KR200430632Y1 - Assembly Structure of Lower Cap for Receiver Drier - Google Patents

Abstract

The present invention relates to a lower cap coupling structure of the receiver drier, the lower cap 30 of the receiver tank 10 protrudes above the lower cover plate 31 of the lower cap 30 and is coupled to the lower portion of the receiver tank 10. The coupling guide protrusion 32, the locking pin portion 41 protruding to the outside of the coupling guide protrusion 32, and the ring groove 43 is formed in the lower portion of the receiver tank 10, the lower opening The receiver tank 10 includes a cap coupling means 40 including a pinned coupling portion 42 and a spring member 44 which is coupled to the coupling guide protrusion 32 and pushes and supports the lower portion of the pin coupling portion 42. ) Will be combined to the bottom.

That is, the lower cap 30 is the engaging pin portion 41 is coupled to the ring groove 43, this coupling state is supported by the spring member 44 can be simply coupled to the lower portion of the receiver tank 10 manufacturing process The effect is to simplify.

In addition, the present invention minimizes the friction between the O-ring and the inner surface of the receiver tank 10 when the lower cap 30 is coupled, thereby increasing the durability of the O-ring and maintaining the airtightness of the receiver tank 10 constantly.

Therefore, it is a very useful design to increase the productivity and durability of the receiver dryer 100, and to reduce the manufacturing cost and maintenance cost.

Description

Assembly structure of lower cap for receiver drier

1 is a cross-sectional view of a state of use showing the lower cap structure of a conventional receiver dryer

Figure 2 is a use state showing the receiver dryer applied of the present invention

3 is an exploded perspective view showing the configuration of the present invention

Figure 4 is a perspective view showing a combined state of the present invention

* Description of the major symbols in the drawings *

1: condenser 2: first tank

3: second tank 4: tube

10: receiver tank 20: upper cap

30: lower cap 31: lower cover plate

32: coupling guide protrusion 40: cap coupling means

41: locking pin 42: pin coupling portion

43: ring groove 44: spring member

The present invention relates to a lower cap coupling structure of the receiver drier, and more specifically, it is designed to improve the convenience when assembling the lower cap can be easily combined.

Generally, the receiver dryer is installed between the condenser and the expansion valve to temporarily store the liquid refrigerant flowing from the condenser so that the required amount can be supplied to the evaporator according to the cooling load, and at the same time supply the complete liquid refrigerant to the expansion valve. 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 condenser.

Recently, the receiver drier is located on its channel, not the outlet of the condenser, and is supplied until the liquid zone of the refrigerant is developed in the receiver drier, and the lower side of the receiver drier is used as a subcooling zone where the liquid is cooled. To keep it.

1 shows a condenser 1 incorporating a conventional receiver drier. As shown, between the first and second tanks (2) (3), which are installed to face each other, the plurality of tubes (4) for communicating the tank (2) (3), between the tubes (4) Heat dissipation fins 5 interposed therebetween, inlet and outlet pipes 6, 6a provided in the first tank 2, baffles 7 provided in the tanks 2, 3, and the first It comprises a receiver dryer 100 in communication with the two tank (3).

The receiver dryer 100 includes a receiver tank 10 communicating with the second tank 3, upper and lower caps 20 and 30 sealing upper and lower ends of the receiver tank 10, and The desiccant 11 and the filter member 12 which are provided in the receiver tank 10 are provided.

The receiver dryer 100 performs a brazing process in a state in which the receiver tank 10 to which the upper cap 20 is coupled is temporarily assembled to the second tank 3.

Then, after the brazing is bonded, the desiccant 11 is inserted into the receiver tank 10, and then the lower cap 30 having the filter member 12 is coupled to the lower portion of the receiver tank 10. To complete the assembly.

The lower cap 30 is a situation in which the screw coupling portion 30a protrudes and is screwed into the lower portion of the receiver tank 10.

The lower cap 30 may be detachably coupled to the lower portion of the receiver tank 10 as described above to facilitate replacement, repair, and cleaning of the internal filter member 12.

However, the conventional receiver drier has a problem in that it takes a long time in the process of screwing and removing the lower cap by screwing the lower cap to seal the receiver tank.

In addition, the lower cap is mounted on the outer peripheral surface of the receiver tank in close contact with the inner ring of the sealing tank, the O-ring is worn in contact with the inner surface of the receiver tank by the rotational force generated when the lower cap is coupled, separated There was a closure that lowered the airtightness.

Therefore, the productivity is lowered because the O-ring must be replaced and repaired during use, there was a problem in that the maintenance cost is increased.

