KR101549673B1 - Pinch valve - Google Patents

Abstract

According to the present invention, a pinch valve comprises: a flexible pipe wherein a fluid flows and penetrates through between a first and a second body unit; a housing composed of the first and the second body unit; pressing units composed of a cylindrical first rotary unit with a first gear on a top and a cylindrical second rotary unit with a second gear on the top, arranged inside the housing to face each other while interposing the pipe; a driving unit composed of a driving gear engaged with a first and a second gear inside the housing, rotating a first and a second rotary unit in different direction, and a driving shaft protruding from the top of the driving gear to the outside of the housing. The first rotary unit includes a first closing protrusion protruding from a lateral surface in a direction parallel to the rotary shaft, and a first opening groove formed on the lateral surface to an inner side. The second rotary unit includes a second closing protrusion protruding from a lateral surface to a direction parallel to the rotary shaft and a second opening groove formed on the lateral surface to the inner side. The pipe is able to be in an opening state in which the first and the second opening groove face; a first closing state in which the lateral surfaces of the first and the second rotary unit, and a second closing stage in which the first and the second closing protrusions face. Accordingly, the present invention is capable of doubly pressing the pipe, thus completely sealing airtightly.

Description

Pinch Valve {PINCH VALVE}

The present invention relates to a pinch valve, and more particularly to a pinch valve capable of compressing a flexible pipe installed in a housing of a pinch valve in two stages.

A valve is a device for controlling the flow rate, pressure, etc. of a fluid by installing it in the middle of a pipeline or in a container. As the types of commonly used valves, a stop valve (a globe valve and an angle valve) Check valves, cocks, plug valves, ball valves, diaphragm valves, and pinch valves are widely used.

The pinch valve is a valve for inserting a cylindrical flexible pipe having elasticity into the valve body and controlling the flow rate through the flexible pipe by pressing the central portion of the flexible pipe on both sides and the flow path portion is naturally contracted. Cement production facilities, paper making facilities, thermal power plants, oil refineries and so on.

The conventional pinch valve has a problem in that it can not maintain perfect airtightness when the flexible pipe is squeezed.

Although the 'pinch valve device' disclosed in Japanese Laid-Open Patent Publication No. 10-2014-0077870 discloses a pinch valve device having a simplified structure, there is a problem that the pinch lever can press the cylindrical tube only once.

The pinch valve according to the present invention is contrived to solve the above-mentioned problems, and it is intended to provide a pinch valve capable of maintaining a perfect airtightness by pressing the flexible pipe in two stages.

The problems to be solved by the present invention are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

A pinch valve according to the present invention includes: a flexible pipe through which a fluid flows; A housing having a first body portion and a second body portion, the pipe passing between the first body portion and the second body portion; A compression unit including a cylindrical first rotating part having an upper part coupled to a first gear and a second rotating part having a cylindrical shape with an upper part coupled to the second gear and mounted so as to face each other with a pipe interposed in the housing; And a driving unit configured to engage between the first gear and the second gear in the housing to rotate the first and second rotating units, and a driving shaft extending from an upper end of the driving gear and protruding to the outside of the housing .

In the pinch valve according to the present invention, the first rotating portion includes a first closing tang protruding in a direction parallel to the rotation axis at the side surface and a first opening trench formed inward at the side surface, and the second rotating portion has, And a second open groove formed inwardly from the side surface of the pipe, wherein the pipe has an open state in which the first open groove and the second open groove face each other, a side surface of the first turn part, It is preferable that the side of the second rotating portion has a first closed state and a second closed state in which the first closing jaw faces the second closing jaw.

In the pinch valve according to the present invention, it is preferable that a spiral groove or protrusion is formed in the pipe to form a vortex in the fluid flowing therein.

In the pinch valve according to the present invention, the first pressing projection is formed on the upper and lower sides of the side of the first rotating portion, the second pressing projection is formed on the upper and lower sides of the second rotating portion, It is preferable that the pressing projections press the upper and lower portions of the pipe in the first closed state.

In the pinch valve according to the present invention, it is preferable that the first rotating portion is subjected to a rounding process between the first closing step and the first opening groove, and the second rotating portion is rounded between the second closing step and the second opening groove.

In the pinch valve according to the present invention, the first closing step is formed with a first concavo-convex part on the surface in contact with the pipe, and the second closing step is formed with a second concavo-convex part in the shape of engaging with the first concave- .

