JP5694855B2 - Fire hydrant inspection system - Google Patents

Description

The present invention relates to an inspection system for a fire hydrant apparatus that pulls out a hose with a nozzle and extinguishes fire, and more particularly, to a fire hydrant apparatus inspection system that checks a pressure sensor and a pressure gauge for confirming a water discharge pressure during a water discharge inspection.

  Conventionally, an emergency facility has been installed in a tunnel for an automobile exclusive road in order to protect a person and a vehicle from a fire accident occurring in the tunnel. Such emergency facilities include a fire detector and emergency telephone for fire monitoring and reporting, and water spray automatic spraying water from fire hydrant devices and water spray heads for tunnel protection for fire extinguishing. A valve device is provided.

  The fire hydrant device contains a hose with a nozzle. In the event of a fire, the fire hydrant door is opened, the hose with a nozzle is pulled out, and the fire hydrant valve opening / closing lever is operated to discharge water from the nozzle. In addition, the fire hydrant device is provided with an automatic pressure regulating function (automatic pressure regulating valve) that automatically adjusts the water discharge pressure from the nozzle so as not to hinder the user in the event of a fire.

  Emergency facilities in the tunnel are regularly inspected once every six months or once a year. Among them, the fire hydrant device has a function that automatically adjusts the discharge water pressure, and in order to check whether it satisfies the specified fire extinguishing performance, pull out the hose with a nozzle while restricting passage in the tunnel. Check the water discharge to check whether there is any abnormality in the hose, and check the water discharge to check whether the discharge pressure meets the standard. After the inspection is completed, the hose is rolled up and stored in the apparatus while draining water from the hose.

  Since the water discharge check of such a fire hydrant device requires a lot of work and time, such as taking in and out of the hose, draining the water inside the hose and measuring the water discharge pressure, a maintenance device ( At the time of water discharge inspection, a dummy hose with an inspection nozzle is attached to the maintenance device for water discharge inspection, so that the nozzle water discharge state and water pressure can be checked without pulling out and storing the hose. Water discharge inspection has been carried out.

In addition to the above-described periodic inspection, this water discharge inspection may be performed to set the pressure regulation value of the automatic pressure regulating valve when installing the fire hydrant device on site.

JP 2000-279544 A JP 2005-318972 A

  However, in the inspection method of the fire hydrant device using the maintenance device, the inspector goes to the installation location of the fire hydrant device in the tunnel, installs the maintenance device and performs actual water discharge one by one for the inspection. Therefore, it takes a long time to check, and during that time it is necessary to regulate the lane.

  In order to avoid this, stop the actual water discharge by the dummy hose, and switch the pressurized fire-extinguishing water supply path from the hose with nozzle to the drain pipe side at the time of inspection by using a valve, etc. It is conceivable to drain the water through an orifice that causes a loss and measure the discharge pressure with a pressure sensor connected to the secondary side of the automatic pressure regulating valve. With this configuration, lane control is not necessary because inspection can be performed without discharging water on the road side. It is also conceivable to perform such water discharge inspection by remote control by command transmission from the center.

  When such a fire hydrant device is equipped with a pressure sensor and water discharge inspection is performed locally or remotely, the detection accuracy of the pressure sensor as a measuring device provided in the fire hydrant device is important, and it is provided for each fire hydrant device. Work to calibrate the pressure sensor is required. When inspecting the pressure sensor, it is necessary to remove the pressure sensor from the fire hydrant device and connect it to the inspection device for the pressure sensor to check whether the correct water pressure value is output when the inspection water discharge pressure is applied. There is a problem that the inspection of the sensor itself takes time and labor.

  As a member to detect pressure, water pressure is measured mechanically and displayed on the spot in an analog manner with an indicator needle. Generally, it is called a pressure gauge, or the measured water pressure is digitally connected to the outside. There is also a pressure sensor that can output via

  Note that this pressure sensor can be used not only at the time of water discharge inspection, but also to check whether the specified water pressure is being released during actual fire fighting work. It is necessary to perform inspection or calibration.

An object of the present invention is to provide an inspection system for a fire hydrant device that makes it easy and easy to check or calibrate a water pressure detection unit of a pressure sensor or a pressure gauge used for water discharge inspection provided in the fire hydrant device. .

The present invention inspects a fire hydrant device connected with a fire hydrant valve that is opened and closed by operating a lever between a connection part of a water supply pipe to which pressurized fire-fighting water is supplied and a hose connection part connected with a hose with a nozzle. In the fire hydrant inspection system
In the fire hydrant device,
A remote fire hydrant valve connected in parallel to the fire hydrant valve and opened and closed by an external control signal;
Connected to the secondary side of the fire hydrant valve, and in response to an external switching signal, the normal position where the secondary side of the fire hydrant valve communicates with the hose with a nozzle, and the secondary side of the fire hydrant valve communicates with the drain side via the orifice A remote inspection valve for switching between inspection positions to be performed,
A water discharge pressure sensor for detecting the pressure on the primary side of the orifice;
A remote switching valve that switches between a normal position that communicates the secondary side of the fire hydrant valve with the water discharge pressure sensor and a calibration position that communicates the primary side of the fire hydrant valve with the water discharge pressure sensor by an external switching signal;
Provided,
A master pressure sensor for detecting the feed water pressure is provided in the feed water pipe for supplying pressurized fire-fighting water to the fire hydrant device,
In the center device,
The water supply pressure detected by the master pressure sensor is measured as the reference span pressure, and the zero point pressure detected by the water discharge pressure sensor and the remote switching valve calibration position are switched while the remote switching valve is switched to the normal position. Calibration processing unit that measures the span pressure detected by the discharge water pressure sensor and derives the zero point correction constant and span correction coefficient for calibrating the zero point pressure and span pressure of the discharge water pressure sensor to the zero point pressure and span pressure of the master pressure sensor When,
A pressure correction unit that corrects the pressure value detected by the discharge water pressure sensor based on the zero point correction constant and the span correction coefficient;
Is provided.

