KR101005341B1 - Control Valve for Flux - Google Patents

Abstract

The present invention relates to a flow control valve, the inlet 121 and the outlet 123 is formed, the lower housing 105 formed with a guide space 102 in communication with the inlet 121 and outlet 123 therein and; A cylindrical body bushing (109) installed in the lower housing (105) and having a stopper (108) protruding from one end in the opposite direction of the lower housing (105); A bottom plate portion 153, a cylindrical portion 155 extending from the bottom plate portion 153, an installation portion 157 extending from the central portion of the bottom plate portion 153 in the cylindrical portion 155 extending direction, and Consists of a circular flow path cross-sectional variable member 110 having a circular cross section connected to the mounting portion 157, and a stop projection 104 protruding from the base plate 153 between the mounting portion 157 and the cylindrical portion 155. A flow rate control member 107 having the variable member 110 positioned inwardly of the body bushing 109 for vertical movement; An upper housing 103 surrounding the body bushing 109 and the flow control member 107 and coupled to the lower housing 105; O-ring 111 is provided in the coupling portion of the lower housing 105 and the upper housing 103, wherein the flow path cross-sectional variable member 110 is discharged to the outlet 123 of the lower housing 105 Characterized in that the flow rate is adjusted sequentially, this is because there is no welding process, the production process is shortened, it is possible to construct a flow control valve simpler and more economical than the conventional.

Flow Control, Valve, Sequential Control

Description

Flow Control Valve {Control Valve for Flux}

The present invention relates to a flow regulating valve, and more particularly, to a flow regulating valve capable of contributing to an improved structure and a simplified work process, thereby greatly improving economical and durability.

In general, the flow control valve basically functions to control the flow rate of the circulating fluid in each part in the flow circulation system connected by a pipe and a hose. In particular, flow control valves that control the flow rate of the refrigerant circulating through each component of the refrigeration system, e.g. evaporator, compressor, condenser, expansion valve, etc. It performs essential functions in the circulation system.

This conventional flow control valve will be described with reference to FIG. 1.

1 is a cross-sectional view showing a part of the configuration of the flow control valve 1 according to the prior art. The flow control valve 1 according to the related art is largely composed of a lower housing 5 having an inlet 11 and an outlet 15, and an upper housing 3 connected to the lower housing 5. The connecting member 13 is installed between the upper housing 3 and the lower housing 5. And a flow rate adjusting member (not shown) is installed in the space formed by the upper housing (3) and the lower housing (5).

The upper housing 3 and the lower housing 5 are installed to face each other via the connecting member 13, and specifically, the connecting member 13 is fixed to the lower housing 5 by high frequency welding. Reference numeral 9 in FIG. 1 shows a high frequency weld 9 carried out to fix the connecting member 13 to the lower housing 5. One side of the connection member 13 is connected to the upper housing 3 by a welding process, and a weld 7 is formed at one side of the upper housing 3 and the connection member 13.

A fluid, such as a refrigerant, flows through the inlet 11 formed in the lower housing 5 and is discharged to the outlet 15, and the flow control member (not shown) is a control unit (not shown) provided in the refrigeration system. In accordance with the signal applied from the vertical movement to the lower housing 13, the flow rate is variable.

The flow control valve 1 according to the related art shown in FIG. 1 has the following problems.

First, the flow control valve 1 of the related art is connected to the upper housing 3 and the lower housing 5 closely by a connecting member 13, resulting in a complicated structure, resulting in a lower price competitiveness of the product. do.

Second, the conventional flow control valve 1 is produced by having the structure in which the connecting member 13 is welded to the upper housing 3 and the lower housing 5 by a welding process or connected by high frequency welding, respectively. The process is complicated, there is a disadvantage to be equipped with expensive high-frequency welding equipment.

 Third, when welding is not performed properly in such a welding process, a gap is generated in the welding part 7 or the high frequency welding part 9, and the refrigerant leaks through the welding part 7 or the high frequency welding part 9. .

The present invention has been proposed to solve the problems of the prior art as described above, the structure is improved, the strength is improved, and the airtightness of the fluid is maintained, the work process is improved by eliminating unnecessary processes such as welding process It is an object of the present invention to provide a flow control valve that can be easily produced without expensive manufacturing equipment.

