JP7054489B2 - Valve overtightening prevention device and valve equipped with it - Google Patents

Description

The present invention relates to a valve overtightening prevention device and a valve provided with the device. More specifically, the valve overtightening prevention device has a simple structure of the threaded portion and can reliably tighten the valve with a predetermined tightening force even if the user applies an excessive rotational force to the rotation operating member. Regarding.

Conventionally, in a manual valve such as a diaphragm valve, when an excessive rotational force is applied to a rotation operating member such as a handle or a knob, the valve body such as the diaphragm is pressed against the valve seat by an excessive pressing force. There is a risk of deterioration or damage to the 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 the rotation operating member and the member that presses 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 that opens and closes the flow path, an operation mechanism provided on the back side of the diaphragm, and this operation. It consists of a handle that moves the mechanism up and down.
The operating mechanism consists of a presser that presses or separates the diaphragm toward the flow path side, a shaft that extends in the vertical direction and whose lower end is loosely fitted to the presser, and a tubular shape in which the shaft is inserted from the lower end opening. It includes a stem, a spring receiving portion movably arranged in the vertical direction on the outer peripheral side of the stem, and a spring disposed in the gap between the spring receiving portion and the press. The stem penetrates the center of the spring receiving portion in the vertical direction.
The tubular stem can rotate both clockwise and counterclockwise by rotating the handle. The inner peripheral surface and the outer peripheral surface of the stem have two types of threaded portions for raising and lowering the shaft and the spring receiving portion by the rotational force received by the stem from the handle. That is, a screw hole (female thread portion) is formed on the inner peripheral surface of the stem. This screw hole is screwed into a male thread portion formed on the outer peripheral surface of the shaft inserted into the stem.
Further, a thread (male thread portion) is formed on the outer peripheral surface of the stem. Since this thread is formed inside the through hole of the spring receiving portion, it is screwed into the threaded portion.
An abutting portion made of a ring-shaped flange that abuts on the spring receiving portion is provided on the outer peripheral surface of the lower end of the stem. When the spring receiving portion is in contact with the contact 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 is rotated with the rotation of the handle. The rotation of the stem lowers the shaft and presser screwed into the screw hole of the stem, pressing the diaphragm against the seal seat of the valve box. At the same time, the spring receiving portion screwed to the thread on the outer peripheral portion of the stem is lowered, and the lowering of the spring receiving portion causes the spring to contract in the gap between the presser and the spring receiving portion. When the handle is rotated more than a certain amount, the spring receiving portion abuts on the contact portion at the lower end of the stem, so that the rotational force is suppressed 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 if the rotation of the stem is locked, the presser is pressed by a constant elastic force by the spring, so that the diaphragm is pressed against the seal seat and the flow path is closed.

In the above fluid controller, a screw hole to be screwed with the shaft is formed inside the stem, and a thread thread to be screwed with the screw receiving portion is formed on the outer peripheral surface of the stem. The structure is very complicated.
Moreover, since the structure of the threaded portion formed inside and outside the stem is complicated, if there is even a slight defect in the stem, the shaft may be caught inside the stem, or the screw receiving portion may be caught on the outer peripheral surface of the stem. , There is a possibility that the operation to prevent excessive tightening cannot be performed reliably.
Further, when an 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 the present invention, in order to solve the above-mentioned problems of the prior art, the structure of the threaded portion is simple and small, and even if the user applies an excessive rotational force to the rotation operation member, the predetermined shape is surely determined. It is an object of the present invention to provide a valve overtightening prevention device capable of tightening a valve with a tightening force of the above.

