KR20180013441A - Valve device and the manufacturing method of the same - Google Patents

Abstract

A multi-directional switching valve device and a manufacturing method thereof are disclosed. The multi-directional switching valve device according to one embodiment of the present invention includes: a valve housing having at least two ports through which a fluid flows in or out; a valve body installed in the valve housing so as to be rotatable and selectively opening and closing the port; and a sealing member installed between the port and the valve body such that at least one portion thereof is in close contact with the valve body, and maintaining airtightness around an opening formed in the valve body, wherein the portion of the sealing member in close contact with the valve body may be changed according to the rotation of the valve body.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-

The present invention relates to a multi-directional switching valve device and a method of manufacturing the same, and more particularly, to a multi-directional switching valve device and a method of manufacturing the same, Way switching valve device and a method of manufacturing the same.

A vehicle driven by an internal combustion engine has various kinds of valve devices therein. These valve devices are used for various types of fluids (for example, a cylinder type, a cylinder type, etc.) depending on applications such as cooling of an engine, cooling / heating of an indoor space, exhaust gas recirculation Control, or intermittence of the flow to the control unit.

A valve device capable of controlling the fluid flow path in two or more directions among these valve devices is referred to as a multi-directional switching valve device or a multi-valve device. Such a multi-directional switching valve device can be mainly used for a cooling water circulation circuit of an internal combustion engine have.

Among these multi-directional switching valve devices, a rotary valve may include a valve housing having two or more ports and a valve body selectively rotatable about a rotational axis within the valve housing to open and close two or more ports. have.

In the conventional multi-directional switching valve device, when two or more ports are formed in the valve housing, it is common to arrange the ports having the same size at the same height of the valve housing. When the ports are different from each other, Since the valve housing is formed at a different height, that is, in a separate layer, the length of the valve housing is increased and the size of the entire parts is increased.

In addition, when the ports of different sizes are arranged at the same height of the valve housing, the valve seat of the smaller-sized port, that is, the sealing member is separated from the assembling position while passing through the valve opening for opening the larger- A large load is generated on the rotary shaft during the forward and backward movement by the elastic body, thereby causing a problem of failure occurrence and life of the multi-directional switching valve device.

Korean Patent No. 10-1256291 Korean Patent No. 10-1577213

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems of the conventional multi-directional switching valve apparatus, and it is an object of the present invention to provide a multi- Directional switching valve device.

 Another object of the present invention is to provide a multi-directional switching valve device including a sealing member having a close contact position which varies according to the size of an opening of a valve body rotating in a valve housing.

A further object of the present invention is to provide a method of manufacturing a multi-directional switching valve device in which a port fitting is integrated with a port formed in a valve housing in a state where components for sealing the valve body are coupled in advance.

A multi-directional switching valve apparatus according to an embodiment of the present invention includes: a valve housing having at least two ports through which a fluid flows or flows; A valve body rotatably installed in the valve housing and selectively opening and closing the port; And a sealing member installed between the port and the valve body such that at least one portion thereof is in close contact with the valve body, and a sealing member surrounding the opening formed in the valve body to maintain airtightness, The portion of the sealing member which is in close contact with the valve body may be changed.

At least two or more ports of the ports may have different sizes, and the valve body may have a size corresponding to the ports, and at least one or more openings may be formed in the valve body to selectively communicate with the ports. have.

The sealing member is formed with at least two airtight contact portions that are in close contact with the valve body, and the outermost airtight contact portion formed at the outermost one of the airtight contact portions is in close contact with the edge of the opening having the largest size among the openings. The inner airtight contact portion formed at the innermost side of the airtight contact portion can be brought into close contact with the edge of the opening having the smallest size among the openings.

The sealing member may be installed in a port other than the largest port among the at least two ports opened by the same opening of the valve body among the ports.

The outer hermetic contact portion may protrude further toward the valve body than the inner hermetic contact portion.

The hermetic contact portion may be formed of a closed curve formed by two surfaces extending at different angles to each other, and the hermetic contact portion and the valve body may be in line contact.

In addition, a through-hole through which the fluid flows may be formed at the center of the sealing member, and an inclined surface may be formed between the inner hermetic contact portion and the through-hole.

In addition, a part of the hermetic contact portion may be formed as an inclined surface, and the hermetic contact portion may be in surface contact with the valve body.

At least one inclined surface or a curved surface may be formed between the outer hermetic contact portion and the inner hermetic contact portion.

The port fitting is coupled to the port through which a fluid can flow, and the end of the port fitting is coupled with a retainer to which the sealing member is coupled, and between the retainer and the inner circumferential surface of the port fitting, An elastic member may be provided to provide an elastic force so that the sealing member is in close contact with the valve body, and a plurality of protrusions may be formed at an inner end of the port fitting to prevent the retainer from being detached from the port fitting.