  The calibration processing unit measures the reference span pressure detected by the master pressure sensor in a static pressure state where there is no water flow in the water supply pipe for the fire hydrant device.

  The center device further switches the remote inspection valve to the inspection switching position, and then opens the remote hydrant valve to remotely perform the inspection water discharge to flow the fire-fighting water to the drainage side through the orifice, and the water is discharged in the water discharge inspection state. An inspection processing unit for measuring the water discharge pressure detected by the pressure sensor is provided.

The present invention also relates to a fire hydrant inspection system in which a fire hydrant valve that is opened and closed by a lever operation is connected between a connection part of a water supply pipe to which pressurized fire-fighting water is supplied and a hose connection part to which a hose with a nozzle is connected. And
In addition to the fire hydrant device,
A check valve that is connected to the secondary side of the hydrant valve and switches between a normal position where the secondary side of the hydrant valve communicates with the hose side with the nozzle and an inspection position where the secondary side of the hydrant valve communicates with the drain side;
An orifice that is provided between the check valve and the drainage side and allows a predetermined check flow rate to flow to the drainage side;
A water discharge pressure detector for detecting the pressure on the primary side of the orifice as the water discharge pressure;
A switching valve for switching between a normal position where the secondary side of the fire hydrant valve communicates with the water discharge pressure detection unit and a calibration position where the primary side of the fire hydrant valve communicates with the water discharge pressure detection unit;
Provided,
A master pressure detection unit for detecting a feed water pressure is provided in a feed water pipe for supplying pressurized fire-fighting water to the fire hydrant device.

  According to the present invention, the value of the master pressure detection unit that has been calibrated as a reference by switching the pipe connection switching at the time of inspection to the inspection (calibration) position and introducing the feed water source pressure to the pressure detection unit. In comparison, it is possible to confirm whether or not the water discharge pressure detection unit on the fire hydrant device side is in a normal state, and the inspection work of the water discharge pressure detection unit provided in the fire hydrant device can be performed easily and easily.

  In addition, the inspection can be performed without sprinkling water for fire extinguishing from the hose with the nozzle and without removing the water discharge pressure detector.

  In addition, by measuring the pressure with the discharge pressure sensor in the connection position that opens to the atmosphere, it is possible to easily and easily grasp whether the value on the zero point side of the end pressure sensor shows the correct value. Can be judged.

  Further, by obtaining a zero point correction constant for calibrating the zero point of the water discharge pressure sensor, the zero point side of the water discharge pressure sensor can be calibrated easily and easily.

  In addition, measure the pressure detected by the master pressure sensor as the reference span pressure and connect the detected pressure of the water discharge pressure sensor to the span pressure in a state where it is connected to the water supply piping side so that pressurized fire extinguishing water is supplied to the water discharge pressure sensor. And comparing the measured reference span pressure with the span pressure, it can be determined whether the water discharge pressure sensor is normal or can be calibrated.

  Furthermore, by calibrating the pressure detection value of the discharge water pressure sensor based on the measured reference span pressure and span pressure, the discharge water pressure detector can be easily calibrated, and then a reliable discharge check can be performed. Can do.

If the pressure measurement of each pressure detection part and the setting of the correction coefficient can be performed remotely by the center device, it is not necessary to go to the site and the calibration of the discharge pressure detection part can be performed easily and easily. .

Explanatory drawing which showed embodiment of the fire hydrant apparatus inspection system by this invention Explanatory drawing which removed the external appearance of the fire hydrant apparatus provided in FIG. Explanatory drawing which showed embodiment of the water discharge valve system and inspection valve system of the fire hydrant apparatus provided in FIG. The block diagram which showed the detail of the terminal unit provided in the center apparatus and fire hydrant apparatus of FIG. Explanatory drawing which showed the graph for calibrating the detection characteristic of a discharge water pressure sensor to the detection characteristic of a master pressure sensor by the pressure calibration part of FIG. The flowchart which showed the pressure calibration process by the pressure calibration part and pressure correction part of FIG. Explanatory drawing which showed other embodiment of the discharge valve system of the fire hydrant apparatus for checking the discharge pressure gauge manually, and the check valve system

  FIG. 1 is a block diagram showing an embodiment of a fire hydrant inspection system according to the present invention. In FIG. 1, a plurality of fire hydrant apparatuses 10 are installed along the side wall of the tunnel at intervals of, for example, 50 meters, and house a hose with a nozzle and a fire extinguisher used for fire extinguishing work. Each of the fire hydrant devices 10 is provided with a terminal unit 12 that exchanges transmission signals with an external device and monitors the detection states of various sensors.

