JP4616418B1 - Flowing water detector - Google Patents

Abstract

A novel actuated valve type water flow detection device that can be applied to a relatively large diameter.
A flowing water detection device of the present invention has a swing check type valve structure, and a lever shaft 11 that is installed through a main body 1 is provided in a portion of a valve body 7 facing a bearing 8, and the lever shaft 11 is provided. The first lever 11A and the second lever 11B were connected and fixed to the respective end portions, and the first lever 11A was biased in the valve opening direction. When the valve body 7 is opened, the first lever 11A and the second lever 11B rotate to turn on the switch device 17. When the lever shaft 11 is provided at a portion of the valve body 7 facing the bearing 8 to detect displacement due to the opening of the valve body 7, the displacement amount is greater in the portion facing the bearing 8 than in the vicinity of the bearing 8. Since it is large, it is easy to detect displacement by the switch device 17.
[Selection] Figure 2

Description

The present invention relates to a water flow detection device that is installed in a fire extinguishing equipment pipe and detects a flow of water inside a filled pipe and outputs a signal, and in particular, between the primary side and the secondary side of a valve body when a water flow occurs. The present invention relates to an operating valve type flowing water detection device that mechanically detects a generated differential pressure and outputs a signal such as a fire signal or an alarm.

The flowing water detection device is installed in a fire extinguishing equipment pipe such as a sprinkler equipment or a foam fire extinguishing equipment, and detects a running water inside the pipe and outputs a predetermined signal (fire signal, alarm). The inside of the flowing water detection device has a check valve structure, and the inside is divided into a primary side chamber and a secondary side chamber by the valve body, and the valve body is always in a closed state separating them. The primary side chamber and the secondary side chamber are always filled with water, the piping connected to the primary side chamber is connected to a water source such as a water storage tank, and the piping connected to the secondary side chamber is connected to a spraying head such as a sprinkler head or foam head. It is connected.

There are various types of water flow detection devices depending on the detection method.For example, a differential pressure generated between the primary side and the secondary side of the valve body during the flow of water is mechanically detected to detect fire signals, alarms, etc. An actuating valve type that outputs a signal is known. This operating valve type water flow detection device has a constant and stable operating flow rate that outputs an alarm, and there is no water channel connected to other systems such as an automatic alarm valve type alarm water channel. There are various merits such as being unaffected at all and being able to simply configure the device (see Patent Document 1 as an example of a conventional automatic alarm valve type water flow detector).

JP-A-9-103515

By the way, there exists a subject that it cannot be implement | achieved as a flowing water detection apparatus of the comparatively large aperture | diameter (for example, 65A-200A) about the operating valve type flowing water detection apparatus with such a merit that is installed in a general building. That is, when a large number of sprinkler heads are installed as in a general building, the differential pressure generated between the primary side and the secondary side of the valve body due to the water flowing from the sprinkler head is very small, and the diameter of the water flow detection device As the flow rate is increased by increasing the pressure, the differential pressure becomes smaller. When the differential pressure becomes small, the rotation angle of the valve body becomes small, and it becomes difficult to accurately detect the flowing water from the sprinkler head based on the rotation angle of the valve body. As described above, the conventional actuated valve type water flow detection device has many technical advantages as described above, but it has been put to practical use only for the water flow detection device having a relatively small diameter, and is compared with the installation in a general building. The automatic alarm valve type water flow detector is still used in the large diameter water flow detector.

The present invention has been made against the background of the prior art as described above. The object is to provide a new actuated valve type water flow detector which can be applied even with a relatively large diameter.

In order to achieve the above object, the present invention provides the following water flow detection device.