In addition, the sealing member may be coupled to the retainer in an interference fit manner.

In addition, the port fitting may be formed of a plastic injection molded product, and the port fitting may be coupled to the port in a state where the elastic member and the retainer coupled with the sealing member are pre-coupled.

The valve body is formed with a chamber in which a fluid can be received. The opening is formed by cutting a part of an outer circumferential surface of the valve body into a predetermined shape, and the valve body has a plurality of openings Or at least one opening whose width in the direction of the axis of rotation varies in the circumferential direction may be formed.

The valve housing includes an upper housing and a lower housing, and at least two ports through which fluids flow in and out, respectively, are formed in the upper housing and the lower housing, and at least two of the upper housing and the lower housing A port having a different size from each other may be provided.

According to another aspect of the present invention, there is provided a multi-directional switching valve device comprising: a valve housing including at least two ports having different sizes; A valve body rotatably installed in the valve housing and having an opening selectively communicating with the valve; A port fitting coupled to the port and having a flow path through which fluid can flow; And a sealing unit disposed inside the port and sealing at least a part of the valve body to seal the periphery of the opening, wherein the sealing unit includes a first And a second airtight contact portion which is in close contact with an edge of the smallest one of the openings.

Further, one end of the sealing unit may be in close contact with the valve body, and the other end of the sealing unit may be coupled to the port fitting.

The sealing unit may include a sealing member that is in close contact with an outer peripheral surface of the valve body, a retainer to which the sealing member is coupled, and an elastic member that is provided between the retainer and the port fitting and that provides an elastic force to the sealing member And a protruding portion for preventing the detachment of the retainer may protrude from an inner end of the port fitting.

The first airtight contact portion and the second airtight contact portion are formed on one surface of the sealing member, the first airtight contact portion is formed on the outside of the second airtight contact portion, And the distance between the retainer and the first airtight contact portion is larger than the distance between the retainer and the second airtight contact portion.

A method of manufacturing a multi-directional switching valve apparatus according to an embodiment of the present invention includes: a valve housing including at least two ports having different sizes; A valve body rotatably installed in the valve housing and having an opening formed in various sizes for selectively communicating with the port; And a sealing member having an outer airtight contact portion which is in close contact with an edge of the opening having the largest one of the openings and an inner airtight contact portion which is in close contact with an edge of the opening of the smallest one of the openings, Coupling a retainer having a sealing member fixed to a port fitting formed of a material having elasticity using the elasticity of the port fitting; And coupling the port fitting with the retainer to a valve housing having the valve body received therein.

The method may further include inserting an elastic member between the port fitting and the retainer to apply an elastic force to the sealing member before the retainer is coupled to the port fitting.

Further, the port fitting may be formed of a plastic injection molded product, and protruding portions may be formed at an inner end portion of the port fitting to prevent the retainer from being detached.

According to the present invention, the sealing member can be adhered to the periphery of the opening of the valve body irrespective of the varying opening size while the valve body rotates, thereby improving the airtightness to the port, and at the same time, Lt; / RTI >

In addition, since a plurality of ports of different sizes can be arranged at the same height of the valve housing, the length of the valve housing can be made shorter than that of the ports arranged at different heights, .

Further, when the ports having different port sizes are disposed at the same height of the valve housing, it is possible to prevent the sealing members of the smaller port from being detached from the assembled position, The load on the rotating shaft is not generated in the moving process, so that the durability of the valve device can be improved.

In addition, since the port fitting and other parts are modularly coupled to the port of the valve housing, it is possible to solve the problem that the components are separated from each other in the process of assembling the port fitting, and the stability of the components to be assembled can be secured.

Further, as the assembling and manufacturing work of the valve device is simplified, the process efficiency is increased and the production cost can be reduced.

1 is a perspective view of a multi-directional switching valve device according to an embodiment of the present invention.
2 is a perspective view showing a valve body of a multi-directional switching valve device according to an embodiment of the present invention.
3 is a perspective view showing a sealing member of a multi-directional switching valve device according to an embodiment of the present invention.
4 is a cross-sectional view taken along line A-A 'in Fig.
Figures 5 (a) -5 (c) are cross-sectional views showing sealing member shapes according to various embodiments of the present invention.
6 is a view showing a state in which a port fitting is coupled to a port of a multi-directional switching valve device according to an embodiment of the present invention.
7 is a perspective view showing the inside of a port fitting coupled to a port of a multi-directional switching valve apparatus according to an embodiment of the present invention.
8 is a view showing an interior of a multi-directional switching valve device according to an embodiment of the present invention.
9 (a) is a view showing a state in which a valve body and a port of a multi-directional switching valve device according to an embodiment of the present invention are shielded, and FIG. 9 (b) FIG. 9 (c) is a view showing a state in which the valve body of FIG. 9 (b) is rotated so that the largest one of the openings formed in the valve body And the large opening communicates with the port.
10 is a flowchart showing a method of manufacturing a multi-directional switching valve apparatus according to an embodiment of the present invention.

