JPH09269081A - Self-retaining type cut-off valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent fluid from being penetrated into a part beyond the bottom of a cylindrical guide body, by forming the cylindrical guide body having an electromagnet to have a bottom, and arranging the bottom of the cylindrical guide body at near the other end of a plunger. SOLUTION: A guide body 21 is formed into a bottomed cylindrical shape by using a non-magnetic material such as brass, the opening side one end of the guide body 21 is retained to a frame body 64, the other end thereof is closed by a bottom 211, and a magnetic pole 62 is oppose to a permanent magnet 22 sandwiching the bottom 211 of the guide body 21, and fixed on the inner surface side of the bottom 211. A minor protective film in such an extent that prevents weak oxidation by atmosphere, is used for a protective film applied to the permanent magnet 22. Fluid 9a is prevented from being penetrated into a part beyond the bottom 211 of the guide body 21 by the bottom 211 of the guide body 21, a seal body mounted at near an end which becomes the opposite side of a valve element 71 in the conventional case is no more required, and metal whose material characteristics are stable for a long time is used for sealing the fluid 9a in the end instead of the conventional rubber seal and so on, thereby the long reliability of the performance of a seal can be remarkably improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas cutoff valve used for opening and closing a fuel gas supply passage in an automatic gas cutoff device used as a safety device for a fuel gas supply source in general households. The present invention relates to a self-holding type shutoff valve, etc., and its configuration improved so that power consumption, manufacturing cost, etc. are reduced and reliability is improved.

[0002]

2. Description of the Related Art It is well known that self-holding shutoff valves used for opening and closing fluid passages are widely used for various fluids in various industrial fields or general households. It is known. here,
As a representative of the self-holding type gas shut-off valve used in automatic gas shut-off devices, which is installed as a safety device in the supply source of city gas, which is fuel gas, in households, etc. The valve will be described with reference to FIG.
Here, FIG. 7 is a longitudinal sectional view showing a conventional self-holding shutoff valve in an open state.

In FIG. 7, 9 is a valve body 8 and a valve body 7.
1, a plunger 72, a spring 73 as a pressurizing body, a seal body 74 using a flat seal material, and an electromagnet 6
It is a self-holding shutoff valve having and. The valve body 8 is a structure that forms a passage for a fluid 9a, which is a fuel gas such as city gas, and in this case, a cylindrical casing portion 83 and a casing portion 83. An inflow part 81 formed in the side wall part and into which the fluid 9a flows in, an outflow part 82 formed in one end part of the casing part 83 for flowing out the fluid 9a toward its intended use, and an outflow part 82.
Valve seat 84 integrally formed to face the casing and the casing portion 8
3 has a mounting portion 85 for mounting the electromagnet 6 formed at a portion facing the valve seat 84, which is the other end portion of 3. That is, the shutoff valve 9 in this case is a two-way valve. Then, the mounting portion 85 is formed with a through hole 851 through which the valve body 8 can pass.

The valve body 71 is disposed so as to face the valve seat 84, and is held by the plunger 72 at one end 72b of the columnar plunger 72. The spring 73 is a known compression coil spring in this case, and generates a spring force F _{S in the} direction of pressing the valve body 71 against the valve seat 84. The electromagnet 6 includes a permanent magnet 61, a magnetic pole 62, a guide body 63, a frame body 64 for fixing the electromagnet 6 to the mounting portion 85 of the valve body 8, an exciting coil 65 wound around a winding frame 66, and a yoke 6.
7, an auxiliary yoke 68, and seal bodies 691 and 692. A ferromagnetic material is used for at least the portion of the plunger 72 that is inserted into the electromagnet 6, and the magnetic pole 6 of the electromagnet 6 is used.
2. The yoke 67 and the auxiliary yoke 68 are also made of ferromagnetic material. The magnetic pole 62 is installed as needed, and in this case, the magnetic flux 6a generated from the permanent magnet 61 having a cross-sectional area larger than that of the plunger 72 is efficiently supplied to the plunger 72. It is installed to let the air flow well. The magnetic pole 62 has one end face fixed to the permanent magnet 61 and the other end face at the end face 72 at the end opposite to the valve body 71 side of the plunger 72.
It is arranged so as to face a. The yoke 67 also serves as a protective container for the permanent magnet 61, the exciting coil 65, and the like.