The flowing water detection apparatus of the present invention detects a flowing water generated by a cylindrical main body connected to a fire extinguishing equipment pipe, a check valve structure provided inside the main body, and rotation of the valve body, and outputs a predetermined signal. For a flowing water detection device comprising a switch device for rotating the lever shaft, the lever shaft is inserted from the outside of the main body into a portion facing the bearing of the valve body and rotates around the shaft, and the lever shaft is in contact with the edge of the valve body. A first lever that is provided at the end of the valve body and rotates in the opening direction of the valve body by rotation of the lever shaft; a biasing member that biases the first lever in the opening direction of the valve body; A second lever provided on the outer side of the main body and a switch device that is turned on and off by the rotation of the second lever.

The flowing water detection device of the present invention includes a lever shaft installed through the main body, and the first lever and the second lever fixed to the end portions thereof are rotated by a rotation operation around the axis of the lever shaft. It is possible to turn on and off the switch device by moving. More specifically, the first lever that is in contact with the valve body receives a biasing force in the valve opening direction by the biasing member, but is prevented by the closed valve body from rotating. . When the valve body is opened, the urging member rotates the first lever in the valve opening direction with the lever shaft rotating around the axis as a fulcrum. At the same time, the second lever fixedly installed on the lever shaft also rotates to turn on the switch device.
Further, the lever shaft is installed in a portion facing the bearing of the valve body, that is, a portion away from the bearing of the valve body, so that the valve body is more than the displacement amount of the bearing portion of the valve body when the valve body is opened. The amount of displacement of the portion facing the bearing is greater. Also, since the lever pivoting operation is independent of the valve body pivoting operation, the lever and lever shaft are installed in the part where the displacement due to the valve pivoting is large, and the length of the lever is set arbitrarily. This makes it possible to control the rotation angle of the lever when the valve element is opened. The rotation angle of the lever when the valve body is opened is preferably in the range of 10 to 60 degrees, more preferably in the range of 20 to 45 degrees.
The urging member urges the first lever in the valve opening direction, and the urging force extends to the valve body in the closed state, but is a force that does not open the valve body in the closed state.
Further, the urging member can be directly installed on the first lever, and as a means thereof, a rubber-like elastic body, a spring, a weight, a magnet, etc. are provided on the side opposite to the side of the first lever that contacts the valve body. This can be realized by installing. Furthermore, the urging member can be applied to the first lever via the lever shaft, and can be realized by installing a rubber-like elastic body, spring, weight, magnet, etc. on the second lever side as the means. It is.

The present invention can be configured as having a rotation restricting member that stops the maximum rotation position of the first lever at a position inside the trajectory of the rotation operation of the valve body.
When the valve body is fully opened, the first lever is moored by the rotation restricting member at a position inside the trajectory of the valve body, that is, within a range inside the trajectory of the edge of the valve body from the rotational axis of the valve body. Is done. When the valve body returns from the fully open state to the closed state, the first lever is urged to return to the closed state, so that the first lever can also return to the original position.
When the valve body is formed with an abutting portion protruding outward from the valve seat surface on which the valve body is seated, the valve body is closed from the open state as the edge of the valve body on which the first lever abuts. In this case, the first lever can be prevented from being caught between the valve body and the valve seat.

In the flowing water detection device of the present invention, a projecting skirt portion is provided on the primary side surface of the valve body to form an orifice-shaped flow path inside the main body by the rotation of the valve body.
The differential pressure for rotating the valve body changes depending on the flow rate of the fluid and the area and shape of the flow path through which the fluid passes. Therefore, in the present invention, a skirt portion that forms an orifice in the flow path inside the main body is provided on the primary side surface of the valve body to reduce the passage area of the fluid, and a small change in flowing water is amplified to increase the opening angle of the valve body. can do.

The flowing water detection device of the present invention is provided with a weight portion that urges the valve body in the closing direction.
The secondary pipe is depressurized due to minute water leaks from the joint of the secondary pipe, etc., or the pump is activated by the operation of the water flow detector of another system, causing water vibration in the pipe. Then, the valve body may be temporarily opened even during non-fire. Thus, even when the valve element is temporarily opened during a non-fire, in the present invention, the valve portion can be immediately returned to the closed state, and the sealing property at the time of closing can be ensured.