Flow control valve according to the present invention for achieving the above object is the inlet and outlet is formed, the lower housing formed with a guide space in communication with the inlet and outlet; A cylindrical body bushing installed in the lower housing and having a stopper protruding from one end in an opposite direction of the lower housing; A bottom plate portion, a cylindrical portion extending from the bottom plate portion, an installation portion extending from the central portion of the bottom plate portion in a cylindrical portion extending direction, a cross-sectional flow path variable member having a circular cross section connected to the installation portion, and the installation portion; A flow rate adjusting member formed of a stop protrusion projecting from the bottom plate portion between the cylindrical portions, wherein the variable member is positioned inward of the body bushing; An upper housing surrounding the body bushing and the flow control member and coupled to the lower housing; It includes an O-ring installed in the coupling portion of the lower housing and the upper housing, the flow path cross-sectional variable member is characterized in that to sequentially control the flow rate to the outlet of the lower housing.

In the above, a male thread is formed on the outer diameter surface of the flow path cross-section variable member of the flow regulating member, a female thread is formed on the inner diameter surface of the body bushing, the flow regulating member is coupled to the body bushing to rotate and move up and down It features.

The lower housing further includes a lower coupling guide extending radially outwardly and having a concave portion, wherein the upper housing includes an upper coupling guide in which a portion of the end of the cylindrical portion is bent outwardly; The O-ring is located in the recess of the lower coupling guide, and the upper coupling guide of the upper housing is located in the recess outward of the O-ring; The upper coupling is coupled to the lower housing while the lower coupling guide is deformed radially inward to press the upper coupling guide and the O-ring.

The O-ring is connected to the lower housing by an adhesive, characterized in that the upper outer diameter portion of the lower housing is formed with a recessed adhesive storage space to prevent the overflow of the adhesive.

In the outer side of the upper coupling guide, characterized in that it further comprises a stop ring between the upper coupling guide and the lower coupling guide.

In the flow control valve 100 according to the present invention as described above, the upper housing 103 is directly fixed to the lower housing 105 without the conventional connecting member 13, and the upper housing 103 and the By connecting the lower housing 105 in a plastic deformation structure, the structure of the flow control valve 100 is simplified, and at this time, the airtightness of the fluid can be maintained at a higher level than the conventional one, and the upper housing 103 and the lower housing 105 The possibility of refrigerant leakage between the m) is reduced, and the strength of the flow regulating valve 100 is improved. In addition, since the separate welding and joining process is unnecessary at the time of manufacturing the flow control valve 100, the manufacturing process is simplified, and the manufacturing cost is reduced by reducing the cost of expensive welding equipment, and the price competitiveness of the product is increased. .

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the flow control valve according to the present invention will be described in detail.

Figure 2 is an exploded perspective view showing a flow control valve according to a preferred embodiment of the present invention, Figure 3 is a schematic cross-sectional view showing a part of the flow control valve shown in Figure 2, Figures 4 to 6 the present invention 3 is an enlarged cross-sectional view of the portion A of FIG. 3 illustrating a coupling process of the upper housing and the lower housing in the flow control valve according to FIG. 8 shows another example in which the upper and lower housings are coupled, and FIG. 9 illustrates an example of an operation of the flow regulating valve according to the present invention.

As shown in FIG. 2, the flow regulating valve 100 according to the present invention has an upper housing 103, a lower housing 105, a body bushing 109, a flow regulating member 107, and an o-ring ( 111).

As shown in FIG. 2 and FIG. 3, an inlet 121 is formed at one side of the lower housing 105, and the shape of the inlet 121 is generally circular in cross section. An inlet pipe 125 is inserted into the inlet 121 to guide the introduction of a fluid, such as a refrigerant, into the flow control valve 100. In addition, a discharge port 123 through which the fluid introduced into the flow control valve 100 is discharged is formed at one lower surface of the lower housing 105, and a discharge pipe 127 is inserted into the discharge port 123. . In addition, the positions of the inlet 121 and the outlet 123 may be disposed in other positions as necessary. For example, the inlet 121 may be located below the lower housing 105, and the outlet 123 may be located on one side of the lower housing 105. A guide space 102 is formed in communication with the inlet 121 and the outlet 123.

3 to 6, the lower coupling guide 106 is formed to protrude outward from the outer circumferential surface of the lower housing 105. The lower coupling guide 106 protrudes outward in the radial direction, and a part of the protruding end is bent upward to form a recess 112. At this time, the O-ring 111 is installed inside the lower coupling guide 106, and as shown in FIG. When the upper housing 103 is coupled to the lower housing 105, the upwardly bent portion of the lower coupling guide 106 of the lower housing 105 is bent inward in the radial direction.

