KR102224967B1 - Device for preventing excessive tightening of valves, and valves provided with the same - Google Patents

Abstract

An object of the present invention is to provide an apparatus for preventing excessive tightening of a valve that has a simple structure of a screw portion and is capable of reliably tightening a valve with a predetermined tightening force even if a user applies excessive rotational force to a rotation operation member.
The overtightening prevention device includes a base, a first stem screwed into a screw hole of the base, a second stem freely inserted into the insertion space of the first stem, a rotation operation member capable of rotational operation, and rotation. A compression spring that is sandwiched between the operation member and the head of the first stem and compressed in the opening and closing direction, and a connection pin that connects the head of the first stem, the second stem, and the rotation operation member so that they cannot rotate relative to each other. do. The head of the first stem has an outer diameter larger than the inner diameter of the screw hole of the pedestal. An elongated hole extending in the opening and closing direction is formed in the head, and the connecting pin is inserted into the elongated hole. Accordingly, the first stem is allowed to move relative to the rotation operation member and the second stem in the opening/closing direction.

Description

Device for preventing excessive tightening of valves, and valves provided with the same

The present invention relates to a device for preventing excessive tightening of a valve, and a valve provided with the same. More specifically, the present invention relates to a device for preventing excessive tightening of a valve that has a simple structure of a screw portion and is capable of reliably tightening the valve with a predetermined tightening force even if a user applies excessive rotational force to the rotation operation member.

Conventionally, in a manual valve such as a diaphragm valve, when excessive rotational force is applied to a rotation operation member such as a handle or a handle, a valve body such as a diaphragm is pressurized by an excessive pressure on the valve seat, There is a risk of deterioration or damage to the valve body or valve seat.

Therefore, in order to prevent excessive tightening of the valve, various manual valves have been proposed in which a spring is interposed between a rotation operation member and a member for pressing the valve body to tighten the valve with a predetermined tightening force.

For example, as an example of a conventional manual valve, the fluid controller described in Patent Document 1 includes a valve box having a flow path, a diaphragm for opening and closing the flow path, an operating mechanism provided on the rear side of the diaphragm, and the operating mechanism. It consists of a handle that moves up and down.

The operating mechanism includes a presser for pressing or separating the diaphragm toward the flow path, a shaft extending in the vertical direction and a shaft whose lower end is loosely fitted to the presser, a cylindrical stem in which the shaft is inserted from the lower opening, and the stem. A spring receiving portion disposed freely movable in the vertical direction on the outer circumferential side, and a spring provided in a gap between the spring receiving portion and the presser are provided. The stem penetrates the center of the spring receiving part in the vertical direction.

The cylindrical stem can be rotated both clockwise and counterclockwise by rotating the handle. On the inner circumferential surface and the outer circumferential surface of the stem, two types of threaded portions are provided in order to raise and lower the shaft and the spring receiving portion by the rotational force the stem receives from the handle. That is, a screwing hole (female threaded portion) is formed on the inner circumferential surface of the stem. This screwing hole is screwed into a male thread formed on the outer circumferential surface of the shaft to be inserted into the stem.

Further, a thread (male threaded portion) is formed on the outer peripheral surface of the stem. This thread is screwed into a female thread formed in the through hole of the spring receiving portion.

On the outer circumferential surface of the lower end of the stem, an abutting portion made of a ring-shaped flange that abuts on the spring receiving portion is provided. When the spring receiving portion is in contact with the abutting portion of the stem, the stem is locked and cannot rotate.

In the fluid controller configured in this way, when the handle is rotated, the stem rotates with the rotation of the handle. As the stem rotates, the shaft and the pressurizer screwed into the screwing hole of the stem descend, and the diaphragm is pressurized against the seal seat of the valve box. Along with it, the spring receiving part screwed to the thread of the outer circumference of the stem is lowered, and by the lowering of the spring receiving part, the spring is contracted in the gap between the presser and the spring receiving part. When the handle is rotated more than a certain amount, the rotational force is suppressed by the spring receiving portion abutting the abutting portion at the lower end of the stem, and the rotation of the stem is stopped. When the rotation of the stem is stopped, the spring is pressed and contracted by the lowering of the spring receiving portion. Therefore, even when the rotation of the stem is locked, the presser is pressed by a constant elastic force by the spring, so that the diaphragm is pressurized against the seal sheet and the flow path is closed.

