JP5683423B2 - Sprinkler head - Google Patents

Description

  The present invention relates to a sprinkler head.

  The conventional sprinkler head includes: a main body that is connected to a water supply pipe and has a nozzle inside; a water stop portion that closes the nozzle by a thermal decomposition portion; a thermal decomposition portion that decomposes by heat; and a main body. A sprinkler head consisting of a frame that supports the thermal decomposition unit and a spray unit that sprays fire-fighting water supplied from the water supply pipe when the nozzle is open. There is a unit that is detachably installed with a unit assembled by a product (for example, see Patent Document 1).

  In the conventional sprinkler head, solder (low melting point alloy) is pressed against the piston in the cylinder, and the solder pressed against the piston in the cylinder can flow out in the event of a fire. Therefore, a gap for allowing the molten solder to flow out is provided between the cylinder inner peripheral surface and the piston outer peripheral surface. The solder is always exposed to the corrosive gas existing around the sprinkler head through this gap. Therefore, the solder may be corroded by the corrosive gas entering from the gap. When the solder is corroded, the melting point of the solder changes, which may make it difficult for the solder to melt. In this case, there is a possibility that the normal operation of the sprinkler head is hindered.

  Therefore, in a sprinkler head in which a heat sensitive body is provided in a cylinder and a piston is provided on the heat sensitive body, a sealing member having a melting temperature higher than that of the heat sensitive body and having corrosion resistance is provided in the cylinder. A sprinkler head has been proposed in which outside air is not brought into contact with the heat sensitive body by the sealing member (see, for example, Patent Document 2). This sprinkler head is provided with a sealing member to block the contact between the solder and the outside air, thereby preventing the corrosion of the solder.

JP 2003-339901 A JP 2007-236443 A

  In the conventional sprinkler head, since there is a gap provided between the inner circumferential surface of the cylinder and the outer circumferential surface of the piston, the solder creep phenomenon is also promoted. That is, since a load is always applied to the solder, the solder always tries to deform toward the gap. This state continues while the solder is being loaded. For this reason, the solder gradually flows out from the gap as time passes, and the sprinkler head operates when the outflow amount reaches a certain amount. That is, the gap provided between the cylinder inner peripheral surface and the piston outer peripheral surface is a factor that shortens the product life.

  The present invention has been made to solve the above-described problems, and protects solder from corrosive gas in normal times, suppresses solder creep phenomenon, and allows solder to flow out in the event of an abnormality such as a fire. An object of the present invention is to provide a sprinkler head that can open a gap.

The sprinkler head according to the present invention is provided in a cylindrical cylinder, solder provided in the cylinder, a piston that presses the solder, and at least a part of a gap serving as an outflow path of the solder or a part facing the gap. the reduced deformation in the center direction with the melting of semi-field, and a gap closing member for opening the gap between the installation portion, the gap is, the outer peripheral surface of the piston and the inner peripheral surface of the cylinder and The gap opening / closing member is installed so as to be in contact with the piston and the solder in the gap .

  According to the sprinkler head according to the present invention, by providing the gap opening / closing member, the gap is closed during normal times to protect the solder from corrosive gas, and the gap is opened so that the solder can flow out in the event of an abnormality such as a fire. It becomes possible to make it. That is, according to the sprinkler head of the present invention, the corrosion of the solder can be efficiently suppressed by the action of the gap opening / closing member, and the solder creep phenomenon can be efficiently suppressed. As a result, the product life can be extended.