The guide body 63 is formed in a cylindrical shape by using a non-magnetic material such as brass, and one end thereof is held by the frame body 64, and a seal body 692 is attached to the other end portion, A wide-diameter portion 631 having a wide diameter is formed so as to surround the peripheral portion of the plate-shaped permanent magnet 61. One of the roles of the guide body 63 is to support the movement of the plunger 72 in the axial direction by the inner peripheral surface of its tubular portion. The seal bodies 691 and 692 have, for example, O
A ring is used, and the seal body 691 is the frame body 64.
The seal body 692 is fitted in the groove 641 formed in the mounting portion of the guide body 63, and the seal body 692 is mounted in the gap portion formed between the wide diameter portion 631 and the permanent magnet 61. In addition, in order to avoid the interference with the outer shape portion of the wide diameter portion 631, the cut portion formed on the winding frame 66 at the portion facing the wide diameter portion 631 secures a large area for the exciting coil 65. It was installed in.

The magnetic pole 62, the plunger 72, the yoke 67, and the auxiliary yoke 68 are the magnetic flux 6a obtained by the permanent magnet 61.
Form a magnetic circuit through which Then, in this case, the magnetic flux 6a flows through this magnetic circuit in the permanent magnet 61 → the magnetic pole 62 → the magnetic pole 62 and the end face 72 of the plunger 72.
It circulates in the route of a gap G between the a and the case (when the gap G exists) → plunger 72 → auxiliary yoke 68 → yoke 67 → permanent magnet 61. The exciting coil 65 is
A magnetomotive force is generated by being excited by a direct current (not shown), and the magnetomotive force increases the amount of the magnetic flux 6a when a positive direct current is applied, and increases the amount of the magnetic flux 6a when a negative direct current is applied. Acts to reduce the amount of.

In the electromagnet 6, the plunger 72 holding the valve body 71 at the end 72b is inserted into the cylindrical guide body 63, and the spring 73 is sandwiched between the valve body 71 and the frame body 64. And the mounting portion 8 of the valve body 8 by the frame 64.
5 is attached. Then, in this case, the valve body 71 and the like are inserted into the valve body 8 through the through hole 851. In addition, the seal body 7 is provided between the frame body 64 and the mounting portion 85.
The fluid 9a is prevented from leaking by inserting 4 and is fixed by using a known binding device such as a screw (not shown).

Since the conventional self-holding shutoff valve 9 is constructed as described above, when the fluid 9a is made to flow from the inflow portion 81 to the outflow portion 82, the end face 72a of the plunger 72 is caused to flow through the magnetic flux 6a. Magnetic pole 6 due to magnetic attraction force F _M
2 to the valve seat 84 of the valve body 8
A flow path through which the fluid 9a flows is formed between the valve body 71 and the valve body 71. In this state, when the supply of the fluid 9a from the outflow portion 82 is to be stopped, the exciting coil 65
A negative direct current is applied to the magnetic field to reduce the amount of the magnetic flux 6a. The value of the magnetic attraction force F _M is proportional to the square of the amount of known as flux 6a, the value of the magnetic attraction force F _M in the amount of magnetic flux 6a is reduced is reduced. The spring force F generated by the spring 73 due to the reduced value of the magnetic attraction force F _M
When the value of _S falls below the value of _S , the valve body 71, together with the plunger 72, is pressed against the valve seat 84 by the spring force F _S , and closes the flow passage toward the outflow portion 82 of the fluid 9a. As a result, the shutoff valve 9 is closed, and a large gap G (not shown) is provided between the magnetic pole 62 and the plunger 72.
Is formed.

