JP5437837B2 - Flowing water detector - Google Patents

Description

The present invention relates to a running water detection device installed on fire extinguishing equipment piping.

The flowing water detection device is a device installed on a fire extinguishing equipment pipe such as a sprinkler equipment or a foam fire extinguishing equipment, and detects a running water in the pipe and outputs a signal.

The inside of the water flow detection device has a check valve structure, and the valve is divided into a primary side chamber and a secondary side chamber by the valve, and the valve body is always closed. The primary side chamber and the secondary side chamber are always filled with water, and piping connected to the primary side chamber (hereinafter referred to as “primary side piping”) is connected to a water source, and piping connected to the secondary side chamber (hereinafter referred to as “ "Secondary side piping" is equipped with a spray head such as a sprinkler head or foam head.

The water flow detector is installed to detect the operation of the spray head installed in the secondary pipe. For example, when the sprinkler head is activated, the water filled in the secondary pipe is discharged from the sprinkler head. As a result, the pressure in the secondary side pipe is reduced. As a result, the pressure in the secondary chamber of the flowing water detector also decreases, the balance of the force due to the pressure acting on the valve body is lost, and the force acting on the valve body from the primary side chamber side is reduced from the secondary side chamber side to the valve body. The force acting on the valve is exceeded and the valve body is opened.

When the opening of the valve body is detected, the switch device is activated and a signal is output. The output signal is connected to a monitoring device installed in a building management room or the like, and notifies the manager or the like that the sprinkler head has been activated by a signal from the monitoring device.

In the check valve structure flowing water detection apparatus shown above, a hole leading to the outside is formed in the valve seat on which the valve body is seated, the hole and the pressure switch are connected, and the pressure switch generates a signal. There are types (for example, refer to Patent Document 1) and types (for example, refer to Patent Documents 2 and 3) that output a signal by detecting displacement due to opening of the valve body.

In the above-mentioned water flow detection device, if a switch is activated and a signal is output during inspection or maintenance that is not in a fire, a fire alarm may be output in the building. Stop means are provided.

For example, in the water flow detection device of Patent Document 1, a signal stop valve is installed in a water passage between a hole drilled in a valve seat and a pressure switch. When the signal stop valve is closed, the water flowing in from the hole formed in the valve seat when the valve body of the water flow detector is opened is blocked by the signal stop valve. Since water does not reach the pressure switch, the pressure switch can be prevented from operating.

Further, the flowing water detection devices of Patent Documents 2 and 3 are provided with a terminal box, and a limit switch that outputs a signal by opening the valve body and a limit switch that operates the limit switch are provided in the terminal box. A switch pressing means is provided. A piece serving as a signal output stop means is inserted between the limit switch and the limit switch pressing means to prevent the limit switch pressing means from moving to the limit switch side.

Japanese Utility Model Publication No. 6-14780 International Publication No. 2009/57236 International Publication No. 2009/130903

In many cases, the water flow detector is generally installed in an inconspicuous place in a building. In particular, when installed in a condominium, such as a condominium, a water flow detection device may be installed in the meter box where the gas meter is installed. In the latter flow detection device, a small piece is placed at a predetermined position near the limit switch. It may be difficult to plug it into

The inside of the meter box is dim, and the limit switch is installed in the terminal box, so the work of removing the terminal box lid and inserting the piece in place while illuminating the electric light was a heavy burden on the operator. . Also, since the piece is a small part, it was easy to lose.

Therefore, in view of the above problems, the present invention has an object to provide a water flow detection device that can realize a signal stop means for preventing the operation of a switch at the time of inspection or maintenance by a simple operation and that is not likely to be lost. It is said.

In order to achieve the above object, a water flow detection apparatus proposed by the present invention is shown below.

That is, it has a valve body that can be opened and closed in the main body installed in the sprinkler equipment piping, and a limit switch is installed on one end side of the rod that is displaced when the valve body is opened. In the flowing water detection device in which a signal is output by actuating, a locking piece that can prevent the displacement of the rod is installed outside the main body, and the locked state that prevents the displacement of the rod by the movement of the locking piece, and the displacement It is possible to switch between permissible unlocked states.

According to the flowing water detection apparatus of the present invention, it is possible to prevent displacement of the rod by moving a locking piece installed outside the main body, and to prevent signal output from a limit switch that operates by displacement of the rod.
At that time, the rod can be switched between the locked state and the unlocked state by moving the locking piece, and the operator determines whether the signal output of the limit switch is blocked by the position of the locking piece. be able to.
The size of the locking piece is such that it can be gripped and operated by the operator. Judgment and operation are possible.
Furthermore, since the locking piece is installed outside the main body, there is no risk of loss as in the conventional example.