It is a longitudinal cross-sectional view which shows an example of the cross-sectional structure of the sprinkler head which concerns on Embodiment 1 of this invention. It is a disassembled perspective view of the sprinkler head concerning Embodiment 1 of the present invention. It is a disassembled perspective view of the link mechanism of the sprinkler head which concerns on Embodiment 1 of this invention. It is the schematic explaining operation | movement of the sprinkler head which concerns on Embodiment 1 of this invention. It is explanatory drawing of the clearance opening / closing member of the sprinkler head which concerns on Embodiment 1 of this invention. It is a figure which shows some shapes of the gap opening / closing member of the sprinkler head which concerns on Embodiment 1 of this invention. It is explanatory drawing which shows another structural example of the gap | interval opening / closing member of the sprinkler head concerning Embodiment 1 of this invention. It is the longitudinal cross-sectional view which showed an example of the cross-sectional structure of the sprinkler head which concerns on Embodiment 2 of this invention. It is the schematic explaining operation | movement of the sprinkler head which concerns on Embodiment 2 of this invention. It is explanatory drawing for demonstrating the space | gap opening / closing member of the sprinkler head which concerns on Embodiment 2 of this invention.

Embodiment 1 FIG.
FIG. 1 is a longitudinal sectional view showing an example of a sectional configuration of a sprinkler head 100 according to Embodiment 1 of the present invention. FIG. 2 is an exploded perspective view of the sprinkler head 100. FIG. 3 is an exploded perspective view of the link mechanism 40. FIG. 4 is a schematic diagram for explaining the operation of the sprinkler head 100. The configuration and operation of the sprinkler head 100 will be described with reference to FIGS. In addition, in the following drawings including FIG. 1, the magnitude | size relationship between each structural member is not limited, and may differ from an actual thing.

[Configuration of Sprinkler Head 100]
As shown in FIG. 1, the sprinkler head 100 includes a head body 1, a frame 10, a valve body 20, an arm guide 30, a balancer 35, a link mechanism 40, a cover 61, and a heat sensitive plate 63.

(Head body 1)
The head main body 1 includes a screw portion provided on the outer periphery, a flange portion 3 provided on the lower end portion of the screw portion, and a screw portion integrally formed with the flange portion 3 on the lower end side outer periphery of the flange portion 3. The water outlet 5 is provided in the central portion so as to penetrate the screw portion, the flange portion 3 and the screw portion. And the lower part of the water discharge port 5 is expanded, the recessed part 6 in which the below-mentioned valve body 20 is accommodated is formed, and the valve seat 7 is provided between the water discharge port 5 and the recessed part 6. FIG.

(Frame 10)
The frame 10 has a bottomed cylindrical shape, and a screw portion that is screwed into the screw portion of the head main body 1 is provided on the upper portion of the inner wall, and below the screw portion (slightly below the central portion in the height direction). A locking step portion 12 is formed in which one end of an arm 41 described later is locked. A water spout 15 is formed below the locking step 12 of the frame 10.

(Valve 20)
The valve body 20 opens and closes the water outlet 5 of the head body 1.

(Arm guide 30)
The arm guide 30 is formed by bending a single metal plate. The arm guide 30 has a function of guiding the operation of the arm 41 described later.

(Balancer 35)
The balancer 35 is formed in a substantially U shape by bending a metal material. A downward load is applied to the center portion of the balancer 35 by the valve body 20 and an upward load from the link mechanism 40 is applied to both ends.

(Link mechanism 40)
As shown in FIG. 3, the link mechanism 40 includes a pair of arms 41, an arm support plate 46, a cylinder 50, a first piston 54, a link pressing plate 55, a second piston 59, and the like.

  As shown in FIG. 3, the arm 41 is formed with a head 42 bent outward in a substantially arc shape and wider than the head 42, and is bent outward (in a direction away from a cylinder described later) from the middle. Further, the leg portion 43 is formed in a substantially inverted J shape with the leg portion 43, and the leg portion 43 is provided with a first locking hole 44 and a second locking hole 45.

  In addition, the lower surface of the first locking hole 44 provided in the leg portion 43 of the arm 41 is formed as a downward slope from the outside to the inside, and the width of the head 42 is the width of the side wall of the balancer 35. The width of the leg portion of the balancer 35 is formed such that it can be loosely fitted between the guide pieces of the arm guide 30.