In the fluid controller described above, a screw hole for screwing with the shaft is formed inside the stem, and a screw thread for screwing with the screw receiving portion is formed on the outer circumferential surface of the stem, and the structure of the screw portion is very complicated.

In addition, since the structure of the screw part formed inside and outside the stem is complicated, if there is any defect in the stem, the shaft may be caught inside the stem or the screw receiving part may be caught on the outer circumference of the stem. There is a concern that it cannot be done with certainty.

In addition, when excessive rotational force is applied to the stem, the spring receiving portion is locally pressed against the flange-shaped abutting portion at the lower end of the stem, so that the flange-shaped abutting portion may be deformed or damaged.

Japanese Patent No. 3465010

In order to solve the problems of the prior art as described above, the present invention has a simple and compact structure of the screw portion, and it is possible to reliably tighten the valve with a predetermined tightening force even if the user applies excessive rotational force to the rotating operation member. It is an object of the present invention to provide a device for preventing excessive tightening of a valve as possible.

The device for preventing over-tightening of a valve of the present invention is a device for preventing over-tightening of the valve body from being over-tightened in a state in which the valve body is in contact with the valve seat. And a cylindrical portion formed on an outer circumferential surface of a pedestal portion formed, a male threaded portion screwed into the screw hole, and a head portion provided at an end of the tip side of the cylindrical portion, and the opening and closing direction in the inside of the cylindrical portion and the head portion And a first stem having a continuous insertion space extending into the first stem, and a rod-shaped portion inserted freely movably in the opening and closing direction in the insertion space of the first stem, and the end of the rod-shaped portion is the A second stem that protrudes inward from the cylindrical portion and is capable of pressing the valve body in a closing direction, and a rotation operation member disposed to cover the outer circumference of the head of the first stem and having a shape capable of rotational operation; , A compression spring fitted in a state compressed in the opening/closing direction between a portion of the rotation operation member near the base portion and the head of the first stem, and extending in a direction crossing the opening/closing direction. A connection pin arranged so as to be provided with a connection pin for connecting the head of the first stem, the rod-shaped portion of the second stem, and the rotation operation member so that they cannot rotate relative to each other, and the first The head of the stem has an outer diameter larger than the inner diameter of the screw hole of the pedestal, and an elongated hole extending in the opening and closing direction is formed in the head, and the connecting pin is in the long hole. It is inserted, and thereby, the first stem is characterized in that relative movement in the opening/closing direction with respect to the rotation operation member and the second stem is allowed.

In the configuration of the device for preventing excessive tightening of the valve, there is only one screw portion, and specifically, it is constituted by a male screw portion formed on the outer circumferential surface of the cylindrical portion of the first stem and a screw hole of the pedestal screwed to the male screw portion. have. Therefore, the structure of the first stem is very simple, and the risk of getting caught in the screw portion is reduced. In addition, since the screw portion is exposed to the outside simply by removing the first stem from the pedestal portion, management of the screw portion is also very convenient. In addition, during the valve closing operation, after the second stem pressing the valve body stops, the first stem having a long hole moves in the closed direction while reducing the compression spring, and the head of the first stem is on the pedestal. Since the tightening of the valve is completed when it comes into contact with the part, excessive tightening is mechanically prevented. Thereby, even if the user applies excessive rotational force to the rotation operation member, it is possible to reliably tighten the valve with a predetermined tightening force.

Specifically, in the operation of closing the valve, when the user manually rotates the rotation operation member in the closing direction, the first and second stems connected to the rotation operation member by a connecting pin also rotate. Since the outer circumferential male screw portion of the cylindrical portion of the first stem is screwed into the screw hole of the pedestal portion, the rotation operation member, the first stem, and the second stem move in the closing direction while being integrally rotated. As the first stem and the second stem are inserted deeper into the interior of the pedestal, the end of the second stem presses the valve body in the closing direction.

When the valve body comes into contact with the valve seat, the second stem and the rotation operation member connected to the second stem via a connecting pin stop advancing in the closing direction.