To open the shutoff valve 9 in the closed state,
Despite the wide gap G formed between the magnetic pole 62 and the plunger 72, the valve body 71 is resisted against the spring force F _S.
It is necessary to obtain a magnetic attraction force F _M of a value capable of moving downward in the plane of FIG. By the way, when the exciting coil 65 is in the non-excited state, the value of the magnetic attraction force F _M obtained by the cutoff valve 9 is the same as the value of the magnetic attraction force F _M generally obtained in the magnetic circuit excited by only the permanent magnets. shows the characteristics such as the graph shown by a dotted line in FIG. 2 to be described later with respect to the length L _G of the gap G. According to the dotted line of the graph in FIG. 2, the value of the gap length L _G is, exceeds the value L _GC9 the gap length L _G of the condition that the magnetic attraction force F _M = the spring force F _S, F _M <F _S Has become. The shutoff valve 9 in the closed state is in this relationship. Further, in order to obtain a magnetic attraction force F _M having a value exceeding the spring force F _S in the state where the wide gap G having a value exceeding L _GC9 is formed, the permanent magnet 6 is used.
Since the magnetomotive force is insufficient only by the excitation with only 1, the excitation coil 65 needs to be supplied with the direct current in the positive direction.

When a positive direct current is applied to the shutoff valve 9 in the closed state, the amount of the magnetic flux 6a is increased, and F _M > F _S
As a result, the end surface 72a of the plunger 72 is attracted to the magnetic pole 62, and the shutoff valve 9 is returned to the open circuit state.
Since the air gap length L _G in this case is narrower than L _GC9 , it is _possible to maintain the state of F _M > F _S by only exciting the permanent magnet 61. Therefore, the shut-off valve 9 can self-maintain the open circuit state by being excited only by the permanent magnet 61, and can self-maintain the closed circuit state only by the spring force F _S of the spring 73. In both of these states, the exciting coil 65 can be maintained. Can be de-energized.

Further, as is well known, it is necessary to take safety measures for explosion proof in an electric device that handles fuel gas. Therefore, in the shutoff valve 9, this explosion proof measure is performed by the guide body 63 and the seal bodies 691 and 692. There is. That is, in the guide body 63, the fluid 9 a that is the fuel gas is excited by the exciting coil 65.
The seal bodies 691 and 692 respectively prevent the fluid 9a from entering from both ends of the guide body 63.

Further, as the permanent magnet 61, for example, a permanent magnet material having a relatively large coercive force value, such as a ferrite magnet or a NdFeB rare earth magnet, is used, and a sufficiently large magnetic attraction force F is obtained even in the non-excitation state. _{I am trying} to get _M. However, as is well known, these permanent magnet materials are easily oxidized in the presence of an oxidizing substance and have a property of being powdered by the oxidation. If the fluid 9a is city gas, the city gas will contain NO, as is known.
_Since an oxidizing substance such as _{X 2} and SO _X is contained, a sufficient protective film is formed on the surface of the permanent magnet 61 so as not to be oxidized by these substances. As the protective film of this like, the metal plating layer, the synthetic resin layer, S _i O
_A single film or a composite film such as a _two- layer film is used, and in the case of a single film, it is common to use a film having a larger film thickness.

In the above description, the fluid 9a has been described as a fuel gas, but the fluid 9a is a corrosive gas.
Even when it is a liquid, the guide body 63 and the seal body 69
1, 692 serves to prevent such fluid 9a from entering the portion where the exciting coil 65 is present.

[0014]

In the self-holding shutoff valve according to the prior art described above, for example, the shutoff valve 9, the open and closed states of the shutoff valve can be surely self-held even when it is not excited. Even if the fluid 9a is a fuel gas or a corrosive fluid, the fluid 9a can be used without any trouble, but the following problems remain. That is, at least two seal bodies are required to prevent the fluid 9a from entering the charging section where the exciting coil 65 is present, which increases the manufacturing cost of the shutoff valve 9. There is. In addition, the guide body 63 near the permanent magnet 61 and the magnetic pole 62 is present.
The wide-diameter portion 6 is used for mounting the seal body 692.
31 has to be formed, for which purpose the guide body 6
The manufacturing cost of the shut-off valve 9 is high because the manufacturing process of No. 3 requires a long processing man-hour. In addition, since it is necessary to form a sufficient protective film on the permanent magnet 61, a long process man-hour is required for manufacturing the permanent magnet 61, and the manufacturing cost of the shutoff valve 9 is high. Further, in the shutoff valve 9 in the open circuit state, as shown by a dotted line graph in FIG. 2 described later, there is a large magnetic attraction force F _M sufficiently exceeding the spring force F _S , so the shutoff valve 9 In the valve closing operation for switching the open state from the open state to the closed state, it is necessary to increase the value of the DC current in the negative direction given to the exciting coil 65, which reduces the power consumption of the shutoff valve 9 during the valve closing operation. In addition, the current capacity value that the power supply should have is increased. Furthermore, since the sealing body provided to prevent the fluid 9a from entering the charging section is made of a rubber-like substance, its sealing performance is subject to secular change. For this reason, long-term reliability is not sufficient.

