condenser (10) is formed at one side of the receiver dryer tank (20); Further comprising the steps of: 5. The method of claim 4, The step (e) may include a step (S5-1) of inserting a hygroscopic material into the receiver dryer tank 20 after the hygroscopic material 16 is inserted and the upper end is closed by the upper cap 18; Further comprising the steps of:

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