JP3600608B2 - Channel cutoff device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a flow path blocking device, and more particularly to a flow path blocking device that can immediately block a gas flow path when a fire occurs.
[0002]
[Prior art]
As a device in which a flow path blocking device is incorporated in a gas flow path, there is a device employing a ball valve (for example, see Patent Document 1).
[0003]
In this apparatus, a valve accommodating chamber accommodating the ball valve is juxtaposed so as to communicate with a gas flow path. At normal temperature, the ball valve is supported by a bearing body in a state where escape from the valve accommodating chamber to the flow path is prevented, and at the time when an abnormal overheating state occurs due to a fire or the like, the ball bearing is supported. When the force is lost, the ball valve is inserted into the flow path from the valve storage chamber, thereby shutting off the flow path.
[0004]
In this case, for example, if the support is made of a material having a property of causing melting or deformation by heating at a set temperature or more, such as a low-melting point metal or a thermoplastic resin material, the support may be abnormally heated. Is melted or deformed, the ball valve can be injected into the gas flow path from the valve body housing chamber, and the flow path can be reliably closed. Therefore, it is possible to provide a safe gas flow path that can urgently shut off gas when a fire occurs.
[0005]
[Patent Document 1]
Japanese Patent Application Laid-Open No. 2000-2354 [Patent Document 2]
Japanese Patent Application Laid-Open No. 2000-74239
[Problems to be solved by the invention]
However, in the above-described conventional apparatus, the valve housing chamber for housing the ball valve at room temperature is arranged side by side with the pipe. Since the device must be dropped by its own weight, there is a problem that the directionality of the device when the flow path blocking device is installed is limited.
The present invention provides a flow path shut-off device that does not impair the appearance of ordinary pipes or joints and that does not limit the installation location in a “flow path cut-off device that shuts off a gas flow path when abnormally overheated”. The task is to
[0007]
[Means for Solving the Problems]
* 1. The technical means of the present invention for solving the above-mentioned problem includes: a plate-shaped valve provided in a cylinder constituting a gas flow path and formed in a shape capable of shutting off the cylinder;
Urging means for urging the plate-shaped valve in the flow path blocking direction,
A holding member capable of holding the plate-shaped valve in a flow path open state by rotating the valve shaft of the plate-shaped valve by about 90 degrees with respect to the flow direction, against the urging force of the urging means;
The holding member is made of a material that can be deformed or melted at a set temperature,
A through hole for inserting one end or both ends of the holding member is formed in a peripheral wall of the cylinder,
The biasing means is a coil spring, one end of the coil spring is connected to the center of the plate-shaped valve, the other end is connected to a locking pin fixed in the cylinder,
The holding member is a rod-shaped body protruding at right angles to the gas flow path,
The plate-shaped valve is set so as to be held in a rotation-blocking state by the rod-shaped member in a flow path open posture against the urging force of the coil spring . "
[0008]
The above technical means works as follows.
A plate-shaped valve as a shut-off valve, an urging means for urging the plate-shaped valve into a flow path cut-off state, and a holding member for holding the plate-shaped valve in a flow path open state are incorporated in the cylinder. Since one end or both ends of the holding member made of a heat-sensitive deformable or molten material is disposed in a state of being inserted into a through hole formed in a peripheral wall of the cylinder, the holding member is configured of the cylinder. The temperature of the outside area is sensed from the tube wall. At normal temperature, the plate-shaped valve is set by the holding member so as to be maintained in the channel open position by, for example, being positioned parallel to the channel, so that the gas flows upstream in the cylinder. It flows from the side to the downstream without any problems. When the outer region of the cylinder is abnormally heated to a high temperature due to a fire or the like, the holding member penetrating the peripheral wall of the cylinder is melted or deformed by heat. As a result, the holding force for holding the plate-shaped valve in the channel open position is lost. When the holding force is lost, the plate-shaped valve is urged into the flow path cutoff state by the urging force of the urging means, and the gas is shut off by the upstream plate-shaped valve.