The weight portion of the present invention can be realized as a skirt portion.
Since the skirt portion also serves as the weight portion, it is not necessary to prepare a separate member as the weight portion, and an unnecessary increase in parts can be avoided.

The biasing member of the present invention can be any of a rubber-like elastic body, a coil spring, a weight, and a magnet.
By using a rubber-like elastic body, an elastic member such as a spring, a weight, or a magnet as the biasing member, the biasing member can be realized with a simple configuration.

In the present invention, there is provided delay means for delaying the time from when the valve body is opened until the switch device is turned on.
If the valve element opens temporarily during a non-fire, such as when the valve element opens temporarily even during a non-fire due to vibration of water in the piping, etc., the switch device turns on when the valve element opens due to delay means. By delaying the time until it becomes, it prevents the switch device from turning on and generating a false alarm at the time of non-fire. It is preferable to use a delay means that resets the delay state when the valve body is closed before the switch device is turned on after the valve body is opened.
In the conventional operating valve type flowing water detection device, the displacement due to the rotation of the valve body is detected by the switch device, so that the valve body is linked to the opening of the valve body between the member that rotates in conjunction with the opening of the valve body and the switch device. However, in the present invention, the rotation of the valve body and the rotation of the lever are complicated, because a member that acts on the switch device by delaying the displacement due to the movement of the opening member is required. Since it is independent, it is possible to provide a time interval from the opening of the valve body to the operation of the switch device by slowing the turning operation of the lever by the delay means.

The delay means of the present invention slows down the turning operation of the lever shaft.
By slowing down the operation of the lever shaft, the operation of the second lever fixedly installed on the lever shaft is also slowed down, and the time from when the valve element opens until the switch device is turned on can be delayed. it can.
In addition, since the speed at which the lever shaft provided with the first lever rotates relative to the opening speed of the valve body is slowed by the delay means, the first lever rotates immediately away from the valve body. Therefore, the first lever does not hinder the rotation of the valve body.

The delay means of the present invention delays the time from when the second lever is operated until the switch device is turned on.
By delaying the time from when the second lever is operated until the switch device is turned on, the time from when the valve body is opened to when the switch device is turned on can also be delayed. This can be realized by interposing a movable member having a slow operation between the second lever and the switch device. The first lever can be rotated following the rotation of the valve body by the biasing means in the valve opening direction. Further, the urging means has an action of prompting the opening operation of the valve body, and the opening operation of the valve body becomes sensitive.

According to the flowing water detection device of the present invention, a size call (“size call” described in the detailed specifications of the flow detection device) that is often installed in a general building is 65A (2-1 / It is possible to realize a new working valve type water flow detection device that can be applied to a relatively large diameter of about 2 ″) to 200A (8 ″).

Sectional drawing of the flowing water detection apparatus by one Embodiment of this invention. XX sectional drawing of FIG. YY sectional drawing of FIG. Explanatory drawing of the internal structure of the housing | casing seen from the arrow Z direction of FIG. Explanatory drawing which shows the state which the valve body in FIG. 3 opened. Explanatory drawing which shows the state which the valve body in FIG. 4 opened. Sectional drawing which shows the modification of the lever shaft position of FIG. Explanatory drawing which shows the modification of the internal structure of the housing | casing of FIG.

Hereinafter, embodiments of the present invention will be described with reference to FIGS.

The flowing water detection device A of the present invention shown in FIGS. 1 to 3 includes a main body 1, a housing 2, and a drain valve 3.

The main body 1 has a hollow cylindrical shape, and the inside is divided into a primary side chamber I and a secondary side chamber II by a partition wall 4. A maintenance opening 1a is formed on the front surface of the main body 1, and the opening 1a is closed by a cover 1b. 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.