Hereinafter, a valve device and a method of manufacturing the same according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

However, the spirit of the present invention is not limited to such embodiments, and the spirit of the present invention may be proposed differently by adding, modifying and deleting constituent elements constituting the embodiment, .

2 is a perspective view illustrating a valve body of a multi-directional switching valve device according to an embodiment of the present invention, and FIG. 3 is a perspective view of a multi-directional switching valve device according to an embodiment of the present invention. FIG. 4 is a cross-sectional view taken along the line A-A 'in FIG. 3. FIGS. 5 (a) to 5 (c) are cross- Sectional view showing a shape of a sealing member according to various embodiments of the present invention.

1 to 5, a multi-directional switching valve device 1 according to an embodiment of the present invention includes a valve housing 10 in which a port P from which a fluid flows or flows, A valve body 20 rotatably installed in each port P and a sealing member 30 installed on each port P to prevent fluid from leaking.

The valve housing 10 is provided with a plurality of ports P, each of which may have a different size.

The valve housing (10) An upper housing 11 formed at a first height H ₁ from a bottom surface of the valve housing 10 and a lower housing 12 formed at a second height H ₂ from the bottom surface of the valve housing 10 can do.

At least two ports P may be formed in the upper housing 11 and the lower housing 12, respectively. Ports P formed in the upper housing 11 and the lower housing 12 may be formed in various sizes at the same or similar height (same layer). For example, in FIG. 8, the port P for introducing the cooling water from the engine block E and the port P for discharging the cooling water to the radiator R side are disposed at the same or similar height, Diameter.

The valve body 20 may be rotatably installed inside the valve housing 10. The valve body 20 may be coupled to a rotary shaft 23 that is rotatably coupled to the valve housing 10. An actuator such as a driving motor or other electromotive element may be connected to the rotary shaft 23 coupled with the valve body 20, and may be rotated by receiving power from such an actuator.

A plurality of ports P can be disposed around the outer circumferential surface of the valve body 20. The valve body 20 is provided with an opening (not shown) which can be selectively communicated with each port P formed in the valve housing 10 211, and 221 may be formed. The openings 211 and 221 may be formed by cutting the outer peripheral surface of the valve body 20 into a predetermined shape.

When the openings 211 and 221 of the valve body 20 and the port P communicate with each other, fluid such as cooling water may flow into the chamber formed in the valve body 20 through the port P, A fluid such as cooling water may flow out from the chamber inside the body 20 to the port P. [

Conversely, when the port P is clogged by the outer circumferential surface where the openings 211 and 221 of the valve body 20 are not formed, the port P is shielded and the fluid such as the cooling water flows through the port P It can not be leaked or introduced.

Therefore, it is preferable that the sizes of the openings 211 and 221 are formed to correspond to the sizes of the ports P, respectively.

A chamber in which the fluid can be received may be formed inside the valve body 20. [ The chamber is an empty space formed inside the valve body 20 and may serve as a flow passage through which a fluid such as cooling water can flow or may provide a space in which fluid such as cooling water can be temporarily accommodated.

The outer circumferential surface of the valve body 20 may have a shape corresponding to the inner circumferential surface of the valve housing 10 accommodating the valve body. In this embodiment, the inner circumferential surface of the valve housing 10 is curved, and the outer circumferential surface of the valve body 20 is also curved.

The valve body 20 may include a first body portion 21 and a second body portion 22. The valve body 20 includes a first body portion 21 forming an upper portion of the valve body 20 and a second body portion 22 forming a lower portion of the valve body 20, The outer circumferential surfaces of the first body 21 and the second body 22 may be curved and the shape of the valve body 20 may be formed in the form of a peanut having a concave central portion as a whole.

 A first opening 211 may be formed in a predetermined shape on the outer circumferential surface of the first body portion 21 and a second opening 221 may be formed in a predetermined shape on the outer circumferential surface of the second body portion 22 .

The opening formed in the valve body 20 may be a shape in which a plurality of openings having different sizes such as the first opening 211 formed in the first body portion 21 are formed in a circumferentially spaced manner, The width in the direction of the rotation axis 23, that is, the width in the up-and-down direction, may be changed along the circumferential direction like the second opening 221 formed in the body portion 22 (see FIG.

The sizes of the openings formed in the first body portion 21 and the second body portion 22 of the valve body 20 correspond to the sizes of the ports P opened and closed by the respective body portions 21 and 22 The sizes of the openings formed in the first body part 21 and the second body part 22 are equal to the maximum size of the ports P opened and closed by the respective body parts 21, Value and a minimum value.

