JP5688705B2 - Fluid controller - Google Patents

Description

  The present invention relates to a fluid controller including a diaphragm, and more particularly to a fluid controller that can prevent excessive tightening of the diaphragm.

As an example of a conventional fluid controller, a fluid controller disclosed in Patent Document 1 below is known.
The fluid controller disclosed in Patent Document 1 includes a valve body (valve box) having an inlet channel and an outlet channel, a valve body that allows or blocks the flow of fluid from the inlet channel to the outlet channel, An operating mechanism that moves the valve body up and down, and a stem (valve rod) that connects the operating mechanism and the valve body, and a valve rod (metal valve body) that is connected to the lower end of the stem ) And a diaphragm sandwiched between the valve rod and the stem.

In the fluid controller having such a structure, the external thread formed on the upper portion of the valve rod (metal valve body) is screwed into the internal thread formed on the lower end of the stem (valve rod). The diaphragm is fixed between the stem and the valve rod.
For this reason, when the male screw portion of the valve rod is screwed to the female screw portion of the stem, the diaphragm may be damaged due to excessive tightening by screwing. On the other hand, if the tightening is loosened to avoid excessive tightening, the valve rod may fall off the stem, which is not preferable.

The fluid controller disclosed in the following Patent Document 2 is also formed at the upper part of the valve rod with respect to the female thread formed at the lower end of the stem (sliding bar), similarly to the fluid controller of Patent Document 1. By engaging the male thread portion, the diaphragm is sandwiched and fixed between the stem and the valve rod.
The fluid controller disclosed in Patent Document 2 has a stepped attachment portion for attaching a diaphragm to the upper portion of the valve rod, and this stepped attachment portion prevents excessive tightening of the diaphragm described above. It is not something that can be done. That is, the fluid controller disclosed in Patent Document 2 also has the same problem as the fluid controller disclosed in Patent Document 1 described above.

JP-A-6-272770 Japanese Patent No. 3408722

  The present invention has been made to solve the above-described problems of the prior art, and in a fluid controller having a structure in which a diaphragm is fixed by being sandwiched between a stem and a valve rod, the diaphragm is excessively tightened. It is possible to provide a fluid controller that can reliably prevent breakage due to spillage and prevent the valve rod from falling off due to insufficient tightening.

The invention according to claim 1 is a valve body having an inlet channel and an outlet channel, a valve body that allows or blocks the flow of fluid from the inlet channel to the outlet channel, and moves the valve body up and down. And a valve rod connected to a lower end portion of the stem. The valve rod is connected to a lower end portion of the stem. And a diaphragm in which an inner edge portion formed with an annular rib protruding in the vertical direction is sandwiched between the valve rod and the stem, and an outer edge portion is sandwiched between the valve body and the bonnet. The upper surface of the valve rod and the lower surface of the stem sandwiching the inner edge of the diaphragm are formed with recesses into which the ribs are fitted, and both outer ends are rounded, Diaf The upper surface of the valve body and the lower surface of the bonnet sandwiching the outer edge of the valve are rounded at both inner ends, and the upper portion of the valve rod is inserted into the lower end of the stem. The mounting hole has a female screw part on the upper side, a non-female screw part on the lower side, and the non-female screw part has a small diameter part on the upper side and a large diameter part on the lower side. The upper part of the valve rod has a male screw part on the upper side and a non-male screw part on the lower side, and the non-male screw part has a small diameter part on the upper side and a large diameter part on the lower side. When the male threaded portion is screwed into the female threaded portion, the stepped portion of the stepped rod comes into contact with the stepped portion of the stepped hole so that the stepped rod moves upward. The progress of the step is stopped by the step of the stepped hole. A fluid controller according to.

  In the invention according to claim 2, the bonnet is formed of a main body and an adapter disposed below the main body, and an outer edge portion of the diaphragm is sandwiched between the valve body and the adapter, 2. The fluid controller according to claim 1, wherein a disc spring is interposed between the main body and the adapter.