A disc-like 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 rod 9 is inserted into the bearing 8. ing. The valve stem 9 is stretched horizontally inside the main body 1 and is held by the main body 1. The valve body 7 has a check valve structure that can rotate in the direction of the secondary side chamber II around the valve rod 9, and the valve body 7 rotates in the direction of the secondary side chamber II and separates from the valve seat 6. Thus, the fluid in the primary side chamber I can pass through the annular valve seat 6 to the secondary side chamber II.

The valve body 7 includes a valve main body 7a, a convex portion 7b accommodated in a concave portion on the primary side of the valve main body 7a, and a fastening member 7c made of a bolt and a nut for fixing the convex portion 7b to the valve main body 7a. The valve body 7a is made of metal, specifically iron, and an electrodeposition coating layer is formed as a rust-proof coating layer on the entire surface (not shown). Similarly, the convex portion 7b is made of iron on which an electrodeposition coating layer is formed. Here, the valve body 7 is combined with the valve body 7a and the convex part 7b as separate parts. However, the valve body 7 itself may have a shape in which the valve main body 7a and the convex part 7b are integrally formed as one part. it can. The convex portion 7 b enters and is accommodated inside the valve seat 6 in a state where the valve body 7 is seated on the valve seat 6. The convex portion 7b of the present embodiment functions as a protruding skirt portion that forms an orifice in the main body 1 of the flowing water detection device A. Moreover, the convex part 7b functions also as a weight part which ensures the sealing property at the time of closing by immediately returning to the valve closing state when the valve body 7 may be temporarily opened at the time of non-fire. .

A protrusion 10 is formed on the periphery of the valve body 7 so as to protrude from the edge (FIGS. 2 and 3). A first lever 11 </ b> A fixed at the end of the lever shaft 11 is in contact with the surface of the protrusion 10 on the valve seat 6 side. The lever shaft 11 is installed through the main body 1 (FIG. 2), and the first lever 11A can be rotated by the rotation operation of the lever shaft 11. In this way, the rotation of the first lever 11A due to the opening of the valve body 7 (operation of the spraying head) is converted to the rotation operation of the lever shaft 11 without displacement (movement) in the three-dimensional direction and transmitted. It has become. In the state where the first lever 11A is in contact with the valve body 7, the longitudinal direction of the first lever 11A is substantially horizontal (FIG. 3).

A second lever 11 </ b> B is fixedly installed at the outer end of the main body 1 of the lever shaft 11. The lever shaft 11 is fixedly installed substantially in the middle of the second lever 11B (FIGS. 2 and 4). A weight W is provided at the left end of the second lever 11B in the drawing. The weight W urges the first lever 11 </ b> A in the opening direction of the valve body 7 through the second lever 11 </ b> B and the lever shaft 11. At the end opposite to the side where the weight W is installed, when the valve body 7 rotates in the opening direction, the switch device that is turned on when the first lever is rotated by the urging force of the weight W (described later) A limit switch 17) is arranged.

A rotary damper D is installed in the housing 2 as a delay means for the rotation operation of the lever shaft 11. In FIG. 4, the end of the lever shaft 11 protruding into the housing 2 is connected to a gear G <b> 2 and a second lever 11 </ b> B that mesh with the gear G <b> 1 provided on the rotary damper D, and the lever shaft 11 rotates. At the same time, the gear G1 of the rotary damper D is rotatable through the gear G2. As a result, the pivoting operation of the lever shaft 11 becomes slow by the rotary damper D. The rotary damper D of the present embodiment is of a one-way clutch type in which the rotation operation in only one direction is slow. By doing so, the operation of the second lever 11B when the valve body 7 is opened becomes slow, and when the valve body 7 is closed after being opened, the operation of the lever 11B becomes smooth without delay. Does not interfere with operation.

  The housing 2 has a base B formed by bending a plate material in an L-shape and is installed outside the main body 1. Inside the base B, the lever shaft 11, the second lever 11 </ b> B, and the limit switch are provided. 17, a terminal block 18 and the like are provided. The base B is covered with a lid member (not shown), and protects electrical members such as the internal limit switch 17 from dust and water.