On the other hand, in the first stem, the connecting pin is inserted into the elongated hole in the elongated hole formed in its head in the opening and closing direction, so that the first stem is opened and closed with respect to the rotation operation member and the second stem. Relative movement in the direction is permitted. Therefore, when the rotation operation member is further rotated while the valve body is in contact with the valve seat, only the first stem proceeds in a direction in which the male threaded portion of its cylindrical portion is screwed into the screw hole of the pedestal portion and is further closed.

At this time, the distance between the head of the first stem and the end of the rotation operation member on the side close to the base of the rotation operation member is reduced, so that the compression spring interposed therebetween is compressed to press the rotation operation member in the closing direction. This increases. The pressing force that the rotation operation member receives from the compression spring is transmitted to the second stem via the connecting pin, and the second stem further presses the valve body. In this state, the second stem does not receive the tightening force due to screwing between the first stem and the pedestal, but presses the valve body by receiving the pressing pressure of the compression spring, thereby preventing excessive tightening of the valve.

More specifically, when the first stem proceeds further in the closing direction, the head of the first stem having an outer diameter larger than the inner diameter of the screw hole of the pedestal part abuts against the periphery of the screw hole in the distal end of the pedestal, Advancement of the first stem in the closing direction is stopped. As a result, the compression force of the compression spring interposed between the head of the first stem and the end portion on the side close to the pedestal in the rotation operation member does not increase any more, and thus the second through the rotation operation member and the connecting pin The pressing pressure received from the compression spring received by the stem does not increase, and it becomes possible to prevent excessive tightening of the valve.

In this state, even if the rotation operation member is further rotated and tightened, the head of the first stem is already in contact with the distal end of the pedestal, and the first stem cannot proceed. Even if a large rotational operation force is applied to the member, the compression spring does not contract any more, so it is possible to reliably prevent excessive tightening of the valve.

It is preferable that the rotation operation member is configured so that the position of the head of the first stem can be confirmed from the outside of the rotation operation member.

According to this configuration, since the position of the head of the first stem can be checked from the outside of the rotation operation member, when the valve is closed by manually rotating the rotation operation member, the head of the first stem abuts against the pedestal. It is possible for the user to easily and reliably check that the valve is stopped and the tightening operation of the valve is finished.

In the rotation operation member, a through hole in which the head portion of the first stem can protrude to the outside of the rotation operation member is formed, and the head portion is disposed at a position protruding from the rotation operation member to the outside through the through hole. It is desirable to be.

According to this configuration, the head of the first stem is disposed at a position capable of protruding and protruding from the rotation operation member to the outside through the through hole of the rotation operation member. Thereby, it becomes possible to confirm the position of the head of the first stem from the outside of the rotation operation member, and the user can easily and reliably check that the tightening operation of the valve has been completed using the time of day.

It is preferable that the head of the first stem is disposed so that the distal end of the first stem coincides with the opening edge of the through hole of the rotating operation member in a state where it abuts against the periphery of the screw hole in the distal end of the pedestal. Do.

According to this configuration, when the head of the first stem is in contact with the periphery of the screw hole in the distal end of the pedestal, the distal end of the head coincides with the opening edge of the through hole of the rotating operation member, so that the position of the distal end of the head is It becomes possible for the user to more easily and more reliably check that the tightening operation of the valve has been completed simply by seeing whether or not it coincides with the opening edge of the through hole.

It is preferable that the screw holes of the male screw portion and the pedestal portion of the first stem are disposed inside the compression spring.

According to this configuration, it is possible to arrange three parts of the pedestal, the first stem, and the second stem inserted into the inside of the first stem on the inside of the compression spring. It becomes possible to achieve miniaturization.

The valve of the present invention includes the overtightening prevention device according to any one of claims 1 to 5, a valve body pressurized in a closed direction by the second stem, and a position where the valve body abuts against the valve body at a closed position. It characterized in that it is provided with the arranged valve seat.