The present invention has been made in view of the above-mentioned problems of the prior art, and an object thereof is to improve self-holding so that power consumption, manufacturing cost and the like are reduced and reliability is improved. Type shutoff valve.

[0016]

In the present invention, the above-mentioned objects are as follows: 1) At least one fluid outflow portion, a valve seat formed facing this outflow portion, and a mounting for mounting an electromagnet for operation. A valve body having a portion, a valve body arranged to face the valve seat to switch the outflow state of the fluid from the outflow portion, a pressurizing body for generating a force for pressing the valve body against the valve seat, and a columnar shape. And a plunger for holding the valve element at one end thereof, and an electromagnet for operation that applies a force that separates the valve element from the valve seat against the force generated by the pressurizing element to the plunger by a magnetic attraction force. The electromagnet is provided with a cylindrical guide body made of a non-magnetic material that supports the movement of the plunger in the axial direction, and the electromagnet is arranged so as to face the other end of the plunger to generate a magnetic flux that flows through the plunger. Permanent magnet and magnetomotive force that increases or decreases the amount of magnetic flux In a self-holding type cutoff valve having an exciting coil for generating a magnet and a frame body for holding the guide body and fixing the electromagnet to the mounting portion of the valve body, the tubular guide body provided in the electromagnet has a bottom. It is achieved by having a bottom portion near the other end of the plunger.

Thus, since the bottom of the guide body prevents the fluid from further entering, the seal mounted in the vicinity of the end of the guide body opposite to the valve body side in the conventional example. The body does not need to be installed in the self-holding shutoff valve of the present invention. Further, for the same reason, the necessity of forming a sufficient protective film on the permanent magnet is eliminated. 2) In the means described in the above item 1, the electromagnet has a magnetic pole made of a ferromagnetic material between the other end of the plunger and the permanent magnet, and the bottomed guide body provided in the electromagnet is: The bottom portion is located between the magnetic pole and the permanent magnet,
Is achieved by

Then, in addition to the action of the above item 1,
The bottom of the guide made of non-magnetic material will be interposed between the magnetic pole and the permanent magnet, and focusing on the magnetic circuit through which the magnetic flux obtained by the permanent magnet flows, the magnetic resistance value of the magnetic circuit is the bottom meat. It will be increased by the thickness. As a result, the value of the DC current in the negative direction given to the exciting coil is reduced during the valve closing operation for switching the shutoff valve from the open state to the closed state. 3) In the means described in 1) above, the bottomed guide body provided in the electromagnet is configured such that the bottom portion is located between the other end of the plunger and the permanent magnet. To be achieved.

Then, in addition to the action of the above item 1,
The bottom of the guide made of non-magnetic material is interposed between the other end of the plunger and the permanent magnet, and the value of the gap L _G is increased by the thickness of the bottom of the guide. . As a result, the value of the DC current in the negative direction given to the exciting coil is reduced during the valve closing operation for switching the shutoff valve from the open state to the closed state. Furthermore, 4) In the means described in any one of the items 1 to 3, the bottomed guide body provided with the electromagnet is formed integrally with the frame body. .

Thus, in addition to the action of any one of the above items 1 to 3, the bottomed guide body formed integrally with the frame body allows the fluid to flow to the valve body side end of the guide body. There is no gap that can penetrate. As a result, the seal body, which is mounted on the valve body side end of the guide body in the conventional example, does not need to be installed in the self-holding shutoff valve of the present invention.

[0021]

Embodiments of the present invention will be described below in detail with reference to the drawings. In the following description, the same parts as those of the conventional self-holding shutoff valve shown in FIG. 7 are designated by the same reference numerals, and the description thereof will be omitted. In addition, in the drawings used in the following description, as for the reference numerals given in FIG. 7, only representative reference numerals are shown.