In other words, the first opening 211 may be formed to have a size ranging between a maximum value and a minimum value of the size of the port P opened and closed by the first body portion 21, May be formed to have a size ranging between a maximum value and a minimum value of the size of the port P opened and closed by the second body portion 22. [

The first body part 21 and the upper housing 11 are positioned at the first height H ₁ from the bottom surface of the valve housing 10 and the first opening 211 formed in the first body part 21 The second body portion 22 and the lower housing 12 can communicate with at least two ports P formed in the upper housing 11 and the first height H ₁ of the valve housing 10, as the position in than the relatively low second height (H _2), the second body portion 22, the second opening 221 is at least two ports (P) formed in the lower housing 12 to be formed on the Can be communicated.

The sealing member 30 may be at least partially adhered to the outer circumferential surface of the valve body 20 and may serve to maintain airtightness around the openings 211 and 221 formed in the valve body 20. [ The sealing member 30 is in close contact with the periphery of the openings 211 and 221 formed in the valve body 20 so that the fluid flows out to the port through the openings 211 and 221 of the valve body 20, Prevents leakage of fluid such as cooling water to the outside of the valve body 20 or between the valve body 20 and the valve housing 10 when the fluid flows into the openings 211 and 221 of the valve body 20 can do.

A sealing member 30 may be provided at each port P and may be disposed between the valve body 20 and the port P in greater detail.

The sealing member 30 may be formed in a circular shape so as to correspond to the shape of the port P and a through hole 303 through which fluid such as cooling water can pass may be formed at the center of the sealing member 30. [ have.

The sealing member 30 may be made of Teflon or the like having excellent abrasion resistance, but the material is not limited thereto.

The sealing member 30 may be formed with at least two airtight contact portions 301 and 302 which are in close contact with the valve body 20. [ The hermetic contact portions 301 and 302 may protrude toward the valve body 20 on the surface of the sealing member 30 facing the valve body 20.

The outermost hermetic contact portion 301 formed at the outermost portion of the hermetic contact portions 301 and 302 can be brought into close contact with the edge of the largest opening among the openings 211 and 221 formed in the valve body 20, The inner airtight contact portion 302 formed at the innermost one of the openings 211 and 221 may be in close contact with the edge of the opening having the smallest size among the openings 211 and 221. An inclined surface 322 inclined at a predetermined angle may be formed between the inner hermetic contact portion 302 of the sealing member 30 and the through hole 303. [

It can be said that the position of the portion where the sealing member 30 is in close contact with the valve body 20 changes depending on the rotation of the valve body 20. [ When the valve body 20 is rotated and the largest opening among the openings formed in the valve body 20 faces the port P, the outer hermetic contact portion 301 of the sealing member 30 contacts the outer peripheral surface of the valve body 20 And when the smallest opening among the openings formed in the valve body 20 after the valve body 20 is rotated faces the same port P, the inner hermetic contact portion 302 of the sealing member 30 is in contact with the valve body 20, (20).

Ports P having different sizes are formed at the same height of the valve housing 10 and the openings formed in the valve body 20 are formed in different sizes so as to correspond to the ports P having different sizes A sealing member 30 having a plurality of hermetic contact portions in which the sealing member 30 is closely contacted by the rotation of the valve body 20 when the valve body 20 is formed, As shown in Fig.

This is because, even in the case of the sealing member 30 installed in the largest port P, the sealing member 30 is separated from the assembled position even if only a hermetic contact portion of a size large enough to come into close contact with the edge of the largest- Or it is less likely to move back and forth by the elastic member.

The sealing member 30 in which a plurality of the above-mentioned hermetic contact portions are formed has a size such that the size of the opening formed in the valve body 20 is smaller than the size of the port P selectively opposed to the opening in accordance with the rotation of the valve body 20. [ It is more effective when it is larger than the size. In this case, the outer hermetic contact portion 301 of the sealing member 30 is brought into close contact with the valve body 20 as shown in Fig. 9 (c). In this case, The problem of releasing and moving to the inside of the opening may occur. It should be noted that the sealing member 30 having a plurality of hermetic contact portions corresponding to the size of the opening of the valve body 20 can not be installed in the port P having the largest size, Of course, can also be installed.

On the other hand, the outer hermetic contact portion 301 may protrude further toward the valve body 20 than the inner hermetic contact portion 302 (see Fig. 4).

