KR20220109802A - Directional conversion Valve - Google Patents

Abstract

In accordance with the present invention, provided is a direction switching valve including: a body part having an inlet through which a fluid is introduced from the outside, and first and second outlets through which the fluid introduced through the inlet is discharged to the outside; a driving part installed in the body part; and a placement ball placed inside the inlet and the first and second outlets to control the flow of the fluid, and having first, second and third through holes formed to be selectively connected with the inlet, the first outlet and the second outlet, respectively, wherein in the body part, the inlet is formed in a lower part, and the first and second outlets are formed to be spaced upward from the inlet. In accordance with the present invention, the body part in which the inlet for introducing the fluid is provided on a lower side and the first and second outlets for discharging the fluid are provided on an upper side from the inlet, and the first to third through holes installed in the body part, are selectively connected with the inlet and the first and second outlets depending on modes, thereby enabling the selection of an upward flow path. Moreover, in accordance with the present invention, since the second through hole of the placement ball installed in the body part is provided with a smaller diameter than that of the third through hole, differential pressure, which is a resistance difference applied to a fluid line of the second outlet connected with the second through hole in a dehumidification mode, can be controlled such that suitable fluid flow control can be possible. Therefore, in accordance with the present invention, since the selection of the upward flow path and the suitable fluid flow can be possible, the performance of a vehicle system can be improved.

Description

Directional conversion valve

The present invention relates to a valve for switching, and more particularly, to a valve for switching the direction in which a fluid flows.

In general, a direction switching valve is provided as a means for controlling the direction of a fluid by allowing or blocking the fluid in various devices and industrial fields.

Such a direction switching valve includes a main body device having an inlet through which a fluid is introduced, an outlet through which the fluid introduced through the inlet flows out to the outside, a driving device installed at the upper end of the main body device, and installed inside the main body device A seating ball having a through hole communicating with the inlet and outlet is provided.

However, in the conventional directional switching valve, direction switching is possible only when the number of inlets and outlets is matched one-to-one.

Due to this, there is a structural limitation in that it is difficult for the fluid flowing to the inlet to flow to the plurality of outlets at the same time.

In addition, depending on the switching mode, there is a case in which the amount of fluid flowing in from the inlet through which the fluid flows is prevented from flowing properly in all directions with the outlet through the through hole of the seating ball, resulting in deterioration of vehicle system performance. will become more

The present invention has been created to achieve the above object, and an object of the present invention is to provide a valve for switching the direction so that the flow of the fluid is appropriately adjusted according to the mode.

The present invention, the body portion having an inlet through which a fluid is introduced from the outside, and a first outlet and a second outlet through which the fluid introduced through the inlet is discharged to the outside; a driving unit installed in the main body; and a first through hole and a second through hole disposed inside the inlet and the first outlet and the second outlet to control the flow of the fluid, and selectively communicating with the inlet, the first outlet, and the second outlet, respectively. A directional switching valve comprising a seating ball having a hole and a third through-hole formed therein, wherein the main body portion has the inlet formed at the lower portion, and the first outlet and the second outlet are spaced apart from the inlet to the upper portion. do.

The seating ball is provided with the first through-hole communicating with the inlet at the lower portion, and the second and third through-holes are spaced apart from the first through-hole to the upper portion.

The seating ball has a communication space formed therein through which the first through hole to the third through hole respectively communicate.

The seating ball is further formed with a fourth through-hole spaced apart from the first, second, and third through-holes with the communication space therebetween.

The second through-hole has a diameter smaller than that of the third through-hole.

In the first mode, the first through-hole communicates with the inlet, the second through-hole is adjacent to the inner wall of the main body, and the third through-hole is adjacent to the inner wall of the main body, and the second through-hole is adjacent to the inner wall of the main body. The fourth through-hole communicates with the first outlet, and the first through-hole and the fourth through-hole enable the fluid to flow from the inlet to the first outlet through the communication space.

In the second mode, the seating ball is rotated by the driving unit, the first through-hole communicates with the inlet, the second through-hole communicates with the second outlet, and the third through-hole is in communication with the first outlet, the fourth through hole is adjacent to the inner wall of the main body, and the first, second, and third through holes are connected to the first outlet and the inlet at the inlet through the communication space. The second outlet allows for simultaneous fluid flow.