The valve overtightening prevention device of the present invention is an overtightening prevention device that prevents the valve body of the valve from being excessively tightened in a state of being in contact with the valve seat, and is an overtightening prevention device along the opening / closing direction in which the valve body opens and closes. It has a pedestal portion on which a screw hole is formed, a cylindrical portion in which a male screw portion screwed into the screw hole is formed on the outer peripheral surface, and a head portion provided at an end portion on the tip end side of the cylindrical portion. A first stem in which a continuous insertion space extending in the opening / closing direction is formed inside the cylindrical portion and the head, and a rod-shaped portion movably inserted in the insertion space of the first stem in the opening / closing direction. A second stem capable of having an end portion of the rod-shaped portion protruding inward of the pedestal portion from the cylindrical portion and pressing the valve body in a closing direction, and a head portion of the first stem. In the opening / closing direction between the rotation operation member arranged so as to cover the outer periphery of the pedestal and having a shape capable of rotation operation, the portion of the rotation operation member on the side close to the pedestal portion, and the head of the first stem. A compression spring sandwiched in a compressed state and a connecting pin arranged so as to extend in a direction intersecting the opening / closing direction, the head of the first stem, and the rod-shaped portion of the second stem. The head of the first stem has an outer diameter larger than the inner diameter of the screw hole of the pedestal portion. An elongated hole extending in the opening / closing direction is formed in the head, and the connecting pin is inserted into the elongated hole so that the first stem can be attached to the rotation operating member and the second stem. It is characterized in that relative movement in the opening / closing direction is permitted.

In the configuration of the overtightening prevention device for the valve described above, there is only one set of threaded portions, and specifically, the male threaded portion formed on the outer peripheral surface of the cylindrical portion of the first stem and the male threaded portion are threaded. It is composed of screw holes in the matching pedestal. Therefore, the structure of the first stem becomes very simple, and the possibility of being caught in the threaded portion is reduced. Further, since the screw portion is exposed to the outside only by removing the first stem from the pedestal portion, the maintenance of the screw portion is very easy. Moreover, after the second stem that presses the valve body is stopped when the valve is closed, the first stem having a long hole advances in the closing direction while contracting the compression spring, and the head of the first stem hits the pedestal portion. Since the valve tightening is completed when it comes into contact, mechanically excessive tightening is prevented. This makes it possible to reliably tighten the valve with a predetermined tightening force even if the user applies an excessive rotational force to the rotation operating member.

Specifically, in the operation of closing the valve, if the user manually rotates the rotation operating member in the closing direction, the first stem and the second stem connected to the rotation operating member by the connecting pin also rotate. .. Since the threaded portion on the outer peripheral side of the cylindrical portion of the first stem is screwed into the screw hole of the pedestal portion, the rotation operating member, the first stem, and the second stem are integrally rotated and closed. Go in the direction. As the first stem and the second stem are inserted deeper into the pedestal portion, the end portion 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 operating member connected to the second stem via the connecting pin stop traveling in the closing direction.

On the other hand, in the first stem, a connecting pin is inserted into the elongated hole formed in the head of the elongated hole extending in the opening / closing direction, so that the first stem has a rotation control member and a second stem. The relative movement in the opening / closing direction is allowed. Therefore, if the rotation operating member is further rotated while the valve body is in contact with the valve seat, only the first stem advances in the direction of further closing while the screw portion of the cylindrical portion is screwed into the screw hole of the pedestal portion. ..

At this time, as the distance between the head of the first stem and the end portion of the rotation operating member on the side closer to the pedestal portion is shortened, the compression spring interposed between them is compressed and the rotation operating member is closed. The force to press against increases. The pressing force received by the rotation operating member 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 presses the valve body by receiving the pressing force of the compression spring without receiving the tightening force due to the screwing between the first stem and the pedestal portion, so that excessive tightening of the valve is prevented.

More specifically, when the first stem further advances 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 portion is the head of the screw hole at the tip portion of the pedestal portion. By abutting on the peripheral portion, the progress of the first stem in the closing direction is stopped. As a result, the compressive force of the compression spring interposed between the head of the first stem and the end of the rotation operating member on the side closer to the pedestal portion does not increase any more, so that the compression force is not increased any more. The pressing force received from the compression spring received by the second stem does not increase, and it becomes possible to prevent excessive tightening of the valve.

In this state, even if an attempt is made to further rotate and tighten the rotation operating member, the head of the first stem is already in contact with the tip of the pedestal portion inside the rotation operating member, and the first stem cannot advance. Therefore, even if a large rotation operation force is applied to the rotation operation member, the compression spring does not contract any more, so that it is possible to reliably prevent excessive tightening of the valve.

The rotation operation member is preferably configured so that the position of the head of the first stem can be visually recognized from the outside of the rotation operation member.

According to this configuration, the position of the head of the first stem can be visually recognized from the outside of the rotation operating member, so that when the rotation operating member is manually rotated to close the valve, the head of the first stem is moved. The user can easily and surely visually check that the valve has been tightened by contacting the pedestal portion and stopping.