The locking piece is installed on a base on which a limit switch is installed, one end is an engaging portion that prevents displacement of the rod, and the other end has an operation portion that operates movement of the locking piece.
By providing the engaging piece with an engaging part that prevents the displacement of the rod and an operating part that operates the movement of the engaging piece, the operator can easily prevent the rod from moving by operating the operating part. Switching to the locked or unlocked state can be performed.

The locking piece can be held in a locked state.
By enabling the locking state of the locking piece to be maintained, it is possible to prevent the locking piece from being released due to vibration or the weight of the locking piece when the operator leaves the place, and the locked state being released. It is.

The locking piece has means that can be joined to the base in the locked state.
According to this, the locking piece is joined to the base in the locked state, and the locked state can be maintained.

In the locked state, a part of the locking piece protrudes from the base.
According to this, the operator can easily determine that a signal cannot be output from the limit switch due to the positional relationship between the operation unit and the base.

A member for restricting the rotation angle range of the locking piece and a member for restricting the slide movement direction were installed.
According to this, the movable range / direction of the locking piece can be restricted, and the locking piece can be prevented from interfering with other components.

A member for urging the locking piece toward the base was installed.
According to this, by applying an appropriate load when the locking piece is moved, it is possible to prevent the locking piece from moving due to its own weight, surrounding vibration, or the like. Moreover, it has the effect | action which hold | maintains a locked state at the time of a locked state by the previous effect.

The rod is pivotally supported at the intermediate portion, and the other end side of the rod is in contact with the valve body when the valve body is closed.
According to this, the rod is configured to be rotatable by the opening operation of the valve body, and the rotation operation of the rod can be prevented by bringing the rod into a locked state by operating the locking piece. Furthermore, when the valve body is opened in the locked state, it is possible to configure so that an excessive load is not applied to the component parts such as the valve body and the rod because the rod is in the locked state.

The rod is installed in a pressure switch connected to a hole communicating from the valve seat to the outside of the main body, and is displaced by the pressure of water flowing in from the hole. According to this, the rod and the valve body have a non-contact structure, Even if the rod is locked by operating the locking piece, it is possible to configure so that an excessive load is not applied to the valve body and the rod.

According to the flowing water detection device described above, the displacement of the rod that operates the limit switch can be blocked by the locking piece, and the signal output stop state (locked state) and unlocked state of the limit switch are further controlled between the locking piece and the base. It can be easily determined by the positional relationship. In addition, by installing a locking piece on the base to enable switching between the locked state and the unlocked state, it can be easily operated even in dimly lit places and there is no risk of loss.

Sectional drawing of the flowing water detection apparatus of 1st Embodiment X1-X1 cross section X2-X2 cross section Explanatory drawing of base structure with locking piece (unlocked state) YY cross section Exploded perspective view of rotating shaft part of locking piece Locked state of FIG. Explanatory drawing when the running water detection device of FIG. Modified example a of the first embodiment Modification b of the first embodiment Modification c of the first embodiment Sectional drawing of the flowing water detection apparatus of 2nd Embodiment Sectional view of the pressure switch of FIG. Z1-Z1 cross section Sectional drawing of the modification of 2nd Embodiment Z2-Z2 cross section

1st Embodiment (FIGS. 1-8)
A first embodiment of the present invention will be described below with reference to FIGS.

The flowing water detection device according to the first embodiment includes a main body 1, a housing 2, and a drain valve 3.

The main body 1 has a hollow shape and is divided into a primary side chamber I and a secondary side chamber II by a partition wall 4. A communication hole 5 is formed in the partition wall 4, and an annular valve seat 6 is installed on the secondary side chamber II side of the communication hole 5.

A valve body 7 is seated on the valve seat 6, and a cylindrical bearing 8 is formed on a part of the periphery of the valve body 7, and a valve stem 9 passes through the bearing 8 and is installed in the main body 1. Has been. The valve body 7 is configured to be rotatable in the secondary side II direction with the valve rod 9 as an axis. When the valve body 7 is rotated, the valve body 7 is separated from the valve seat 6 and the fluid in the primary side chamber I is annular. It is possible to pass through the valve seat 6 to the secondary side chamber II.

On the periphery of the valve body 7 is provided a protruding portion 10 that protrudes from the edge. The end 11A of the rod 11 is in contact with the surface of the protrusion 10 on the valve seat 6 side, the rod 11 is pivotally supported in the middle, and the rod 11 is configured to be able to rotate up and down in the drawing. .

An end 11 </ b> B opposite to the end in contact with the valve body 7 of the rod 11 protrudes outside the side surface of the main body 1 and is covered with the housing 2. As shown in FIGS. 4 to 7, the end 11 </ b> B is provided with a spring seat 12 provided so as to protrude upward in the drawing, and a spring seat 13 provided on the base B is provided on the same axis as the spring seat 12. A coil spring 14 is provided between the spring seats 12 and 13 as an elastic body.

