JP4510965B2 - Operation detection device and sprinkler fire extinguishing device - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an operation detection device used in a sprinkler fire extinguishing device and a sprinkler fire extinguishing device including the operation detection device.
[0002]
[Prior art]
The sprinkler fire extinguishing device is generally provided with an operation detection device that detects that the device has been operated. Conventionally, as shown in FIG. 4, a tank 230 connected to a pipe 210 of a sprinkler fire extinguishing device via a pipe 220 provided with a throttle 221 in the middle, and an air pressure in the tank 230 as the operation detecting device. And a pressure switch 240 that detects the above.
[0003]
In the operation detection device 200, when the sprinkler fire extinguishing device is operated, the fire-extinguishing water 250 flowing through the pipe 210 of the device flows into the tank 230 through the pipe 220 having the throttle 221. When the air 260 in the tank 230 is compressed by 250 and the air pressure rises, the pressure switch 240 detects it and is turned on. Here, the pressure switch 240 is connected to, for example, an alarm device attached to the sprinkler fire extinguisher. When the pressure switch 240 is turned on as described above, the alarm device is activated, and the fire station or the like is related. It is possible to report the occurrence of fire to various places and operate fire doors.
[0004]
[Problems to be solved by the invention]
The sprinkler fire extinguishing apparatus is installed in a building such as a building. However, the above-described operation detection apparatus 200 requires a tank 230 having a large capacity, and the installation space of the tank 230 is equivalent to the living space of the building. There is a problem that it is necessary to divide a certain amount. Further, such a large capacity tank 230 and pressure switch 240 are generally expensive, and it is desired to reduce the cost of disaster prevention facilities.
[0005]
Further, in the operation detection device 200 described above, the alarm switch is operated by detecting that the air pressure in the tank 230 has been increased by the pressure switch 240, and therefore, the connecting portion between the tank 230 and other components, When air leakage occurs due to a crack or the like generated in the tank 230, the pressure switch 240 is activated because the air pressure in the tank 230 does not increase even if the fire-extinguishing water 250 flows into the tank 230 when the sprinkler fire extinguishing device is activated. May remain off. For this reason, when such an abnormality occurs, the alarm device does not operate, and there is a problem that it is not possible to report to various places related to the occurrence of a fire.
[0006]
Further, for example, as shown in FIG. 5, the primary side pipe 340 that connects the water storage tank 310, the fire extinguishing pump 320, and the valve 330 and the secondary side pipe 360 that connects the valve 330 and the sprinkler head 350 are always connected. In the sprinkler fire extinguishing apparatus 300 that is pressurized by fire-extinguishing water, when water leakage occurs in the secondary side pipe 360, a pressure difference occurs between the front and rear of the valve 330, so that the valve body of the valve 330 is opened. The fire-extinguishing water filled in the primary side pipe 340 flows into the secondary side pipe 360, and the air pressure in the tank 230 connected to the secondary side pipe 360 may temporarily increase. However, even when the sprinkler fire extinguishing device 300 is not actually operated in this way, in the operation detection device 200 described above, the pressure switch 240 detects the temporary increase in air pressure, and is turned on. There is a problem that the alarm device 370 is activated and an alarm (false alarm) is transmitted to various places.
[0007]
The present invention has been made in view of the above points, and an object thereof is to provide a small and inexpensive operation detection device. It is another object of the present invention to provide an operation detection device that can reliably detect the operation of a sprinkler fire extinguishing device even when an abnormality occurs in the device itself. It is another object of the present invention to provide an operation detection device that can prevent malfunction of an alarm device or the like connected to a switch. It is another object of the present invention to provide a sprinkler fire extinguishing device including such an operation detection device.