In the vicinity of the weight W arranged in the base B, a stopper 19 is provided so as to protrude from the base B. Stopper 19 is a rotation restricting member which is adapted maximum rotation position of the first lever 11A is located inside the locus of rotation of the valve body 7, the first lever 11A is rotating above a predetermined position Configured to not move. This is to return to the closed state while energizing the first lever 11A when returning to the closed state after the valve body 7 is fully opened, and the lever 11A is within the trajectory of the rotational movement of the valve body 7. It is set to be moored. Further, as another action, the limit switch 17 and the second lever 11B are prevented from interfering with each other by the rotation of the lever shaft 11.

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

Then, operation | movement of the flowing water detection apparatus A of this embodiment is demonstrated.

The above-mentioned water flow detection device A is installed in a fire extinguishing equipment pipe, and the primary side chamber I is connected to a water supply device such as a pump (not shown) and a pipe leading to a water source such as a water tank, and a pipe connected to the secondary side chamber II A sprinkler head (not shown) is installed at the end of the head.

The fire extinguishing equipment pipe is filled with water, and the main body 1 of the water flow detector A is also filled with water in 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 the convex portion 7 b enters and is accommodated in the flow path inside the valve seat 6, so that water flows from the primary side chamber I to the secondary side chamber II. Is blocked. Further, the first lever 11A in contact with the valve body 7 is in a substantially horizontal state.

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 has closed the valve body 7 is reduced, so that the valve body 7 is pushed up by the pressure of the water in the primary side chamber I and rotates around the valve rod 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. When the valve body 7 is rotated and the water in the primary side chamber I is sent to the secondary side chamber II, the convex portion 7b of the valve body 7 is gradually removed from the inside of the valve seat 6, so that the outer periphery of the convex portion 7b. An orifice-shaped flow path is formed between the surface and the inner peripheral surface of the valve seat 6, and as a result of the valve body 7 being pushed up by flowing water passing therethrough, the valve body 7 rotates greatly even with a small amount of flowing water. .

When the valve body 7 continues to rotate, the valve body 7 opens as shown in FIG. At the same time, the first lever 11A that has been in contact with the valve body 7 also rotates about the lever shaft 11 as a fulcrum by the urging force of the weight W. At this time, the end of the first lever 11A slowly rotates upward in the figure by the action of the rotary damper D. At the same time, the second lever connected by the lever shaft 11 similarly slowly rotates.

The limit switch 17 is turned on by the rotation of the second lever 11B, and the signal of the limit switch 17 is sent to the monitoring device installed in the manager's room through the lead wire connected to the terminal block 18 in the housing 2. The above-described pump is activated by a signal from the limit switch 17, water is sent from the water source to the sprinkler head activated by the fire, and water is continuously sprayed from the sprinkler head to stop the fire.

The said embodiment is an example of embodiment of this invention, It is also possible to change and implement in another form. Next, an example of the modification will be described.

In the first embodiment described above, the valve shaft 9 and the lever shaft 11 are arranged in parallel as shown in FIG. 2, but not limited to this, the lever shaft with respect to the valve shaft 9 as shown in FIG. It is also possible to arrange so that 11 intersect. Even if it changes to this arrangement | positioning, the effect obtained is the same. As described above, in the flowing water detection device of the present invention, the rotation of the first lever 11A due to the opening of the valve body 7 (operation of the spraying head) is the rotation operation of the lever shaft 11 without displacement (movement) in the three-dimensional direction. And is transmitted to the outside of the main body 1. Therefore, as shown in the two exemplified embodiments, the degree of freedom of layout of the constituent elements is large, and it is possible to flexibly respond to customer requests such as layout change and downsizing.

In the first embodiment described above, the first lever 11A is screwed to the end of the lever shaft 11 on the main body 1 side. However, the first lever 11A and the lever shaft 11 are not separate components. It can also be configured as one part.