The end 11B of the rod 11 is always biased downward in the figure by the coil spring 14. The end 11A opposite to the end 11B is biased upward in the figure, that is, in the direction in which the valve body 7 opens, by the intermediate shaft of the rod 11, but the force acting on the coil spring 14 is weak enough not to open the valve body 7 It is.

A contact 16 that contacts the limit switch pressing piece 15 is fixedly installed at the end 11 </ b> B of the rod 11. The contact 16 urges the limit switch pressing piece 15 in a direction away from the limit switch 17 by the action of a curved spring portion at the tip thereof.

A delay mechanism 18 is installed in the direction in which the spring portion at the tip of the contact 16 urges the limit switch pressing piece 15. The delay mechanism 18 has a function of delaying the operation of the limit switch pressing piece 15, and a structure using an air damper or an oil damper is used. A detailed description of the delay mechanism 18 is omitted.

The limit switch pressing piece 15 is urged by a projecting body (not shown) in the direction of the limit switch 17 and is prevented from moving in the direction of the limit switch 17 by the contact 16.

The base B of the housing 2 shown in FIGS. 4 to 7 has a shape in which a flat plate is bent in an L shape, and a surface as a “first surface” through which the rod 11 passes and is connected to the main body 1. B1 and a surface B2 as a “second surface” provided by being bent from the surface B1. An end of a bracket 19 that supports the limit switch 17 and the delay mechanism 18 is connected to the surface B1, and a hole H for inserting a lead wire connected to the terminal block 29 from the outside into the housing 2 is formed in the surface B2. It is installed.

A locking piece 20 that can prevent the end 11B of the rod 11 from rotating downward is installed on the surface B1. The locking piece 20 has a long and narrow plate shape, and a long hole 21 is formed in an intermediate portion. One end side of the locking piece 20 is an engaging portion 22 with the rod 11, and a tapered portion 22 </ b> A that is tapered toward the tip end side is formed. The tip 22B is formed in a rounded curved shape. The other end side is an operation unit 23 which is moved by the operator and moves the locking piece 20.

As shown in FIG. 6, a hole 21 </ b> A having a diameter larger than the width of the long hole 21 is formed on the engagement portion 22 side of the long hole 21 of the locking piece 20. The diameter of the hole 21A is slightly larger than the outer peripheral diameter on the other end side of the holder 26 described later.

The holder 26 has a cylindrical shape, and an internal thread portion of a bolt 24 described later can be inserted into the inner hole. A flange is formed at one end of the holder 26. The outer diameter of the other end 26 </ b> A is smaller than that of the flange portion, and is slightly smaller than that of the hole 21 </ b> A of the locking piece 20. Further, the outer surface of the other end 26A is provided with two flat surfaces 26B and 26B formed to face each other.

A wave washer 27, a washer 25, and a hole 21A of the locking piece 20 are inserted through the other end 26A of the holder 26 in this order. When these parts are inserted and the two flat surfaces 26B of the holder 26 are inserted between the two protruding portions 26C formed by protruding from the base B, the flat surface 26B is fitted between the two protruding portions 26C. The As a result, the holder 26 is prevented from rotating. Thereafter, the bolt 24 is inserted into the hole of the holder 26 and screwed into the female screw N screwed between the two protruding portions 26C.

Here, the two flat surfaces 26B formed in the long hole 21 of the locking piece 20 and the holder 26 will be described. The interval between the two flat surfaces 26 </ b> B is slightly smaller than the width dimension 21 </ b> B of the long hole 21. At other times, the other end 26A of the holder 26 is inserted into the hole 21A of the locking piece 20, and the flat surface 26B is positioned perpendicular to the elongated hole 21, so that the elongated hole 21 and the other end 26A of the holder 26 cannot slide. When the locking piece 20 is rotated 90 ° with the holder 26 as a fulcrum, the two flat surfaces 26B become parallel to the elongated hole 21, and the elongated hole 21 and the flat surface 26B of the holder 26 are slidable to move the locking piece. 20 can be slid to the rod 11 side. Thereby, the locking piece 20 can be slid and moved only at a position where the two flat surfaces 26B of the holder 26 and the long hole 21 are parallel (position where the locking piece 20 is rotated approximately 90 ° from the original position). Yes, the direction in which sliding is possible is restricted.

When the locking piece 20 is rotated as described above, the locking piece 20 is urged in the B1 surface direction by the wave washer 27 to apply an appropriate load, so that the locking piece 20 has its own weight, surrounding vibration, and the like. This prevents the locking piece 20 from moving. Moreover, it has the effect | action which can hold | maintain a locked state at the time of a locked state by these effects.

As for the locking piece 20, the operation part 23 is always stored in the base B (lock release state). When the locking piece 20 is rotated, the movement of the rod 11 can be prevented, and the operation unit 23 protrudes from the base B (locked state). Thus, the operator can easily determine that a signal cannot be output from the limit switch 17 due to the positional relationship between the operation unit 23 and the base B.