  The arm support plate 46 is formed in a substantially quadrangular shape by two straight sides and two arc-shaped sides, and a main body 47 having a through hole 48 at the center and a slight downward inclination from the two straight sides. And a locking piece 49 whose front end is bent obliquely downward. The locking piece 49 is disposed between the arms 41 and is locked in the first locking hole 44 of the arm 41. Is done.

  As shown in FIG. 3, the cylinder 50 is provided with a flange portion 51 at a substantially central portion in the height direction of the outer wall, and with a threaded portion 52 protruding from the lower surface. The cylinder 50 is inserted into the through hole 48 of the arm support plate 46 until the collar portion 51 comes into contact therewith, and is fixed integrally with the arm support plate 46 at that position. Solder 99 made of, for example, compression solder is accommodated in the cylinder 50. The first piston 54 has an outer diameter slightly smaller than the inner diameter of the cylinder 50 and is slidably accommodated in the cylinder 50 so as to press the solder 99. That is, in a state where the first piston 54 is accommodated in the cylinder 50, the gap 95 serving as an outflow path for the solder 99 to flow out between the inner peripheral surface of the cylinder 50 and the outer peripheral surface of the first piston 54. Is formed.

  Further, a gap opening / closing member 90 is provided on the periphery of the upper surface of the solder 99. The gap opening / closing member 90 will be described in detail later. The gap 95 described in the first embodiment is opened upward.

  As shown in FIG. 3, the link retainer plate 55 has a rectangular main body 56 having a screw hole 57 at the center and slightly narrower than the width of the main body 47 of the arm support plate 46, and fittings projecting on both sides thereof. The fitting piece 58 is formed between the both arms 41 and is loosely fitted into the second locking holes 45 of the both arms 41. The second piston 59 has a screw portion 60 provided at one end screwed into the screw hole 57 of the link presser plate 55 and the other end abutting the first piston 54.

(Cover 61)
The cover 61 also serves as a heat receiving plate and covers the link mechanism 40 and the like from below. The cover 61 covers the lower surface of the frame 10 and the link mechanism 40 by passing the hole in the center of the cover 61 through the screw part 52 protruding to the center and then screwing the center of the heat sensitive plate 63. Fixed. Note that the cover 61 may be extended to a height at which the upper end thereof covers the water spout 15 of the frame 10. Further, a screw portion 62 into which the screw portion 52 is screwed is provided at the center of the heat sensitive plate 63.

(Thermal plate 63)
The heat sensitive plate 63 is provided below the cover 61 so as to fix the cover 61.

  The sprinkler head 100 configured as described above is inserted from a hole provided in a ceiling of a building, and a screw portion is screwed into a water supply pipe (not shown) disposed in the ceiling hole to be connected to the ceiling surface. A part (about half of the total length) is exposed from the ceiling surface.

[Operation of Sprinkler Head 100]
Now, a fire has occurred and the cover 61 and the heat sensitive plate 63, which also serve as a heat receiving plate, are heated, and the solder 99 is heated by the heat and a hot airflow from the periphery. When the solder 99 starts to melt, a part of the melted solder 99 flows out from the gap 95 formed between the cylinder 50 and the first piston 54. Then, the cylinder 50 and the arm support plate 46 fixed to the cylinder 50 are lifted, and at least one arm 41 of both the arms 41 is rotated outward with the locking portion with the locking step portion 12 of the frame 10 as a fulcrum. To do.

  As a result, at least one arm 41 of both arms 41 is disengaged from the arm support plate 46, and the link mechanism 40 is disassembled. Thereby, the link mechanism 40 and the balancer 35 including the cover 61 fall outside.

  At the same time, the arm guide 30 integrated with the valve body 20 is lowered along both side edges of the opening of the frame 10 by its own weight and the pressure of the fire extinguishing water, and the flange portion of the valve body 20 is seated on the bottom of the frame 10. Then, the opening of the frame 10 is closed. As a result, the water outlet 5 is opened, and the fire extinguishing water is sprinkled from the water spout 15 through the frame 10.