The valve structured as described above has a simple structure of the screw portion by providing the above-described over-tightening prevention device, and furthermore, it is long after the second stem that presses the valve body in the valve closing operation stops. Since the first stem having the hole moves in the closed direction while reducing the compression spring, and the tightening of the valve is completed when the head of the first stem abuts the pedestal, the user is mechanically prevented from excessive tightening. Even if an excessive rotational force is applied to the rotating operation member, it is possible to reliably tighten the valve with a predetermined tightening force.

According to the device for preventing excessive tightening of the valve of the present invention and the valve provided with the same, the structure of the screw portion is simple, and even if the user applies excessive rotational force to the rotation operation member, the valve can be reliably tightened with a predetermined tightening force.

1 is a cross-sectional view showing an entire configuration of a valve provided with an excessive tightening prevention device according to an embodiment of the present invention.
FIG. 2 is a cross-sectional explanatory view illustrating that a lower handle, a first stem, and a second stem are connected to each other so that they cannot rotate relative to each other by the connection pin of FIG. 1.
3 is a cross-sectional explanatory view showing a state in which a lower portion of a handle, a first stem, and a second stem are separated.
FIG. 4 is a diagram showing a procedure of a method of using the overtightening prevention device of FIG. 1, and is a cross-sectional explanatory view showing a fully open state of a valve.
FIG. 5 is a diagram showing a procedure of a method of using the excessive tightening prevention device of FIG. 1, and is a cross-sectional explanatory view showing a state in which the valve is fully closed.
Fig. 6 is a diagram showing a procedure of a method of using the overtightening prevention device of Fig. 1, and is a cross-sectional explanatory view showing a fully closed state of a valve.

Next, with reference to the drawings, an embodiment of a valve for preventing excessive tightening of a valve according to the present invention and a valve having the same will be described in more detail.

As a valve provided with a device for preventing excessive tightening of a valve according to an embodiment of the present invention, the valve 1 shown in FIG. 1 is a manual valve that is manually opened/closed, and as an example, a diaphragm valve as the valve body 4 A diaphragm valve is shown having a.

The valve 1 includes an over-tightening prevention device 2 for preventing over-tightening of the valve, a valve box 3, a valve body 4, and a valve seat 5.

The valve box 3 has a flow path 3a through which a fluid flows, and a valve seat 5 is provided inside the flow path 3a. The valve seat 5 has a shape that closes a part of the flow path 3a.

The valve body 4 is made of, for example, a diaphragm valve, and is disposed at a position above the valve seat 5 of the valve box 3, and moves reciprocally in the opening and closing direction A, and the valve seat 5 It is possible to move between the closed position in which the flow path 3a is closed by contacting with and the open position that opens the flow path 3a apart from the valve seat 5. In addition to the diaphragm valve, the valve body 4 may be configured to open and close when a force is applied.

The valve 1 of the present embodiment is configured such that the opening and closing direction A of the valve body 4 is the vertical direction in FIG. 1, but this positional relationship is relative, and the present invention is not limited thereto, The opening/closing direction A may be configured to face in a direction other than the vertical direction, for example, a horizontal direction.

The valve seat 5 is disposed at a position where the valve body 4 abuts against the valve body 4 from the closed position.

The over-tightening prevention device 2 has a configuration such that the valve body 4 of the valve 1 is prevented from being over-tightened in a state in which the valve body 4 is in contact with the valve seat 5.

Specifically, the overtightening prevention device 2 includes a base 6, a first stem 7, a second stem 8, a handle 9 serving as a rotation operation member, and a compression coil spring ( 10) and a connecting pin 11 are provided.

In the upper part of the pedestal 6, a through screw hole 6a is formed along the opening/closing direction A in which the valve body 4 opens and closes. Inside the pedestal 6, a lower end 8b of the second stem 8 and a part of the valve body 4 are accommodated.

The first stem 7 is a cylindrical portion 7a formed on an outer circumferential surface of a male threaded portion 7c screwed to a screw hole 6a, as shown in Figs. 1 to 3, and the cylindrical portion 7a It has a head portion (7b) provided at the tip-side end of the. In the inside of the cylindrical portion 7a and the head portion 7b, a continuous insertion space 7d extending in the opening/closing direction A is formed.