The outer airtight contact portion 301 and the inner airtight contact portion 302 may be formed as curved lines formed by two surfaces extending at different angles. For example, the outer hermetic contact portion 301 and the inner hermetic contact portion 302 may be formed as a closed curve, i.e., a circular shape, surrounding the through hole 303 of the sealing member 30. The diameter of the circle formed by the outer hermetic contact portion 301 of the sealing member 30 is set so as to correspond to the width of the largest opening among the openings formed in the valve body 20 And the diameter of the circle formed by the inner airtight contact portion 302 of the sealing member 30 is set to be larger than the width in the direction of the rotation axis of the smallest opening among the openings formed in the valve body 20, As shown in FIG.

In the present embodiment, two sealing portions formed in the sealing member 30 are described as an example. However, when the size of the opening formed in the valve body 20 is three or more, Three or more hermetic contacts may be formed in close contact with the body 20.

In this case, however, the outermost airtight contact portion is formed in a size or diameter corresponding to the largest opening, sealing the periphery of the largest opening, and the innermost airtight contact portion is formed in the smallest opening Is formed with a corresponding size or diameter, and seals the periphery of the smallest opening.

5A shows the shape of a main part of the sealing member according to an embodiment of the present invention. In Fig. 5A, the outer hermetic contact portion 301 has a sloped surface formed at the outermost portion of the sealing member 30 And the inner airtight contact portion 302 is formed by a slope surface 322 formed at the edge of the through hole 303 of the sealing member 30, And a flat surface 306 formed on the outer side thereof. Therefore, the outer hermetic contact portion 301 and the inner hermetic contact portion 302 can be in line contact with the outer circumferential surface of the valve body 20, respectively.

An inclined surface 305 formed to be inclined downward toward the inside of the sealing member 30 and an inclined surface 305 formed between the inclined surface 305 and the inclined surface 305 are provided between the outer hermetic contact portion 301 and the inner hermetic contact portion 301 of the sealing member 30 according to the present embodiment A plane 306 may be formed which extends flat toward the inner airtight contact portion 302. [

In other words, at least one of the surfaces formed between the outer hermetic contact portion 301 and the inner hermetic contact portion 302 may be formed as a sloped surface inclined at a predetermined angle, and the protruding length of the outer hermetic contact portion 301 Can be formed to be larger than the projecting length of the inner airtight contact portion (302).

The outer hermetic contact portion 301 is formed on the outer side relative to the inner hermetic contact portion 302 and is formed so as to protrude further toward the valve body 20 so that the inner hermetic contact portion 302 is closer to the valve body 20 That is, the periphery of the opening which is formed to be larger in the direction of the axis of rotation (the vertical direction in Fig. 2) can be sealed.

5 (b) shows the shape of the main part of the sealing member according to another embodiment of the present invention. In Fig. 5 (b), the outer hermetic contact portion 301 is formed at the outermost portion of the sealing member 30 The inner airtight contact portion 302 is formed by a slant surface 322 formed at the edge of the through hole 303 and a slant surface 322 formed on the outer side thereof by a curved line formed by the inclined surface 304 and the intermediate curved surface 307 formed therein, And the intermediate curved surface 307 formed on the curved surface 307 is formed. The intermediate curved surface 307 may be formed between the outer airtight contact portion 301 and the inner airtight contact portion 302. [

The intermediate curved surface 307 may be formed in a curved shape between the outer airtight contact portion 301 and the inner airtight contact portion 302 and the intermediate curved surface 307 may be concavely formed to be inclined downward toward the inside of the sealing member 30 .

An intermediate curved surface 307 formed between the outer airtight contact portion 301 and the inner airtight contact portion 302 can be concave so that the protruding length of the outer airtight contact portion 301 is less than that of the inner airtight contact portion 302, As shown in FIG.

The outer hermetic contact portion 301 is formed on the outer side of the inner hermetic contact portion 302 and is further protruded toward the valve body 20 so that the inner hermetic contact portion 302 is sealed by the valve body 20 It is the same as the embodiment shown in Fig. 5 (a) that the periphery of the opening formed to be larger than the opening can be sealed.

5C shows the shape of the main part of the sealing member according to another embodiment of the present invention. In Fig. 5C, the outer hermetic contact part 301 is formed at the outermost part of the sealing member 30 The inner airtight contact portion 302 is formed by a closed curve formed by a plane 304a on the inner side and an inclined plane 305 formed on the inner side by being in contact with each other, (Not shown).

5 (c), the outer hermetic contact portion 301 is in line contact with the outer peripheral surface of the valve body 20 as in the embodiment of Figs. 5 (a) and 5 (b) May be in surface contact with the outer peripheral surface of the valve body 20, unlike the above-described embodiments. The inner hermetic contact portion 302 is in surface contact with the outer peripheral surface of the valve body 20 in the embodiment of Fig. 5 (c), so that the contact surface at which the sealing member 30 comes into contact is further widened.