2 and 7, since the valve shaft 9 and the lever shaft 11 are independent without contacting each other, the rotation speed of the valve body 7 that rotates with the valve shaft 9 as a fulcrum. And a speed difference by a delay means can be given between the rotation speed of the first lever 11A and the second lever 11B that rotate with the lever shaft 11 as a fulcrum. Due to this difference in speed, the speed of the lever shaft 11 to which the second lever 11B for operating the limit switch 17 is connected is made slower than the rotational speed of the valve body 7, so that the time for which the limit switch 17 is operated is reduced. In addition to the effect of preventing the occurrence of false alarms due to the rotation of the valve body 7 based on the flowing water that is not caused by the operation of the spraying head, the first lever is operated during the opening operation of the valve body 7 11A can be moved away from the valve body 7. Thereby, the surface accuracy and shape restrictions of the surface of the projecting portion 10 of the valve body 7 in contact with the first lever 11A and the contact portion of the first lever 11A with the projecting portion 10 are not so required. More specifically, when the protruding portion 10 and the first lever 11A rotate while being in contact, the first lever 11A is placed on the surface of the protruding portion 10 that contacts the lever 11A so that the rotating operation is smooth. It is necessary to reduce the frictional resistance by providing a coating with an electrodeposition coating layer or the like for improving the sliding property of the first lever 11A or by making the contact portion with the protruding portion 10 of the first lever 11A in an arc shape. If the first lever 11A moves away from the valve body 7 during the opening operation of the valve body 7, the valve body 7 and the first lever 11A rotate away when the valve body 7 is opened, and conversely, the valve body Since the valve body 7 and the first lever 11A rotate while being in contact with each other when the valve 7 is closed, the valve body 7 and the first lever 11A are in contact with each other only during the closing operation in one opening and closing. In particular, the smooth closing operation of the valve body 7 when the valve body is closed by temporarily flowing water can be exhibited continuously over a long period of time.

In the embodiment shown in FIGS. 1 to 6, the rotation operation of the first lever 11 </ b> A and the second lever 11 </ b> B is always interlocked with the delay means (rotary damper D). Is possible. FIG. 8 shows a configuration in which no delay means is interposed in the rotating operation of the valve body 7 and the rotating operations of the first lever 11A and the second lever 11B. In this case, since the valve element 7 is urged in the opening direction by the weight W, which is an urging member, via the first lever 11A and the like, when the spraying head is operated and the valve element 7 is opened. There is an effect that the opening operation of the valve body 7 becomes sharp. Further, when the second lever 11B rotates more than the design value for some reason, the second lever 11B does not act directly on the limit switch 17, and therefore, interference between the limit switch 17 and the second lever 11B is avoided. be able to.

In FIG. 8, the rotary damper D which is a delay means is configured to slow the movement of the switch operating piece 21 whose one end is in contact with the second lever 11B. A weight W is placed on the other end side of the switch operating piece 21, and a limit switch 17 is arranged in the rotation direction on the other end side.

FIG. 8A shows a state in which the valve body 7 is closed, and the second lever 11B is biased upward in the figure by the elastic body 22. When the valve body 7 is opened, the second lever 11B is rotated upward in the figure by the elastic body 22 as shown in FIG. At this time, the rotation range of the second lever 11B is limited by the lever stopper 23. Further, the switch operating piece 21 that has been in contact with the second lever 11B is rotated clockwise by the action of the weight W because the second lever 11B is rotated and separated, and the rotating operation is as follows. The operation is slowed by the rotary damper D. Thereby, generation | occurrence | production of the misreport by rotation of the valve body 7 based on the flowing water which does not depend on the action | operation of a spraying head is prevented. FIG. 6C shows a state where the spraying head is operating, the switch operating piece 21 is rotated, and the limit switch 17 is operated. The switch operating piece 21 is rotated to the position of the stopper 19 to operate the limit switch 17 and turn it on. As a result, the above-described pump is started, water is sent from the water source to the spraying head activated by the fire, and water is continuously sprayed to extinguish the fire.