Further, even if the operator tries to attach the cover C to the base B in the locked state, the cover C cannot be attached to the base B because the operation unit 23 is in a state of protruding from the base B. Even if the operator is not familiar with the work, it is felt that the cover C cannot be attached to the base B, and an abnormal state is felt, and the locked state can be released by reporting to another skilled worker.

The locking piece 20 is installed near the edge of the base B. Preferably, it is provided at a position where it can be operated from the front side of the flowing water detection device. Specifically, when the front surface of the water flow detection device is a surface provided with an opening 1B closed by a cover 1A, the casing 2 is provided on the side surface, so the locking piece 20 is provided near the front edge of the base B. Install.

Stoppers 28A and 28B are formed on the surface B1 as protrusions for guiding the operation when the locking piece 20 is rotated. When the locking piece 20 is rotated from the unlocked state to the locked state, the locking piece 20 comes into contact with the stopper 28A and is rotated approximately 90 ° from the original position. The protrusion 28A has a stopper action for preventing the locking piece 20 from rotating any more, and the locking piece 20 is restricted in the rotatable angular range.

When the locking piece 20 is slid along the elongated hole 21, the tapered portion 22 </ b> A of the engaging portion 22 moves along the peripheral surface of the rod 11. At that time, even when the rod 11 is slightly inclined downward and the rod 11 is in contact with the tapered portion 22A, the locking piece 20 can be smoothly slid without being caught. At the same time, the tip 22B of the locking piece 20 slides while contacting a guide portion 28C formed by rounding a part of the edge of the stopper 28B.

By the sliding movement of the locking piece 20, the tip 22B of the engaging portion 22 is guided onto the stopper 28B, and the side 22C opposite to the tapered portion 22A is engaged with the stopper 28B. At the same time, the stopper 28A also comes into contact with one side of the locking piece 20, and is held with almost no gap between the stoppers 28A, 28B and the locking piece 20. As a result, the locked state in which the rod 11 is prevented from moving by the locking piece 20 can be maintained.

The cover C covers the limit switch 17, the delay mechanism 18, and the terminal block 29 installed on the base B, and protects them from dust and water droplets. When the cover C is removed, the internal structure of the housing 2 supported by the L-shaped base B is greatly exposed, so that the limit switch 17 and the terminal block 29 accommodated in the housing 2 are connected and inspected. Good sex.

The drain valve 3 is a valve that discharges the fluid in the main body 1 to the outside during inspection and maintenance, and is installed on the surface opposite to the housing 2. The inside of the drain valve 3 has an angle valve structure, and the discharge port is provided downward in FIG. The handle for opening and closing the drain valve 3 is installed on the front side where the cover 1A of the flowing water detection device A is provided, and is provided at a position where the handle can be easily operated.

Then, operation | movement of the flowing water detection apparatus of 1st Embodiment is demonstrated.

The flowing water detection device of the first embodiment is installed in a fire extinguishing equipment pipe, the primary side chamber I is connected to a pump (not shown) and a pipe leading to a water source, and a sprinkler head (not shown) is connected to the end of the pipe connected to the secondary side chamber II. Is installed.

The fire extinguishing equipment piping is filled with water, and the inside of the main body 1 of the water flow detector is also filled with the primary side chamber I and the secondary side chamber II. At all times, the valve body 7 is seated on the valve seat 6 and water flow from the primary side chamber I to the secondary side chamber II is blocked.

When a fire occurs and the sprinkler head installed in the pipe on the secondary side chamber II side operates, the water in the pipe on the secondary side chamber II side is discharged from the sprinkler head and gradually decreases in pressure. When the pressure of the water in the secondary side chamber II that has closed the valve body 7 decreases and becomes lower than the pressure in the primary side chamber I, the valve body 7 is pushed up by the pressure difference between the secondary side chamber II and the primary side chamber I, and the shaft 9 is Rotates to a fulcrum.

Since the valve body 7 is opened away from the valve seat 6, the water in the primary side chamber I is sent to the secondary side chamber II side. At the same time, the rod 11 that has been in contact with the valve body 7 is also rotated by the urging force of the coil spring 14, and the end 11B on the housing 2 side moves downward as shown in FIG.

As a result, the contact 16 at the end 11B is separated from the limit switch pressing piece 15, and the limit switch pressing piece 15 starts moving toward the limit switch 17 side. The limit switch pressing piece 15 activates the limit switch 17 after a predetermined time has elapsed by the delay mechanism 18. The limit switch 17 is connected to a monitoring device (not shown) provided in an administrator room or the like via a terminal block 29, and the operation of the limit switch 17 is output to the monitoring device.