[0008]
[Means for Solving the Problems]
In order to solve the above-described problem, an operation detection device according to the present invention is a pressing shaft provided in a valve of a sprinkler fire extinguishing device, and water for extinguishing water in the valve during operation of the sprinkler fire extinguishing device. is compressed when the input means for moving by being pressed by the pressing pressure bearings that protrudes outwardly of the valve with increasing pressure, the input means being pressed into the pressing axis, said input means A spring that delays movement, a piston rod that moves due to the spring force of the spring when the input means is pressed against the pressing shaft, and a casing that moves when the piston rod moves due to the spring force of the spring A piston formed in the liquid chamber filled with the liquid, and the piston when the piston rod is moved by the elastic force of the spring. A return spring that is compressed by the movement of emissions, the piston rod is moved by the movement of the piston when moved by the elastic force of the spring, on - and output means capable of turning on the switch capable off switching And the spring, piston rod, piston, and return spring are provided between the input means and the output means .
Sprinkler fire extinguishing apparatus of the present invention according to claim 2, a valve to be opened by the operation of the sprinkler head, provided in the valve, projecting with increasing pressure of extinguishing water in the valve to the outside of the valve The press shaft which performs and the operation | movement detection apparatus of Claim 1 are comprised.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a cross-sectional view showing an operation detection device 1 according to an embodiment of the present invention. As shown in the figure, the operation detection device 1 includes a casing 2, an input unit 3, an output unit 4, a delay unit 5, a spring 6, and a switch 7.
[0010]
The casing 2 includes a first cylinder portion 21 that constitutes one end side of the casing 2, a lid member 23 that closes one end portion of the first cylinder portion 21 (one end of the casing 2), It is connected to the other end of the cylinder part 21 and has a second cylinder part 22 constituting the other end side of the casing 2.
[0011]
The first tube portion 21 is formed in a substantially cylindrical shape, and external screws 21 a and 21 b are formed on the outer periphery on each end side.
At one end portion of the first cylindrical portion 21, a base portion 81 formed with an inner screw that can be screwed to an outer screw 21a formed on the outer periphery thereof, and two protruding pieces 82 protruding from the base portion 81, A guide member 8 configured with 82 is attached.
The guide member 8 plays a role of holding a track of a contact portion 32 to be described later, and the contact portion 32 to be described later is disposed between the two protruding pieces 82 and 82 of the guide member 8. By this, it moves in the axial direction along the projecting pieces 82, 82.
In addition, a partition wall portion 24 is disposed inside the first tube portion 21 at approximately the center in the axial direction so as to bisect the inside of the first tube portion 21. A piston rod insertion hole 24a through which a piston rod 51 described later is inserted is formed at substantially the center.
[0012]
The lid member 23 is formed in a substantially disc shape having an input shaft insertion hole 23a through which an input shaft 31 (described later) is inserted at a substantially center thereof, and one end portion of the opened first cylinder portion 21 is formed. It arrange | positions so that it may block | close.
The lid member 23 closes one end portion of the first cylinder portion 21, so that the lid member 23 and the first cylinder portion are provided inside the one end portion side of the first cylinder portion 21. A first chamber 26 surrounded by an inner peripheral surface of one end portion 21 and a partition wall portion 24 is formed, and a spring 6 described later is disposed in the first chamber 26.
[0013]
The second cylindrical portion 22 is formed by integrally forming a large diameter portion 22a formed in a substantially cylindrical shape and a small diameter portion 22b having an outer diameter smaller than the large diameter portion 22a. The inner screw formed on the inner periphery on one end side of the first screw and the outer screw 21b formed on the outer periphery on the other end side of the first cylindrical portion 21 are screwed together to form the first Is connected to the other end of the cylindrical portion 21.
Inside the large-diameter portion 22a, an output shaft as an output means 4 to be described later is inserted into a hole portion 25a formed so as to penetrate along the axis, and a groove formed in one end wall A cylindrical member 25 that can lock the other end of the return spring 53 by inserting the other end of the return spring 53 described later is disposed in 25b.