[0011]
Further, the urging means is a coil spring, one end of the coil spring is connected to the center of the plate-shaped valve, and the other end is connected to a locking pin fixed in the cylinder, and the holding member Is a rod-shaped body projecting at right angles to the gas flow path, and the plate-shaped valve is held in a rotation-blocking state by the rod-shaped body in a flow path open posture against the urging force of the coil spring. Therefore , only one plate-shaped valve is provided so as to be connected to one end of the coil spring, and the other end of the coil spring is connected to a locking pin fixed in the flow path. It is configured to be stopped. The plate-shaped valve is turned parallel to the flow path by rotating the valve shaft by 90 degrees while elastically deforming the urging means in the extension direction with the locking pin as a base end. This is the flow path opening posture of the plate valve. The rod-shaped holding means is projected at right angles to the flow path so as to prevent the rotation of the plate-shaped valve due to the urging force of the coil spring and maintain the parallel posture. When the holding member is melted or deformed due to abnormal overheating such as a fire, the plate-shaped valve is rotated 90 degrees from the parallel posture by the elastic return force of the coil spring, and is positioned perpendicular to the flow path. Thus, the flow path is closed.
[0012]
* Item 2
In addition, the technical means of the present invention is , in the flow path blocking device that shuts off the gas flow path at the time of abnormal overheating,
A plate-shaped valve provided in a cylinder constituting a gas flow path and formed in a shape capable of shutting off the inside of the cylinder;
Urging means for urging the plate-shaped valve in the flow path blocking direction,
A holding member capable of holding the plate-shaped valve in a flow path open state by rotating the valve shaft of the plate-shaped valve by about 90 degrees with respect to the flow direction, against the urging force of the urging means;
The holding member is made of a material that can be deformed or melted at a set temperature,
A through hole for inserting one end or both ends of the holding member is formed in a peripheral wall of the cylinder,
A small diameter step is protruded in the cylinder,
When the plate-shaped valve is in the flow path open state, two points on the periphery of the plate-shaped valve abut against respective positions on the periphery of the small-diameter step portion,
When the plate-like valve by the biasing force of the biasing means is a conduit shutting state, the vicinity of the peripheral edge portion of the plate-like valve is configured to be pressed against the contact state on one side of the cylindrical portion "it It is.
In this configuration , the plate-shaped valve is held in the flow path open posture at a total of three points, that is, two points in contact with the peripheral edge of the small-diameter step portion and a holding portion held by the holding member. In the flow path cutoff state, one side surface of the small-diameter step portion functions as a valve seat of the plate-shaped valve.
[0013]
* 3. In the above paragraph 2, the term "the holding member is a surface on a back side of a surface which is brought into contact with the small-diameter step portion by the urging force of the urging means, of the front and back surfaces of the plate-shaped valve". Is attached in the form of being connected to a coil, for example, as described in Item 4, a coil spring is employed as the urging means, and a rod is employed as the holding member. The other end is fitted into the through hole of the cylinder, and the other end is attached to the surface on the opposite side to the surface on which the coil spring is attached (the surface pressed against the small-diameter stepped portion), for example, by being fitted or screwed in such a manner that it cannot be removed. Configuration. In this case, when the peripheral wall of the cylinder is overheated due to the occurrence of a fire or the like, the holding member that has been melted or deformed is a surface (back surface) on the opposite side to the side of the plate-shaped valve that is pressed against the small-diameter step portion. , But does not flow into the crimping surface side.
In addition, as for the cylinder, as described in Section 4, in the case of “a cylindrical member that can be inserted into the gas pipe in an outer peripheral airtight state”, only the cylinder of the present invention is inserted into the existing gas pipe, A flow path blocking device can be provided. At this time, if the one or both ends of the holding member are configured to penetrate the peripheral wall of the cylinder and come into contact with the inner wall of the gas flow path, heat is quickly transmitted to the holding member when the gas pipe is overheated. The Rukoto.
Further, as described in Item 5, "the cylinder has a tapered thread portion at one end to which a general pipe can be connected, and a nut member which can be screwed to a gas inlet pipe on the upstream side of the gas meter at the other end. In this case, the cylinder can function as a joint member disposed between a gas inlet pipe on the upstream side of the gas meter and a suction pipe for drawing gas from underground.