The pinch valve according to the present invention is capable of maintaining a perfect airtightness by pressing the flexible pipe in two stages with the pressing projection or the pressing portion having the concave and convex portions formed thereon.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a perspective view of a pinch valve according to an embodiment of the present invention.
2 is an exploded perspective view of a pinch valve according to an embodiment of the present invention.
3A to 3C are a front view and a plan cross-sectional view showing a state of a pipe when a crushing portion of a pinch valve is rotated according to an embodiment of the present invention.
4 is a perspective view illustrating a pipe of a pinch valve according to an embodiment of the present invention.
5 is a front cross-sectional view illustrating a crushing portion of a pinch valve according to an embodiment of the present invention.
6 is a front sectional view showing a first concavo-convex portion and a second concavo-convex portion formed in a crushable portion of a pinch valve according to an embodiment of the present invention.
7 is a side cross-sectional view showing the interior of the housing of the pinch valve according to an embodiment of the present invention.

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

In the pinch valve according to the present invention,

A flexible pipe 100 through which fluid flows;

A housing 200 having a first body part 220 and a second body part 240 and passing the pipe 100 between the first body part 220 and the second body part 240;

And a second rotating portion 440 having a cylindrical shape in which a first gear 421 is coupled to an upper portion and a second gear 441 is coupled to an upper portion of the first rotating portion 420. Inside the housing 200, (400) mounted to face the pipe (100); And

A driving gear 620 engaged with the first gear 421 and the second gear 441 and rotating the first and second rotating parts 420 and 440 in the housing 200, And a drive shaft 640 extending from an upper end of the housing 620 and projecting to the outside of the housing 200.

The pipe 100 is a pipe through which a fluid such as a chemical flows in the pipe 100. When the pipe 100 is pressed from both sides of the pipe 100, the pipe 100 is closed and the flow of the fluid is shut off. 100).

Referring to FIG. 4, the pipe 100 passes through the inside of the housing 200, and is formed such that the diameter of the central portion in the longitudinal direction is reduced. When the pipe 100 is closely contacted by the crimping portion 400 in the housing 200 It is preferable that the housing 200 has a space therein so as to accommodate the longitudinal volume of the pipe 100 which is compressed and extended.

A spiral groove 120 or a protrusion (not shown) may be formed on the inner circumferential surface of the pipe 100 so that the fluid flowing therein may form a vortex, and the spiral groove 120 or the protrusion may be formed inside the pipe 100 Smooth flow of flowing fluid.

The pipe 100 may be fixed to the inside of the housing 200 at both ends in the longitudinal direction and may be fixed to the pipe 100 by fixing protrusions 160 formed therein, The groove 246 can be formed.

A flange 140 is formed at both ends of the pipe 100 and a seating groove 245 for fixing the flange 140 is formed in the housing 200 so that the pipe 100 extends in the longitudinal direction It can be prevented from moving.

1 and 2, the housing 200 corresponds to a body for mounting the pipe 100, the pressing part 400 and the driving part 600 therein, and includes a first body part 220 and a second body part 220, And the first body part 220 and the second body part 240 may be coupled to each other by bolts and nuts.

The housing 200 is composed of a first body part 220 and a second body part 240 that are divided in the longitudinal direction of the pipe 100 and the arrangement of the inside of the housing 200 is centered on the pipe 100 And the crimping portion 400 is positioned on both sides.

Referring to FIG. 7, the first body 220 has a first pipe receiving groove 221, which is a space capable of receiving the pipe 100 therein, and the first rotating part 420 is rotatable And a supporting ring 700 coupled to the upper and lower portions of the first rotating portion 420 and supporting the rotation of the first rotating portion 420 is installed in the first pressing portion receiving groove 222, A first insertion groove 223 is formed in the upper and lower portions of the receiving groove 222 of the first pressing portion 400 and the first insertion groove 223 is formed on the upper side of the receiving groove 222 of the first pressing portion 400, A first gear receiving groove 224 is formed in which the gear 421 can rotate.

The second body portion 240 is symmetrical with respect to the first body portion 220 and is formed in the same shape as that formed in the first body portion 220. The second pipe receiving groove 241, Receiving grooves 242, second insertion grooves 243, and second gear receiving grooves 244 are formed.

The housing 200 is connected to an external connection pipe (not shown) connected to the pipe 100 at the front and rear.

5, the crimping portion 400 is a portion that compresses the pipe 100 to open and close the pipe 100, and includes a first rotating portion 420 having a cylindrical shape and spaced apart from the first rotating portion 420 by a predetermined distance, And a second rotating part 440.

The first rotating part 420 includes a first closing step 424 protruding in a direction parallel to the rotation axis of the side surface and a first opening groove 422 formed inward from a side surface of the first rotation part 420. The second rotation part 440 Has a second closing step 444 protruding from a side surface in a direction parallel to the rotation axis and a second opening groove 442 formed inward from the side surface.