  The terminal unit 12 provided in the fire hydrant device 10 is connected via a transmission line 16 to a center device 14 installed in a monitoring room or the like. The center device 14 transmits a telegram signal including a water discharge check command (hereinafter simply referred to as “telegram”) to the terminal unit 12 or the like when the fire hydrant device 10 is inspected, and performs a water discharge check operation. Prior to the water discharge check, a message is transmitted and received in order to calibrate the water discharge pressure detection unit provided in the fire hydrant device 10.

  A pump control panel 18 and a disaster prevention reception panel 20 are connected to the center device 14. The pump control panel 18 operates the pump facility in response to the pump activation signal associated with the activation of the water spray device from the center device 14 or the remote inspection of the fire hydrant device and the like, and supplies pressurized fire-extinguishing water to the water supply pipe 22.

  The disaster prevention receiving board 20 receives a fire detection signal from a fire detector installed in a tunnel (not shown) and issues a fire alarm. The fire alarm signal is output to the center device 14 in conjunction with the fire alarm. Remote activation of water spray equipment corresponding to the fire area.

  Furthermore, in this embodiment, the master pressure sensor 24 is provided in the water supply piping 22 which supplies the water for fire extinguishing from the pump control panel 18 (pump equipment) to the fire hydrant apparatus 10. The master pressure sensor 24 corresponds to the master pressure detection unit in the claims, and is a pressure sensor that is calibrated periodically to indicate an accurate pressure value, and is filled in the water supply pipe 22 in a normal monitoring state. The pressure of the water for fire extinguishing is detected and sent to the center device 14, and the pressure detected by the master pressure sensor 24 is used as the reference span pressure during the calibration process of the pressure sensor provided in the fire hydrant device 10 in the center device 14. I have to.

  In the present embodiment, processing for calibrating the detection characteristics of the pressure sensors provided in each of the fire hydrant apparatus 10 is performed so as to match the detection characteristics of the master pressure sensor 24 provided in the water supply pipe 22. For the master pressure sensor 24 that serves as a reference for calibrating the pressure sensor provided in the fire hydrant device, the master pressure sensor 24 has been calibrated in advance by an operator in advance before the inspection. 24, the calibration processing is sequentially executed in response to the detection value of the pressure sensor for the fire hydrant device 10 by a message from the center device 14.

  The master pressure sensor 24 outputs, for example, 4 to 20 mA or 1 to 5 V, and the zero point is, for example, 4 mA and the span is 20 mA. At the time of calibration, 4 mA indicating the zero point when the atmospheric pressure is released, and a span of 20 mA at the maximum detected pressure are obtained. adjust.

  As described above, the master pressure sensor 24 requires on-site calibration work prior to the inspection of the fire hydrant device 10, so that the pump control panel 18 close to a monitoring room or the like in which the center device 14 used for the inspection is installed. It is desirable to install in the water supply pipe 22 of the pump equipment.

  2 is an explanatory view of the fire hydrant device installed in the tunnel shown in FIG. 1, FIG. 2 (A) shows the front view, and FIG. 2 (B) shows the internal structure with the fire hydrant door removed. . In FIG. 2 (A), the fire hydrant device 10 is provided with a fire hydrant door 30 and a maintenance door 32 at the door opening on the right side of the decorative plate 28 disposed on the front surface of the housing 26, and the inside is a hose storage space and a valve. It is a kind of storage space. The fire hydrant door 30 can be opened and closed forward about the lower rotation shaft.

  A maintenance door 32 that opens and closes around the upper pivot shaft is provided on the fire hydrant door 30 and can be opened after opening the fire hydrant door 30 during inspection.

  A notification device door 34 is provided on the right side of the left door opening of the housing 26, and a red indicator lamp 36, a transmitter 38, and a response lamp 40 are provided here. The red indicator lamp 36 is always lit so that the installation location of the fire hydrant device 10 can be seen from a distance. In the event of a fire, when the built-in switch is turned on by pressing the transmitter 38, a transmission signal is transmitted to the disaster prevention receiving board 20 via the center device 14 in the monitoring room, a fire alarm is issued, and a response signal is sent to the center device 14 accordingly. The response lamp 40 is turned on.

  A fire extinguisher door 42 is provided on the left side of the notification device door 34, and the inside of the housing 22 corresponding to the fire extinguisher door 42 is used as a fire extinguisher storage space, and two fire extinguishers 45 as shown in FIG. Is housed. The fire extinguisher door 42 can be opened forward with the left side as a pivot. Also, a viewing window 44 is provided below the fire extinguisher door 44 so that the presence or absence of the fire extinguisher can be confirmed from the outside.

  In FIG. 2B, a hose storage space is formed on the left side of the housing 22, and a valve storage space is formed on the right side. The hose storage space is provided with a hose bucket 46 that surrounds the hose 50 and presses the hose 50, and the hose 50 is housed in the hose storage space surrounded by the hose bucket 46 and the inner wall of the housing. The hose bucket 46 partitions and forms a hose outlet 48 at a position that is substantially in the center in the left-right direction of the door opening by the lattice-like frame arrangement.

  On the right side of the hose bucket 46, a nozzle 52 attached to the tip of the hose 50 drawn from the hose outlet 48 is detachably held sideways.