Embodiment 1 FIG. 1 is a longitudinal sectional view showing a self-holding type shutoff valve according to an embodiment of the present invention corresponding to claims 1 and 2 in an open state. In FIG.
1 is an electromagnet 6 provided in the shutoff valve 9 of the conventional example shown in FIG.
On the other hand, it is a self-holding shutoff valve in which the guide body 63 and the permanent magnet 61 are replaced by the electromagnet 2 using the guide body 21 and the permanent magnet 22. The guide body 21 is formed in a cylindrical shape with a bottom using a non-magnetic material such as brass. One end of the guide body 21 on the opening side is held by the frame body 64, and the other end portion is closed by the bottom portion 211. Has been. Then, the guide body 21 has a bottom portion 211 which is an end surface on the other end side.
The outer surface of the permanent magnet 22 has a length dimension that makes contact with the surface of the permanent magnet 22 facing the magnetic pole 62. The magnetic pole 62 is formed by the guide body 2
It is fixed to the inner surface side of the bottom portion 211 so as to face the permanent magnet 22 with the bottom portion 211 having the thickness L ₂₁₁ of 1 sandwiched therebetween. Further, the permanent magnet 22 is different from the conventional permanent magnet 61 in that
Only the protective film applied to the surface is different. And then
The protective film applied to the permanent magnet 22 is a mild protective film that prevents weak oxidation by the atmosphere, and for example, a thin metal plating layer or a single film of a synthetic resin layer is applied.

Since the first embodiment shown in FIG. 1 has the above-described structure, the bottom portion 211 of the guide body 21 prevents the fluid 9a from further entering. In the shutoff valve 1 of the present invention, the seal body 692 mounted near the end of the valve 63 on the side opposite to the valve body 71 side does not need to be installed. Then, Example 1
Since the fluid 9a at this portion is sealed with a metal whose material properties are stable for a long period of time, instead of the seal body 692 using rubber or the like of the conventional example, the long-term reliability of the sealing performance is It is much better than the example. In addition, the guide body 21 has a wide diameter portion 631.
Since the shape is simplified as compared with the guide body 63 of the conventional example having a complicated shape having, the processing man-hour is shortened. Further, for the same reason, it is sufficient to apply a thin protective film to the permanent magnet 22.

Further, the bottom portion 2 of the guide body 21 made of non-magnetic material
11 is interposed between the magnetic pole 62 and the permanent magnet 22, and focusing on the magnetic circuit through which the magnetic flux 6a obtained by the permanent magnet 22 flows, the magnetic resistance value of the magnetic circuit is the thickness L _{211 of the} bottom _211. This means that the value of the magnetic attraction force F _M obtained by the shutoff valve 1 exhibits the characteristic as shown by the solid line in FIG. 2 with respect to the gap length L _G. Here, FIG. 2, the air gap length L _G of the self-holding of the shut-off valve made to the present invention - the magnetic attraction force F _M property is a graph comparing with the conventional example. Gap length with the shutoff valve 1 shown by a solid line in FIG. 2 L _G - magnetic attraction force - the magnetic attraction force F _M characteristics, gap length L _G having the shut-off valve 9 of the conventional example shown by dotted lines in FIG. 2 compared to F _M characteristic, shutoff valves for one of the characteristic properties of the shut-off valve 9, the gap L value of _G is the bottom 2
This is equivalent to the case where the thickness L _{211 of} 11 is increased. That is, the graph shown by the solid line which is the characteristic of the shutoff valve 1 has a relationship in which the corresponding portion of the graph shown by the dotted line which is the characteristic of the shutoff valve 9 is horizontally moved in the Y axis direction by L _{211 with} respect to the X axis. Has become. As a result, the value of the DC current in the negative direction given to the exciting coil 65 is reduced during the valve closing operation for switching the shutoff valve 1 from the open state to the closed state.