The second stem 8 has a rod-shaped portion 8a inserted freely movably in the opening/closing direction A in the insertion space 7d of the first stem 7, and the rod-shaped portion 8a It is possible for the lower end 8b to protrude from the cylindrical portion 7a to the inside of the pedestal 6 and pressurize the valve body 4 in the closing direction A1. In this embodiment, the configuration in which the diaphragm presser 14 is disposed between the lower end portion 8b and the valve body 4 made of the diaphragm valve is shown, but the configuration inside the pedestal 6 may be appropriately changed. .

The handle 9 is disposed so as to cover the outer periphery of the head 7b of the first stem 7 and has a shape in which the user can manually rotate. The handle 9 is a substantially cylindrical member having a lower handle 9a and an upper handle 9b. The handle lower portion 9a and the handle upper portion 9b are connected by screwing the male screw portion formed on the outer peripheral surface of the handle lower portion 9a and the screw hole formed in the inner peripheral surface of the handle upper portion 9b.

In the upper part of the handle 9, an upper through hole 9c is formed in which the head 7b of the first stem 7 can protrude to the outside of the handle 9. The head 7b of the first stem 7 is disposed at a position capable of protruding from the handle 9 to the outside through the upper through hole 9c. Thereby, the handle 9 is configured so that the position of the head 7b of the first stem 7 can be viewed and confirmed from the outside of the handle 9.

The compression coil spring 10 is opened/closed in the opening/closing direction (A) between the handle lower portion 9a and the head portion 7b of the first stem 7, which is a portion of the handle 9 on the side close to the pedestal 6 ) Compressed. The compression coil spring 10 is a type of compression spring that generates elastic force by being compressed, and has a coil shape. In this embodiment, the compression coil spring 10 is pressed from above by the spring presser 13 attached to the head 7b, but the present invention is not limited thereto. A part of the head 7b may be protruded in the horizontal direction, and the compression coil spring 10 may be pressed from above by the protruding part.

The connecting pin 11 is a connecting pin 11 arranged so as to extend in a horizontal direction orthogonal to the opening and closing direction A in the present embodiment, specifically, in a direction crossing the opening and closing direction A, and the first The head portion 7b of the stem 7, the rod-shaped portion 8a of the second stem 8, and the handle 9 are connected so that they cannot rotate relative to each other. Specifically, as shown in Figs. 2 to 3, the rod-shaped portion 8a of the second stem 8 is inserted into the insertion space 7d of the first stem 7, and 1 A handle lower portion 9a of the handle 9 is disposed on the outer circumferential side of the stem 7. In this state, the long hole 12 formed in the head portion 7b of the first stem 7, the through hole 8c formed in the rod-shaped portion 8a of the second stem 8, and the handle 9 The through-holes 9d formed in the lower handle 9a of the are arranged to communicate with each other in the horizontal direction. The connecting pin 11 is inserted into the long hole 12, the through hole 8c, and the through hole 9d, respectively, so that the head 7b and the second stem 8 of the first stem 7 are inserted. ) Of the rod-shaped part 8a and the handle 9 are connected so that they cannot rotate relative to each other.

In addition, in this embodiment, although the connection pin 11 extends in a direction (horizontal direction) orthogonal to the opening/closing direction A, it is not limited to this in this invention. If the connecting pin 11 extends in a direction intersecting the opening and closing direction A in order to connect the first stem 7, the second stem 8, and the handle 9 so that they cannot rotate relative to each other, good. For example, as long as it is a direction intersecting with the opening/closing direction A, it may extend in a slightly inclined direction from the horizontal direction.

The head 7b of the first stem 7 has an outer diameter D2 that is larger than the inner diameter D1 of the screw hole 6a of the pedestal 6 as shown in FIG. 1. Therefore, the distal end (upper end) of the pedestal 6 is prevented from moving (lowering) in the closing direction A1 of the first stem 7 by abutting against the head 7b of the first stem 7 It functions as a stopper.

In the head 7b of the first stem 7, the above-described elongated hole 12 extending in the opening/closing direction A is formed. The connecting pin 11 is inserted into the elongated hole 12. Thereby, relative movement of the 1st stem 7 in the opening/closing direction A with respect to the handle 9 and the 2nd stem 8 is allowed.