FIG. 6 is a view showing a state in which a port fitting is coupled to a port of a multi-directional switching valve apparatus according to an embodiment of the present invention, and FIG. 7 is a cross- Fig. 3 is a perspective view showing the inside of the port fitting to be coupled.

6 and 7, a port fitting 40 may be coupled to a port P of the multi-directional switching valve apparatus 1 according to an embodiment of the present invention. The port fitting 40 may be in the form of a pipe or a tube and may be connected to a radiator, an engine, or the like.

A flow path 41 through which the fluid can flow may be formed in the port fitting 40 and a retainer 31 coupled with the sealing member 30 may be coupled to the end of the port fitting 40. A plurality of protrusions 43 may be formed at an inner end of the port fitting 40 to prevent the retainer 31 from being detached from the port fitting 40. [

The end of the port fitting 40 in which the protruding portion 43 is formed is formed of an injection material such as plastic and can have elasticity and is flexibly bent when the retainer 31 is inserted into the port fitting 40, 31) can be returned to its original position after insertion. The protrusion 43 may be curved so that the retainer 31 can be easily inserted into the port fitting 40.

An elastic member 32 may be provided between the retainer 31 and the inner circumferential surface of the port fitting 40 to provide an elastic force so that the sealing member 30 can be brought into close contact with the valve body 20. [ For example, the elastic member 32 may be formed of an X-shaped ring and formed of a rubber material. The resilient member 32 may be received in the port fitting 40 before the retainer 31 to which the sealing member 30 is coupled is coupled to the port fitting 40. [ In other words, the retainer 31 can be engaged with the port fitting 40 in a state where the elastic member 32 is engaged with the port fitting 40.

The sealing member 30 can be coupled to the retainer 31 in an interference fit manner and the retainer 31 is engaged with the protruding portion 43 of the port fitting 40 in a state of being engaged with the sealing member 30, 40 to the outside. A plurality of protrusions 43 may be formed at the inner end of the port fitting 40 so that the protrusions 43 can stably support the retainer 31 and may be formed at the same angular interval. In one example, the protrusions 43 may be formed at an inner end of the port fitting 40 at intervals of 90 degrees.

Meanwhile, an O-ring (42, O-ring) may be further coupled between the port fitting (40) and the port (P).

The port fitting 40 may be formed of a plastic injection molded product and the port fitting 40 may be formed in a state in which the elastic member 32 and the retainer 31 coupled to the sealing member 30 in a detent- (P).

When the port fitting 40 is engaged with the port P of the valve housing 10 as described above, the sealing member 30, the retainer 31, the elastic member 32, It is possible to solve the problem that the parts are separated in the process of assembling the port fittings 40 by simplifying the assembling and manufacturing work of the port fittings 40. As a result, And the production cost can be reduced.

FIG. 8 is a view showing the interior of a multi-directional switching valve apparatus according to an embodiment of the present invention. FIG. 9 (a) is a view showing the valve body and the port of the multi-directional switching valve apparatus according to the embodiment of the present invention, 9 (b) is a view showing a state in which the valve body of FIG. 9 (a) is rotated so that the smallest opening among the openings formed in the valve body communicates with the port, and FIG. 9 (c) is a view showing a state in which the valve body of Fig. 9 (b) is rotated so that the largest one of the openings formed in the valve body communicates with the port.

An outer airtight contact portion 301 which is in close contact with the edge of the largest one of the openings 211 and 221 formed in the valve body 20 on one surface of the sealing member 30, An inner airtight contact portion 302 which is in close contact with the edge of the small-sized opening can be formed.

The other surface of the sealing member 30 can be engaged with the retainer 31 and the linear distance between the retainer 31 and the outer airtight contact portion 301 is larger than the straight distance between the retainer 31 and the inner airtight contact portion 302 Can be formed larger. In other words, the outer hermetic contact portion 301 may be formed so as to protrude further toward the valve body 20 than the inner hermetic contact portion 302.

Since the valve body 20 is formed in a spherical shape, the outer hermetic contact portion 301, which is in contact with the edge of the relatively larger opening, must protrude more than the inner hermetic contact portion 302, This is because it can be closely sealed and sealed.

The flow path 41 of the port fitting 40 can be opened or shielded by the second body part 22 according to the rotation of the second body part 22 of the valve body 20 (see FIG. 9).

When the uncovered portion of the outer surface of the second body 22 covers the port P, that is, when the uncovered portion of the opening 221 in the outer peripheral surface of the second body 22 9 (a)), the opening 221 of the second body portion 22 and the port (not shown) coupled to the port P are connected to each other in the case where the uncut surface closes the through hole 303 of the sealing member 30 The fluid in the second body part 22 flows out to the port P or the fluid in the second body part 22 flows from the port P to the second body part 22, It can not enter the inside.