  In the valve storage space arranged on the right side of the hose storage space, a water supply valve 54, a fire hydrant valve, and an automatic pressure control valve 58 are connected to a piping system extending from the fire hydrant connection port to which the water supply pipe 22 from the pump facility is connected to the hose connection port. In addition, a water discharge valve system including an automatic drain valve and a maintenance device 65 and a water discharge check valve system which will be clarified in the following description are provided.

  The fire hydrant valve is opened manually during fire extinguishing work to supply fire water to the hose with nozzle. The fire hydrant valve is provided with a fire hydrant valve opening / closing lever 66, which manually opens and closes the fire hydrant valve arranged on the back side of the operation name plate displaying the operation guide at the time of fire extinguishing. The automatic pressure regulating valve 58 adjusts the fire-extinguishing water flowing from the fire hydrant valve to the hose side to a prescribed pressure, and discharges the fire-extinguishing water from the nozzle 52 at the prescribed pressure. The automatic drain valve is provided on the secondary side of the fire hydrant valve, and is opened in a normal state to drain the fire-fighting water in the pipe existing on the secondary side of the fire hydrant valve. When the fire hydrant valve opening / closing lever 66 is operated to the downward open position in the event of a fire, the fire hydrant valve is actuated to the open position, and the automatic drain valve is switched to the closed state in response to water pressure in the pipe. And the water for fire extinguishing is supplied to the hose 50 side without draining with an automatic drain valve. The maintenance device 65 is a joint to which a hose with a nozzle for inspection can be connected. At the time of inspection, the inspection staff heads for the installation site of the fire hydrant device, and the water is actually discharged from the hose with the nozzle for inspection. Even if 50 is not pulled out from the fire hydrant device, it is possible to check whether or not the specified water discharge pressure can be obtained. Note that the maintenance device 65 may not be provided when the water discharge check of the fire hydrant device is performed only by remote control from the center device 14.

  When the hydrant valve opening / closing lever 66 is operated during the fire extinguishing operation, the valve opening / closing detection switch provided behind the lever is turned on, whereby a pump activation signal is sent to the pump control panel 18 via the center device 14 of FIG. Pump equipment is activated. When stopping the water discharge, returning the hydrant valve opening / closing lever 66 to the original upward position closes the hydrant valve.

  A pump start switch 70 is disposed in front of the water supply valve 54. The water supply valve 54 and the pump start switch 70 are devices operated by the fire brigade when the fire extinguishes. The fire brigade performs fire fighting activities by connecting a hose for the fire brigade to the water supply valve 54 and operating the pump start switch 70. Can be done.

  FIG. 3 is an explanatory view showing an embodiment of a water discharge valve system and a check valve system of the fire hydrant device according to the present invention. In FIG. 3, the valve storage space includes a water supply valve 54, a remote fire hydrant valve 55, a fire hydrant valve 56, an automatic pressure regulating valve 58, a remote inspection valve 60, an orifice 72, a remote three-way switching valve 76, a pressure sensor 78, and an automatic drain valve. 62, a safety valve 64 and a maintenance device 65 are provided.

  The fire hydrant valve 56 is branched and connected to the primary pipe of the water supply valve 54 to which the water supply pipe 22 is connected. The fire hydrant valve 56 is opened and closed by operating the fire hydrant valve opening / closing lever 66 and is opened by the fire extinguishing worker during the fire extinguishing work. It is a valve to do. A remote fire hydrant valve 55 using an electric valve is connected in parallel with the fire hydrant valve 56, and is remotely controlled to open and close by a control signal from the center device 14 at the time of inspection. The automatic pressure regulating valve 58 is connected in series to the secondary side of the fire hydrant valve 56 and adjusts the water discharge pressure on the nozzle 52 side to a predetermined pressure.

  The remote check valve 60 is an electric three-way switching valve, and is connected to the secondary side of the automatic pressure regulating valve 58. By the switching signal from the center device 14, the port a on the secondary side of the automatic pressure regulating valve 58 and the nozzle side Is switched to the normal position for communicating with the port b, or the inspection position for communicating the secondary side port a of the automatic pressure regulating valve 58 with the drain side port c.

  The connection and disconnection states of the ports a to c at the two switching positions in the remote inspection valve 60 are taken out to the lower side of FIG. 3 and are shown as a normal position 60a and an inspection position 60b.

  The orifice 72 is provided in the middle of the remote inspection valve 60 and the drain pipe 74a leading to the drain, and when the remote inspection valve 60 is set to the inspection position, fire extinguishing water having a predetermined inspection flow rate flows to the drain side. That is, the orifice 72 flows a flow rate corresponding to the nozzle 52 and functions as a pseudo nozzle. By discharging the fire-extinguishing water from 74a at the time of inspection, it is possible to realize inspection water discharge equivalent to when water is discharged from the nozzle 52. it can.

  The water discharge pressure sensor 78 detects the pressure on the secondary side of the automatic pressure regulating valve 58 as the water discharge pressure, and the detected water discharge pressure value is sent as measurement information by the terminal unit 12 to the center device 14. In the present embodiment, the discharge pressure sensor 78 is connected via the remote three-way switching valve 76 in order to switch and measure the zero pressure Pa, which is the atmospheric release pressure, and the span pressure Pb of the water supply pipe 22 during the calibration process of the discharge pressure sensor 78. doing.