In the overtightening prevention device 2 configured as described above, there is only one screw portion, and specifically, the male screw portion 7c formed on the outer circumferential surface of the cylindrical portion 7a of the first stem 7 and the male screw portion It is constituted by a screw hole 6a of the pedestal 6 that is screwed to (7c). Therefore, the structure of the first stem 7 becomes very simple, and the risk of getting caught in the screw portion is reduced. Moreover, since the screw part is exposed to the outside just by removing the 1st stem 7 from the pedestal 6, the management of the screw part is also very easy.

In addition, after the second stem (8) for pressing the valve body (4) stops during the closing operation of the valve (1), the first stem (7) having the long hole (12) is the compression coil spring (10). It proceeds in the closed direction while reducing the value, and since the tightening of the valve 1 is completed when the head 7b of the first stem 7 abuts against the pedestal 6, it is mechanically prevented from excessive tightening. . Thereby, even if the user applies excessive rotational force to the handle 9, it is possible to reliably tighten the valve 1 with a predetermined tightening force.

Specifically, in the valve 1 provided with the overtightening prevention device 2 configured as described above, the closing operation of the valve 1 is performed as follows.

First, in the valve 1 in the fully open state of FIG. 4, the head 7b of the first stem 7 protrudes upward of the handle 9 through the upper through hole 9c of the handle 9. I'm doing it. In this state, when the user manually rotates the handle 9 in the closing direction A1, the first stem 7 and the second stem 8 connected to the handle 9 by a connecting pin 11 Also rotates. Since the male threaded portion 7c on the outer circumferential side of the cylindrical portion 7a of the first stem 7 is screwed into the screw hole 6a of the pedestal portion 6, the handle 9 and the first stem 7 , And the second stem 8 move in the closing direction A1 while being integrally rotated. The first stem 7 and the second stem 8 are inserted deeper into the interior of the pedestal 6, so that the lower end 8b of the second stem 8 is provided with the valve body 4 (Fig. 1). Reference) in the closing direction (A1). In this way, when the handle 9, the first stem 7 and the second stem 8 are integrated and proceed in the closing direction A1, the side close to the pedestal 6 in the handle 9 The amount of deflection of the compression coil spring 10, which is a part of the handle lower portion 9a and the head portion 7b of the first stem 7 in a compressed state, is maintained in an initial state.

In this state, since a downward force is applied to the handle lower portion 9a by the compression coil spring 10, the second stem 8 is also pressed downward. This downward force is received by the first stem 7 when the connecting pin 11 abuts against the lower end of the elongated hole 12 of the first stem 7.

The handle 9, the first stem 7 and the second stem 8 are integrated and proceed in the closing direction A1, so that the valve body 4 shown in FIG. 1 contacts the valve seat 5 5, the second stem 8 and the handle 9 connected to the second stem 8 and the connecting pin 11 through the closing direction A1 Stop.

On the other hand, the first stem 7 is a connecting pin 11 inside the long hole 12 extending in the opening and closing direction A formed in the head portion 7b thereof, as shown in Figs. 5 to 6 By being inserted into the elongated hole 12, relative movement of the 1st stem 7 in the opening/closing direction A with respect to the handle 9 and the 2nd stem 8 is allowed. Therefore, when the handle 9 is further rotated while the valve body 4 is in contact with the valve seat 5, only the first stem 7 is exposed to the male screw portion 7c of the cylindrical portion 7a. While screwing into the screw hole 6a of the pedestal 6, it proceeds in the direction A1 to be further closed.

At this time, the distance between the head 7b of the first stem 7 (specifically, the spring presser 13 attached to the head 7b) and the lower handle 9a close to the pedestal 6 By reducing, the compression coil spring 10 interposed therebetween is compressed and the force for pressing the handle 9 in the closing direction A1 increases. The pressing force that the handle 9 receives from the compression coil spring 10 is transmitted to the second stem 8 via the connecting pin 11, and the second stem 8 further supports the valve body 4 Pressure. In this state, the second stem 8 does not receive the tightening force due to screwing of the first stem 7 and the pedestal 6, but receives the pressing pressure of the compression coil spring 10, and the valve body 4 Since pressure is applied, excessive tightening of the valve 1 is prevented.