An object of the present invention is to simplify the assembly of the lower cap to the bottom of the receiver tank at a time to increase the ease of assembly and productivity, and to minimize the wear of the O-ring that occurs during the separate coupling to reduce the durability of the receiver dryer It is to provide a cap coupling structure.

An object of the present invention is in the receiver cap of the receiver dryer, a lower cap coupling structure of the receiver dryer including a lower cap coupled to the lower portion of the receiver tank to seal the inside of the tank, and a cap coupling means for coupling the lower cap; The cap coupling means may be formed at a lower portion of the receiver tank, a coupling guide protrusion protruding from the upper portion of the lower cover plate of the lower cap and coupled to the lower portion of the receiver tank, a locking pin portion protruding outward from the coupling guide protrusion, And a pin coupling portion having a ring groove open to the bottom, and a spring member 44 coupled to the coupling guide protrusion to push and support the lower portion of the pin coupling portion.

That is, the lower cap is coupled to the lower portion of the receiver tank by the spring member is pushed and supported by the engaging pin portion is inserted into the ring groove.

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

Figure 2 is a state diagram showing the applied receiver dryer of the present invention, the receiver dryer is connected to the condenser and mounted state, and the lower cap is shown to enlarge the main portion coupled by the capping means of the present invention.

Figure 3 is an exploded perspective view showing the configuration of the present invention, Figure 4 is a perspective view showing a combined state of the present invention, the locking pin is coupled to the hook groove in the lower portion of the receiver tank, the hooked state of the hook groove To support the spring member is shown divided into an exploded state and a coupled state.

 Hereinafter, as shown in FIG. 2, the receiver drier 100 to which the present invention is applied includes a receiver tank 10 formed in a cylindrical tubular shape, and the receiver tank 10 includes a condenser 1. It is connected to either side of the first and second tanks 2 and 3 on both sides, and a drying material 11 and a filter member 12 are mounted therein.

The drying material 11 is to increase the cooling efficiency by removing the refrigerant or water in the gaseous state that is not liquefied in the condenser (1).

In addition, the filter member 12 is located in the refrigerant passage of the receiver tank 10 to remove foreign substances contained in the refrigerant.

The receiver tank 10 is the upper cap 20 is welded or blazed integrally on the upper portion, the lower cap 30 is coupled to the opening formed in the lower portion is hermetically sealed.

In addition, holes 10a and 10b for forming the refrigerant passage are formed in the lower portion of the receiver tank 10 at intervals, and connecting pipes 10c connected to the condenser 1 are provided in the holes 10a and 10b, respectively. Each of these is fitted together.

The configuration and operation of the receiver drier 100 is the same as the conventional known configuration and it is found out that it is included in the configuration of the present invention.

The receiver tank 10 is sealed by the lower cap 30 is coupled to the lower portion, the lower cap 30 is seated on the opening of the receiver tank 10 to cover the lower cover plate 31, The coupling guide protrusion 32 which protrudes to the upper portion of the lower cover plate 31 and couples to the lower inner side of the receiver tank 10 and the outer circumferential surface of the coupling guide protrusion 32 are coupled to the inside of the receiver tank 10. O-ring 33 for sealing between the sides.

In addition, the lower cap 30 is coupled to the filter member 12 for removing the foreign matter of the refrigerant flowing through the connection pipe 10c to the upper portion of the coupling guide projection portion 32, the inside.

The coupling guide protrusion 32 supports the position of the filter member 12 so that the filter member 12 is in the refrigerant passage of the receiver tank 10, and the lower cap 30 is disposed at the lower portion of the receiver tank 10. It is to guide the coupling vertically to facilitate the coupling operation.

The filter member 12 includes a lower support portion 12a coupled to an upper portion of the lower cap 30, an upper support portion 12b supported at an interval to an upper portion of the lower support portion 12a, and the lower support portion ( The mesh network filter 12d mounted between the filter support part 12c for supporting the upper support part 12b and the filter support part 12c with a gap between the plurality of protrusions at an interval of the upper part 12a to filter foreign matters of the refrigerant 12d). ).

The mesh network filter 12d turns out that any filter that filters foreign matters of the refrigerant can be used, and this is included in the configuration of the present invention.

The lower cap 30 is coupled to the cap coupling means 40, the cap coupling means 40 of the present invention includes the coupling guide protrusion 32, and protrudes to the outside of the coupling guide protrusion 32 The locking pin portion 41, formed in the lower portion of the receiver tank 10, the pin coupling portion 42, the ring groove 43 is open to the bottom is coupled to the coupling guide projection 32, the pin It includes a spring member 44 for pushing the lower portion of the coupling portion 42.