In the third mode, the seating ball is rotated by the driving unit, the first through-hole communicates with the inlet, and the second through-hole is adjacent to the inner wall of the main body, and the third through-hole is adjacent to the inner wall of the body portion, the fourth through hole communicates with the second outlet, and the first and fourth through holes allow fluid flow from the inlet to the second outlet through the communication space. make it possible

In the first mode, the first through-hole communicates with the inlet, the second through-hole is adjacent to the inner wall of the main body, and the third through-hole communicates with the first outlet, and The first through hole and the third through hole enable the fluid to flow from the inlet to the first outlet through the communication space.

In the second mode, the first through-hole communicates with the inlet, the second through-hole communicates with the second outlet, and the third through-hole is adjacent to the inner wall of the main body, and The first through hole and the second through hole enable a fluid to flow from the inlet to the second outlet through the communication space.

In a third mode, the first through-hole communicates with the inlet, the second through-hole is adjacent to the inner wall of the main body, the third through-hole communicates with the second outlet, and the second through-hole communicates with the second outlet. The first through hole and the third through hole enable the fluid to flow from the inlet to the second outlet through the communication space.

According to the valve for direction switching according to the present invention, the first and second outlets through which the fluid flows in the lower side are provided on the upper side from the inlet, and the first of the seating balls installed inside the body unit. The through-holes to the third through-holes selectively communicate with the inlet and the first and second outlets depending on the mode, so that an upward flow path can be selected.

In addition, according to the valve for direction switching according to the present invention, the second through-hole of the seating ball installed inside the main body is provided with a smaller diameter than the third through-hole, so that the second through-hole communicates with the second through-hole in the dehumidification mode. By controlling the difference in resistance applied to the fluid line at the outlet side, that is, by controlling the differential pressure, it is possible to control the flow of the appropriate fluid.

Therefore, according to the valve for direction switching according to the present invention, it is possible to select an upward flow path and to control the flow of a suitable fluid, thereby improving the performance of the vehicle system.

1 is a perspective view of a direction switching valve according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view of the valve for direction switching in the first mode of FIG. 1 .
FIG. 3 is a cross-sectional view of the valve for direction switching in the second mode of FIG. 1 .
FIG. 4 is a cross-sectional view of the valve for direction switching in the third mode of FIG. 1 .
5 is a perspective view of a direction switching valve according to a second embodiment of the present invention.
FIG. 6 is a cross-sectional view of the valve for direction switching in the first mode of FIG. 5 .
FIG. 7 is a cross-sectional view of the valve for direction switching in the second mode of FIG. 5 .
FIG. 8 is a cross-sectional view of the valve for direction switching in the third mode of FIG. 5 .

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1 to 7 , the direction switching valve 100 according to the first embodiment of the present invention includes a body part 110 , a driving part 120 , and a seating ball 130 .

The body part 110 is formed with an inlet 111 through which a fluid is introduced from the outside, and a first outlet 112 and a second outlet 113 through which the fluid introduced through the inlet 111 flows out to the outside. .

Here, the body part 110 is not limited in shape and may be provided in a block shape of a hexahedron or a rectangular prism shape.

In addition, the inlet 111 is formed in the lower portion of the main body 110 , and the first outlet 112 and the second outlet 113 are spaced apart from the inlet 111 to the upper portion.

Due to this, in the body part 110 , it is possible to select an upward flow path for the flowing fluid from the inlet 111 to the first outlet 112 and the second outlet 113 .

The driving unit 120 is installed above the main body 110 .

The seating ball 130 is disposed inside the inlet 111, the first outlet 112, and the second outlet 113 to control the flow of the fluid, and the inlet 111, the first outlet A first through hole 131 , a second through hole 132 , and a third through hole 133 selectively communicating with the 112 and the second outlet 113 are formed.

Here, in the seating ball 130, the first through hole 131 communicating with the inlet 111 is provided at the lower portion, and the second and third through hole 132 and 133 are the first through hole ( 131) from the top.

And the seating ball 130 has a communication space 135 formed therein through which the first through hole 131 to the third through hole 133 communicate, respectively, with the communication space 135 interposed therebetween. A fourth through hole 134 spaced apart from the third through hole 133 is further formed.

Here, the communication space 135 has a structure that allows the fluid to flow through the first through hole 131 to the fourth through hole 134 .