The rotation operation member is formed with a through hole through which the head of the first stem can protrude to the outside of the rotation operation member, and the head can appear and disappear from the rotation operation member through the through hole. It is preferable that it is arranged in a suitable position.

According to such a configuration, the head of the first stem is arranged at a position where it can appear and disappear from the rotation operation member through the through hole of the rotation operation member. This makes it possible to visually recognize the position of the head of the first stem from the outside of the rotation operating member, and the user can easily and surely check visually that the valve tightening work has been completed. It is possible.

When the head of the first stem is in contact with the peripheral portion of the screw hole at the tip of the pedestal, the tip of the head is positioned at a position where the tip of the head coincides with the opening edge of the through hole of the rotation operating member. It is preferable that they are arranged so as to be.

According to this configuration, when the head of the first stem is in contact with the peripheral portion of the screw hole at the tip of the pedestal, the tip of the head coincides with the opening edge of the through hole of the rotation operating member. By simply checking whether the position of the tip of the head coincides with the opening edge of the through hole, the user can more easily and more reliably check that the valve tightening work has been completed. become.

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

According to such a configuration, three parts of the pedestal portion, the first stem, and the second stem inserted inside the first stem can be arranged inside the compression spring, and the overtightening prevention can be prevented. It becomes possible to achieve miniaturization of the device.

The valve of the present invention includes the overtightening prevention device according to any one of claims 1 to 5, a valve body pressed in a closing direction by the second stem, and the valve at a position where the valve body is closed. It is characterized by having a valve seat arranged at a position where it comes into contact with the body.

Since the valve configured as described above is provided with the above-mentioned overtightening prevention device, the structure of the threaded portion is simple, and the second stem that presses the valve body is stopped when the valve is closed. After that, the first stem having a long hole advances in the closing direction while contracting the compression spring, and the valve tightening is completed when the head of the first stem abuts on the pedestal portion, so that the valve is mechanically excessive. By preventing tightening, it is possible to reliably tighten the valve with a predetermined tightening force even if the user applies an excessive rotational force to the rotation operating member.

According to the valve over-tightening prevention device of the present invention and the valve provided with the device, the structure of the threaded portion is simple, and even if the user applies an excessive rotational force to the rotation operating member, the predetermined tightening is ensured. The valve can be tightened by force.

It is sectional drawing which shows the whole structure of the valve provided with the over-tightening prevention device which concerns on embodiment of this invention. It is sectional drawing explaining that the lower part of a handle, the 1st stem, and the 2nd stem are connected by the connecting pin of FIG. 1 so that they cannot rotate relative to each other. It is sectional drawing which shows the state which the lower part of a handle, the 1st stem, and the 2nd stem are separated. It is a figure which shows the procedure of how to use the over-tightening prevention device of FIG. 1, and is the sectional explanatory view which shows the fully open state of a valve. It is a figure which shows the procedure of the usage of the over-tightening prevention device of FIG. 1, and is the sectional explanatory view which shows the state which the valve starts to fully close. It is a figure which shows the procedure of how to use the over-tightening prevention device of FIG. 1, and is the sectional explanatory view which shows the fully closed state of a valve.

Next, the valve overtightening prevention device of the present invention and the embodiment of the valve provided with the device will be described in more detail with reference to the drawings.
As a valve provided with a valve overtightening prevention device according to an embodiment of the present invention, the valve (1) shown in FIG. 1 is a manual valve that is manually opened and closed, and as an example, a diaphragm as a valve body (4). A diaphragm valve with a valve is shown.

The valve (1) includes an overtightening prevention device (2) for preventing overtightening 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 blocks a part of the flow path (3a).

The valve body (4) is composed of, for example, a diaphragm valve, is arranged above the valve seat (5) of the valve box (3), reciprocates in the opening / closing direction (A), and abuts on the valve seat (5). It is possible to move between the closed position where the flow path (3a) is closed and the open position where the flow path (3a) is opened apart from the valve seat (5). The valve body (4) may have a configuration other than the diaphragm valve that can be opened and closed when a force is applied.