According to the first aspect of the present invention, when the male thread portion provided in the upper portion of the valve rod is screwed into the female thread portion of the mounting hole provided in the lower end portion of the stem, the non-female thread portion of the mounting hole is formed. Since the stepped part of the stepped rod that forms the non-threaded part of the valve rod contacts the stepped part of the stepped hole, the valve rod is prevented from moving above the contacted position, and the diaphragm is overtightened. Can be reliably prevented.
Further, when the valve rod reaches the contact position, the tightening can no longer be performed, so that the tightening force can always be kept constant, and the valve rod can be prevented from falling off due to insufficient tightening.
Furthermore, the diaphragm is prevented from being scratched by forming all end portions of the member sandwiching the diaphragm from above and below in a rounded shape.

According to the invention which concerns on Claim 2, generation | occurrence | production of the stress relaxation by the cold flow of a diaphragm can be prevented with a disc spring.
In addition, the outer edge of the diaphragm is not directly pressed by the body of the bonnet, but is clamped between the valve body by being pressed through the disc spring and the adapter, so that the outer edge of the diaphragm is held at an appropriate pressure. And damage due to excessive tightening of the diaphragm is prevented.

It is front sectional drawing of the principal part of the fluid controller which concerns on this invention. It is a side view of the principal part of the fluid controller which concerns on this invention. It is a disassembled perspective view of the principal part of the fluid controller which concerns on this invention. It is a principal part enlarged view of FIG. It is an enlarged view of the connection part of the stem and valve rod of the fluid controller which concerns on this invention.

Hereinafter, preferred embodiments of a fluid controller according to the present invention will be described with reference to the drawings.
1 is a front sectional view of a main part of a fluid controller according to the present invention, FIG. 2 is a side view of the main part of the fluid controller according to the present invention, and FIG. 3 is an exploded view of the main part of the fluid controller according to the present invention. 4 is an enlarged view of a main part of FIG. 1, and FIG. 5 is an enlarged view of a connecting portion between a stem and a valve rod of the fluid controller according to the present invention.

  The fluid controller according to the present invention includes a valve body (1) having an inlet channel (5) and an outlet channel (6), and fluid flow from the inlet channel (5) to the outlet channel (6). Allowed or blocked valve body (2), operation mechanism (not shown) for moving the valve body (2) up and down, bonnet (3) provided above the valve body (1), operation mechanism and valve body A stem (4) for connecting (2) and (2) is provided.

The inlet channel (5) and the outlet channel (6) extend in a direction perpendicular to each other.
In the illustrated example, the inlet channel (5) extends in the horizontal direction (right direction), and the outlet channel (6) extends in the vertical direction (downward direction).
In addition, the vertical and horizontal directions in this specification refer to directions when the fluid controller is arranged in the direction shown in FIG.

The valve body (2) is composed of a valve rod (7) and a diaphragm (8).
The valve rod (7) is made of a metal material.
The type of metal material can be selected according to the physical properties, temperature, pressure, etc. of the fluid used, but it is preferable to use stainless steel having excellent mechanical strength, heat resistance, corrosion resistance, etc. SUS630 is preferably used.

The valve rod (7) has an upper part (71) connected to the lower end part of the stem (4), a lower part (73) inserted into and removed from the upper end part of the outlet channel (6), It has an intermediate part (72) formed between the upper part (71) and the lower part (73).
The upper part (71) has a male screw part (711) on the upper side and a non-male screw part (712) on the lower side. The non-male screw part (712) is formed in a stepped rod having a small diameter part (712a) on the upper side and a large diameter part (712b) on the lower side (see FIG. 5).
The outer diameter of the male screw portion (711) is equal to the outer diameter of the small diameter portion (712a).

The lower part (73) gradually becomes smaller in diameter toward the lower side, and by changing the insertion depth with respect to the upper end part of the outlet channel (6), the inlet channel (5) to the outlet channel (6). The flow rate of the fluid flowing into the can be adjusted.
The intermediate part (72) is formed with a larger diameter than the upper part (71) and the lower part (73).

The diaphragm (8) is made of a material excellent in heat resistance, flexibility, corrosion resistance, and the like, and is made of, for example, a synthetic resin such as polytetrafluoroethylene (PTFE), natural rubber, synthetic rubber, or the like.
The diaphragm (8) has an inner edge sandwiched between the intermediate portion (72) of the valve rod (7) and the stem (4), and an outer edge sandwiched between the valve body (1) and the bonnet (3). Has been.
The inner edge of the diaphragm (8) moves up and down as the stem (4) moves up and down, but the outer edge does not move. Therefore, as the stem (4) moves up and down, the non-clamped portion between the inner edge portion and the outer edge portion of the diaphragm (8) is elastically deformed.