The above-described pump is activated by a signal generated by the operation of the limit switch 17, the water supply starts from the water source to the sprinkler head, and water is continuously sprayed from the sprinkler head to stop the fire.

Next, a procedure for stopping signal output due to the operation of the limit switch in the flowing water detection device of the first embodiment will be described.

First, the cover C is removed from the housing 2. Holding the operating portion 23 of the locking piece 20, the locking piece 20 is rotated (in FIG. 4, it rotates clockwise). The locking piece 20 hits the stopper 28A and stops. At this time, the locking piece 20 is in a position rotated approximately 90 degrees from the original state (unlocked state). Next, the locking piece 20 is slid along the long hole 21.
At this time, when the rotation angle of the locking piece 20 is rotated at an angle smaller than the aforementioned 90 °, the two flat surfaces 26B of the holder 26 inserted in the sliding direction of the long hole 21 and the long hole 21 are used. Are not parallel, the locking piece 20 cannot be slid.

When the locking piece 20 is slid, the distal end 22B of the engaging portion 22 moves along the guide portion 28C of the stopper 28B and is guided onto the stopper 28B, and the side 22C opposite to the tapered portion 22A is connected to the stopper 28B. Engage. Thus, the lock state is established, and the movement of the rod 11 is blocked by the locking piece 20 even when the valve body is opened, so that it is possible to prevent a signal from being output from the limit switch 17.

The procedure of returning the locking piece 20 from the locked state to the unlocked state can be realized by a procedure reverse to the above.

First Embodiment Modification A (FIG. 9)
Next, a modification a of the first embodiment will be described with reference to FIG.

In the modification a of the first embodiment, a projectile that performs a sliding operation is installed in addition to the configuration of the first embodiment.

In the locking piece 20 shown in FIG. An annular rubber 30 is hung on the protrusion 20A as an elastic body, and the rubber 30 is also hung on the rotating shaft 31 of the locking piece 20.

When the locking piece 20 is rotated, the locking piece 20 can be slid along the elongated hole 21 by the elastic force of the rubber 30. Unlike the first embodiment, the operator does not need to perform a slide operation after rotating the locking piece 20, and the locking piece 20 is slid by the elastic force of the rubber 30 only by performing the rotating operation. Thus, the side 22C of the locking portion 22 can be engaged with the stopper 28B. The rubber 30 can maintain the locked state.

In the above description, the annular rubber 30 has been described as an elastic body, but it may be configured by replacing it with a tension spring, a weight, or a magnet.

First Embodiment Modification b (FIG. 10)
Next, a modification b of the first embodiment will be described with reference to FIG.

In the modified example b of the first embodiment, the shape of the engaging portion 22 is notched, and the rod 11 is sandwiched from above and below to prevent the rod 11 from moving.

First Embodiment Modification c (FIG. 11)
Next, a modification c of the first embodiment will be described with reference to FIG.

In the modified example c of the first embodiment, the operation of the locking piece in the locked state and the unlocked state can be realized only by the sliding operation.

The locking piece 40 shown in FIG. 11 has an elongated plate shape as in the first embodiment, and a long hole 41 is formed on one end side. An engaging portion 42 is formed at the edge near the elongated hole 41, and a curved portion 42A corresponding to the tapered portion 22A of the first embodiment is provided. A stepped portion 42B that engages with the stopper 44 is formed in a hook shape on the edge opposite to the curved portion 42A across the elongated hole 41.

The other end side of the locking side 40 is bent at an end portion to form an operation portion 43. The operator can grasp the operation portion 43 and operate the locking piece 40. It is also possible to display “stop signal” or the like on the operation unit 43.

Bolts 24 are inserted into the long holes 41 as in the first embodiment. A stopper 44 is provided on the base B in the vicinity of the edge between the long hole 41 and the operation portion 43 to guide the sliding operation of the locking piece 40.

As shown in FIG. 11A, the locking piece 40 of the above embodiment is in the unlocked state when the operation unit 43 is housed in the base B, and the operation unit 43 is installed in the base B as shown in FIG. The state that protrudes is defined as a locked state. Since the cover C cannot be attached to the base B when the operation part 43 protrudes from the base B, the operator notices that the operator is locked when the cover C is attached, and operates the operation part 43 to release the lock. be able to.

In the first embodiment described above and its modification, as another embodiment of the means capable of maintaining the locked state, an operation of attaching a weight to the operation portion 23 of the locking piece 20 and returning from the locked state to the unlocked state. It is possible to add a load during the process.

As another embodiment in which the locking piece can be held in a locked state using means that can be joined to the base, the stopper 28B (44) is made of a magnet, and the locking piece 20 (40) is made of iron or the like. If it is made of a material that can be attracted to the magnet, the locked state can be maintained by the magnetic force.

Second Embodiment (FIGS. 12 to 14)
Next, a second embodiment will be described with reference to FIGS.