In addition, the seating ball 130 is disposed inside the main body 110 so that the first through hole 131 to the fourth through hole 134 are formed between the inlet 111 and the first through hole 134 depending on the shape of each mode. It selectively communicates with the outlet 112 and the second outlet 113, which will be described later.

Hereinafter, in the direction switching valve 100 according to the first embodiment of the present invention, the first through hole 131 to the fourth through hole 134 of the seating ball 130 are connected to the inlet 111 and the second through hole. A mode in which the fluid flows by communicating with the outlets 1 and 2, 112 and 113, respectively, will be described.

2, in the first mode, the first through hole 131 communicates with the inlet 111, and the second through hole 132 is adjacent to the inner wall of the main body 110, The third through-hole 133 is adjacent to the inner wall of the main body 110 , and the fourth through-hole 134 communicates with the first outlet 112 .

Therefore, when the fluid flows into the inlet 111 , the first through hole 131 causes the fluid to flow into the fourth through hole 134 through the communication space 135 , so that the fluid flows into the inlet 111 . to enable the flow of the fluid to the first outlet 112 .

Referring to FIG. 3 , the second mode is a mode generated during dehumidification in a form in which the seating ball 130 is rotated by the driving unit 120 in the first mode.

Here, the seating ball 130 may be rotated by 90 degrees when rotated by the driving unit 120 , but is not necessarily limited thereto.

In the second mode, the first through hole 131 communicates with the inlet 111, the second through hole 132 communicates with the second outlet 113, and the third through hole ( 133 ) communicates with the first outlet 112 , and the fourth through hole 134 is adjacent to the inner wall of the main body 110 .

That is, when the fluid flows into the inlet 111 , the first through hole 131 to the third through hole 133 allow the fluid to pass through the communication space 135 through the first outlet 112 and the second through hole 113 . It is possible to simultaneously flow the fluid through the two outlets 113 .

Here, the second through-hole 132 is formed to have a smaller diameter than the third through-hole 133, and the size can be determined by measuring the differential pressure applied to each circuit for each system.

That is, due to this, a differential pressure is generated due to a difference in resistance applied to the fluid line on the side of the second outlet 113 through which the second through hole 132 communicates, thereby enabling proper flow control of the fluid.

Referring to FIG. 4 , in the third mode, the seating ball 130 is rotated by the driving unit 120 in the second mode.

Here, the seating ball 130 may be rotated by 90 degrees when rotated by the driving unit 120 , but is not necessarily limited thereto.

In the third mode, the seating ball 130 is rotated by the driving unit 120 , the first through hole 131 communicates with the inlet 111 , and the second through hole 132 is , adjacent to the inner wall of the main body 110 , the third through hole 133 is adjacent to the inner wall of the main body 110 , and the fourth through hole 134 is the second outlet ( 113) is connected.

Accordingly, when the fluid flows into the inlet 111 , the first through hole 131 and the fourth through hole 134 are connected from the inlet 111 to the second outlet 113 through the communication space 135 . to enable the flow of fluid.

in other words, As described above, the direction switching valve 100 according to the first embodiment of the present invention has the first through hole 131 to the fourth through hole ( 134) selectively communicates with the inlet 111, the first outlet 112, and the second outlet 113 according to the rotation for each mode so that the fluid flows, and in the dehumidification mode, the second through hole 132 It is possible to control the flow of a fluid suitable for generating a differential pressure due to a difference in resistance applied to the fluid line on the side of the communicating second outlet 113 .

Hereinafter, a direction switching valve 200 according to a second embodiment of the present invention will be described with reference to FIGS. 5 to 8 .

The direction switching valve 200 according to the second embodiment of the present invention includes a body portion 210 , a driving unit 220 , and a seating ball 230 .

The main body 210 is formed with an inlet 211 through which a fluid is introduced from the outside, and a first outlet 212 and a second outlet 213 through which the fluid introduced through the inlet 211 flows out to the outside. .

In addition, the inlet 211 of the main body 210 is formed at a lower portion, and the first outlet 212 and the second outlet 213 are spaced apart from the inlet 211 to the upper portion.

As a result, in the body part 210 , it is possible to select an upward flow path for the flowing fluid from the inlet 211 to the first outlet 212 and the second outlet 213 .

The driving unit 220 is installed above the main body 210 .