  The remote three-way switching valve 76 has a port a connected to the secondary side of the automatic pressure regulating valve 58, a port b connected to the primary water supply pipe 22 of the water supply valve 54, and a pressure sensor 78 connected to the port c. Connected. In the normal monitoring state, the remote three-way switching valve 76 is in the normal position 76a shown on the right side where the port a and the port c communicate with each other, and therefore the secondary side of the automatic pressure regulating valve 58 communicates with the water discharge pressure sensor 78. Since the secondary side of the automatic pressure regulating valve 58 communicates with the hose 50 side via the remote check valve 60, the introduction pressure of the water discharge pressure sensor 78 is the atmospheric release pressure.

  Further, in the calibration process of the discharge pressure sensor 78 according to the present embodiment, the remote three-way switching valve 76 is switched to the calibration position 76b shown on the right side where the port b and the port c communicate with each other, whereby the primary side water supply pipe is switched. 22 is introduced into the water discharge pressure sensor 78 so that the same pressure in the water supply pipe 22 as the master pressure sensor 24 shown in FIG. 1 can be detected.

  A maintenance device 65 is provided in the middle of the piping from the remote inspection valve 60 to the hose connection port 67, and an actual water discharge inspection can be performed from the inspection hose instead of the nozzle 52 by connecting the inspection hose. In addition, an automatic drain valve 62 and a safety valve 64 are provided in parallel in a drain pipe 74b extending from the nozzle-side port b to the drain of the remote three-way switching valve 60. The automatic drain valve 62 stops water discharge when the pressure of the pipe is lower than a predetermined pressure. At times, it is opened to prevent convection of water in the pipe, and when the fire hydrant valve 56 is opened, the water pressure rise is detected, the drainage is stopped, and the fire-fighting water regulated by the automatic pressure regulating valve 58 is sent to the nozzle. When the water pressure in the nozzle pipe or hose becomes higher than a predetermined pressure, the safety valve 64 opens the valve and drains fire-fighting water, thereby reducing the pressure in the pipe.

  A remote fire hydrant valve 55, a remote inspection valve 60, and a remote three-way switching valve 76 are connected to the terminal unit 12 as control loads, and a valve opening / closing detection switch 68 of a fire hydrant valve 56 and a discharge pressure sensor 78 are used as a detection unit and an operation unit. And a pump start switch 70 used by the fire brigade.

  Here, the water discharge operation at the time of the fire according to the embodiment of FIG. 3 will be described. In the normal monitoring state of the fire hydrant device 10, the remote check valve 60 is in the normal position 60 a, and the secondary side of the automatic pressure regulating valve 58 is connected via the remote check valve 60 by communicating the port a and the port b. It communicates with the hose 50 with nozzle.

  In the event of a fire, the hydrant door 30 shown in FIG. 2 is opened, and the hydrant valve opening / closing lever 66 is operated to an open position that faces downward. By opening the fire hydrant valve opening / closing lever 66, the fire hydrant valve 56 is moved to the open position, and the pressure-extinguishing water supplied from the water supply pipe 22 is regulated to a predetermined pressure by the automatic pressure regulating valve 58, and then passed through the remote check valve 60. The water is supplied to the hose 50 side and discharged from the nozzle 52.

  At the same time, the valve opening / closing detection switch 68 is turned on by the change in the position of the fire hydrant valve opening / closing lever 66, and the terminal unit 12 transmits a message for detecting the opening operation of the hydrant valve 56 to the center device 14 in FIG. To start the pump equipment.

  The water discharge pressure in the water discharge from the nozzle 52 is introduced into the water discharge pressure sensor 78 via the remote three-way switching valve 76 at the normal position 76a, and the water discharge pressure detected by the water discharge pressure sensor 78 is sent from the terminal unit 12 to the center device 14. The fire hydrant device start-up display and whether or not the water discharge pressure value is normal are monitored, and the water discharge pressure is displayed on the center device 14 if necessary.

  When stopping the water discharge, returning the hydrant valve opening / closing lever 66 to the original upward position closes the hydrant valve 56, and simultaneously turns off the valve opening / closing detection switch 68, so that the terminal unit 12 performs the closing operation to the center device 14 in FIG. A detection telegram is transmitted and a pump stop signal is sent to the pump control panel 18 to stop the operation of the pump equipment.

  Next, the operation | movement at the time of the water discharge check by embodiment of FIG. 3 is demonstrated. When the water discharge check is performed, a water discharge check start operation in which the fire hydrant device is designated is performed by the center device 14 shown in FIG. 1, and a control telegram for the water discharge check is received by the terminal unit 12 accordingly. The terminal unit 12 that has recognized the water discharge check from the received telegram outputs a control signal to the remote check valve 60 and switches from the normal position 60a to the check position 60b. As a result, the secondary side of the automatic pressure regulating valve 58 communicates with the drain pipe 74a through the orifice 72.

  Subsequently, the terminal unit 12 outputs a control signal to the remote fire hydrant valve 55 to control the opening. When the remote fire hydrant valve 55 is opened, the pressurized fire extinguishing water from the water supply pipe 22 is regulated by the automatic pressure regulating valve 58 and then passed through the remote inspection valve 60 which is switched to the inspection position 60b from the orifice 72 to the drain pipe. It flows to 74a and creates a simulated actual water discharge check state.