Further , as the holding member, as shown in item 6 , a member made of a thermoplastic synthetic resin, a bimetal, a shape memory alloy, or a low melting point metal can be used.
[0014]
【The invention's effect】
The present invention has the following specific effects because of the above configuration.
Since the flow path shut-off device including the plate-shaped valve, the urging means, and the holding member is incorporated in the cylinder, the structure is simplified, and the plate-shaped valve as the shut-off valve shuts off the flow path by the urging means. With such a setting, the directionality of the cylinder is not limited, and the range of use is expanded. Further, since the holding portion for holding the plate-shaped valve is disposed so as to easily detect an abnormal heating state, at the time of abnormal overheating, heat is easily transmitted to the holding member, and until the holding member is deformed or melted. , And a quick shutoff effect by the plate-shaped valve can be expected.
[0016]
Further, on the inexpensive and the structure is more simple, there is an effect that can be held in a flow path open position the plate-like valve in a stable state.
[0017]
In item 2 , the plate-shaped valve mounted in the flow path is reliably held stable in the open state of the flow path by the three points of the peripheral edge of the small-diameter stepped portion and the holding member. There is no interruption.
[0018]
In the case of the item (3) , since the melted or deformed holding member does not flow into the crimped portion between the plate-shaped valve and the small diameter step portion, the inconvenience that the crimping of both is prevented by the melted or deformed holding member is eliminated. Absent. Therefore, the flow path can be more reliably blocked.
[0019]
The cylinder having the above configuration can be inserted into a gas pipe as shown in section 4, or can be used as a joint member on the upstream side of a gas meter as described in section 5. In such a usage mode, the appearance of the gas pipes and the joints is not impaired because the overall appearance does not change.
Further, by specifying the material of the holding member as described in item 6 , melting or deformation at the time of abnormal overheating can be ensured.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, the above-described embodiment of the present invention will be described in detail with reference to the drawings.
FIGS. 1 to 4 relate to the first embodiment, and FIG. 1 is a cross-sectional view showing a state where the flow path blocking device according to the embodiment of the present invention is installed in a flow path open state. 2 is a cross-sectional view taken along line XX of FIG. 1, FIG. 3 is a cross-sectional view taken along YY of FIG. 1, and FIG.
[0021]
The flow path shut-off device according to this embodiment has a plate-shaped valve (2) and one end locked to the plate-shaped valve (2) and for urging the plate-shaped valve (2) in the flow path cut-off direction. A coil spring (3) as urging means, a locking pin (4) for locking the other end of the coil spring (3), and a plate-like member provided at a position for preventing the coil spring (3) from elastically returning. A melting pin (5) as a holding member for holding the valve (2) in the channel open position is assembled in the cylinder (1), and the cylinder (1) is connected to a gas pipe (10). Shall be used with the interior.
[0022]
The cylinder (1) is a cylindrical body having an outer diameter substantially coinciding with the inner diameter of the gas pipe (10) and an inner diameter set to be larger than the diameter of the plate valve (2). The O-ring (11) made of a thermal expansion packing and the C-shaped elastic ring (12) are fitted to each other. A small-diameter cylinder having an inner diameter smaller than the diameter of the plate-shaped valve (2) is provided on the inner peripheral wall of the cylinder (1) in the area where the O-ring (11) and the C-shaped elastic ring (12) are provided. A part (13) is formed.
As shown in FIG. 2 or FIG. 3, a through hole for inserting a tip of a melting pin (5), which will be described later, at a position on the peripheral wall of the cylinder (1), which is separated from the small-diameter cylindrical portion (13). A hole (14) is formed.
[0023]
The plate-shaped valve (2) is a metal disc having a diameter larger than the inside diameter of the small-diameter cylindrical portion (13) and smaller than the inside diameter of the cylinder (1). A locking projection (20) is provided at the center of a surface (hereinafter, referred to as a crimping surface (21)), and is located on one side of the small-diameter cylindrical portion (13) in the cylinder (1). It is arranged in.