  5A and 5B are explanatory views of the gap opening / closing member 90. FIG. 5A is a schematic enlarged cross-sectional view schematically showing a cross-section of the cylinder 50 in a normal state, and FIG. It is the general | schematic expanded sectional view which expanded the cross section of the cylinder 50 in the state of (at the time of fusion | melting) roughly expanded. FIG. 6 is a view showing several shapes of the gap opening / closing member 90. FIG. 7 is an explanatory view showing another configuration example of the gap opening / closing member 90. The gap opening / closing member 90 will be described in detail with reference to FIGS.

  As described above, in the state where the first piston 54 is housed in the cylinder 50, the gap 95 for the solder 99 to flow out between the inner peripheral surface of the cylinder 50 and the outer peripheral surface of the first piston 54. Is formed. In this state, the solder 99 is always exposed to the outside air (corrosive gas). When the corrosive gas enters from the gap 95, the solder 99 may be corroded by the corrosive gas. When the solder 99 is corroded, the melting point thereof is changed, which may make it difficult to melt. Further, since the gap 95 exists, the creep phenomenon of the solder 99 is also promoted. That is, since the solder 99 is constantly loaded by the first piston 54, the solder 99 always tries to deform toward the gap 95.

  Therefore, in the sprinkler head 100, a step portion 96 is provided on the periphery of the upper surface of the solder 99, which has conventionally been a columnar shape, and a gap opening / closing member 90 is installed on the step portion 96. In other words, the gap opening / closing member 90 is provided in a portion facing the gap 95. The gap opening / closing member 90 has a rectangular shape as shown in FIG. 6, for example. In addition, as shown in FIG. 6, the gap opening / closing member 90 has a ring shape in a plan view, a shape in which a part of the ring is cut out (C ring shape), or a part in which the ring is cut out to overlap the end portion. It is formed in a combined shape (coil shape) or the like. By forming a notch in a part of the gap opening / closing member 90, the deformation amount in the center direction of the gap opening / closing member 90 can be adjusted. The gap opening / closing member 90 and the step 96 have the same height, or the gap opening / closing member 90 is lower.

  As shown in FIG. 5, the gap opening / closing member 90 normally closes the gap 95 to suppress the intrusion of corrosive gas from the gap 95 and to suppress the creep phenomenon of the solder 99. On the other hand, when the solder 99 starts to melt, the gap opening / closing member 90 contracts toward the center until, for example, the outer diameter thereof becomes the same as the inner diameter of the first piston 54, opens the gap 95, and the solder 99 flows out. The road is secured.

  The gap opening / closing member 90 is formed of a member that can expand and contract in the center direction by, for example, elastic deformation, thermal deformation, or the like. The gap opening / closing member 90 is provided in the solder 99 or the step portion 96 of the first piston 54 in a state of being opened larger than normal. Due to the fire, the solder 99 is melted and softened to return to the normal size. The expansion / contraction in the center direction of the gap opening / closing member 90 may be such that the gap 95 is opened so that the solder 99 can flow out. That is, the normal outer diameter of the gap opening / closing member 90 is the same as or smaller than the inner diameter of the first piston 54. The constituent material of the gap opening / closing member 90 is not particularly limited. For example, the gap opening / closing member 90 may be made of a resin material or a metal material having the above-described properties. Since it has such a property, the gap opening / closing member 90 is deformed in the center direction by the melting (liquefaction) of the solder 99 as a trigger. The gap opening / closing member 90 may have a disk shape in addition to the planar shape shown in FIG. The gap opening / closing member 90 only needs to be able to close at least a part of the gap 95 in a normal state, and does not necessarily need to close the entire gap 95. Furthermore, the cross-sectional shape of the gap opening / closing member 90 is not limited to a rectangular shape, and the cross-sectional shape may be a circular shape or an elliptical shape (see FIG. 7B).