In the second embodiment, parts having the same configurations as those of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. 2nd Embodiment demonstrates the flowing water detection apparatus with which a rod and a valve body are non-contact.

About the flowing water detection apparatus of 2nd Embodiment shown in FIG. 12, since the structure of a main body and a valve body and the structure of a limit switch vicinity are substantially the same as the flowing water detection apparatus of 1st Embodiment, it is the same code | symbol about a part with the same structure. Detailed description will be omitted. The difference from the first embodiment is that a hole 50 leading to the outside of the main body 1 is formed in the valve seat 6 on which the valve body 7 is seated. The hole 50 is connected to a pressure switch 51 having a limit switch 17 inside. As shown in FIG. 13, the pressure switch 51 has a structure in which the rod 52 is pushed up by the pressure of water passing through the hole 50 and the lever 52 is rotated. The configuration in which the limit switch pressing piece 15 is unlocked by the turning operation of the lever 52 and the limit switch 17 is activated is substantially the same as in the first embodiment.

The base 53 of the pressure switch 51 on which components such as the limit switch 17 are arranged is a flat plate, and the components such as the limit switch 17 are covered with a cover 51A to prevent dust and dirt from adhering. Yes.

A hollow connection portion 54 to which the hole 50 is connected is installed on the outer surface 53A of the base 53. The limit switch 17 and the lever 52 are installed on the surface 53B on the opposite side (inner side) of the base 53.

A space 54A is formed above the hollow connecting portion 54 (in the direction of the base 53), and a diaphragm 55 is installed to partition the space 54A up and down, and flows into the connecting portion 54 through the hole 50. Water is prevented from leaking into the space on the base 53 side. A rod 56 penetrating the diaphragm 55 is installed in the diaphragm 55, and the rod 56 is engaged with the lever 52, and the lever 52 can be rotated by the vertical movement of the rod 56.

The limit switch 17 is installed on the surface 53B side of the base 53. The limit switch 17 is positioned and installed in the bracket 57 so as to be installed at a predetermined position with respect to the rod 56. The bracket 57 has a box shape formed by bending a flat plate, and each surface of the bracket 57 covers the limit switch 17. The bracket 57 is fixedly installed at a predetermined position on the base 53 with a screw 58. A terminal block 59 connected to the limit switch 17 is installed on the bracket 57.

Normally, the rod 56 is positioned on the hole 50 side (lower side in the figure). However, when water flows into the connection portion 54 from the hole 50, the diaphragm 55 swells upward in the figure due to the pressure of the water, and the diaphragm The rod 56 is displaced to the lever 52 side by the deformation of 55. The lever 52 is rotated by the displacement of the rod 56, and the limit switch 17 is operated as described in the first embodiment. A signal generated by the operation of the limit switch 17 is transmitted to a receiving board in the building, and the operation of the water flow detection device is transmitted to a manager or the like.

In the above-described pressure switch, as shown in FIG. 14, the locking piece 70 has an elongated plate shape, and a hole 71 is formed in the middle portion. One end side of the locking piece 70 is an engaging portion 72 that can prevent the rod 56 from moving. The other end side is an operation unit 73 that is moved by the operator and moves the locking piece 70.

The locking piece 70 is rotatably installed by inserting the bolt 24 provided on the base 53 into the hole 71. Since the locking piece 70 is always (unlocked), the operation portion 73 is housed in the base 53, and the cover 51A can be attached to the base 53. Further, a notch 73A formed at the tip of the operation portion 73 is in contact with the edge of one surface 57A of the bracket 57, and prevents the locking piece 70 from rotating more than necessary in the unlocked state.

When the locking piece 70 is rotated as indicated by a dotted line in FIG. 14, the engaging portion 72 is positioned on the upper portion of the rod 56, and the upward movement of the rod 56 can be prevented (locked state). At this time, the operation unit 73 protrudes from the base B, and the cover 51 </ b> A cannot be attached to the base 53. Thus, the operator can easily determine that a signal cannot be output from the limit switch 17 due to the positional relationship between the operation unit 73 and the base 53.

The protruding portion 72A formed to protrude from the tip of the engaging portion 72 is in contact with the surface 57B of the bracket 57 to limit the range in which the locking piece 70 can be rotated, and has a function as a stopper.

Then, operation | movement of the flowing water detection apparatus of 2nd Embodiment is demonstrated.

The fire extinguishing equipment piping is filled with water, and the inside of the main body 1 of the water flow detector is also filled with the primary side chamber I and the secondary side chamber II. At all times, the valve body 7 is seated on the valve seat 6 and water flow from the primary side chamber I to the secondary side chamber II is blocked.