The outer end of the upper surface of the intermediate portion (72) of the valve rod (7) and the lower surface of the stem (4) sandwiching the inner edge portion of the diaphragm (8) is formed in a round shape. In addition, the upper surface of the valve body (1) and the lower surface of the bonnet (3) (the lower surface of the adapter (32) to be described later) sandwiching the outer edge of the diaphragm (8) have inner ends formed in a round shape. Yes.
Thus, the diaphragm (8) can be prevented from being scratched by forming the end portions of the members that sandwich the diaphragm (8) from above and below in a rounded shape.

On the inner edge and outer edge of the diaphragm (8), annular ribs (81) and (82) in a plan view projecting in the vertical direction are formed (see FIG. 4).
A concave portion into which the ribs (81) and (82) are fitted is formed in the portion sandwiching the diaphragm (8) from above and below.
Specifically, a concave portion into which the inner rib (81) is fitted is formed on the upper surface of the intermediate portion (72) of the valve rod (7) and the lower surface of the stem (4). In addition, a recess for fitting an outer rib (82) is formed on the lower surface of the bonnet (3) (the lower surface of the adapter (32) described later) and the upper surface of the valve body (1) facing the lower surface. Yes.
Thereby, the diaphragm (8) is held at both the inner edge portion and the outer edge portion, and is positioned reliably.

The outer end of the outer rib (82) of the diaphragm (8) is in contact with the inner surface of the valve body (1).
This reliably prevents the diaphragm (8) from spreading outward.

The bonnet (3) is formed of a main body (31) and an adapter (32) disposed below the main body (31). A disc spring (9) is interposed between the main body (31) and the adapter (32).
The main body (31) has a flange portion. The flange portion formed on the upper end of the flange portion of the main body (31) and the valve body (1) is clamped by the clamp band (10). (1) and the bonnet (3) are integrated.
The lower surface of the adapter (32) sandwiches the outer edge portion of the diaphragm (8) with the valve body (1).
The disc spring (9) has the role of preventing the stress relaxation due to the cold flow of the diaphragm (8) and appropriately adjusting the clamping pressure of the diaphragm (8) by the adapter (32) and the valve body (1). ing.

The stem (4) penetrates the bonnet (3) in the vertical direction.
An operating mechanism (not shown) is connected to the upper end of the stem (4). As the operation mechanism, a known operation mechanism such as a handle or a pneumatically operated actuator can be used.
A guide tube (11) is fitted on the intermediate portion of the stem (4).
A mounting hole (41) into which the upper part (71) of the valve rod (2) is inserted is formed at the lower end of the stem (4).

The mounting hole (41) has a female thread portion (411) on the upper side and a non-female thread portion (412) on the lower side. The non-internal thread portion (412) is formed in a stepped hole having a small diameter portion (412a) on the upper side and a large diameter portion (412b) on the lower side (see FIG. 5).
The inner diameter of the female thread portion (411) is equal to the inner diameter of the small diameter portion (412a).

The male screw portion (711) formed above the upper portion (71) of the valve rod (7) is screwed with the female screw portion (411) formed above the mounting hole (41) of the stem (4). Yes.
In a state where the male threaded portion (711) of the valve rod (7) and the female threaded portion (411) of the mounting hole (41) are screwed together, the stepped hole (non-female threaded portion (412)) of the mounting hole (41) The stepped portion of the stepped rod (non-male threaded portion (712)) of the valve rod (7) contacts the portion (see FIGS. 4 and 5).
Thereby, the valve rod (7) cannot be screwed any further. That is, the upward movement of the valve rod (7) is stopped by the stepped portion.
In this contact state, the upper end of the valve rod (7) does not reach the upper end (the deepest part) of the mounting hole (41) (see FIG. 4).