As shown in FIGS. 2 to 6, the upper housing 103 serves to protect the body bushing 109 and the flow rate control member 107, and has a cup-shaped opening formed at one side thereof. The formed end has the upper coupling guide 130 bent outward. When the upper housing 103 is directly coupled to the lower housing 105, as shown in FIG. 5, the upper coupling guide 130 is positioned in the recess 112 of the lower coupling guide 106. do. The upper coupling guide 130 may be bent to have a large radius of curvature as shown in FIG. 5, or may be bent at a right angle.

As shown in FIGS. 2 and 3, the body bushing 109 has a cylindrical shape and a central through hole 150 is formed therein, and a female screw is formed around a portion of the central through hole 150. The central through hole 150 generally has the same diameter as the guide space 102 formed in the lower housing 105. As shown in FIGS. 2 and 3, the body bushing 109 includes a stopper 108 protruding from the top. The stopper 108 may be preferably integrally formed with the body bushing 109. The body bushing 109 is inserted into and installed in the insertion portion 151 formed on the upper portion of the lower housing 105. The diameter of the insertion portion 151 is formed larger than the diameter of the guide space 102, the jaw portion is formed between the insertion portion 151 and the guide space 102, the lower portion of the body bushing 150 in the jaw portion Will come into contact.

2 and 3, the flow rate control member 107 is installed in the upper housing 103, the cylindrical cup shape of one side is opened, the bottom plate 153 and the bottom plate 153 ) And a mounting portion 157 protruding from the central portion of the bottom plate portion 153 in the extending direction of the cylindrical portion 155. The outer diameter of the mounting portion 157 is smaller than the inner diameter of the cylindrical portion 155. The installation unit 157 is provided with a flow path cross-sectional variable member 110. The flow path cross-sectional area variable member 110 may be integrally formed with the installation portion 157 or may be coupled to the installation portion 157 by screwing. The flow path cross-sectional variable member 110 has a circular cross section, and an outer diameter surface is formed with a male thread 115 that engages with a female screw formed inside the body bushing 109, and thus the male screw of the flow path cross-sectional variable member 110 is formed. 115 is screwed to the female thread of the body bushing 109 is coupled. The body bushing 109 is positioned in the space 133 between the installation portion 157 and the cylindrical portion 155. The flow control member 107 further includes a stop protrusion 104 protruding from the bottom plate portion 153 in the extending direction of the cylindrical portion 155 between the installation portion 157 and the cylindrical portion 155. The stop protrusion 104 corresponds to the stopper 108 formed on the body bushing 109, and when the stop protrusion 104 is caught by the stopper 108, the stop protrusion 104 can no longer rotate.

Hereinafter, the connection structure of the upper housing 103 and the lower housing 105 and the O-ring 111 of the flow control valve 100 according to the preferred embodiment of the present invention will be described with reference to FIGS. 4 to 6.

An o-ring 111 is installed in the recess 112 of the lower coupling guide 106 formed in the lower housing 105. The O-ring 111 performs a function of maintaining the airtightness of the fluid or the refrigerant, and an adhesive is applied to the recess 112 formed by the lower coupling guide 106. At this time, the adhesive is applied to the recess 112 of the O-ring 111 and the lower coupling guide 106 and then the upper coupling guide 130 formed in the upper housing 103 is inserted into the recess 112. .

When the coated adhesive is excessive, it is stored in the adhesive accommodating space 113 formed in the groove shape on one side of the lower housing 105 to prevent airtightness and leakage of the adhesive.

After the adhesive, the O-ring 111, and the upper coupling guide 130 of the upper housing 103 are positioned in the recess 112 of the lower coupling guide 106, the lower housing 105 The lower coupling guide 106 formed is deformed inward in the radial direction as shown in FIG. 5. By the deformation of the coupling guide 106, the upper coupling guide 130 of the upper housing 103 is pressed inward, the O-ring 111 is pressed between the lower housing 105 and the upper coupling guide 130 do. At this time, the upper coupling guide 130 and the O-ring 111 is deformed as shown in Figure 6, the upper housing 103 and the lower housing 105 is completely sealed. As shown in FIG. 8, it is possible to further include a stop ring 137 between the upper coupling guide 130 and the lower coupling guide 106 to the outside of the upper coupling guide 130. When the lower coupling guide 106 is deformed by providing a ring 137, a greater pressure is transmitted to the upper coupling guide 130 to increase the sealing effect.

With this structure, the flow control valve 100 can maintain airtightness with a simple structure without the need for a separate welding operation. And with this simple structure, the breaking strength is also increased.

Hereinafter, the operation of the flow control valve according to a preferred embodiment of the present invention with reference to FIG.