The valve (1) of the present embodiment is configured so that the opening / closing direction (A) of the valve body (4) is in the vertical direction of FIG. 1, but this positional relationship is relative and the present invention. Is not limited to this, and may be configured so that the opening / closing direction (A) faces a direction other than the vertical direction, for example, the horizontal direction.
The valve seat (5) is arranged at a position where the valve body (4) is in contact with the valve body (4) at a closed position.

The overtightening prevention device (2) has a configuration for preventing the valve body (4) of the valve (1) from being overtightened in a state of being in contact with the valve seat (5).
Specifically, the overtightening prevention device (2) includes a pedestal portion (6), a first stem (7), a second stem (8), a handle (9) which is a rotation operation member, and a compression coil. It includes a spring (10) and a connecting pin (11).

A threaded hole (6a) is formed in the upper portion of the pedestal portion (6) along the opening / closing direction (A) in which the valve body (4) opens and closes. The lower end portion (8b) of the second stem (8) and a part of the valve body (4) are housed inside the pedestal portion (6).

As shown in FIGS. 1 to 3, the first stem (7) has a cylindrical portion (7a) having a male screw portion (7c) screwed into the screw hole (6a) formed on the outer peripheral surface thereof, and the cylindrical portion. It has a head (7b) provided at the end on the distal end side of (7a). Inside 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) movably inserted in the opening / closing direction (A) inside the insertion space (7d) of the first stem (7), and the rod-shaped portion (8a). The lower end portion (8b) of the pedestal portion (8b) protrudes inward of the pedestal portion (6) from the cylindrical portion (7a) and can be pressed in the closing direction (A1) of the valve body (4). In the present embodiment, the configuration in which the diaphragm retainer (14) is arranged between the lower end portion (8b) and the valve body (4) composed of the diaphragm valve is shown, but the configuration inside the pedestal portion (6) is shown. It may be changed as appropriate.

The handle (9) is arranged so as to cover the outer periphery of the head portion (7b) of the first stem (7), and has a shape that can be manually rotated by the user. The handle (9) is a substantially cylindrical member having a lower part of the handle (9a) and an upper part of the handle (9b). The lower part of the handle (9a) and the upper part of the handle (9b) are screwed by the male screw portion formed on the outer peripheral surface of the lower part of the handle (9a) and the screw hole formed on the inner peripheral surface of the upper part of the handle (9b). And are concatenated.

An upper through hole (9c) is formed in the upper part of the handle (9) so that the head portion (7b) of the first stem (7) can protrude to the outside of the handle (9). The head portion (7b) of the first stem (7) is arranged at a position where it can appear and disappear from the handle (9) through the upper through hole (9c). As a result, the handle (9) is configured so that the position of the head portion (7b) of the first stem (7) can be visually recognized from the outside of the handle (9).

The compression coil spring (10) has an opening / closing direction (7b) between the lower part of the handle (9a), which is a portion of the handle (9) near the pedestal portion (6), and the head portion (7b) of the first stem (7). It is sandwiched in a compressed state in A). The compression coil spring (10) is a kind of compression spring that generates an elastic force by being compressed, and has a coil shape. In the present embodiment, the compression coil spring (10) is pressed from above by a spring retainer (13) attached to the head (7b), but the present invention is not limited thereto. A part of the head portion (7b) may be projected in the horizontal direction, and the compression coil spring (10) may be pressed from above by the protruding portion.

The connecting pin (11) is arranged so as to extend in a direction intersecting the opening / closing direction (A), specifically, in the present embodiment, in a horizontal direction orthogonal to the opening / closing direction (A). The head portion (7b) of the first stem (7), the rod-shaped portion (8a) of the second stem (8), and the handle (9) are connected so as not to 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 the first stem (7) is inserted. The lower part of the handle (9a) of the handle (9) is arranged on the outer peripheral side of the stem (7). In this state, the elongated 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. Through holes (9d) formed in the lower part (9a) of the handle of (9) are arranged so as to communicate with each other in the horizontal direction. By inserting the connecting pin (11) into these elongated holes (12), through holes (8c), and through holes (9d), respectively, the head (7b) and the second stem of the first stem (7) are inserted. The rod-shaped portion (8a) and the handle (9) of (8) are connected so as not to rotate relative to each other.