  FIG. 5 shows an example in which the step 96 is formed on the solder 99 side and the gap opening / closing member 90 is installed. However, as shown in FIG. The step opening portion 96 may be formed and the gap opening / closing member 90 may be installed. In this case, in order to guide the contraction of the gap opening / closing member 90 toward the center side, the wall surface on the center side of the step portion 96 may be inclined as shown in FIG. Even when the gap opening / closing member 90 is installed in the step portion 96 of the first piston 54, the gap opening / closing member 90 having the shape shown in FIG. 6 can be applied. In this case, the solder may be cylindrical.

  That is, in the sprinkler head in which the gap 95 is formed between the inner peripheral surface of the cylinder 50 and the outer peripheral surface of the piston 54, the gap opening / closing member 90 is provided so as to contact the piston 54 and the solder 99 with the gap 95. Will be. Further, the piston 72 or the solder 99 has a stepped portion or a tapered portion at a position in contact with the gap opening / closing member 90.

[Effects of the sprinkler head 100]
According to the sprinkler head 100 according to the first embodiment, since the gap opening / closing member 90 is installed, the gap is closed during normal operation to protect the solder 99 from the corrosive gas, and the solder 99 can flow out in the event of an abnormality such as a fire. Thus, the gap 95 can be opened. That is, according to the sprinkler head 100, the corrosion of the solder 99 can be efficiently suppressed by the action of the gap opening / closing member 90, and the creep phenomenon of the solder 99 can be efficiently suppressed. As a result, the life of the sprinkler head 100 can be extended.

Embodiment 2. FIG.
FIG. 8 is a longitudinal sectional view showing an example of a sectional configuration of a sprinkler head 100A according to Embodiment 2 of the present invention. FIG. 9 is a schematic diagram for explaining the operation of the sprinkler head 100A. Based on FIG.8 and FIG.9, the structure and operation | movement of 100 A of sprinkler heads are demonstrated. In the second embodiment, the difference from the first embodiment will be mainly described, and the description of the same parts as those in the first embodiment will be omitted. Further, “A” is appended to the end of the reference numerals for members corresponding to the first embodiment.

(Valve support mechanism 120)
The valve body support mechanism 120 includes a heat sensitive part 121, a ball holding mechanism 130, and a set screw 65.

  The heat sensitive unit 121 includes a piston 72, a heat sensitive plate 73, a heat sensitive plate 81, and a heat insulating material 74. The piston 72 is formed in a cylindrical shape, and a flange 72a is formed in the lower part. An internal thread 72b is formed inside the piston 72, and the external thread on the leg portion of the set screw 65 is screwed in to couple the two. A donut-shaped solder 99 </ b> A is inserted from the upper part of the piston 72 and is placed on the flange 72 a of the piston 72. On top of this solder 99A, there is provided a heat sensitive plate 73 which is disc-shaped and has a crank section and constitutes a cylinder. That is, the heat sensitive plate 73 has a protrusion (vertical portion) 73a covering the solder 99A provided on the flange 72a of the piston 72, and a direction continuous to the protrusion 73a and perpendicular to the axis of the head body 1A. And a disc portion 73b extending in the direction.

  A force is applied to the piston 72 so as to compress the solder 99A by a ball holding mechanism 130 described later. In addition, a gap 95A is formed between the outer peripheral surface of the flange 72a of the piston 72 and the inner peripheral surface of the heat sensitive plate 73 (projection 73a) serving as a cylinder for allowing the solder 99A to flow out. Further, a gap opening / closing member 90A is provided on the lower surface periphery of the solder 99A. The gap opening / closing member 90A will be described in detail later. The gap 95A described in the second embodiment is a downward opening type that is open downward, and the solder 99A flows downward.

  A donut-shaped heat insulating material 74 is provided on the heat sensitive plate 72 so that the heat received by the heat sensitive plate 73 does not escape to the balancer 133 described later. Further, another heat sensitive plate 81 is provided between the heat insulating material 74 and the heat sensitive plate 73.

  The ball holding mechanism 130 includes a ball 131, a slider 132, and a balancer 133.