The flow path cross-sectional area variable member 110 formed in the flow control valve 100 is configured in a multi-stage form in which the cross-sectional area is narrowed. In general, the three-stage form is preferable, but if necessary, it can be configured in various ways, such as two or four stages.

It is preferable that the cross section 140 having the largest diameter of the flow path cross-sectional variable member 110 is slightly larger than the diameter of the outlet 123, and the cross section 140 is fitted to the outlet 123 by fitting. Can be plugged in to shut off the flow. At this time, the required flow control signal is rotated up and down by rotating the flow rate control member 107 according to a signal applied from a control unit (not shown) installed in the refrigerant system (not shown). As shown in FIG. 9, the flow rate adjusting member 107 is formed of a magnet 107b, a coil 107a is provided outside the upper housing 103, and electrically connected to the coil. It is possible to rotate the adjusting member 107. At this time, when it is necessary to block the flow rate as necessary, the flow rate adjusting member 107 is lowered to control the flow rate. As the flow rate control member 107 is lowered, the flow rate discharged to the outlet 123 is sequentially controlled due to the multi-step shape of the flow path cross-sectional variable member 110.

When the flow rate needs to be completely blocked, the flow path cross-sectional area variable member 110 is completely lowered to closely fit the flow path cross-section variable member 110 to the outlet 123.

At this time, when the flow path cross-sectional area variable member 110 is excessively lowered to the outlet 123 in a fitting fit, the outlet 123 is worn to prevent the flow rate adjusting function from being lowered. The stop protrusion 104 formed at 107 is stopped by the stopper 108 formed at the body bushing 109. Therefore, wear at the outlet 123 is prevented, and the flow rate control member 107 blocks the inlet 121 to control the flow rate.

1 is a cross-sectional view showing a flow control valve according to the prior invention.

Figure 2 is an exploded perspective view schematically showing a flow control valve according to an embodiment of the present invention.

3 is a schematic cross-sectional view of a portion of the flow control valve of FIG. 2.

4, 5, and 6 are partial cross-sectional views illustrating a process of coupling the upper and lower housings illustrated in FIG. 2.

FIG. 7 illustrates a state in which the flow rate control member shown in FIG. 3 operates in the lower housing.

8 illustrates another example in which the upper and lower housings are coupled.
9 is shown to explain an operation example of the flow control valve according to the present invention.

* Description of the symbols for the main parts of the drawings *

103: upper housing 104: stop projection

105: lower housing 108: stopper

109: body bushing 107: flow control member

110: flow path cross section variable member 111: O-ring

Claims (5)

A lower housing 105 having an inlet 121 and an outlet 123 formed therein and a guide space 102 communicating with the inlet 121 and the outlet 123 therein; A cylindrical body bushing (109) installed in the lower housing (105); A bottom plate portion 153, a cylindrical portion 155 extending from the bottom plate portion 153, an installation portion 157 extending from the central portion of the bottom plate portion 153 in the cylindrical portion 155 extending direction, and A flow path adjusting member 107 having a circular cross-sectional area variable member 110 having a circular cross section connected to the installation part 157 is positioned inside the body bushing 109 and moves up and down. Wow; An upper housing 103 surrounding the body bushing 109 and the flow control member 107 and coupled to the lower housing 105; It comprises an O-ring 111 installed in the coupling portion of the lower housing 105 and the upper housing 103, the lower housing 105 extends in the radial direction on the outside and has a recess 112 Further provided with a lower coupling guide 106, the upper housing 103 includes an upper coupling guide 130 bent outwardly a portion of the cylindrical portion 155, the O-ring 111 is the lower coupling guide Located in the recess 112 of the 106, the upper coupling guide 130 is located in the recess 112 out of the O-ring (111); The lower coupling guide 106 is radially inwardly deformed to press the upper coupling guide 130 and the O-ring 111 while the upper housing 103 is coupled to the lower housing 105 flow control valve, characterized in that . According to claim 1, wherein the male screw is formed on the outer diameter surface of the flow path cross-sectional area variable member 110 of the flow control member 107, the female screw is formed on the inner diameter surface of the body bushing 109, 107 is a flow control valve 100, characterized in that the screw is coupled to the body bushing 109 and rotates up and down. delete According to claim 1, wherein the O-ring 111 is connected to the lower housing 105 by an adhesive, the upper outer diameter portion of the lower housing 105 is formed concave adhesive storage space 113 to prevent the overflow of the adhesive Flow control valve, characterized in that formed. The flow control valve according to claim 1, further comprising a stop ring (137) between the upper coupling guide (130) and the lower coupling guide (106) to the outside of the upper coupling guide (130).

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