The locking pin (4) is made of a metal wire having a length substantially coinciding with the inner diameter of the cylinder (1), and is connected to the axis of the cylinder (1) at the other side of the small-diameter cylindrical portion (13). It is arranged so as to be located along a center line that intersects at right angles to it.
[0024]
A coil spring (3) is interposed between the locking projection (20) of the plate-shaped valve (2) and the locking pin (4), and the plate-shaped valve (20) is moved by the urging force. The small-diameter cylindrical portion (13) is set so as to be in close contact with one side surface thereof.
[0025]
In order to set the flow path blocking device of this embodiment in the gas pipe (10), first, the plate-like valve (2) in which one end of the coil spring (3) is locked to the locking projection (20). Is inserted from one side of the cylinder (1) in a posture parallel to the axis, and as shown in FIG. 1, two points (2a) and (2b) on the periphery of the plate-shaped valve (2) are In a state where each of the open ends is in contact with a predetermined position of the open edge, the finger is supported so that the parallel posture is maintained. At this time, as shown in FIG. 3, the plate-shaped valve is so arranged that the crimping surface (21) on which the locking projection (20) is projected is opposed to the through hole (14) of the cylinder (1). The direction of (2) is set.
[0026]
While maintaining this posture, the coil spring (3) is elastically deformed and pulled toward the other side of the cylinder (1), so that the other end of the coil spring (3) is locked in a substantially central area of the locking pin (4). The locking pin (4) is housed in the cylinder (1) so as to be locked on the other side surface of the small-diameter cylindrical portion (13).
[0027]
In this state, the plate-like valve (2) is moved from the parallel posture by the urging force of the coil spring (3) so that the crimping surface (21) moves to one side surface of the small-diameter cylindrical portion (13) in the cylinder (1). The plate-like valve (2) positioned at a right angle to the flow path is urged to rotate by 90 degrees in the direction in which the flow path is to be crimped, with the center line of the plate-shaped valve (2) positioned at right angles to the flow path. In order to prevent this rotation, a melting pin (5) is inserted into the cylinder (1).
[0028]
The melting pin (5) is a rod-shaped body made of a thermoplastic resin that melts at a temperature equal to or higher than a set temperature, and has at one end a length substantially corresponding to the thickness of the cylinder (1) and a through-hole (14). A small-diameter portion (50) having a thickness that can be inserted into the cylinder (1) is formed, and the length of the portion excluding the small-diameter portion (50) substantially matches the radius of the inner diameter of the cylinder (1). Is set to Then, when the tip small diameter portion (50) of the fusion pin (5) is inserted into the through hole (14) of the peripheral wall of the cylinder (1), the other end of the fusion pin (5) is, as shown in FIG. This is a mode located at the center of (1).
[0029]
In addition, two points (2a) and (2b) on the periphery of the plate-shaped valve (2) are brought into contact with predetermined positions on the open end of the small-diameter cylindrical portion (13), respectively, and the parallel posture is maintained. The melting pin (5) abuts on a predetermined position of the crimping surface (21) of the plate-like valve (2) closer to the open end side of the cylinder (1) than the locking projection (20). The positions of the small-diameter cylindrical portion (13) and the through-hole (14) with respect to the size of the plate-shaped valve (2) are set in a predetermined relationship.
[0030]
Therefore, the plate-like valve (2) is positioned in the cylinder (1) in parallel with the flow path, and the small-diameter portion (50) of the tip of the melting pin (5) is inserted into the through-hole (14). In a state where the other end of (5) is in contact with a predetermined position of the crimping surface (21) of the plate-like valve (2), the rotation of the plate-like valve (2) by the elastic return force of the coil spring (3). The movement is prevented by the fusion pin (5). In addition, the plate-like valve (2) has two points in contact with the open end of the small-diameter cylindrical portion (13) and the fusion pin (5). ) Is supported in a stable state at a total of three points, that is, one point at which the other end abuts, and the flow path opening posture is maintained.
[0031]
Thereby, the assembly of each component to the cylinder (1) is completed.
Since the cylinder (1) is set to a size that can be inserted into a general gas pipe, if the cylinder (1) is inserted into the existing gas pipe (10), the pipe into which the cylinder (1) is inserted becomes , And functions as a pipe with a flow path blocking device.