  The lower outer periphery of the ball 131 is locked to the locking step 12A of the frame 10A. In this state, it is the slider 132 that presses the ball 131 from above, and when a force is applied from the slider 132 to the ball 131, a force acts on the ball 131 in the inward direction. The balancer 133 is provided inside the ball 131 and regulates the movement of the ball 131 trying to enter inside the ball 131. Both the slider 132 and the balancer 133 are formed in a disk shape, and there is a through hole in the center, and a set screw 65 passes through the through hole of the balancer 133. The through hole of the balancer 133 is slightly larger than the outer diameter of the set screw 65, and the two are not coupled.

  The balancer 133 has a stepped portion at the lower outer periphery. The step portion at the lower outer periphery is configured to contact the step portion at the lower inner periphery of the locking step portion 12A of the frame 10A, and when an external force is applied from the lower side of the balancer 133, Absorb the shock at the part. In addition, a stepped portion 133 a into which the heat insulating material 74 is fitted protrudes around the central through hole of the balancer 133, and an inclined portion 133 b to which the ball 131 hits is formed at the upper portion of the balancer 133.

  A recess 132a is formed in the lower portion of the outer periphery of the slider 132, and the surface of the recess 132a that contacts the ball 131 is formed in a tapered shape (inclined portion) so as to be inclined inwardly downward.

  The spring force of the disc spring 32 is transmitted to the ball 131 through the valve body 20A and the set screw 65 via the slider 132, and a force is applied so that the ball 131 always moves inward. As a result, the balancer 133 is moved downward. A force acts to move it. Therefore, if the solder 99A melts and flows out, the balancer 133 moves downward, and accordingly, the ball 131 enters inside, and the locked state with the locking step portion 12A of the frame 10A is released. The ball holding mechanism 130 falls together with the heat sensitive part 121. If the ball holding mechanism 130 falls, the valve body 20A, the stopper ring 113, etc. which comprise the water sprinkling part 110 will fall in connection with it, and water discharge will be performed.

  The set screw 65 is a bolt composed of a head and a leg, and the lower part of the leg is coupled to the upper part of the piston 72, so that the balancer 133, the slider 132, and the heat sensitive part 121 as the ball holding mechanism 130 are connected. It is integrated.

  In the sprinkler head 100A as described above, in the state shown in FIG. 8, the water pressure of the fire extinguishing water at the outlet 5A and the assembly load of the parts act on the ball 131, and the ball 131 tends to move inward (center side). However, the movement of the ball 131 is blocked by the balancer 133, and the ball holding mechanism 130 holds the ball 131. In this state, the valve body 20A and the disc spring 32 seal the water outlet 5A of the head body 1A. For this reason, although the pressurized fire extinguishing water is supplied to the sprinkler head 100A, the fire extinguishing water does not leak. Further, in the water sprinkling part 110, the deflector 111 is fixed to the valve body 20A, the guide rod 112 is fixed to the deflector 111, and the guide rod 112 is the head when the valve body 20A seals the water outlet 5A. It is in a state of being housed in the space 18 of the main body 1A.

[Operation of Sprinkler Head 100A]
As shown in FIG. 8, in the monitoring state of the sprinkler head 100A, pressurized fire extinguishing water is supplied to the water outlet 5A of the head main body 1A, and the pressure of the fire extinguishing water is applied to the valve body 20A. Yes. When a fire occurs and the hot airflow hits the heat sensitive plate 73 and the heat sensitive plate 81, they are heated, and the heat of the heat sensitive plate 73 and the heat sensitive plate 81 propagates to the solder 99A. When the solder 99A starts to be heated and melted from the surroundings, the melted solder 99A flows out from the gap 95A formed between the piston 72 and the heat sensitive plate 73 (projection 73a), and its volume decreases.

  As shown in FIG. 9A, when the solder 99A is melted and flows out, the heat sensitive plate 73 and the heat sensitive plate 81 descend according to the amount of the solder 99A flowing out. When the heat sensitive plate 73 and the heat sensitive plate 81 are lowered, the heat insulating plate 74 and the balancer 133 attached on the heat sensitive plate 73 and the heat sensitive plate 81 are lowered.