More specifically, the head of the first stem 7 having an outer diameter larger than the inner diameter of the screw hole 6a of the pedestal 6 when the first stem 7 proceeds further in the closing direction A1 When (7b) abuts on the periphery of the screw hole 6a in the distal end 6b of the pedestal 6, the progress of the first stem 7 in the closing direction A1 is stopped. As a result, the compression force of the compression coil spring 10 interposed between the head 7b of the first stem 7 and the lower handle 9a does not increase further, so that the handle 9 and the connecting pin ( The pressing pressure received from the compression coil spring 10 received by the second stem 8 via 11) does not increase, and it becomes possible to prevent excessive tightening of the valve 1.

In this state, even if the handle 9 is further rotated and tightened, in the interior of the handle 9, the head 7b of the first stem 7 already fits the distal end 6b of the pedestal 6. Since the first stem 7 cannot proceed due to contact, the compression coil spring 10 does not contract any more even if a large rotational operation force is applied to the handle 9, so excessive tightening of the valve 1 is prevented. It is possible to prevent it with certainty.

In the overtightening prevention device 2 of the present embodiment, the handle 9 is configured so that the position of the head 7b of the first stem 7 can be viewed and confirmed from the outside of the handle 9.

Specifically, in the overtightening prevention device 2 of the present embodiment, in the handle 9, the head 7b of the first stem 7 can protrude to the outside of the handle 9 ( 9c) is formed. This head portion 7b is disposed at a position capable of protruding and protruding from the handle 9 to the outside through the upper through hole 9c.

According to this configuration, the head 7b of the first stem 7 is disposed at a position capable of protruding from the handle 9 to the outside through the upper through hole 9c of the handle 9. This makes it possible to see and confirm the position of the head 7b of the first stem 7 from the outside of the handle 9, and the user uses the time that the tightening operation of the valve 1 is finished. Therefore, it is possible to check easily and reliably. In other words, the head 7b of the first stem 7 can function as an indicator indicating the completion of tightening of the valve according to its position.

In particular, when the head 7b of the first stem 7 is in contact with the peripheral portion of the screw hole 6a in the distal end 6b of the pedestal 6, as shown in FIG. It is preferable that the distal end 7e of the head 7b is arranged so as to be at a position coincident with the opening edge of the upper through hole 9c of the handle 9. In this configuration, in a state in which the head 7b of the first stem 7 abuts against the periphery of the screw hole 6a in the distal end 6b of the pedestal 6, the distal end ( Since 7e) coincides with the opening edge of the upper through-hole 9c of the handle 9, it is only necessary to see whether the position of the tip of this head 7b coincides with the opening edge of the upper through-hole 9c. , It becomes possible for the user to more easily and more reliably check that the tightening operation of the valve 1 has been completed.

In the above configuration, since the position of the head 7b of the first stem 7 can be viewed and confirmed from the outside of the handle 9, the valve 1 can be closed by rotating the handle 9 manually. At this time, the user can easily and reliably check using time that the head 7b of the first stem 7 comes into contact with the pedestal 6 and stops and the tightening work of the valve 1 is finished. Do. In addition, in addition to the example of using the head portion 7b of the first stem 7 protruding outside the handle as an indicator as described above, the position of the head portion 7b of the first stem 7 is adjusted to the outside of the handle 9 Other configurations may be used as long as the configuration can be viewed and checked. For example, as another configuration, the handle 9 is formed of a transparent or translucent material, or a slit or a monitoring window (a peep window) is formed on the handle 9, the head of the first stem 7 ( It becomes possible to see 7b) from the outside of the handle 9.

In addition, in the overtightening prevention device 2 of the present embodiment, the male screw portion 7c of the first stem 7 and the screw hole 6a of the pedestal portion 6 are inside the compression coil spring 10. It is placed. In this configuration, on the inside of the compression coil spring 10, three of the pedestal 6, the first stem 7, and the second stem 8 inserted into the first stem 7 It becomes possible to arrange a part, and it becomes possible to achieve the miniaturization of the said excessive tightening prevention apparatus 2.