  The water discharge pressure value detected by the pressure sensor 78 during the water discharge check is sent from the terminal unit 12 to the center device 14 of FIG. 1 and displayed, and it can be determined whether or not an appropriate water discharge pressure is obtained. There is no need to go to the installation site.

  During the inspection, fire extinguishing water only flows from the remote inspection valve 60 to the drain pipe 74a through the orifice 72, and in the tunnel as in the actual water discharge inspection in which a dummy hose with a nozzle is connected to the maintenance device 65. There is no need to discharge water, and there is no need to control the lane in the tunnel at the time of water discharge inspection, so water discharge inspection can be performed easily and easily.

  When it is determined whether or not the water discharge pressure measured by the water discharge check is appropriate, a control message indicating the end of the water discharge check is sent from the center device 14, this control message is received by the terminal unit 12, and a control signal is output to the remote fire hydrant valve 55. At the same time, a pump stop signal is sent from the center device 14 to the pump control panel 18 to stop the operation of the pump equipment.

  With the closing control of the remote hydrant valve 55, the pressure on the orifice 72 side decreases, and when the water discharge pressure detected by the water discharge pressure sensor 78 decreases to the atmospheric release pressure on the drain side, the terminal unit 12 turns to the remote check valve 60. A control signal is output to switch from the inspection position 60b to the normal position 60a, and the water discharge inspection is completed. Switching from the inspection position 60b to the normal position 60a of the remote inspection valve 60 is desirably performed after a predetermined delay time in order to completely drain the fire-extinguishing water remaining in the pipe.

  Each fire hydrant device is inspected by sequentially controlling it. The timing of the inspection may be an operator's inspection start operation in the center device 14, or the center device 14 may automatically inspect periodically.

  When the fire hydrant valve opening / closing lever 66 is opened during the water discharge check, the center device 14 receives the ON signal of the valve opening / closing detection switch 68 and moves the remote check valve 60 to the check position 60b. Is switched to the normal position 60a to switch to the water discharge from the nozzle 52.

  The automatic pressure regulating valve 58 may be provided not on the secondary side of the fire hydrant valve 56 but on the primary side of the automatic pressure regulating valve 58 and the remote fire hydrant valve 55.

  FIG. 4 is a block diagram showing details of a terminal unit provided in the center device and the fire hydrant device of FIG. In FIG. 4, a terminal transmission unit 80 and a terminal processing unit 82 are provided in the terminal unit 12 of the fire hydrant apparatus. As for the terminal processing unit 82, a remote hydrant valve 55, a remote inspection valve 60, and a remote three-way switching valve are used as control loads. 76, and a fire hydrant valve opening / closing detection switch 68, a pump activation switch 70, and a discharge pressure sensor 78 are provided as sensors. A sensor for monitoring the switching position of each switching valve connected to the terminal unit 12 may be provided in each switching valve so that the center device 14 can monitor the sensor via the terminal unit 12.

  On the other hand, a center transmission unit 84 and a center processing unit 86 are provided in the center device 14, and a display unit 94, an operation unit 96, an alarm unit 98, and a storage unit 100 are connected to the center processing unit 86. The center processing unit 86 is provided with a fire hydrant device monitoring unit 87, an inspection processing unit 88, a calibration processing unit 90, and a pressure correction unit 92 as functions realized by execution of a program by the CPU of the computer. Further, a transmission line from the master pressure sensor 24 provided on the water supply pipe side with respect to the fire hydrant device is connected to the center transmission unit 84.

  The fire hydrant monitoring part 87 provided in the center processing part 86 turns on the fire hydrant valve detection switch 68 when the fire hydrant valve opening / closing lever 66 is operated to the open position when the fire hose withdraws the nozzle hose from the fire hydrant device and discharges water. When receiving a telegram based on the terminal unit 12, a pump activation signal is sent to the pump control panel 18 to activate the pump equipment.

  Then, based on the measurement message of the water discharge pressure detected by the water discharge pressure sensor 78 received from the terminal unit 12, the operation display of the fire hydrant device is displayed on the display unit 98 when the water discharge pressure is obtained. The received water discharge pressure is compared with a predetermined normal water pressure range to display whether the water discharge state is normal or abnormal. Further, when a message based on turning off the hydrant valve detection switch 68 is received from the terminal unit 12, a pump stop signal is sent to the pump control panel 18 to stop the pump equipment.

  The inspection processing unit 88 transmits a control message for water discharge inspection to the terminal unit 12 based on the inspection instruction operation of the person in charge or the arrival of the automatic inspection time during the periodic inspection of the fire hydrant device 10 to perform the water discharge inspection.

  Prior to the water discharge inspection by the inspection processing unit 88, the calibration processing unit 90 and the pressure correction unit 92 operate based on the calibration instruction operation of the person in charge and the calibration instruction due to the arrival of the automatic calibration time, and the water discharge provided in the fire hydrant apparatus 10 The pressure detection unit of the pressure sensor 78 is calibrated to determine whether a correct water discharge pressure can be detected, and the pressure detection value is corrected. The inspection process of the water discharge pressure sensor 78 may be performed immediately before the water discharge inspection, or the center device may automatically check and calibrate the water discharge pressure sensor periodically.