The seating ball 230 is disposed inside the inlet 211, the first outlet 212, and the second outlet 213 to control the flow of the fluid, and the inlet 211, the first outlet A first through hole 231 , a second through hole 232 , and a third through hole 233 selectively communicating with the 212 and the second outlet 213 are formed.

Here, in the seating ball 230, the first through hole 231 communicating with the inlet 211 is provided at a lower portion, and the second and third through holes 232 and 233 include the first through hole ( 231) is spaced upwards.

And the seating ball 230, the first through-hole 231 to the third through-hole 233 is further formed therein a communication space 234 to communicate with each other.

Here, the communication space 234 has a structure that allows the fluid to flow through the first through hole 231 to the third through hole 233 .

In addition, the seating ball 230 is disposed inside the body portion 210 according to the shape of each mode, so that the first through hole 231 to the third through hole 233 are connected to the inlet 211 and the second through hole 211 . The first outlet 212 and the second outlet 213 selectively communicate with each other, which will be described later.

Hereinafter, in the direction switching valve 200 according to the second embodiment of the present invention, the first through hole 231 to the third through hole 233 of the seating ball 230 are connected to the inlet 211 and the A mode for each mode selectively communicating with the first and second outlets 212 and 213 will be described.

Referring to FIG. 6 , in the first mode, the first through hole 231 communicates with the inlet 211 , and the second through hole 232 is adjacent to the inner wall of the main body 210 . , the third through hole 233 communicates with the first outlet 212 .

Therefore, when the fluid flows into the inlet 211, the first through hole 231 allows the fluid to flow into the third through hole 233 through the communication space 234, so that the fluid flows into the inlet 211. to enable the flow of the fluid to the first outlet 212 .

Referring to FIG. 7 , the second mode is a mode in which the seating ball 230 is rotated by the driving unit 220 in the first mode and is generated when dehumidifying.

Here, the seating ball 230 can be rotated by 90 degrees when rotated by the driving unit 220 , but is not necessarily limited thereto.

In the second mode, the first through hole 231 communicates with the inlet 211, the second through hole 232 communicates with the second outlet 213, and the third through hole ( 233 is adjacent to the inner wall of the main body 210 .

The first through hole 231 and the second through hole 232 allow the fluid to flow from the inlet 211 to the second outlet 213 through the communication space 234 . .

Here, the second through hole 232 is formed to have a smaller diameter than the third through hole 233 , and the size can be determined by measuring the differential pressure applied to each circuit for each system.

That is, due to this, a differential pressure is generated due to a difference in resistance applied to the fluid line on the side of the second outlet 213 through which the second through hole 232 communicates, thereby enabling proper flow control of the fluid.

Referring to FIG. 8 , in the third mode, the seating ball 230 is rotated by the driving unit 220 in the second mode.

Here, the seating ball 230 can be rotated by 90 degrees when rotated by the driving unit 220 , but is not necessarily limited thereto.

In the third mode, the seating ball 230 is rotated by the driving unit 220 , the first through hole 231 communicates with the inlet 211 , and the second through hole 232 is , adjacent to the inner wall of the main body 210 , the third through hole 233 communicates with the second outlet 213 .

Therefore, when the fluid flows into the inlet 211 , the first through hole 231 and the third through hole 233 are connected from the inlet 211 to the second outlet 213 through the communication space 234 . ) to enable the flow of fluid.

That is, as described above, the first through hole 231 to the third through hole 233 formed in the seating ball 230 disposed on the main body 210 rotates according to the rotation of the inlet 211 for each mode. and the first outlet 212 and the second outlet 213 are selectively communicated to allow the fluid to flow, and in the dehumidification mode, the second through hole 232 and the second outlet 213 are connected to the fluid line. By allowing a suitable amount of fluid to flow toward the second outlet 213 with the differential pressure generated by the difference in resistance, it is possible to control the flow of the appropriate fluid.

However, the conventional directional switching valve must match the number of inlets and outlets in a one-to-one manner in order to be able to change the direction, thereby making it difficult for the fluid flowing in the inlet to flow to the plurality of outlets at the same time.

In addition, depending on the switching mode, there are cases in which the fluid introduced from the inlet through which the fluid flows may not be properly flow controlled to the outlet through the through hole of the seating ball, resulting in deterioration of vehicle system performance.