In the present embodiment, the connecting pin (11) extends in a direction (horizontal direction) orthogonal to the opening / closing direction (A), but the present invention is not limited to this. The connecting pin (11) extends in a direction intersecting the opening / closing direction (A) in order to connect the first stem (7), the second stem (8), and the handle (9) so as not to rotate relative to each other. Just do it. For example, as long as it intersects with the opening / closing direction (A), it may extend in a direction slightly inclined from the horizontal direction.

As shown in FIG. 1, the head portion (7b) of the first stem (7) has an outer diameter D2 larger than the inner diameter D1 of the screw hole (6a) of the pedestal portion (6). Therefore, the tip end portion (upper end portion) of the pedestal portion (6) moves (descends) in the closing direction (A1) of the first stem (7) by abutting on the head portion (7b) of the first stem (7). ) Functions as a stopper.

The head (7b) of the first stem (7) is formed with the elongated hole (12) extending in the opening / closing direction (A). The connecting pin (11) is inserted into the elongated hole (12). As a result, the first stem (7) is allowed to move relative to the handle (9) and the second stem (8) in the opening / closing direction (A).

In the overtightening prevention device (2) configured as described above, there is only one set of screw portions, and specifically, it is formed on the outer peripheral surface of the cylindrical portion (7a) of the first stem (7). It is composed of a male threaded portion (7c) and a screw hole (6a) of a pedestal portion (6) screwed into the male threaded portion (7c). Therefore, the structure of the first stem (7) becomes very simple, and the possibility of being caught in the threaded portion is reduced. Further, since the screw portion is exposed to the outside only by removing the first stem (7) from the pedestal portion (6), the maintenance of the screw portion is very easy.
Moreover, after the second stem (8) that presses the valve body (4) is stopped when the valve (1) is closed, the first stem (7) having the elongated hole (12) presses the compression coil spring (10). The valve (1) is tightened mechanically when the head (7b) of the first stem (7) comes into contact with the pedestal portion (6) while contracting and proceeding in the closing direction. To prevent. This makes it possible to reliably tighten the valve (1) with a predetermined tightening force even if the user applies an excessive rotational force to the handle (9).

Specifically, in the valve (1) provided with the overtightening prevention device (2) configured as described above, the valve (1) is closed as follows.
First, in the fully opened valve (1) of FIG. 4, the head portion (7b) of the first stem (7) protrudes above the handle (9) through the upper through hole (9c) of the handle (9). .. In this state, if the user manually rotates the handle (9) in the closing direction (A1), the first stem (7) and the second stem (7) connected to the handle (9) by the connecting pin (11). The stem (8) also rotates. Since the threaded portion (7c) on the outer peripheral 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 The stem (7) and the second stem (8) proceed in the closing direction (A1) while rotating together. As the first stem (7) and the second stem (8) are inserted deeper into the pedestal portion (6), the lower end portion (8b) of the second stem (8) becomes the valve body (4) ( (See FIG. 1) is pressed 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), they are close to the pedestal portion (6) in the handle (9). The amount of deflection of the compression coil spring (10) sandwiched between the lower part of the handle (9a), which is a side portion, and the head (7b) of the first stem (7) in a compressed state is maintained in the initial state. Has been done.

In this state, a downward force is applied to the lower part (9a) of the handle by the compression coil spring (10), so that the second stem (8) is also pressed downward. This downward force is received by the first stem (7) as the connecting pin (11) abuts on 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 integrally advanced in the closing direction (A1), and the valve body (4) shown in FIG. 1 is the valve seat (5). When in contact with, as shown in FIG. 5, the second stem (8) and the handle (9) connected to the second stem (8) via the connecting pin (11) are in the closing direction (A1). ) Stop progressing.

On the other hand, as shown in FIGS. 5 to 6, the first stem (7) has a connecting pin (11) inside an elongated hole (12) formed in its head (7b) and extending in the opening / closing direction (A). Is inserted into the elongated hole (12) so that the first stem (7) is allowed to move relative to the handle (9) and the second stem (8) in the opening / closing direction (A). ing. Therefore, if 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 the threaded portion (7c) of the cylindrical portion (7a). ) Further advances in the closing direction (A1) while being screwed into the screw hole (6a) of the pedestal portion (6).