When a fire occurs and the sprinkler head installed in the pipe on the secondary side chamber II side operates, the water in the pipe on the secondary side chamber II side is discharged from the sprinkler head and gradually decreases in pressure. The pressure of the water in the secondary side chamber II that had closed the valve body 7 is reduced, so that the valve body 7 is pushed up by the water pressure in the primary side chamber I and rotates around the shaft 9 as a fulcrum.

Since the valve body 7 is opened away from the valve seat 6, the water in the primary side chamber I is sent to the secondary side chamber II side. At the same time, water flows into the hole 50 formed in the valve seat 6 and reaches the pressure switch 51 connected to the hole 50. Water flows into the hollow connection portion 54 of the pressure switch 51 and causes the diaphragm 55 to expand toward the base 53 side. The rod 56 installed on the diaphragm 55 is displaced upward in the drawing along with the expansion of the diaphragm 55 to push up one end of the lever 52 engaged with the tip of the rod 56.

The lever 52 is rotated by the displacement of the rod 56, and the other end side of the lever 52 that has locked the limit switch pressing piece 15 is separated from the limit switch pressing piece 15. The limit switch pressing piece 15 moves to the limit switch 17 side, and the limit switch pressing piece 15 operates the limit switch 17 after a predetermined time has passed by the delay mechanism 18. The limit switch 17 is connected to a monitoring device provided in an administrator room or the like via a terminal block 59, and the operation of the limit switch 17 is output to the monitoring device.

The above-described pump is activated by a signal generated by the operation of the limit switch 17, water supply starts from the water source to the sprinkler head operated, and water is continuously sprayed from the sprinkler head to extinguish the fire.

Next, a procedure for stopping signal output from the limit switch in the flowing water detection device of the second embodiment will be described.

First, the cover 51 </ b> A is removed from the pressure switch 51. At this time, the locking piece 70 is in a state of being accommodated in the base 53 (unlocked state). Holding the operating portion 73 of the locking piece 70, the locking piece 70 is rotated. The protrusion 72A of the locking piece 70 comes into contact with the surface 57B of the bracket 57 to prevent the locking piece 70 from rotating. In this state, the engaging portion 72 is positioned above the rod 56 and can prevent the rod 56 from moving (locked state). Further, the operation unit 73 is in a state of protruding from the base 53, and the cover 51A cannot be attached to the base 53 in this state.

The procedure for returning the locking piece 70 from the locked state to the unlocked state can be realized by a procedure reverse to the above.

Second Embodiment Modification a (FIGS. 15 to 16)
Next, a modification of the second embodiment will be described with reference to FIGS.

The modification of 2nd Embodiment makes it the structure which can implement | achieve operation | movement of the latching piece of a locked state and a lock release state by a slide operation | movement.

The locking piece 80 shown in FIGS. 15 and 16 has an elongated plate shape, and a long hole 81 is formed in an intermediate portion. A long hole 81 is formed on one end side. An engaging portion 82 is provided at an intermediate portion of the locking piece 80. The other end side is bent at an end portion to form an operation portion 83. The operator can operate the locking piece 80 by grasping the operation portion 83. Further, a display such as “stop signal” can be given to the operation unit 83.

A stepped shaft 84 is erected on the base 53, and the shaft 84 is formed with a step 84 </ b> A at an intermediate portion. The shaft 84 </ b> B is opposite to the base 53 on the outer diameter of the base 53 side. The outer diameter is smaller than the outer diameter on the base 53 side. The height dimension from the step 84A to the base 53 is slightly larger than the height when the rod 56 protrudes from the base 53 in normal times.

The shaft portion 84B is inserted through the elongated hole 81, and the sliding operation of the locking piece 80 is guided by the shaft portion 84B. The locking piece 80 is placed on the step 84A.

The bracket 57 is formed with a notch 85 through which the locking piece 80 can pass. The position of the notch 85 is substantially the same as the height dimension of the step 84A described above. The width of the notch 85 is slightly larger than the thickness dimension of the locking piece 80, can guide the sliding movement of the locking piece 80, and can prevent the locking piece 80 from moving up and down. is there.

As shown in FIG. 16, the locking piece 80 is in the unlocked state where the end on which the elongated hole 81 is formed is accommodated in the base 53, and the elongated hole 81 is formed as indicated by the dotted line in FIG. A state in which the end on the side where the hole is formed protrudes from the base 53 is referred to as a locked state. Since the cover 51A cannot be attached to the base 53 when the operation part 83 protrudes from the base 53, the operator is aware that the cover 51A is in the locked state when the cover 51A is attached, and operates the operation part 83 to enter the unlocked state. be able to.

In the second embodiment and its modification described above, if a magnet is installed at a location where the locking piece 70 (80) of the surface 57B of the bracket 57 contacts as a means for holding the locked state, The magnet and the locking piece 70 (80) are attracted by the magnetic force, and the locked state can be maintained.