As described above, the second cylindrical portion 22 is connected to the first cylindrical portion 21, so that the cylindrical member 25 and the first cylindrical portion 25 are provided inside the first cylindrical portion 21 on the other end side. A second chamber (liquid chamber) 27 surrounded by the inner peripheral surface on the other end side of the one cylindrical portion 21 and the partition wall portion 24 is formed, and the liquid chamber 27 is filled with the liquid 9. Yes. As the liquid 9, silicon oil or the like can be used.
An output shaft as the output means 4 to be described later is inserted through a hole 22c formed so as to penetrate along the axis of the small diameter portion 22b. Further, a nut 22e for attaching a switch box 72 (to be described later) to the second cylindrical portion 22 is screwed onto the external screw 22d formed on the outer periphery of the small diameter portion 22b.
[0014]
The input means 3 includes an input shaft 31 having a substantially T-shaped cross section, and a contact portion 32 attached to the distal end portion 31a of the input shaft 31.
The input shaft 31 is disposed so that the front end portion 31a protrudes outward from the lid member 23, and the rear end portion 31b is disposed in the first chamber 26 formed in the first cylindrical portion 21 described above. The shaft portion is inserted through the input shaft insertion hole 23 a of the lid member 23 and is disposed along the axis of the casing 2.
The abutting portion 32 is formed such that a part of the lower end surface is inclined, and a groove 32a for holding a track of a pressing shaft provided in a valve of a sprinkler fire extinguishing device described later is formed on the inclined surface. It is installed.
In the figure, reference numeral 10 denotes a collar. By adjusting the width of the collar 10, the length of the input means 3 protruding from the casing 2 can be adjusted.
[0015]
The output means 4 includes an output shaft formed by including a shaft portion 41 having a predetermined length and an end wall 42 having a diameter larger than the diameter of the shaft portion 41.
In the output shaft 4, the shaft portion 41 is inserted into the hole portion 25 a formed in the cylindrical member 25 and the hole portion 22 c formed in the small diameter portion 22 b constituting the second tube portion 22. The distal end portion 41a is disposed so as to protrude outward from the small diameter portion 22b of the second cylindrical portion 22, and an end wall 42 constituting the rear end portion of the output shaft 4 is formed in a piston 52 described later. It arrange | positions along the axial center of the casing 2 so that it may contact | abut and arrange | position to the bottom wall of the recessed part 52a.
The output shaft 4 arranged in this way is arranged coaxially with the input means 3 described above, and moves forward and backward according to the operation of the input means 3 as will be described later.
[0016]
The slowing means 5 includes a piston rod 51, a piston 52, and a return spring 53.
The piston rod 51 is inserted into a piston rod insertion hole 24a formed in the partition wall 24, and the tip thereof is disposed in contact with a second spring guide 62 described later.
The piston 52 is disposed in contact with the rear end of the piston rod 51. The piston 52 is formed integrally with the piston rod 51, and has a concave shape having a predetermined depth at the approximate center of its upper end surface. A portion 52a is formed.
The piston 52 is disposed in a liquid chamber 27 formed in the casing 2, and moves in the axial direction as the piston rod 51 moves back and forth in the liquid chamber 27 filled with the liquid 9. ing.
In addition, in order to reduce liquid leakage from the outer periphery of the piston 52 to the outer periphery of the piston 52 and the inner surface of the peripheral wall of the liquid chamber 27 (the inner peripheral surface on the other end side of the first cylindrical portion 21). The piston ring 52b is disposed.
The piston 52 is formed with an orifice (not shown) formed of a small hole penetrating in the axial direction, and the liquid 9 pressed by the movement of the piston 52 in the liquid chamber 27 passes through the orifice. Thus, the fluid flows in the liquid chamber 27.
The return spring 53 is formed of a coil spring, and is arranged such that one end is in contact with the end wall 42 of the output shaft 4 and the other end is in contact with the bottom wall of the groove 25b formed in the tubular member 25 described above. The piston 52 is urged toward the one end of the casing 2.