Hereinafter, as shown in FIGS. 3 to 4, the locking pin portion 41 preferably protrudes a plurality of times at a predetermined interval on the outer circumferential surface of the coupling guide protrusion 32 to more firmly support the coupled state. The coupling guide protrusion 32 is based on the protruding symmetrically toward both sides of the outer circumferential surface.

In addition, the pin coupling portion 42 is formed integrally extended to the lower portion of the receiver tank 10, the hook groove 43 is inserted into the engaging pin portion 41 is inserted is dug.

The ring groove 43 is open to the bottom is formed so that the pin coupling portion 42 is inserted into the open lower.

The ring groove 43 is a vertical groove (43a) that is open to the bottom of the receiver tank 10 is vertically dug and formed, a horizontal groove (43b) horizontally dug at the upper end of the vertical groove (43a), It includes a locking groove (43c) which is dug downward from the end of the horizontal groove (43b).

In addition, the spring member 44 uses a leaf spring 44a that is coupled to the coupling guide protrusion 32 to be seated and supported by an upper portion of the lower cover plate 31 of the lower cap 30.

The leaf spring 44a includes an elastic flexure 44b that is integrally bent and protrudes, and the elastic flexure 44b elastically supports the lower portion of the receiver tank 10.

Referring to the coupling and separation of the lower cap 30 by the cap coupling means 40 of the present invention in detail as follows.

The coupling guide protrusion 32 is coupled to the lower portion of the receiver tank 10, and the locking pin portion 41 is inserted through the lower opening of the vertical groove 43a.

The receiver tank 10 is coupled to the coupling guide protrusion while pressing and compressing the elastic bending portion 44b of the leaf spring 44a is inserted into the vertical groove (43a).

When the locking pin 41 is positioned at the end of the vertical groove 43a, the receiver tank 10 is rotated in the direction in which the horizontal groove 43b is formed so that the locking pin 43c is formed at the end of the horizontal groove 43b. It is located at the top.

In this state, when the receiver tank 10 is pressed to release the combined force, the receiver tank 10 is pushed upward by the elastic force of the compressed leaf spring 44a, and the locking pin 41 is moved to the upper portion of the locking groove 43c. It is inserted into the inside and caught on the bottom part.

The locking pin portion 41 is a state in which the receiver tank 10 is pushed upward by the elastic force of the leaf spring 44a to be locked to the locking groove 43c.

In addition, the receiver tank 10 is pushed so that the locking pin 41 is positioned at the upper end of the locking groove 43c, and then rotates in the opposite direction to the direction in which the locking pin 41 is rotated at the time of engagement. When positioned in the engaging pin portion 41 is to be separated from the coupling guide projection of the lower cap 30 while falling out of the vertical groove (43a).

According to the configuration of the present invention described above, the lower cap has a locking pin portion coupled to the ring groove, the coupling state is supported by the spring member can be simply coupled to the bottom of the receiver tank has the effect of simplifying the manufacturing process.

In addition, the present invention is to minimize the friction between the O-ring and the receiver tank inner surface when the lower cap is coupled to increase the durability of the O-ring, it is possible to maintain a constant airtightness of the receiver tank.

Therefore, it is a very useful design to increase the productivity, durability of the receiver drier, and lower the manufacturing cost and maintenance cost.

Claims (3)

A receiver tank 10 of the receiver dryer 100, a lower cap 30 coupled to a lower portion of the receiver tank 10 to seal the inside of the tank, and a cap coupling means 40 coupling the lower cap 30. In the lower cap coupling structure of the receiver dryer including), The cap coupling means 40 is protruded to the upper portion of the lower cover plate 31 of the lower cap 30, the coupling guide protrusion 32 for coupling to the lower portion of the receiver tank 10, and the coupling guide protrusion 32 The engaging pin portion 41 protruding to the outside, the pin coupling portion 42 formed in the lower portion of the receiver tank 10, the ring groove 43 is opened to the lower portion, and the coupling guide projection portion 32 Coupled to the lower cap coupling structure of the receiver dryer, characterized in that it comprises a spring member (44) for pushing and supporting the lower portion of the pin coupling portion (42). The method according to claim 1, The ring groove 43 is a vertical groove (43a) that is open to the bottom of the receiver tank 10 is vertically dug and formed, a horizontal groove (43b) horizontally dug at the upper end of the vertical groove (43a), Lower cap coupling structure of the receiver dryer, characterized in that it comprises a locking groove (43c) which is dug downward from the end of the horizontal groove (43b). The method according to claim 1, The spring member 44 is coupled to the coupling guide protrusion 32 is seated in the upper portion of the lower cover plate 31 of the lower cap 30 and includes a leaf spring including an elastic flexure (44b) that is integrally bent to protrude ( 44a), the lower cap coupling structure of the receiver dryer.

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