1 body
2 Case
3 Drain valve
4 Bulkhead
5 communication hole
6 Valve seat
7 Disc
8 Bearing
9 Valve stem
10 Protrusion
11, 56 Rod
15 Limit switch pressing piece 16 Contact
17 Limit switch
18 Delay mechanism
19, 57 Brackets 20, 40, 70, 80 Locking pieces 21, 41, 81 Slots 22, 42, 72, 82 Engaging parts 23, 43, 73, 83 Operation part 24 Bolt 27 Wave washer 28A, 28B, 44 Stopper 30 Rubber 31 Rotating shaft 50 Hole 51 Pressure switch 52 Lever 53, B Base 55 Diaphragm 71 Hole A Flowing water detection device C Cover

Claims (10)

The main body installed in the sprinkler equipment piping ;
A valve element that will be openably installed on an inner portion of the main body,
A rod that is displaced from the closed state by opening the valve body ;
A limit switch installed at one end of the rod ,
In the flowing water detection device in which a limit switch is activated by the displacement of the rod and a signal is output,
A locking piece capable of preventing displacement of the rod is installed outside the main body ,
By the movement of the locking piece, it is possible to switch between a locked state in which the rod is closed when the valve body is opened and an unlocked state in which the displacement of the rod is allowed by opening the valve body. A featured water detection device.
The main body installed in the sprinkler equipment piping;
A valve body installed in the main body so as to be freely opened and closed;
A rod that is displaced by opening the valve body;
A limit switch installed on one end of the rod;
A limit switch pressing piece that operates by displacement of the rod,
In the flowing water detection device in which a limit switch is operated by a limit switch pressing piece that is operated by displacement of the rod and a signal is output,
A locking piece capable of preventing displacement of the rod is installed outside the main body,
A running water detection device characterized in that the lock piece can be switched between a locked state for preventing displacement of the rod and an unlocked state for allowing displacement of the rod by the movement of the locking piece.
The main body installed in the sprinkler equipment piping;
A valve body installed in the main body so as to be freely opened and closed;
A rod that is displaced by opening the valve body;
A limit switch installed at one end of the rod,
In the flowing water detection device in which a limit switch is activated by the displacement of the rod and a signal is output,
A locking piece capable of preventing displacement of the rod is installed outside the main body,
By moving the locking piece, it is possible to switch between a locked state that prevents displacement of the rod and an unlocked state that allows displacement of the rod ,
The locking piece, the limit switch is installed outside on the base body which is installed at one end is engaged portion to prevent displacement of the rod, the other end is operated to operate the movement of the locking piece The flowing water detection device characterized by being a part.
The main body installed in the sprinkler equipment piping;
A valve body installed in the main body so as to be freely opened and closed;
A rod that is displaced by opening the valve body;
A limit switch installed at one end of the rod,
In the flowing water detection device in which a limit switch is activated by the displacement of the rod and a signal is output,
A locking piece capable of preventing displacement of the rod is installed outside the main body,
By moving the locking piece, it is possible to switch between a locked state that prevents displacement of the rod and an unlocked state that allows displacement of the rod,
The engaging piece, water flow detection apparatus characterized by having a base and bondable means the limit switch is located in the locked state.
The main body installed in the sprinkler equipment piping;
A valve body installed in the main body so as to be freely opened and closed;
A rod that is displaced by opening the valve body;
A limit switch installed at one end of the rod,
In the flowing water detection device in which a limit switch is activated by the displacement of the rod and a signal is output,
A locking piece capable of preventing displacement of the rod is installed outside the main body,
By moving the locking piece, it is possible to switch between a locked state that prevents displacement of the rod and an unlocked state that allows displacement of the rod,
The locking piece is partially in the locked state, the water flow detection apparatus characterized by a state of the limit switch protruding from the base in which it is installed.
The main body installed in the sprinkler equipment piping;
A valve body installed in the main body so as to be freely opened and closed;
A rod that is displaced by opening the valve body;
A limit switch installed at one end of the rod,
In the flowing water detection device in which a limit switch is activated by the displacement of the rod and a signal is output,
A locking piece capable of preventing displacement of the rod is installed outside the main body,
By moving the locking piece, it is possible to switch between a locked state that prevents displacement of the rod and an unlocked state that allows displacement of the rod,
Furthermore , the flowing water detection apparatus provided with the member which urges | biases the said locking piece to the base side in which the said limit switch is installed .
The flowing water detection device according to any one of claims 1 to 6, wherein the rod is pivotally supported at an intermediate portion, and the other end side of the rod is in contact with the valve body when the valve body is closed.
The flowing water detection device according to any one of claims 1 to 7 , wherein the locking piece can hold a locked state.
The flowing water detection device according to any one of claims 1 to 8, wherein a member that regulates a rotation angle range of the locking piece is installed.
The flowing water detection device according to any one of claims 1 to 9, wherein a member that regulates a sliding movement direction of the locking piece is installed.

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