Embodiment 2; FIG. 3 is a longitudinal sectional view showing a self-holding shutoff valve according to an embodiment of the present invention corresponding to claims 1 and 3 in an open state. In FIG.
The same parts as those of the self-holding shutoff valve according to the embodiment of the present invention corresponding to claims 1 and 2 shown in FIG. 1 are designated by the same reference numerals, and the description thereof will be omitted. In FIG. 3, 1A is a guide body 31, instead of the guide body 63 and the permanent magnet 61 with respect to the electromagnet 6 included in the shutoff valve 9 of the conventional example shown in FIG.
It is a self-holding type cutoff valve equipped with an electromagnet 3 using a permanent magnet 22. The guide body 31 is formed in a bottomed tubular shape using a non-magnetic material such as brass. One end of the guide body 31 on the opening side is held by the frame body 64, and the other end portion has a thickness L _211. It is closed by a bottom portion 311 having. Thus, the guide body 31 has such a length dimension that the outer surface of the bottom portion 311 which is the other end side is in contact with the surface of the magnetic pole 62 facing the end portion 72a of the plunger 72.

Since the second embodiment shown in FIG. 3 has the above-described structure, the bottom portion 311 of the guide member 31 prevents the fluid 9a from entering further, and thus, as in the case of the first embodiment. The body 692 does not need to be installed in the shutoff valve 1A of the present invention, the long-term reliability of the sealing performance is improved, and the guide body 31 has a simplified shape, which shortens the processing man-hours. The permanent magnet 22 provided with a thin protective film can be applied.

Thus, the bottom portion 311 of the guide body 31 made of a non-magnetic material is interposed between the end portion 72a of the plunger 72 and the magnetic pole 62, and the thickness L ₂₁₁ of the bottom portion 311 corresponds to the gap length L _{211. Since G} is increased, the value of the magnetic attraction force F _M obtained by the shutoff valve 1A exhibits the characteristics shown by the solid line in FIG. 4 with respect to the gap length L _G.
Here, FIG. 4, the gap length L _G of the self-holding of the shut-off valve made to the present invention - is a graph showing the magnetic attraction force F _M properties.
Figure 4 gap length with the shut-off valve 1A shown by the solid line in L _G - magnetic attraction force F _M characteristic, the gap length L _G having the shut-off valve 9 of the conventional example shown by dotted lines in FIG. 2 described above - Magnetic It is the same as the graph of the attraction force F _M characteristic. The point to be noted in FIG.
_G includes the thickness L ₂₁₁ of the bottom portion 311. That is, in the open state of the shutoff valve 1A, the value of the gap length L _G is not zero but L ₂₁₁ . As a result, the value of the DC current in the negative direction given to the exciting coil 65 is reduced during the valve closing operation for switching the shutoff valve 1A from the open state to the closed state.

Embodiment 3; FIG. 5 is a longitudinal sectional view showing a self-holding shutoff valve according to an embodiment of the present invention corresponding to claims 1, 2 and 4 in an open state. 5, the same parts as those of the self-holding shutoff valve according to the embodiment of the present invention corresponding to claims 1 and 2 shown in FIG. 1 are designated by the same reference numerals, and the description thereof will be omitted. In FIG. 5, 1B
In contrast to the electromagnet 6 included in the shutoff valve 9 of the conventional example shown in FIG. 7, instead of the frame body 64, the guide body 63, and the permanent magnet 61, the electromagnet 4 using the frame body 41 and the permanent magnet 22 is provided. It is a self-holding shutoff valve. The frame body 41 has the groove 641 omitted from the frame body 64 of the conventional example, and the guide body 411 is made of an adhesive agent such as a welding method, a brazing method, and a synthetic resin material having high chemical stability such as epoxy resin. It is different in that they are integrally formed by a known joining method such as an adhesive method. Here, the guide body 411 is substantially the same as the guide body 21 according to the first embodiment of the present invention.