[0017]
The spring 6 is composed of a coil spring, and is disposed opposite to each other in the first chamber 26 formed in the first cylindrical portion 21 so as to be provided between the input means 3 and the delay means 5 described above. Between the provided first and second spring guides 61 and 62, they are loaded along the axial direction.
Specifically, the first and second spring guides 61 and 62 have base portions 61 a and 62 a having an outer diameter larger than the outer diameter of the spring 6 and protrusions having an outer diameter smaller than the inner diameter of the spring 6, respectively. It has parts 61b and 62b. The first spring guide 61 is disposed such that its base portion 61 a comes into contact with the rear end portion 31 b of the input shaft 31, and the second spring guide 62 is arranged so that its base portion 62 a comes into contact with the tip end of the piston rod 51. It is installed. The one end of the spring 6 abuts the base 61a of the first spring guide 61 so that one end of the spring 6 surrounds the protrusion 61b of the first spring guide 61, and the other end is the second spring. The other end is disposed in contact with the base 62a of the second spring guide 62 so as to surround the protrusion 62b of the guide 62.
In the figure, reference numeral 11 denotes a bush, and this bush 11 is disposed in a first chamber 26 formed in the first tube portion 21, and includes an input shaft 31, first and second springs. It functions as a guide that holds the tracks of the guides 61 and 62.
[0018]
The switch 7 is a limit switch that includes a contact mechanism and a lever 71 that operates the contact mechanism. The limit switch 7 projects outward from the small-diameter portion 22b of the second cylindrical portion 22. When the output shaft 4 moves forward, the lever 71 is pushed up by the output shaft 4 and is disposed in a switch box 72 attached to the second cylindrical portion 22.
The limit switch 7 is connected to an alarm device attached to the sprinkler fire extinguishing device. When the lever 71 is pushed up by the output shaft 4 moving upward, the alarm switch is turned on. Yes. On the other hand, when the output shaft 4 moves backward and the force that pushes up the lever 71 is removed, the lever 71 returns to the initial position and the limit switch 7 is turned off.
[0019]
For example, as shown in FIG. 2, the operation detection device 1 configured as described above includes a water storage tank 110, a fire extinguishing pump 120, a valve 130, a primary side pipe 140 connecting these, a sprinkler head 150, a valve 130 and a sprinkler fire extinguishing apparatus 100 having a secondary side pipe 160 connecting the sprinkler head 150 and applying pressure to the primary side pipe 140 and the secondary side pipe 160 with water for fire extinguishing during normal times. In this case, the sprinkler fire extinguishing apparatus 100 is attached to a valve 130 and used.
[0020]
More specifically, as shown in FIG. 3, the valve 130 is provided with a pressing shaft 130b protruding from the valve box 130a of the valve 130, and a plate 130c provided at the protruding opening of the pressing shaft 130b. The one protruding piece 82 constituting the guide member 8 of the operation detecting device 1 is connected, and the tip of the protruding pressing shaft 130b comes into contact with the groove 32a formed in the contact portion 32 constituting the input means 3. In addition, the operation detection device 1 is attached to the valve 130. Here, when the pressure of the fire-extinguishing water in the valve 130 rises to a predetermined level or more, the pressing shaft 130b receives the water pressure and protrudes outward from the valve 130. When the pressure of the fire-extinguishing water decreases, the pressing shaft 130b moves inward. It is arrange | positioned so that it may reverse | retreat.