The valve 1 of this embodiment is provided with the above-described overtightening prevention device 2, a valve body 4, and a valve seat 5. The valve 1 constructed in this way is provided with the over-tightening prevention device 2, so that the structure of the screw portion is simple, and the valve body 4 is pressurized when the valve 1 is closed. After the second stem (8) is stopped, the first stem (7) having the long hole (12) moves in the closing direction (A1) while reducing the compression coil spring (10), and Since the tightening of the valve 1 is completed when the head 7b is in contact with the pedestal 6, it is ensured even if the user applies excessive rotational force to the handle 9 by mechanically preventing excessive tightening. It is possible to tighten the valve 1 with a predetermined tightening force.

[Industrial availability]

The present invention can be used for an apparatus for preventing excessive tightening of a valve, and a valve provided with the same. More specifically, the present invention can be used for a device for preventing excessive tightening of a valve that has a simple structure of a screw portion and is capable of reliably tightening the valve with a predetermined tightening force even if a user applies excessive rotational force to the rotating operation member, Even manual valves that are manually rotated are widely available. Therefore, in addition to the diaphragm valve disclosed in the above embodiment, any manual valve capable of adjusting the flow rate or pressure of the fluid can be widely applied.

1: valve
2: overtightening prevention device
3: valve box
4: valve body
5: valve seat
6: pedestal
7: first stem
7a: cylindrical part
7b: head
7c: male thread
7d: insert space
8: second stem
8a: rod-shaped part
8b: lower part
9: handle (rotation operation member)
9a: under the handle
9b: upper handle
9c: upper through hole
10: compression coil spring (compression spring)
11: connecting pin
12: long hole
13: spring presser
14: diaphragm presser
A: opening and closing direction
A1: Closed direction

Claims (6)

As an over-tightening prevention device that prevents excessive tightening of the valve body of the valve in contact with the valve seat,
A pedestal having a screw hole formed along the opening and closing direction in which the valve body opens and closes,
A cylindrical portion formed on an outer circumferential surface of a male threaded portion screwed into the screw hole, and a head portion provided at an end of the cylindrical portion, and a continuous insertion space extending in the opening/closing direction in the cylindrical portion and the head portion is formed. With the first stem,
The first stem has a rod-shaped portion inserted freely movably in the opening/closing direction in the insertion space of the first stem, and an end portion of the rod-shaped portion protrudes toward the inside of the pedestal portion rather than the cylindrical portion and is pressed in a direction to close the valve body A second stem that can be used,
A rotation operation member disposed so as to cover the outer circumference of the head of the first stem and having a shape capable of rotation operation,
A compression spring fitted in a state compressed in the opening/closing direction between a portion of the rotation operation member on a side close to the pedestal and a head of the first stem;
A connection pin arranged to extend in a direction crossing the opening/closing direction, wherein the head of the first stem, the rod-shaped part of the second stem, and the rotation operation member are connected to each other so that they cannot rotate relative to each other. pin
It is equipped with,
The head portion of the first stem has an outer diameter larger than the inner diameter of the screw hole of the pedestal portion, and a long hole extending in the opening and closing direction is formed in the head portion,
The connecting pin is inserted into the elongated hole, whereby the first stem is allowed to move relative to the rotation operation member and the second stem in the opening/closing direction,
Device for preventing excessive tightening of the valve, characterized in that. The method of claim 1,
The rotation operation member is configured so that the position of the head of the first stem can be viewed and confirmed from the outside of the rotation operation member. The method of claim 2,
In the rotation operation member, a through hole through which the head portion of the first stem can protrude to the outside of the rotation operation member is formed,
The head portion is disposed at a position capable of protruding from the rotation operation member to the outside through the through hole. The method of claim 3,
In a state in which the head of the first stem is in contact with the periphery of the screw hole in the distal end of the pedestal, the distal end of the head is arranged to be at a position coincident with the opening edge of the through hole of the rotating operation member. Device to prevent overtightening. The method according to any one of claims 1 to 4,
The device for preventing overtightening of a valve, wherein the screw holes of the male screw portion and the pedestal portion of the first stem are disposed inside the compression spring. The excessive tightening prevention device according to any one of claims 1 to 4, and
A valve body pressurized in a direction closed by the second stem,
A valve seat disposed in a position where the valve body is in contact with the valve body in a closed position
A valve comprising a.

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