In this way, the male screw portion (711) provided in the upper portion (71) of the valve rod (7) is replaced with the female screw portion (411) of the mounting hole (41) provided in the lower end portion (41) of the stem (4). The stepped portion of the stepped rod that forms the non-male threaded portion (712) of the valve rod (7) is brought into contact with the stepped portion of the stepped hole that forms the non-female threaded portion (412) of the mounting hole. As a result, the valve rod (7) does not move upward from the contact position, and the diaphragm (8) can be reliably prevented from being damaged due to excessive tightening.
Further, when the valve rod (7) reaches the contact position, the tightening can no longer be performed, so that the tightening force can be kept constant, and the valve rod (7) can be prevented from falling off due to insufficient tightening. .

The step formed in the stepped hole and the stepped rod (the difference in the outer diameter between the small diameter portion (412a) and the large diameter portion (412b), the difference in the outer diameter between the small diameter portion (712a) and the large diameter portion (712b)) 0.5 to 1.5 mm is preferable.
This is because if the step is less than 0.5 mm, the upward movement due to screwing of the valve rod (7) may not be reliably stopped at the step, and the product size increases even if it exceeds 1.5 mm. This is because the effect of stopping the upward movement of the valve rod (7) at the stepped portion does not increase only by demerits, which is not preferable in any case.

  The large diameter part (412b) of the stepped hole and the large diameter part (712b) of the stepped bar are provided for the purpose of centering by fitting.

The fluid controller according to the present invention includes a stepped rod for forming the non-male threaded portion (712) of the valve rod (7) at the stepped hole of the stepped hole that forms the non-female threaded portion (412) of the mounting hole (41). When the stepped portion comes into contact, the tightening torque of the rib (81) of the diaphragm (8) is set to an appropriate value. An appropriate tightening torque is appropriately set according to the diameter of the male screw portion (711). For example, in the case of an M6 screw, it is set to 5 to 6 N · m.
Thereby, at the time of assembling the fluid controller, the inner edge portion (specifically, the rib (81)) of the diaphragm (8) can be securely fixed. Further, the movement of the diaphragm (8) is not hindered after assembly.

  The present invention is applicable to a fluid controller having a structure in which a diaphragm is fixed between a stem and a valve rod.

DESCRIPTION OF SYMBOLS 1 Valve body 2 Valve body 3 Bonnet 31 Main body 32 Adapter 4 Stem 41 Mounting hole 411 Female thread part 412 Non-female thread part 412a Small diameter part 412b Large diameter part 5 Inlet channel 6 Outlet channel 7 Valve rod 71 Upper part 711 Male thread part 712 Non Male thread portion 712a Small diameter portion 712b Large diameter portion 72 Intermediate portion 73 Lower portion 8 Diaphragm 9 Belleville spring

Claims (2)

A valve body having an inlet channel and an outlet channel;
A valve body that allows or blocks the flow of fluid from the inlet channel to the outlet channel;
An operating mechanism for moving the valve body up and down;
A bonnet provided above the valve body;
A stem for connecting the operating mechanism and the valve body;
The valve body includes a valve rod connected to the lower end portion of the stem, and an inner edge portion formed with an annular rib protruding in the vertical direction between the valve rod and the stem, and an outer edge. The part consists of a diaphragm sandwiched between the valve body and the bonnet,
The upper surface of the valve rod sandwiching the inner edge of the diaphragm and the lower surface of the stem are formed with a recess into which the rib fits, and both outer ends are rounded, and the outer edge of the diaphragm The inner surface of the upper surface of the valve body and the lower surface of the bonnet sandwiching the portion are formed in a round shape,
A mounting hole into which the upper part of the valve rod is inserted is formed at the lower end of the stem,
The mounting hole has a female screw part on the upper side and a non-female screw part on the lower side, and the non-female screw part is formed in a stepped hole having a small diameter part on the upper side and a large diameter part on the lower side,
The upper part of the valve rod has a male threaded part on the upper side, a non-male threaded part on the lower side, and the non-male threaded part is formed as a stepped rod having a small diameter part on the upper side and a large diameter part on the lower side. And
When the male threaded portion is screwed into the female threaded portion, the stepped portion of the stepped rod comes into contact with the stepped portion of the stepped hole so that the upward movement of the valve rod is stepped on the stepped hole. A fluid controller characterized in that it is stopped by The bonnet is formed of a main body and an adapter disposed below the main body,
The outer edge of the diaphragm is sandwiched between the valve body and the adapter,
2. The fluid controller according to claim 1, wherein a disc spring is interposed between the main body and the adapter.

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