[0021]
In the sprinkler fire extinguishing apparatus 100 described above, when a fire occurs and the temperature rises, the sprinkler head 150 is activated, and the fire-fighting water filled in the secondary side pipe 160 is discharged from the water discharge port. Due to this water discharge, the pressure in the secondary side pipe 160 is reduced, whereby the valve body of the valve 130 is opened and the secondary side pipe 160 and the primary side pipe 140 are in communication with each other. At the same time, a fire detector (not shown) senses a fire and sends a signal to the control unit, and the control unit receives this and activates the fire pump 120. As a result, fire extinguishing water is sent from the water storage tank 110 to the sprinkler head 150. In addition, the primary side pipe 140 and the secondary side pipe 160 are in communication with each other, and further, when the fire fighting water is sent by the fire pump 120, the pressure of the fire fighting water in the valve 130 increases. Thus, the pressing shaft 130b moves forward so as to protrude outward from the valve 130.
[0022]
In the operation of the sprinkler fire extinguishing apparatus 100, the contact detection portion 32 of the input unit 3 is pressed by the pressing shaft 130 b that moves forward so as to protrude from the valve 130. Since the lower end surface of the contact portion 32 is formed to be inclined, and the groove 32a for holding the track of the pressing shaft 130b is formed on the inclined surface, the pressing shaft 130b has the groove 32a. Accordingly, the contact portion 32 is pushed upward along the protruding piece 82 of the guide member 8, and the entire input means 3 including the input shaft 31 moves backward.
[0023]
By the backward movement of the input means 3, the spring 6 is compressed, and the piston rod 51 is pushed upward by the elastic force of the spring 6 to move backward. Accordingly, the piston 52 compresses the return spring 53 and moves upward while pressing the liquid 9 in the liquid chamber 27. At this time, the pressed liquid 9 passes through the orifice penetrating the piston 52 in the axial direction and flows in the liquid chamber 27. The piston 52 moves slowly in the liquid chamber 27 due to the elastic force of the return spring 53 and the resistance generated when the liquid 9 passes through the orifice. Thereby, the backward movement of the input means 3 is also slow. In the present embodiment, since the spring 6 is provided between the input means 3 and the delay means 5, the backward movement of the input means 3 is first temporarily delayed by the spring 6, Further, it is secondarily delayed by the delay means 5.
[0024]
Then, when the piston 52 moves in the liquid chamber 27, the output shaft as the output means 4 is pushed upward and moves forward. As a result, the output shaft 4 pushes up the lever 71 of the limit switch 7 that is in contact with the tip 41a, the limit switch 7 is turned on, and the alarm device 170 connected to the limit switch 7 is activated. Then, alarms are sent to the various places concerned.
[0025]
On the other hand, when the operation of the sprinkler fire extinguishing apparatus 100 is stopped, the pressure of the water for fire extinguishing in the valve 130 decreases accordingly. As a result, the pressing shaft 130b retreats inward of the valve 130, so that the input unit 3 moves forward. Further, the force that presses the abutting portion 32 of the input means 3 is removed, so that the compressed return spring 53 extends, whereby the output shaft 4 moves backward, and the lever 71 is moved accordingly. Returning to the initial position, the limit switch 7 is turned off. In addition, the piston 52 moves downward to return to the initial position, and in conjunction with the piston 52, the piston rod 51 moves forward to return to the initial position. Further, the spring 6 returns to the initial state, and the input means 3 also returns to the initial position.
[0026]
As described above, according to the operation detection device 1, the alarm device 170 can be operated by detecting the pressure increase of the fire-extinguishing water during the operation of the sprinkler fire extinguishing device 100. Further, since the delay means 5 and the spring 6 are disposed between the input means 3 and the output means 4, even if the pressure of fire-extinguishing water is input to the input means 3 via the pressing shaft 130b. Since the backward movement of the input means 3 is delayed and the output means 4 moves forward slowly, a predetermined time lag occurs before the limit switch 7 is turned on. Due to this delay action, the sprinkler fire extinguishing device is not actually activated without causing the alarm device 170 to operate due to a temporary rise in the water pressure of the fire extinguishing water due to abnormality of the sprinkler fire extinguishing device 100 such as water leakage from the secondary side pipe 160. The alarm device 170 can be activated only when 100 is activated and the increased pressure is maintained above a certain level. As a result, it is possible to prevent misreporting to related places. Further, even when an abnormality occurs in the operation detection device 1 itself, such as a liquid leak from the liquid chamber 27, the input means 3 is pressed against the pressing shaft 130b only by reducing the resistance of the liquid 9 received by the piston 52. Thus, if the reversing operation is performed, the output unit 4 can be moved forward via the spring 6 and the delaying unit 5 so that the switch 7 can be turned on, and the alarm device 170 can be operated. Therefore, even in such a case, it is possible to report to various places concerned. In addition, the structure is simple, there are few failures, and it is very compact and inexpensive compared with the conventional operation detection device.