At this time, between the head portion (7b) of the first stem (7) (specifically, the spring retainer (13) attached to the head portion (7b)) and the lower part of the handle (9a) near the pedestal portion (6). As the distance between the two is reduced, the compression coil spring (10) interposed between them is compressed, and the force for pressing the handle (9) in the closing direction (A1) is increased. The pressing force received by the handle (9) from the compression coil spring (10) is transmitted to the second stem (8) via the connecting pin (11), and the second stem (8) is the valve body (4) described above. Is further pressed. In this state, the second stem (8) receives the pressing force of the compression coil spring (10) without receiving the tightening force due to the screwing between the first stem (7) and the pedestal portion (6), and the valve body. Since (4) is pressed, excessive tightening of the valve (1) is prevented.

More specifically, when the first stem (7) further advances in the closing direction (A1), the first stem (7) has an outer diameter larger than the inner diameter of the screw hole (6a) of the pedestal portion (6). ) Head (7b) advances in the closing direction (A1) of the first stem (7) by abutting on the peripheral portion of the screw hole (6a) at the tip portion (6b) of the pedestal portion (6). Stops. As a result, the compressive force of the compression coil spring (10) interposed between the head portion (7b) of the first stem (7) and the lower portion (9a) of the handle does not increase any more, so that the handle (9) and the handle (9) are connected. The pressing force received from the compression coil spring (10) received by the second stem (8) via the pin (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, the head portion (7b) of the first stem (7) is the tip portion (6b) of the pedestal portion (6) inside the handle (9). Since the first stem (7) cannot advance due to contact with the valve (7), the compression coil spring (10) does not contract any more even if a large rotational operation force is applied to the handle (9). It is possible to reliably prevent excessive tightening in 1).

In the overtightening prevention device (2) of the present embodiment, the handle (9) is configured so that the position of the head portion (7b) of the first stem (7) can be visually recognized from the outside of the handle (9). ..
Specifically, in the overtightening prevention device (2) of the present embodiment, the handle (9) has an upper portion on which the head portion (7b) of the first stem (7) can protrude to the outside of the handle (9). A through hole (9c) is formed. The head (7b) is arranged at a position where it can appear and disappear from the handle (9) through the upper through hole (9c).

According to this configuration, the head portion (7b) of the first stem (7) is arranged at a position where it can appear and disappear from the handle (9) through the upper through hole (9c) of the handle (9). As a result, the position of the head portion (7b) of the first stem (7) can be visually recognized from the outside of the handle (9), and the user can visually recognize that the tightening work of the valve (1) has been completed. It is possible to check easily and surely by using it. In other words, the head portion (7b) of the first stem (7) can function as an indicator indicating that the valve has been tightened depending on its position.

In particular, as shown in FIG. 6, the head portion (7b) of the first stem (7) is in contact with the peripheral portion of the screw hole (6a) at the tip portion (6b) of the pedestal portion (6). It is preferable that the tip (7e) of the head (7b) is arranged so as to coincide with the opening edge of the upper through hole (9c) of the handle (9). In this configuration, when the head portion (7b) of the first stem (7) is in contact with the peripheral portion of the screw hole (6a) at the tip portion (6b) of the pedestal portion (6), the head portion (7b) Since the tip (7e) coincides with the opening edge of the upper through hole (9c) of the handle (9), whether or not the position of the tip of the head (7b) coincides with the opening edge of the upper through hole (9c). The user can more easily and more reliably check that the tightening work of the valve (1) has been completed just by looking at the valve (1).

In the above configuration, since the position of the head portion (7b) of the first stem (7) can be visually recognized from the outside of the handle (9), the handle (9) is manually rotated to close the valve (1). Occasionally, the user can easily and surely visually confirm that the head portion (7b) of the first stem (7) abuts on the pedestal portion (6) and stops, and the tightening work of the valve (1) is completed. It is possible to check. In addition to the example in which the head portion (7b) of the first stem (7) protruding to the outside of the handle is used as an indicator as described above, the position of the head portion (7b) of the first stem (7) is set to the handle (9). Any other configuration may be used as long as it can be visually recognized from the outside. For example, as another configuration, the handle (9) may be made of a transparent or translucent material, or the handle (9) may have a slit or peephole, but the head of the first stem (7) (7). 7b) can be seen from the outside of the handle (9).

Further, in the overtightening prevention device (2) of the present embodiment, the 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). Is located in. In this configuration, inside the compression coil spring (10), there are three stems (6), a first stem (7), and a second stem (8) inserted inside the first stem (7). It becomes possible to arrange the parts, and it becomes possible to achieve the miniaturization of the overtightening prevention device (2).