Since the third embodiment shown in FIG. 5 has the above-mentioned configuration, the bottom portion 211 of the guide member 411 prevents the fluid 9a from entering further, and thus, as in the first embodiment, the seal is formed. The body 692 does not need to be installed in the shutoff valve 1B of the present invention, the long-term reliability of the sealing performance is improved, and the guide body 411 has a simplified shape, which shortens the processing man-hours, and is a permanent magnet. The permanent magnet 22 provided with a thin protective film can be applied. In the shutoff valve 1B according to the third embodiment, in addition to these, the guide body 411 is formed integrally with the frame body 41, so that in the shutoff valve 9 of the conventional example, the valve body 71 side of the guide body 63 is provided. Seal body 69 attached to the end of
The installation of 1 is also unnecessary. Then, the sealing of the fluid 9a at this portion in the third embodiment is performed by using a metal or an adhesive whose material characteristics are stable for a long period of time, instead of the sealing body 691 made of rubber or the like in the conventional example. Therefore, the long-term reliability of the sealing performance is improved as compared with the case of the conventional example. Since the guide body 411 is substantially the same as the guide body 21 according to the first embodiment, the characteristics of the gap length L _G and the magnetic attraction force F _M obtained by the cutoff valve 1B are the same as those of the cutoff valve 1. is there.

Embodiment 4; FIG. 6 is a longitudinal sectional view showing a self-holding type shutoff valve according to an embodiment of the present invention corresponding to claims 1, 3 and 4 in an open state. 5, a self-holding shutoff valve according to an embodiment of the present invention corresponding to claims 1 and 2 shown in FIG. 1, and an embodiment of the present invention corresponding to claims 1 and 3 shown in FIG. The same parts as those of the self-holding shutoff valve according to 1 are given the same reference numerals and the description thereof will be omitted. 6, reference numeral 1C is a frame body 51, a permanent magnet 22 instead of the frame body 64, the guide body 63, and the permanent magnet 61 with respect to the electromagnet 6 included in the shutoff valve 9 of the conventional example shown in FIG.
It is a self-holding type cutoff valve equipped with an electromagnet 5 using. Similar to the case of the frame body 41 according to the third embodiment, the frame body 51 has the groove 641 omitted from the frame body 64 of the conventional example, and the guide body 511 is welded, brazed, and has a strong adhesive. It is different that they are integrally formed by the bonding method used. Here, the guide body 511 is substantially the same as the guide body 31 according to the second embodiment of the present invention.

Since the fourth embodiment shown in FIG. 6 has the above-described configuration, the guide body 511 has the bottom portion 311 and the guide body 511 is formed integrally with the frame body 51. As in the case, the seal bodies 691, 692
The cutoff valve 1C of the present invention does not need to be installed, the long-term reliability of the sealing performance is improved, and the guide body 511 has a simplified shape, which shortens the processing man-hour.
Permanent magnet 2 with a thin protective film as a permanent magnet
2 will be applicable. In addition, the guide body 5
Since 11 is substantially the same as the guide member 31 according to the second embodiment, the gap length L _G -magnetic attraction force F _M characteristic obtained by the cutoff valve 1C is the same as the characteristic of the cutoff valve 1A.

In the above description of Examples 2 and 4,
The electromagnets 3 and 5 have been provided with the magnetic poles 62, but the present invention is not limited to this. For example, the permanent magnets 22 may have the function of the magnetic poles 62, so that the magnetic poles 62 are provided.
It is also possible to omit the installation of. In the above description of the first to fourth embodiments, the reel 66 included in each of the electromagnets 2 to 5 included in each of the shutoff valves 1 to 1C has the shutoff valve 9 of the conventional example.
It is assumed that the winding frame 66 is the same as the winding frame 66 included in the electromagnet 6 included in, but the present invention is not limited to this. For example, the winding frame included in the electromagnets 2 to 5 includes guide members 21, 31, Corresponding to the fact that the wide-diameter portion 631 is not formed on the 411 and 511, the shape may be simplified without forming a cut portion.

[0033]

According to the present invention, the following effects can be obtained by adopting the structure described in the above-mentioned claims. With the configuration according to the first to third aspects of the claims, the fluid such as the fuel gas is prevented from entering beyond the bottom portion, so that it is not necessary to install the seal body at this portion, The long-term reliability of the fluid sealing performance is improved. In addition, since the fluid is prevented from entering beyond the bottom portion, the protective film applied to the permanent magnet can be simplified and the shape of the guide body can be simplified.
It is possible to reduce the manufacturing cost of the shutoff valve. The configuration described in the above item means that the bottom of the guide body made of a non-magnetic material is, for example, between the magnetic pole and the permanent magnet,
Alternatively, it is interposed between the other end of the plunger and the magnetic pole. This makes it possible to reduce the negative DC current value that is applied to the exciting coil when the shutoff valve closes, so that the power consumption for shutting off the shutoff valve and the power supply for closing the valve can be reduced. It is possible to reduce the current capacity value to be provided. Furthermore, with the configuration according to the fourth aspect of the claims, no gap is formed at the end of the guide body on the valve body side so that fluid can enter. As a result, it is not necessary to install a seal body at this portion, and in addition to the effects of the above items and items, it is possible to further improve the long-term reliability of the sealing performance for the fluid of the shutoff valve, and also the shutoff valve. It is possible to further reduce the manufacturing cost of.