[0027]
In the above-described embodiment, the operation detection device 1 is externally attached to the valve 130, and the pressure of fire-extinguishing water is indirectly input to the input means 3 via the pressing shaft 130b. It is also possible to connect the operation detecting device directly to the valve so that the water directly touches the fire-extinguishing water so that the pressure of the fire-extinguishing water is directly input to the input means 3. Moreover, the sprinkler fire extinguishing device 100 shown in the above embodiment is an example, and the operation detection device of the present invention can be applied to various sprinkler fire extinguishing devices.
[0028]
【The invention's effect】
As described above, the operation detection device of the present invention and the sprinkler fire extinguishing device configured to include the operation detection device correspond to a change in the pressure of fire-extinguishing water when the operation detection device operates the sprinkler fire extinguishing device. An input means that moves forward and backward, an output means that moves forward and backward in response to the operation of the input means, and the input means and the output means. The backward movement of the input means is delayed. And a switch that can be switched on and off as the output means moves forward and backward. Thereby, compared with the conventional operation detection apparatus, a very compact and cheap operation detection apparatus can be provided. Further, even when an abnormality occurs in the operation detection device itself, it is possible to reliably detect the operation of the sprinkler fire extinguishing device and operate an alarm device or the like connected to the switch. In addition, due to the delay action of the operation detection device, malfunction of an alarm device or the like connected to the switch can be prevented.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing an operation detection device according to an embodiment of the present invention.
FIG. 2 is a schematic configuration diagram showing a sprinkler fire extinguishing device provided with an operation detection device according to the embodiment;
FIG. 3 is a view showing a state in which an operation detection device according to the embodiment is provided.
FIG. 4 is a schematic configuration diagram showing a conventional operation detection device.
FIG. 5 is a schematic configuration diagram showing a sprinkler fire extinguishing device provided with a conventional operation detection device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Operation | movement detection apparatus 2 Casing 3 Input means 4 Output means (output shaft)
5 Delaying means 51 Piston rod 52 Piston 53 Return spring 6 Spring 7 Switch 8 Guide member 9 Liquid 100 Sprinkler fire extinguishing device

Claims (2)

A pressing shaft provided in the valve sprinkler fire extinguishing apparatus, pressing the press pressure bearings that protrudes outwardly of the valve with increasing pressure of extinguishing water in the valve during operation of the sprinkler fire extinguishing device Input means to move by being
A spring that is compressed when the input means is pressed against the pressing shaft and delays the movement of the input means;
A piston rod that moves by the resilient force of the spring when the input means is pressed against the pressing shaft;
A piston that is formed in the casing and moves in a liquid chamber filled with a liquid when the piston rod is moved by the elastic force of the spring;
A return spring that is compressed by movement of the piston when the piston rod is moved by the resilient force of the spring;
The piston rod is moved by the movement of the piston when moved by the elastic force of the spring, on - and an output device capable of turning on the switch capable off switching,
The operation detection device , wherein the spring, the piston rod, the piston, and the return spring are provided between the input means and the output means . The valve which opens by the action | operation of a sprinkler head, the press axis | shaft which is provided in this valve, and protrudes outward of the said valve with the raise of the pressure of the water for fire extinguishing in the said valve, The operation detection of Claim 1 And a sprinkler fire extinguishing device .

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