[0032]
In addition, since the outer periphery of the cylinder (1) is provided with the O-ring (11) and the C-shaped elastic ring (12) as described above, the cylinder (1) is provided with a gas pipe (10). The inside can be housed in an outer peripheral airtight state.
[0033]
When the gas pipe (10) is in an abnormally overheated state due to the occurrence of a fire or the like, the small-diameter portion (50), which is a part of the melting pin (5), penetrates the cylinder (1), and the gas ( Since it is arranged so as to be in contact with the pipe (10), the heat of the gas pipe (10) is quickly transmitted to the melting pin (5). Since the fusion pin (5) is molded from a thermoplastic synthetic resin that melts at the set temperature as described above, it melts or deforms when it is heated to a temperature higher than the set temperature. When the melting pin (5) is melted or deformed, the plate-shaped valve (2) cannot be held in the rotation preventing state, and the plate-shaped valve (2) is locked by the urging force of the coil spring (3). As shown in FIG. 4, it is pulled toward the (4) side, and the vicinity of the periphery of the crimping surface (21) is crimped to the side surface of the small-diameter cylindrical portion (13).
[0034]
Thereby, the flow path in the cylinder (1) is shut off by the plate-shaped valve (2), and the O-ring (11) made of the thermal expansion packing is also heated between the cylinder (1) and the pipe (10). Since the airtightness is ensured by the expansion, the flow path in the gas pipe (10) is reliably shut off.
[0035]
FIG. 5 shows a modification of the melting pin (5). The melting pin (5) is formed into a rod having a length substantially corresponding to the outer diameter of the cylinder (1) and having the same thickness as the whole. It is assumed that a pair of through holes (15a) (15b) through which the melting pin (5) can be inserted are formed at positions facing the peripheral wall of the cylinder (1) while being molded.
[0036]
In a state where both ends of the melting pin (5) are respectively passed through the through holes (15a) and (15b), the melting pin (5) can prevent the rotation of the plate valve (2). At a suitable position and in parallel with the valve axis of the plate-shaped valve (2).
[0037]
In this case, since both ends of the melting pin (15) penetrate the cylinder (1) and come into contact with the inner wall of the pipe (10), abnormal overheating at the time of a fire occurrence is applied to the melting pin (15). Since the transmission is easy and the time until the melting pin (15) is deformed or melted is shortened, a rapid flow path blocking effect by the plate valve (2) can be expected.
[0038]
The one shown in FIG. 6 includes a gas inlet pipe (40) on the upstream side of the gas meter (M) and a suction pipe (41) for drawing gas from underground without inserting the cylinder (1) into the pipe. It functions as a joint member (100) to be disposed therebetween. The upper end is provided with a tapered screw portion (16) to which general piping can be connected, and the lower end is provided with a gas meter (M). A nut member (17) that can be screwed into the gas inlet pipe (40) on the upstream side is mounted.
[0039]
In the cylinder (1), a small-diameter cylindrical portion (13) is provided, as in the above-described embodiment, and a plate-like valve (2) is provided above the small-diameter tubular portion (13), and a locking pin ( 4) are disposed in such a manner that they are stretched by coil springs (3), and a melting pin (5) for holding the plate-like valve (2) in the flow path open position shown in FIG. The plate-like valve (2) is prevented from rotating by being inserted through an insertion hole (18) provided in the peripheral wall of the cylinder (1). The outer open end of the insertion hole (18) is formed with a female screw cylinder (19) having a larger diameter than the fusion pin (5), and the fusion pin (5) is inserted into the insertion hole (18). ) Is inserted from the outside, and the insertion end is brought into contact with a predetermined position of the plate-shaped valve (2), and the open end of the insertion hole (18) is inserted into the female screw cylinder (19). It is configured to be closed in an airtight state by screwing a closing screw (30) that can be screwed.