When the valve body 20 is rotated and the opening 221a having the smallest size among the openings 221 formed in the second body part 22 and the flow path 41 of the port fitting 40 are communicated with each other, (See Fig. 9 (b)) in which the edge of the smallest opening 221a and the inner hermetic contact portion 302 of the sealing member 30 are in close contact with each other. At this time, the outer hermetic contact portion 301 may be in close contact with the outer peripheral surface of the second body portion 22, or may not be in close contact with the second hermetic contact portion. The opening 221a having the smallest size among the openings 221 formed in the second body part 22 and the flow path 41 of the port fitting 40 are communicated with each other, There is an advantage that the leakage of the fluid to the outside can be prevented and the airtight performance of the port P can be maintained.

When the valve body 20 is rotated and the opening 221b having the largest size among the openings 221 formed in the second body part 22 is communicated with the flow path 41 of the port fitting 40, The edge of the large opening 221b and the outer hermetic contact portion 301 of the sealing member 30 can be brought into close contact with each other (see Fig. 9 (c)). 9 (c), as the outer hermetic contact portion 301 is in close contact with the second body portion 22 of the valve body 20, the diameter of the port P is smaller than the diameter or size of the port P in the relatively small- Even if the large-size opening 221b is arranged so as to communicate, the sealing member 30 can be prevented from moving or moving from the position.

In other words, openings 221a and 221b of different sizes formed in the second body part 22 are communicated with the flow path 41 formed in the port fitting 40 according to the rotation of the valve body 20, The sealing member 30 has a sealing member 30 which is in close contact with the valve body 20 so as to be in close contact with the edges of the respective openings 221a and 221b. Even when the opening formed in the valve body 20 rotatable within the valve housing 10 is formed in various sizes, the leakage of the fluid around the valve body 20 is prevented, It is possible to maintain the airtightness of the sealing member 30 and to prevent the sealing member 30 from being separated and moved.

10 is a flowchart showing a method of manufacturing a multi-directional switching valve apparatus according to an embodiment of the present invention.

10, a method of manufacturing a multi-directional switching valve apparatus according to an embodiment of the present invention includes the steps of inserting an elastic member 32 between a port fitting 40 and a retainer 31, (S20) connecting the retainer 31 to which the sealing member 30 is fixed to the valve body 40, and coupling the port fitting 40 to the valve housing 10 (S30).

The retainer 31 having the sealing member 30 fixed to the port fitting 40 formed of a material having elasticity can be coupled (S20) using the elasticity of the port fitting 40 (S20) An elastic member 32 for applying an elastic force to the sealing member 30 may be inserted between the port fitting 40 and the retainer 31 before the fitting 40 is engaged.

The port fitting 40 may be formed of a plastic injection molded product and a protrusion 43 may be protruded from the inner end of the port fitting 40 to prevent the retainer 31 from coming off. A plurality of protrusions 43 may be formed at the inner end of the port fitting 40 so that the protrusions 43 can stably support the retainer 31 and may be formed at the same angular interval. In one example, the protrusions 43 may be formed at an inner end of the port fitting 40 at intervals of 90 degrees.

The sealing member 30 and the retainer 31 and the elastic member 32 can be combined in one assembly form in the port fitting 40 so that the port fitting 40 It is possible to solve the problem that the durability is lowered in a state of being coupled to the valve housing 10 and the stability of the entire sealing unit S including the sealing member 30 can be secured when assembling the multi- .

Particularly, since the protruding portion 43 is formed on the inner circumferential surface of the port fitting 40 to prevent the retainer 31 fitted with the sealing member 30 from being detached, the port fitting 40 can be inserted into the valve housing 10, The sealing member 30 can be installed at the correct position because the sealing member S is coupled to the port P in a state where the sealing unit S is preliminarily coupled to the port fitting 40. [ .

The scope of the present invention is not limited to the above-described embodiments, but may be embodied in various forms of embodiments within the scope of the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

1 valve device 10 valve housing
20 valve body 21 first body part
22 second body part 23 rotary shaft
30 sealing member 31 retainer
32 Elastic member 40 Port fitting
43 protrusion 211, 221 opening
301, 302 airtight contact portion 303 through hole

Claims (20)