The first rotating part 420 is subjected to a rounding process between the first closing step 424 and the first opening groove 422 and the second rotating part 440 is rotated between the second closing step 444 and the second opening groove 442 are rounded, it is possible to prevent breakage of the pipe 100 when the pipe 100 is changed from the open state to the first closed state.

The second closing part 444 is located in the diagonal direction of the first closing part 424 so that the diagonally opposite parts of the first rotating part 420 and the second rotating part 440 are symmetrical to each other, 1 gear 421 and a second gear 441 are respectively formed.

The pipe 100 is opened when the first opening 422 and the second opening 442 face each other and the first rotation part 420 and the second rotation part 440 are opened. The pipe 100 is brought into the first closed state when the side of the second rotating part 440 faces the side of the second rotating part 440. When the first closing step 424 and the second closing step 444 face each other, Is in the second closed state.

In the pinch valve according to the present invention, the flow of the fluid flowing inside the pipe 100 in the first closed state is temporarily blocked, and when the pipe 100 needs to be further compressed, 100) can be squeezed.

A first pressing protrusion 423 is formed on the upper and lower sides of the first rotating part 420 so as to further compress the upper and lower portions of the pipe 100 in the first closed state, The first pressing protrusion 423 and the second pressing protrusion 443 are formed such that the first rotating portion 420 and the second rotating portion 440 are opposed to each other Diagonal direction.

When the pipe 100 having a circular cross section is squeezed from the left and right sides, a space is formed at the upper and lower portions where the pipe is folded, so that the pipe 100 may not be completely closed. Therefore, the first and second compression protrusions 423, The upper portion and the lower portion of the pipe 100 may be further compressed to completely block the open portion of the pipe 100. [

The first compression protrusion 423 may be formed as a single protrusion or may be formed by separating the upper end and the upper end side of the pipe 100 and the lower end side and the lower end side of the pipe 100 into two.

The second pressing protrusion 443 may be formed as one protrusion or two protrusions as in the first pressing protrusion 423.

The first compression protrusion 423 and the second compression protrusion 443 press the upper and lower portions of the folded pipe 100 in half to completely block the fluid flowing into the pipe 100.

The first closure protrusion 424 and the second closure protrusion 444 may be formed with protrusions (not shown) similar to the first and second compression protrusions 423 and 443 to obtain the same effect have.

6, the first closure jaw 424 has a first concave-convex portion 425 formed on a surface thereof in contact with the pipe 100, and a second closure jaw 444 is formed on a surface contacting the pipe 100 A second concave-convex portion 445 having a shape engaging with the first concave-convex portion 425 is formed, so that the area for pressing the pipe 100 can be increased.

When the pipe 100 is squeezed between the first concave-convex part 425 and the second concave-convex part 445, the surface of the pipe 100 is folded and pressed, thereby increasing the effect of blocking the fluid flowing inside the pipe 100 Can be increased.

The supporting ring 700 is installed inside the housing 200 by coupling the supporting ring 700 to the upper and lower parts of the first rotating part 420 and the second rotating part 440, The first rotation part 420 and the second rotation part 440 support the rotation of the first rotation part 420 and the second rotation part 440 by being inserted into the insertion groove 223 and the second insertion groove 243, And a fitting groove may be formed so that the support ring 700 can be engaged with the upper and lower ends.

The outer diameter of the support ring 700 is larger than the outer diameter of the first rotation part 420 and the second rotation part 440 and is larger than the outer diameter of the support ring 700 and the second rotation part 440 coupled to the first rotation part 420 In this case, the pipe 100 pressed between the first closure jaw 424 and the second closure jaw 444 is brought into contact with the support ring 700, It is possible to prevent the pipe 100 from moving up and down, and to increase the effect of pressing the pipe 100.

The driving unit 600 is installed inside the housing 200 and drives the pressing unit 400. The driving unit 600 is engaged with the first gear 421 and the second gear 441 to rotate the first rotating part 420 and the second rotating part 420. [ And a driving shaft 640 extending from the upper end of the driving gear 620 and protruding out of the housing 200. The driving gear 620 rotates the rotation unit 440 in opposite directions.

The drive gear 620 is disposed between the first gear accommodating groove 224 and the second gear accommodating groove 244 so as to be engaged with the first gear 421 and the second gear 441 at the same time, 640 are coupled to the driving gear 620 at the lower end and protrude to the outside of the housing 200 at the upper end.