The valve (1) of the present embodiment includes the above-mentioned overtightening prevention device (2), a valve body (4), and a valve seat (5). Since the valve (1) configured in this way is provided with the overtightening prevention device (2), the structure of the threaded portion is simple, and the valve body (4) is in the closed operation of the valve (1). ) Is stopped, and then the first stem (7) having the elongated hole (12) advances in the closing direction (A1) while contracting the compression coil spring (10), and the first stem (A1) is pressed. Since the tightening of the valve (1) is completed when the head portion (7b) of the 7) comes into contact with the pedestal portion (6), the user can handle the handle (9) by mechanically preventing excessive tightening. ) Can be reliably tightened with a predetermined tightening force even if an excessive rotational force is applied to the valve (1).

The present invention can be used for valve overtightening prevention devices and valves equipped thereof. More specifically, the present invention relates to a valve having a simple structure of a threaded portion and capable of reliably tightening a valve with a predetermined tightening force even if a user applies an excessive rotational force to the rotation operating member. It can be used as an overtightening prevention device, and even a manual valve that is manually rotated can be widely used. Therefore, in addition to the diaphragm valve as shown in the above embodiment, any manual valve that can adjust the flow rate and 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 part 7 1st stem 7a Cylindrical part 7b Head 7c Male thread part 7d Insertion space 8 2nd stem 8a Rod-shaped part 8b Lower end 9 Handle (rotation) Operating member)
9a Lower part of handle 9b Upper part of handle 9c Upper through hole 10 Compression coil spring (compression spring)
11 Connecting pin 12 Long hole 13 Spring retainer 14 Diaphragm retainer A Opening / closing direction A1 Closing direction

Claims (6)

An overtightening prevention device that prevents the valve body of the valve from being overtightened while in contact with the valve seat.
A pedestal portion having a screw hole formed along the opening / closing direction in which the valve body opens / closes, and a pedestal portion.
The male screw portion screwed into the screw hole has a cylindrical portion formed on the outer peripheral surface and a head provided at the end portion on the tip end side of the cylindrical portion, and inside the cylindrical portion and the head portion. The first stem in which a continuous insertion space extending in the opening / closing direction is formed, and
The valve body has a rod-shaped portion that is movably inserted in the opening / closing direction inside the insertion space of the first stem, and the end portion of the rod-shaped portion protrudes inward of the pedestal portion from the cylindrical portion. With a second stem that can be pressed in the closing direction,
A rotation operation member arranged so as to cover the outer periphery of the head of the first stem and having a shape capable of rotation operation, and a rotation operation member.
A compression spring sandwiched between a portion of the rotation operation member close to the pedestal portion and the head of the first stem in a compressed state in the opening / closing direction.
A connecting pin arranged so as to extend in a direction intersecting the opening / closing direction so that the head of the first stem, the rod-shaped portion of the second stem, and the rotation operating member cannot rotate relative to each other. The connecting pin to connect and
Equipped with
The head 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 / closing direction is formed in the head.
The connecting pin is inserted into the elongated hole, whereby the first stem is allowed to move relative to the rotation operating member and the second stem in the opening / closing direction.
A valve overtightening prevention device characterized by this. The rotation operating member is configured so that the position of the head of the first stem can be visually recognized from the outside of the rotation operating member.
The valve overtightening prevention device according to claim 1. The rotation operating member is formed with a through hole through which the head of the first stem can protrude to the outside of the rotation operating member.
The head is arranged at a position where it can appear and disappear from the rotation operating member through the through hole.
The valve overtightening prevention device according to claim 2. When the head of the first stem is in contact with the peripheral portion of the screw hole at the tip of the pedestal, the tip of the head is positioned at a position where the tip of the head coincides with the opening edge of the through hole of the rotation operating member. The valve overtightening prevention device according to claim 3, which is arranged so as to be. The screw holes of the male thread portion and the pedestal portion of the first stem are arranged inside the compression spring.
The valve overtightening prevention device according to any one of claims 1 to 4. The overtightening prevention device according to any one of claims 1 to 5.
A valve body pressed in the closing direction by the second stem,
A valve comprising a valve seat arranged at a position where the valve body abuts on the valve body at a closed position.

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