  As shown in FIG. 9B, when the balancer 133 is lowered, the gap between the balancer 133 and the slider 132 is widened, and the ball 131 biased inwardly passes over the inclined portion 133b of the balancer 133 to the inside. Then, the engagement between the locking step 12A of the frame 10A and the ball 131 is released. Thereby, the valve body 20A and the valve body support mechanism 120 are lowered.

  As shown in FIG. 9C, when the valve body support mechanism 120 including the disc spring 32 disposed below the valve body 20A falls, the valve body 20A descends. As the valve body 20A is lowered, the deflector 111 attached to the valve body 20A, the guide rod 112 attached to the deflector 111, and the stopper ring 113 are lowered. When the guide rod 112 is lowered, the stopper ring 113 is locked to the locking step portion 12A of the frame 10A, and the valve body 20A and the deflector 111 are suspended from the frame 10A by the guide rod 112.

  In the second embodiment, the deflector 111 descends together with the guide rod 112 during the water discharge operation, so that the descending operation of the deflector 111 is smoothly performed.

  As described above, when the valve body 20A is lowered, the water outlet 5A is opened, and the pressurized fire extinguishing water is sprayed from the deflector 111 to extinguish the fire.

  FIG. 10 is an explanatory diagram for explaining the gap opening / closing member 90A. The gap opening / closing member 90A will be described in detail with reference to FIG.

  As described above, the gap 95A for allowing the solder 99A to flow out is formed between the outer peripheral surface of the flange 72a of the piston 72 and the inner peripheral surface of the heat sensitive plate 73 (projection 73a). In this state, the solder 99A is always exposed to the outside air (corrosive gas). Further, since the solder 99A is constantly loaded by the heat sensitive plate 73, the solder 99A always tries to deform toward the gap 95A.

  Therefore, in the sprinkler head 100A, the gap opening / closing member 90A is installed on the periphery of the lower surface of the solder 99A. The gap opening / closing member 90A has a circular shape as shown in FIG. 10, for example. The gap opening / closing member 90A is formed in a planar shape as described in the first embodiment. As with the gap opening / closing member 90, the gap opening / closing member 90A normally closes the gap 95A to suppress the intrusion of corrosive gas from the gap 95A and to suppress the creep phenomenon of the solder 99A. On the other hand, when the solder 99A starts to melt, the gap opening / closing member 90A shrinks toward the center due to heat at the time of the fire, thereby opening the gap 95A and securing the outflow path of the solder 99A.

  The gap opening / closing member 90A is formed of a member that can expand and contract in the center direction by, for example, elastic deformation, thermal deformation, or the like. Although the constituent material of the gap opening / closing member 90A is not particularly limited, for example, the gap opening / closing member 90A may be made of a resin material or a metal material having the above properties. Since it has such properties, the gap opening / closing member 90A is deformed in the center direction by the melting (liquefaction) of the solder 99A as a trigger. The gap opening / closing member 90A may have a disk shape or a cylindrical shape in addition to the planar shape shown in FIG. The gap opening / closing member 90A only needs to be able to close at least a part of the gap 95A in a normal state, and does not necessarily need to close the entire gap 95A. Furthermore, the cross-sectional shape of the gap opening / closing member 90A is not limited to a circular shape, and the cross-sectional shape may be a rectangular shape or an elliptical shape.

  Further, in FIG. 10, the peripheral edge of the upper surface of the flange 72a of the piston 72 is cut away so as to secure the installation location of the gap opening / closing member 90A. In this case, in order to guide the contraction of the gap opening / closing member 90A toward the center side, the periphery of the upper surface of the flange 72a may be inclined as shown in FIG. Alternatively, the gap opening / closing member 90A may be installed by forming a step (a step corresponding to the step 96 described in the first embodiment) on the solder 99 side.