A Flowing water detector
1 Body
1a opening
1b cover
2 Case
3 Drain valve
6 Valve seat
7 Disc
7a Valve body
7b Convex part (skirt part, weight part)
8 Bearing
9 Valve stem
11 Lever shaft
11A 1st lever
11B Second lever
17 Limit switch (switch device)
18 Terminal block
19 Stopper
21 Switch operation piece
22 projectile
23 Leverstopper
D Rotary damper
W weight (biasing member)

Claims (8)

Flowing water detection comprising a cylindrical main body connected to a fire extinguishing equipment pipe, a valve body with a check valve structure provided inside the main body, and a switch device that detects flowing water due to the rotation of the valve body and outputs a predetermined signal In the device
A lever shaft that is inserted from the outside of the main body into a portion facing the bearing of the valve body, rotates around the shaft , converts the opening / closing operation of the valve body into a rotational operation, and transmits it;
A first lever that is provided at the valve body side end of the lever shaft so as to contact the edge of the valve body in the closed state, and rotates in the opening direction of the valve body by rotation of the lever shaft;
A biasing member that biases the first lever in the opening direction of the valve body;
A second lever provided outside the main body of the lever shaft;
And a switch device that is turned on and off by the rotation of the second lever. The flowing water detection device according to claim 1, further comprising a rotation restricting member that stops the maximum rotation position of the first lever at a position inside the locus of the rotation operation of the valve body. The flowing water detection device according to claim 1, wherein a protruding skirt portion that forms an orifice-shaped flow path inside the main body by rotation of the valve body is provided on a primary side surface of the valve body. The flowing water detection device according to claim 1, further comprising a weight portion that urges the valve body in a closing direction. The water flow detection device according to any one of claims 1 to 4, wherein the weight portion is formed on a primary side surface of the valve body by a projecting skirt portion that forms an orifice inside the main body. The flowing water detection device according to any one of claims 1 to 5, wherein the biasing member is any one of a rubber-like elastic body, a spring, a weight, and a magnet. Flowing water detection comprising a cylindrical main body connected to a fire extinguishing equipment pipe, a valve body with a check valve structure provided inside the main body, and a switch device that detects flowing water due to the rotation of the valve body and outputs a predetermined signal In the device
A lever shaft that is inserted from the outside of the main body into a portion facing the bearing of the valve body and rotates around the shaft;
A first lever that is provided at the valve body side end of the lever shaft so as to contact the edge of the valve body in the closed state, and rotates in the opening direction of the valve body by rotation of the lever shaft;
A biasing member that biases the first lever in the opening direction of the valve body;
A second lever provided outside the main body of the lever shaft;
A switch device that is turned on and off by rotation of the second lever,
Rotary damper provided as delay means for delaying the time from the valve body is opened until the switch device is turned off, and the gear installed in the gear and the lever shaft installed in the rotary damper rotates while meshing lever A flowing water detection device characterized in that the rotation operation of the shaft is slowed down. Flowing water detection comprising a cylindrical main body connected to a fire extinguishing equipment pipe, a valve body with a check valve structure provided inside the main body, and a switch device that detects flowing water due to the rotation of the valve body and outputs a predetermined signal In the device
A lever shaft that is inserted from the outside of the main body into a portion facing the bearing of the valve body and rotates around the shaft;
A first lever that is provided at the valve body side end of the lever shaft so as to contact the edge of the valve body in the closed state, and rotates in the opening direction of the valve body by rotation of the lever shaft;
A biasing member that biases the first lever in the opening direction of the valve body;
A second lever provided outside the main body of the lever shaft;
A switch device that is turned on and off by rotation of the second lever,
A rotary damper is provided as a delay means for delaying the time from when the valve element is opened until the switch device is turned on and off, and the rotary damper has a switch lever that has one end in contact with the second lever and the other end that operates the switch device. It is installed on the rotating shaft of the water flow detector.

Images