The first gear 421 and the second gear 441 are engaged with both sides of the driving gear 620. When the driving shaft 640 is rotated, the first gear 421 and the second gear 441 rotate, The first rotating part 420 and the second rotating part 440 rotate in the same direction with each other with the pipe 100 interposed therebetween.

When the driving shaft 640 is rotated, the first rotating part 420 and the second rotating part 440 are rotated, so that the pipe 100 in the opened state is deformed in the first closed state and the second closed state.

The driving shaft 640 can be operated by using a driving motor (not shown) or the like, and the driving motor can be directly attached to the upper portion of the housing 200.

Hereinafter, the opening and closing procedures of the pipe 100 will be described with reference to FIGS. 3A to 3C.

When the first opening groove 422 of the first rotating part 420 and the second opening groove 442 of the second rotating part 440 face each other inside the housing 200, It is in an open state where it can flow.

When the driving shaft 640 is rotated, the first opening groove 422 of the first rotating portion 420 and the second opening groove 442 of the second rotating portion 440 face each other, The width of the inner space in the left and right direction decreases and the width in the up and down direction increases.

 When the drive shaft 640 is rotated at a predetermined angle, the space formed between the first open groove 422 of the first rotating portion 420 and the second open groove 442 of the second rotating portion 440 disappears, The pipe 100 is completely compressed in the space formed by the side surface of the rotation part 420 and the side surface of the second rotation part 440 facing each other to reach the first closed state in which the fluid flowing in the pipe 100 is blocked.

When the driving shaft 640 is further rotated by a predetermined angle, the first closing jaw 424 of the first rotating part 420 and the second closing jaw 444 of the second rotating part 440 are opposed to each other in the space formed by the pipe 100 Is brought into a second closed state in a state in which it is compressed further than the first closed state.

The first closed state and the second closed state can be selected according to the kind, speed, pressure, etc. of the fluid flowing in the pipe 100.

The pipe 100 in the first closed state or the second closed state is returned to the initial opened state when the driving shaft 640 is rotated in the opposite direction.

It is to be understood that the present invention is not limited to the above-described embodiment, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100: pipe 120: spiral groove
140: Flange 160: Fixing projection
200: housing 220: first body part
221: first pipe receiving groove 222: first pressing part receiving groove
223: first insertion groove 224: first gear receiving groove
240: second body part 241: second pipe receiving groove
242: second pressing portion receiving groove 243: second insertion groove
244: second gear receiving groove 245: seat groove
246: Fixing groove 400:
420: first rotating portion 421: first gear
422: first opening groove 423: first pressing projection
424: first closing chin 425: first concave / convex portion
440: second rotating portion 441: second gear
442: second opening groove 443: second pressing projection
444: second closing chin 445: second uneven portion
600: driving part 620: driving gear
640: drive shaft 700: support ring

Claims (5)

A flexible pipe through which fluid flows;
A housing having a first body part and a second body part, the pipe passing between the first body part and the second body part;
And a second rotating part having a cylindrical shape and having a first rotating part having a first gear coupled to an upper part thereof and a second gear coupled to an upper part of the second rotating part and mounted on the inside of the housing so as to face each other with the pipe interposed therebetween; And
And a driving unit that is engaged with the first gear and the second gear in the housing to drive the first and second rotating units and a driving shaft extending from the upper end of the driving gear and protruding to the outside of the housing However,
Wherein the first rotating part has a first closing step protruding in a direction parallel to the rotation axis at a side surface and a first opening groove formed inward from a side surface,
Wherein the second rotating portion has a second closing step protruding from a side surface in a direction parallel to the rotation axis and a second opening groove formed inward from a side surface,
Wherein the pipe has an open state in which the first open groove and the second open groove face each other, a first closed state in which the side face of the first rotating part faces the side face of the second rotating part, And a second closed state opposite to the first closed state.
The method according to claim 1,
Wherein the pipe is formed with a spiral groove or a protrusion so that the fluid flowing therein forms a vortex.
The method according to claim 1,
A first pressing protrusion is formed on the upper side and the lower side of the first rotating part,
A second pressing protrusion is formed on upper and lower sides of the second rotating part,
Wherein the first compression protrusion and the second compression protrusion press the upper and lower portions of the pipe in the first closed state.
The method according to claim 1,
Wherein the first rotating portion is rounded between the first closing step and the first opening groove,
And the second rotating portion is rounded between the second closing step and the second opening groove.
The method according to claim 1,
The first closing jaw is provided with a first concave-convex portion on a surface in contact with the pipe,
And the second closing jaw is formed with a second concavo-convex portion in a shape of engaging with the first concavo-convex portion on a surface contacting with the pipe.

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