[0040]
In this case, when the cylinder (1) is overheated to a set temperature or more in an abnormally overheated state such as the occurrence of a fire, the melting pin (5) is melted and the holding force on the plate valve (2) is lost, and the coil spring is released. The elastic return force of (3) acts. Thereby, the plate-shaped valve (2) is pressed against the upper end surface of the small-diameter cylindrical portion (13) by the urging force of the coil spring (3), and the flow path in the cylinder (1) is shut off.
[0041]
As described above, when a fire occurs, the gas sent from the suction pipe (41) to the gas meter (M) is supplied to the cylinder (1) as a joint member (100) provided on the upstream side of the gas meter (M). Since the gas can be cut off, even if the gas meter (M) falls carelessly for some reason, the gas in the suction pipe (41) is cut off on the upstream side of the joint member (100), and the gas is discharged to the outside. The danger of leaking into can be prevented.
Further, the joint member (100) composed of the cylinder (1) can be attached as a piping joint on either the inlet side or the outlet side of the gas meter (M) due to its structure. It is desirable to install it in the piping on the side.
[0042]
FIGS. 7 and 8 are explanatory views of modified examples of the plate-like valve (2) and the holding member.
A small-diameter cylindrical portion (13) is provided in a cylinder (1) inserted into a gas pipe (10), and a plate-like valve (2) and a locking pin (4) are arranged on both sides thereof via a coil spring (3). The configuration to be provided is the same as that of the flow path shut-off device of each of the above-described embodiments, except that the melting pin (5) as the holding member is not provided on the crimping surface (21) side of the plate valve (2). , On the surface (22) corresponding to the back side.
[0043]
In FIG. 7, one end of the melting pin (5) is inserted into a through hole (14) provided in the cylinder (1), and the other end causes the plate-like valve (2) to maintain a flow path open posture. 8 is screwed to a screw cylinder (23) provided near the edge of the other surface (22) located farthest from the locking pin (4). The insertion cylinder (24) into which the other end of the fusion pin (5) is inserted is provided just behind the locking projection (20).
[0044]
In the embodiment shown in each of these figures, when the melting pin (5) is thermally melted or deformed during abnormal overheating, the melted or deformed material is applied to the other surface (22) of the plate valve (2). When the pressure contact surface (22) of the plate-shaped valve (2) is pressed against the small-diameter cylindrical portion (13) by the elastic restoring force of the coil spring (3), the melting or deformation is performed. The melt pin (5) does not hinder the pressure bonding, and the flow path can be reliably shut off.
[0045]
In particular, in the one shown in FIG. 8, with the plate-like valve (2) held in a flow path open position positioned parallel to the flow path, the insertion cylinder (24) is placed on the other surface. It extends vertically from the center of (22) to the vicinity of the peripheral wall of the cylinder (1), and has an insertion hole at the tip for inserting the shaft of the melting pin (5). ing.
[0046]
At a predetermined position on the peripheral wall of the cylinder (1), a counterbore (51) is formed as a through hole, and the melting pin (5) has an inverted conical shape adapted to the taper of the counterbore (51). It is assumed to be configured in a shape having a head.
[0047]
With the insertion tube (24) facing the counterbore (51), insert the melting pin (5) from the outside of the cylinder (1), and attach the shaft to the insertion tube ( Insert into the insertion hole at the tip of 24). As a result, the plate-like valve (2) is held in the channel open position.
[0048]
In this case, since the diameter of the molten pin (5) exposed on the outer peripheral surface of the cylinder (1) can be set large, heat is easily transmitted to the molten pin (5) at the time of abnormal overheating. In addition, since the entire length of the fusion pin (5) can be shortened, the amount of heat fusion or deformation is reduced, and the pressure contact surface (21) of the plate-like valve (2) to the small-diameter cylindrical portion (13) is reduced. The inconvenience that the molten or deformed molten pin (5) flows into the side can be further prevented.
[0049]
7 and 8 can be used as a joint member (100) as shown in FIG.