  That is, in the sprinkler head in which the gap 95A is formed between the inner peripheral surface of the heat-sensitive plate 73 serving as a cylinder and the outer peripheral surface of the flange 72a, the gap opening / closing member 90A is the gap 95A and the flange 72a. And in contact with the solder 99A. Further, the piston 72 or the solder 99A has a stepped portion or a tapered portion at a position in contact with the gap opening / closing member 90A.

[Effects of the sprinkler head 100A]
According to the sprinkler head 100A according to the second embodiment, since the gap opening / closing member 90A is installed, the gap is normally closed to protect the solder 99A from the corrosive gas, and the solder 99A can flow out in the event of an abnormality such as a fire. Thus, the gap 95A can be opened. That is, according to the sprinkler head 100A, the corrosion of the solder 99A can be efficiently suppressed by the action of the gap opening / closing member 90A, and the creep phenomenon of the solder 99A can be efficiently suppressed. As a result, the life of the sprinkler head 100A can be extended.

  DESCRIPTION OF SYMBOLS 1 Head main body, 1A Head main body, 3 flange part, 3A flange part, 5 water outlet, 5A water outlet, 6 recessed part, 7 valve seat, 7A valve seat, 10 frame, 10A frame, 12 locking step part, 12A locking Step part, 15 Water spout, 18 space, 19 Water discharge pipe, 20 Valve body, 20A Valve body, 20a Valve body, 20b Flange part, 20bA Flange part, 20c Caulking piece, 21 Protruding part, 23 Upper surface, 23a Packing, 30 arm Guide, 32 Disc spring, 35 Balancer, 40 Link mechanism, 41 Arm, 42 Head, 43 Leg, 44 First locking hole, 45 Second locking hole, 46 Arm support plate, 47 Main body, 48 Through Hole, 49 Locking piece, 50 cylinder, 51 collar part, 52 threaded part, 54 1st piston, 55 link presser plate, 56 body, 57 Hole, 58 fitting piece, 59 second piston, 60 threaded portion, 61 cover, 62 threaded portion, 63 heat sensitive plate, 65 set screw, 72 piston, 72a flange, 72b threaded portion, 73 heat sensitive plate, 73a protruding portion, 73b disc part, 74 heat insulating material, 81 heat sensitive plate, 90 gap opening / closing member, 90A gap opening / closing member, 95 gap, 95A gap, 96 step part, 99 solder, 99A solder, 100 sprinkler head, 100A sprinkler head, 110 watering part , 111 Deflector, 112 Guide rod, 113 Stopper ring, 120 Valve body support mechanism, 121 Heat sensitive part, 130 Ball holding mechanism, 131 Ball, 132 Slider, 132a Recess, 133 Balancer, 133a Step part, 133b Inclined part.

Claims (4)

A cylindrical cylinder;
Solder provided in the cylinder;
A piston that presses the solder;
A gap opening / closing member that is provided in at least a part of the gap serving as an outflow path of the solder or a portion facing the gap, shrinks and deforms in the central direction as the solder melts, and opens the gap of the installed part; equipped with a,
The gap is formed between the inner peripheral surface of the cylinder and the outer peripheral surface of the piston,
The sprinkler head , wherein the gap opening / closing member is installed in contact with the piston and the solder in the gap . A cylindrical cylinder;
Solder provided in the cylinder;
A piston on which the solder is placed, and a piston that presses the solder;
A gap opening / closing member that is provided in at least a part of the gap serving as an outflow path of the solder or a portion facing the gap, shrinks and deforms in the central direction as the solder melts, and opens the gap of the installed part; equipped with a,
The sprinkler head , wherein the gap is formed between an inner peripheral surface of the cylinder and an outer peripheral surface of the flange . The sprinkler head according to claim 2 , wherein the gap opening / closing member is installed in contact with the flange and the solder in the gap . The sprinkler head according to any one of claims 1 to 3 , wherein the piston or the solder has a stepped portion or a tapered portion at a position in contact with the gap opening / closing member.

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