A valve housing having at least two ports through which fluids flow in or out;
A valve body rotatably installed in the valve housing and selectively opening and closing the port; And
A sealing member installed between the port and the valve body such that at least one portion of the sealing member is in close contact with the valve body, the sealing member maintaining airtightness around the opening formed in the valve body;
Lt; / RTI >
Wherein the portion of the sealing member which is in close contact with the valve body changes according to the rotation of the valve body. The method according to claim 1,
Wherein at least two ports of the port, which are opened by the same opening of the valve body, have different sizes,
Wherein the valve body has a size corresponding to each of the ports, and at least one or more openings selectively communicating with the ports are formed. 3. The method of claim 2,
The sealing member may include at least two airtight contacts that are in close contact with the valve body,
Wherein an outermost airtight contact portion formed at the outermost one of the airtight contact portions is in close contact with an edge of the opening having the largest size among the openings and an innermost airtight contact portion formed at the innermost one of the airtight contact portions has an edge Wherein the multi-directional switching valve device is in close contact with the multi- The method of claim 3,
Wherein the sealing member is installed in a port other than the largest port among the at least two ports opened by the same opening of the valve body among the ports. The method of claim 3,
Wherein the outer hermetic contact portion further protrudes toward the valve body than the inner hermetic contact portion. The method of claim 3,
Wherein the hermetic contact portion is formed by a closed curve formed by two surfaces extending at different angles to each other, and the hermetic contact portion and the valve body are in line contact with each other. The method of claim 3,
A portion of the hermetic contact portion is formed as an inclined surface, and the hermetic contact portion is in surface contact with the valve body. The method of claim 3,
Wherein at least one inclined surface or a curved surface is formed between the outer hermetic contact portion and the inner hermetic contact portion. The method according to claim 1,
Wherein the port fitting is formed with a port fitting through which a fluid can flow,
Wherein an elastic member is provided between the retainer and the inner circumferential surface of the port fitting to provide an elastic force such that the sealing member is in close contact with the valve body,
Wherein a plurality of projections for preventing the retainer from being detached from the port fitting are formed at the inner end of the port fitting. 10. The method of claim 9,
Wherein the sealing member is coupled to the retainer in a forced fit manner. 10. The method of claim 9,
Wherein the port fitting is formed of a plastic injection material,
Wherein the port fitting is coupled to the port in a state where the elastic member and the retainer with which the sealing member is engaged are pre-engaged. 3. The method of claim 2,
Wherein the valve body is formed with a chamber in which a fluid can be received, and the opening is formed by cutting a part of an outer circumferential surface of the valve body into a predetermined shape,
Wherein the valve body is formed with a plurality of openings having different sizes in the circumferential direction or at least one opening having a width in the direction of the rotational axis is formed along the circumferential direction. 3. The method of claim 2,
The valve housing includes an upper housing and a lower housing,
The upper housing and the lower housing are provided with at least two ports through which fluids flow in and out, respectively,
Wherein at least one of the upper housing and the lower housing has ports different in size from each other. A valve housing including at least two ports having different sizes;
A valve body rotatably installed in the valve housing and having an opening selectively communicating with the valve;
A port fitting coupled to the port and having a flow path through which fluid can flow; And
A sealing unit installed inside the port fitting and sealing at least a part of the valve body to seal the periphery of the opening;
/ RTI >
Wherein the sealing unit has a first airtight contact portion that is in close contact with an edge of the largest opening in the opening and a second airtight contact portion that is in close contact with an edge of the smallest one of the openings. 15. The method of claim 14,
Wherein one end of the sealing unit is in close contact with the valve body and the other end of the sealing unit is coupled to the port fitting. 16. The method of claim 15,
Wherein the sealing unit comprises:
A sealing member which is in close contact with an outer circumferential surface of the valve body,
A retainer to which the sealing member is coupled,
And an elastic member provided between the retainer and the port fitting for providing an elastic force to the sealing member,
And a protruding portion protruding from an inner end of the port fitting to prevent the retainer from being separated from the port fitting. 17. The method of claim 16,
Wherein the first hermetic contact portion and the second hermetic contact portion are formed on one surface of the sealing member, the first hermetic contact portion is formed outside the second hermetic contact portion,
The other surface of the sealing member is coupled to the retainer,
And the distance between the retainer and the first airtight contact portion is larger than the distance between the retainer and the second airtight contact portion. A valve housing including at least two ports having different sizes; A valve body rotatably installed in the valve housing and having an opening formed in various sizes for selectively communicating with the port; And a sealing member having an outer airtight contact portion which is in close contact with an edge of the opening having the largest one of the openings and an inner airtight contact portion which is in close contact with an edge of the opening of the smallest one of the openings is formed In this case,
Coupling a retainer having a sealing member fixed to a port fitting formed of a material having elasticity using the elasticity of the port fitting; And
Coupling a port fitting to which the retainer is coupled to a valve housing in which the valve body is received;
Wherein the multi-directional switching valve device comprises: 19. The method of claim 18,
Further comprising inserting an elastic member between the port fitting and the retainer to apply an elastic force to the sealing member before the retainer is coupled to the port fitting. 19. The method of claim 18,
Wherein the port fitting is formed of a plastic injection molded product, and a protrusion protruding from the retainer is protruded from an inner end of the port fitting.

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