  At the time of calibration, the calibration processing unit 90 first measures the feed water pressure detected by the master pressure sensor 24 provided in the feed water pipe 22 as the reference span pressure Pm.

  Next, the calibration processing unit 90 transmits a measurement request message instructing the terminal unit 12 to measure the detected pressure in the normal monitoring state of the water discharge pressure sensor 78. The terminal processing unit 82 that has received this measurement request message reads the atmospheric open pressure on the hose side detected by the water discharge pressure sensor 78 at that time, and transmits it to the center device 14 as the zero point pressure Pa of the water discharge pressure sensor 78. As a result, the calibration processing unit 90 can obtain the atmospheric open pressure on the hose 50 side, that is, the zero point pressure Pa that the water discharge pressure sensor 78 communicates with the normal position 60a of the remote check valve 60 in the normal monitoring state. At this time, it is determined whether or not the zero point pressure Pa indicates a predetermined calibratable range that can be calibrated. If the zero point pressure Pa is outside the calibratable range, the water discharge pressure sensor 78 can no longer be used for inspection, and the calibration is performed. Since it is impossible to do so, the abnormality of the water discharge pressure sensor 78 is warned.

  If the discharge water pressure sensor 78 is not abnormal, the calibration processing unit 90 subsequently transmits a switching control message for the remote three-way switching valve 76 to the terminal unit 12. Upon receiving this switching control message, the terminal processing unit 82 of the terminal unit 12 makes the remote three-way switching valve 76 shown in FIG. 3 calibrate from the normal position 76a that communicates the ports a and c to the ports b and c. Switching to the position 76b, thereby introducing the same pressure of the water supply pipe 22 as introduced into the master pressure sensor 78, detecting the detected pressure value of the water discharge pressure sensor 78 obtained at this time as the span pressure Pb, and measuring response message Is transmitted to the center device 14 and taken into the calibration processing unit 90.

  As a result, the calibration processing unit 90 includes the reference span pressure Pm, which is the feed water pressure detected by the master pressure sensor 24, the zero point pressure Pa of the discharge water pressure sensor 78 to be calibrated, and the master pressure sensor 24 detected by the discharge water pressure sensor 78. A span pressure Pb based on the same feed water pressure is acquired.

  Subsequently, the calibration processing unit 90 compares the reference span pressure Pm detected by the master pressure sensor 24 with the span pressure Pb of the discharge water pressure sensor 78, and if the difference between the values is lower than a predetermined calibratable value, the calibration process. If the difference is larger than a value that can be calibrated, it is determined that calibration is no longer possible, the calibration process is terminated, and an abnormality warning of the water discharge pressure sensor 78 is output.

  If the water discharge pressure sensor 78 is normal, the calibration processing unit 90 then sets the zero pressure Pa of the water discharge pressure sensor 78 to the atmospheric release pressure, and further uses the span pressure Pb of the water discharge pressure sensor 78 as a reference master pressure sensor. A zero point correction constant and a span correction coefficient, which are correction elements for calibrating to match the 24 reference span pressure Pm, are obtained.

  FIG. 5 is an explanatory diagram showing a graph for calibrating the detection characteristic of the water discharge pressure sensor based on the detected pressure value of the master pressure sensor by the calibration processing unit 90 of FIG. In FIG. 5, the horizontal axis indicates the master pressure sensor value Px, and the vertical axis indicates the water discharge pressure sensor value Py. The master pressure sensor 24 measures the reference span pressure Pm corresponding to the feed water pressure. The result of calibrating the water discharge pressure sensor 78 so as to match 24 is given by the straight line 102 connecting the zero point of Px = Py = 0 and the point D (Pm, Pm) where Px = Py = Pm.

  However, the water discharge pressure sensor 78 is deviated from the zero point of the master pressure sensor 24 and the reference span pressure Pm before calibration. For example, it is assumed that the zero point pressure of the water discharge pressure sensor 78 is the zero point pressure Pa at the point A, and the span pressure when measured by introducing the same feed water pressure as that of the master pressure sensor 24 is, for example, Pb at the point B. Therefore, the detection characteristic of the water discharge pressure sensor 78 is a detection characteristic of a straight line 104 connecting the point A (0, Pa) and the point B (Pm, Pb) that determines the span.

  Therefore, in order to make the characteristic of the straight line 104 that is the detection characteristic of the discharge pressure sensor 78 coincide with the characteristic of the straight line 102 that matches the characteristic of the master pressure sensor 24, a zero point correction constant and a span correction coefficient are obtained. First, the zero point correction constant should be moved from the zero point A of the straight line 104 to the zero point which is the origin of the straight line 102. Therefore, the zero point correction constant Pa is set to Pa, and this zero point correction constant Pa is set to the measured discharge water pressure sensor. What is necessary is just to subtract from the pressure Py. By the subtraction of the zero point correction constant Pa, the straight line 104 that is the characteristic of the water discharge pressure sensor 78 is calibrated to the characteristic of the translated straight line 106.