In each of the embodiments, as a holding member for holding the plate-shaped valve (2) in the flow path open state, a portion holding the plate-shaped valve (2) when overheated to a set temperature or more is used. The material is not particularly limited as long as it is a material that dissolves or deforms, and a shape memory alloy, a low melting point metal, or the like can be used in addition to a thermoplastic resin and a bimetal. Further, only the part which is inserted and fixed in the through holes (14) (15a) (15b) or the insertion hole (18) of the cylinder (1) may be made of the above-mentioned thermoplastic material.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view at room temperature showing an example in which a flow path blocking device according to a first embodiment of the present invention is inserted into a gas pipe.
FIG. 2 is a sectional view taken along line XX of FIG.
FIG. 3 is a sectional view taken along line YY of FIG. 1;
FIG. 4 is a cross-sectional view showing a state of the channel shut-off device according to the first embodiment of the present invention at the time of abnormal overheating.
FIG. 5 is a cross-sectional view at room temperature showing an example in which the flow path blocking device according to the second embodiment of the present invention is inserted into a gas pipe.
FIG. 6 is a sectional view of a flow path blocking device according to a third embodiment of the present invention.
FIG. 7 is a sectional view of a flow path blocking device according to another embodiment of the present invention.
FIG. 8 is a sectional view of a flow path blocking device according to another embodiment of the present invention.
[Explanation of symbols]
(1) Cylinder (14) Through-hole (2) Plate valve (3) Biasing means (coil spring)
(5) ····· Holding member (melting pin)

Claims (6)

In a flow path cutoff device that cuts off the gas flow path when abnormal overheating,
A plate-shaped valve provided in a cylinder constituting a gas flow path and formed in a shape capable of shutting off the cylinder;
Urging means for urging the plate-shaped valve in the flow path blocking direction,
A holding member capable of holding the plate-shaped valve in a flow path open state in which the valve shaft of the plate-shaped valve is rotated by about 90 degrees with respect to the flow path direction against the urging force of the urging means,
The holding member is made of a material that can be deformed or melted at a set temperature,
A through hole for inserting one end or both ends of the holding member is formed in a peripheral wall of the cylinder,
The biasing means is a coil spring, one end of the coil spring is connected to the center of the plate-shaped valve, the other end is connected to a locking pin fixed in the cylinder,
The holding member is a rod-shaped body protruding at right angles to the gas flow path,
A flow path shut-off device , wherein the plate-shaped valve is set to be held in a rotation-blocking state by the rod-shaped body in a flow path open position against a biasing force of the coil spring . In a flow path cutoff device that cuts off the gas flow path when abnormal overheating,
A plate-shaped valve provided in a cylinder constituting a gas flow path and formed in a shape capable of shutting off the cylinder;
Urging means for urging the plate-shaped valve in the flow path blocking direction,
A holding member capable of holding the plate-shaped valve in a flow path open state in which the valve shaft of the plate-shaped valve is rotated by about 90 degrees with respect to the flow path direction against the urging force of the urging means,
The holding member is made of a material that can be deformed or melted at a set temperature,
A through hole for inserting one end or both ends of the holding member is formed in a peripheral wall of the cylinder,
A small diameter step is protruded in the cylinder,
When the plate-shaped valve is in the flow path open state, while two points on the periphery of the plate-shaped valve abut each position on the periphery of the small-diameter stepped portion,
When the plate-shaped valve is turned off by the urging force of the urging means, a portion near the periphery of the plate-shaped valve is pressed against one side surface of the small-diameter step portion in close contact with the flow passage. Blocking device. 3. The flow path shut-off device according to claim 2, wherein the holding member is provided on a front surface and a rear surface of the plate-shaped valve that are brought into contact with the small-diameter step portion by the urging force of the urging unit. 4. A flow path blocking device mounted in a connected manner. 4. The flow path blocking device according to claim 1, wherein the cylinder is a tubular member that can be inserted into a gas pipe in an outer peripheral airtight state. 5. 4. The flow-path shut-off device according to claim 1, wherein the cylinder has a tapered thread portion at one end to which a general pipe can be connected, and a gas inlet tube at an upstream end of the gas meter at the other end. A flow path blocking device equipped with a screwable nut member. The flow path blocking device according to any one of claims 1 to 5, wherein the holding member is made of a thermoplastic synthetic resin, a bimetal, a shape memory alloy, or a low melting point metal.

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