However, according to the valve for direction switching according to the present invention, the first and second outlets through which the fluid flows in the lower side are provided on the upper side from the inlet, and the seating ball installed inside the main body is provided. Since the first through hole to the third through hole selectively communicate with the inlet and the first and second outlets depending on the mode, an upward flow path can be selected.

In addition, according to the valve for direction switching according to the present invention, the second through-hole of the seating ball installed inside the main body is provided with a smaller diameter than the third through-hole, so that the second through-hole communicates with the second through-hole in the dehumidification mode. By controlling the difference in resistance applied to the fluid line at the outlet side, that is, by controlling the differential pressure, it is possible to control the flow of the appropriate fluid.

Therefore, according to the valve for direction switching according to the present invention, it is possible to select an upward flow path and to control the flow of a suitable fluid, thereby improving the performance of the vehicle system.

100,200: direction switching valve 110,210: body part
111,211: inlet 112,212: first outlet
113,213: second outlet 120,220: driving unit
130,230: seating ball 131,231: first through hole
132,232: second through hole 133,233: third through hole
134: fourth through hole 135,234: communication space

Claims (11)

a body portion having an inlet through which a fluid is introduced from the outside, and a first outlet and a second outlet through which the fluid introduced through the inlet flows out;
a driving unit installed in the main body; and
A first through hole and a second through hole disposed inside the inlet and the first outlet and the second outlet to control the flow of the fluid, and selectively communicate with the inlet, the first outlet, and the second outlet, respectively and a seating ball having a third through-hole formed thereon,
The main body portion, the inlet is formed in the lower portion, the first outlet and the second outlet is a directional valve that is formed to be spaced apart from the upper portion from the inlet. The method according to claim 1,
The seating ball, the first through-hole communicating with the inlet is provided at a lower portion,
The second and third through-holes are directional switching valves spaced upwardly from the first through-hole. 3. The method according to claim 2,
The seating ball is a direction switching valve having a communication space in which the first through-hole to the third through-hole communicate, respectively. 4. The method of claim 3,
The seating ball is a direction switching valve in which a fourth through-hole spaced apart from the first, second, and third through-holes is further formed with the communication space interposed therebetween. 3. The method according to claim 2,
The second through-hole has a diameter smaller than a diameter of the third through-hole. 5. The method according to claim 4,
In the first mode,
The first through hole communicates with the inlet,
The second through hole is adjacent to the inner wall of the main body,
The third through hole is adjacent to the inner wall of the main body,
The fourth through hole communicates with the first outlet,
The first through-hole and the fourth through-hole are valves for direction switching that enable a fluid to flow from the inlet to the first outlet through the communication space. 5. The method according to claim 4,
In the second mode,
The seating ball is rotated by the driving unit,
The first through hole communicates with the inlet,
The second through hole communicates with the second outlet,
The third through hole communicates with the first outlet,
The fourth through hole is adjacent to the inner wall of the main body,
The first, second, and third through holes are
A direction switching valve for enabling a fluid flow from the inlet to the first outlet and the second outlet at the same time through the communication space. 5. The method according to claim 4,
In the third mode,
The seating ball is rotated by the driving unit,
The first through hole communicates with the inlet,
The second through hole is adjacent to the inner wall of the main body,
The third through hole is adjacent to the inner wall of the main body,
The fourth through hole communicates with the second outlet,
The first and fourth through holes are
A direction switching valve for enabling a fluid flow from the inlet to the second outlet through the communication space. 4. The method of claim 3,
In the first mode,
The first through hole communicates with the inlet,
The second through hole is adjacent to the inner wall of the main body,
The third through hole communicates with the first outlet,
The first through-hole and the third through-hole are valves for direction switching that enable the flow of a fluid from the inlet to the first outlet through the communication space. 4. The method according to claim 3,
In the second mode,
The first through hole communicates with the inlet,
The second through hole communicates with the second outlet,
The third through hole is adjacent to the inner wall of the main body,
The first through-hole and the second through-hole are valves for direction switching that enable a fluid to flow from the inlet to the second outlet through the communication space. 4. The method of claim 3,
In the third mode,
The first through hole communicates with the inlet,
The second through hole is adjacent to the inner wall of the main body,
The third through hole communicates with the second outlet,
The first through-hole and the third through-hole are valves for direction switching that enable a fluid to flow from the inlet to the second outlet through the communication space.

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