[Brief description of drawings]

1 is a longitudinal sectional view showing a self-holding shutoff valve according to an embodiment of the present invention corresponding to claims 1 and 2 in an open state.

FIG. 2 is a gap length L of the self-holding shutoff valve according to the present invention.
_G -Magnetic attraction force F _M characteristic graph comparing with the case of the conventional example

FIG. 3 is a longitudinal sectional view showing a self-holding shutoff valve according to an embodiment of the present invention corresponding to claims 1 and 3 in an open state.

FIG. 4 is a gap length L of the self-holding shutoff valve according to the present invention.
_G - a graph showing the magnetic attraction force F _M Characteristics

FIG. 5 is a longitudinal sectional view showing a self-holding shutoff valve according to an embodiment of the present invention corresponding to claims 1, 2 and 4 in an open state.

FIG. 6 is a longitudinal sectional view showing a self-holding shutoff valve according to an embodiment of the present invention corresponding to claims 1, 3, and 4 in an open state.

FIG. 7 is a longitudinal sectional view showing a conventional self-holding shutoff valve in an open state.

[Explanation of symbols]

 1 Shut-off valve 2 Electromagnet 21 Guide body 211 Bottom part 22 Permanent magnet 62 Magnetic pole 64 Frame body

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kazuya Fujisawa 4-13-21 Nakameguro, Meguro-ku, Tokyo A-408 (72) Inventor Haruo Nakazawa 1-1 Tanabe Shinden, Kawasaki-ku, Kanagawa Prefecture Fuji Electric Machinery Co., Ltd. (72) Inventor Ken Sugiura 1-1, Tanabe Nitta, Kawasaki-ku, Kawasaki-shi, Kanagawa Fuji Electric Co., Ltd.

Claims (4)

[Claims] 1. A valve body having at least one fluid outflow portion, a valve seat formed facing the outflow portion, a mounting portion for mounting an electromagnet for operation, and a valve body facing the valve seat. A valve body arranged to switch the outflow state of the fluid from the outflow portion, and a pressurizing body for generating a force for pressing the valve body against the valve seat,
A plunger that has a columnar shape and holds the valve element at one of its ends, and an electromagnet for operation that applies a force that separates the valve element from the valve seat against the force generated by the pressurizing element to the plunger by a magnetic attraction force. The electromagnet is provided with a cylindrical guide body made of a non-magnetic material that supports the movement of the plunger in the axial direction, and the electromagnet is disposed so as to face the other end of the plunger, and a magnetic flux that allows the plunger to flow therethrough. A self-holding shutoff having a permanent magnet to generate, an exciting coil to generate a magnetomotive force that increases or decreases the amount of the magnetic flux, and a frame body that holds the guide body and fixes the electromagnet to the mounting portion of the valve body. In the valve, the self-holding shutoff is characterized in that the tubular guide body of the electromagnet has a tubular shape with a bottom and has a bottom near the other end of the plunger. valve. 2. The self-holding shutoff valve according to claim 1, wherein the electromagnet has a magnetic pole made of a ferromagnetic material between the other end of the plunger and the permanent magnet, and the electromagnet has the magnetic pole. A self-holding shut-off valve characterized in that the bottom guide body has its bottom positioned between a magnetic pole and a permanent magnet. 3. The self-holding shutoff valve according to claim 1, wherein the bottomed guide body provided with the electromagnet has its bottom positioned between the other end of the plunger and the permanent magnet. A self-holding shutoff valve characterized in that 4. The self-holding shutoff valve according to any one of claims 1 to 3, wherein the bottomed guide body provided with the electromagnet is formed integrally with the frame body. Self-holding shutoff valve.