When the zero point adjustment is completed by calibrating the straight line 106 in this way, a span correction coefficient K for calibrating the C point for determining the next span to the D point for determining the span of the straight line 102 serving as the reference characteristic is set. Ask. Since the coordinates of the point C are (Pm, Pc), the span correction coefficient K for calibrating the point C to the point D in the Y-axis direction is K = Pm / Pc = Pm / (Pb−Pa) ( 1)
As given. Therefore, the correction equation for correcting the measured value Py of the measured discharge water pressure sensor 78 to a pressure having the same detection characteristic as the master pressure sensor is Py = K (Py−Pa) (2)
It becomes.

  In FIG. 5, the case where the zero point pressure Pa of the water discharge pressure sensor is shifted to the plus side is taken as an example, but even when the zero point pressure Pa is shifted to the minus side, the above ( 1) The formula (2) can be applied as it is.

  As described above, the calibration of the water discharge pressure sensor in this embodiment is not the calibration with the water discharge pressure sensor itself removed, but the measured discharge water pressure sensor so as to match the detection characteristics of the master pressure sensor calibrated in advance. By calibrating the measured values, the correct pressure can be obtained without going to the site for calibration.

  Referring again to FIG. 4, the pressure correction unit 92 provided in the center processing unit 60 is measured from the discharge water pressure sensor 78 after the zero point correction constant Pa and the span correction coefficient K are obtained by the calibration processing by the calibration processing unit 90. The measured pressure Py is corrected in accordance with the equation (2), and the correction result is displayed on, for example, the display unit 94, or the discharge operation is displayed by determining the discharge operation from the corrected pressure.

  FIG. 6 is a flowchart showing the pressure calibration processing by the pressure calibration unit and the pressure correction unit of FIG. 4, and is a processing flow realized by executing a program by the CPU of the computer.

  In the pressure calibration process of FIG. 6, first, in step S1, the operator determines whether or not there is a pressure calibration request for the water discharge pressure sensor using the operation unit 96 or the like, and if the pressure calibration request is determined, the process proceeds to step S2. It is confirmed that the water supply pipe 22 is in a static pressure state without running water. The static pressure state may be confirmed by confirming that there is no fire hydrant device operating by looking at the display unit 94 of the center device 14, which may be performed artificially or processed by the center processing unit 86. It may be performed as a function.

  The confirmation of the static pressure state without running water in the feed water pipe 22 is that if there is running water, the feed water pressure at the position of the feed water pipe 22 where the master pressure sensor 24 is installed, and the feed water pipe of the discharge pressure sensor 78 that actually performs the inspection. Since there is a difference in the water supply pressure at the position 22, in order to avoid this, the static pressure state is confirmed and the calibration process is performed.

  Subsequently, in step S3, the pressure value Pm of the master pressure sensor 24 calibrated in advance is measured as the reference span pressure. Next, the zero point pressure Pa of the water discharge pressure sensor 78 is measured in step S4. At this time, as shown in FIG. 3, the remote three-way switching valve 76 is in the normal position 76 a, and is measured in a state where the port a and the port c are communicated and the air release pressure on the hose side is introduced into the discharge pressure sensor 78. .

  Subsequently, in step S 5, the remote three-way switching valve 76 of FIG. 3 is switched to the calibration position 76 b that connects the port b and the port c, and the water supply pressure of the primary side water supply pipe 22 is introduced into the water discharge pressure sensor 78. In this state, the water supply pressure Pb is measured as a span pressure by the water discharge pressure sensor 78 in step S6.

  Subsequently, after returning the remote three-way switching valve 76 to the original normal position 76a in step S7, the zero point correction constant Pa and the span correction coefficient K are calculated based on the reference span pressure Pm, the zero point pressure Pa and the span pressure Pb in step S8. To do.

  The next steps S9 to S12 are processing of the pressure correction unit 92 in FIG. In step S9, it is determined whether the remote water discharge inspection is performed. When the remote inspection is determined, the process proceeds to step S10, the pressure Py of the water discharge pressure sensor 78 is measured, and then in step S11, based on the equation (2). The correction calculation is executed, and the corrected correction pressure Py is output in step S12.

  Fig. 7 shows the piping system and control system of the fire hydrant device for manual inspection of the pressure gauge at the site where the fire hydrant device is installed when a pressure gauge is always installed as a pressure detection unit that displays the discharge pressure on the fire hydrant device. It is explanatory drawing which showed other embodiment of the shown this invention.

  In FIG. 7, a fire hydrant valve 56, an automatic pressure regulating valve 58, and an inspection valve 160 are provided in a piping system from the primary side of the water supply valve 54 connected to the water supply pipe 22 to the hose 50. The arrangement of the fire hydrant valve 56 and the automatic pressure regulating valve 58 may be reversed. An orifice 72 is provided in the drain pipe 74a connected to the port c of the check valve 160 so that an inspection water discharge amount equivalent to the actual water discharge amount when water is discharged from a predetermined nozzle 52 flows. A drain pipe 74b is connected from the hose side pipe of the check valve 160, and an automatic drain valve 62 and a safety valve 64 are connected in parallel there.

  The check valve 160 is connected to the secondary side of the automatic pressure regulating valve 58, and between the automatic pressure regulating valve 58 and the check valve 60, in order to display the discharge pressure from the hose 50 with the nozzle, a three-way switching valve 176 is used. A water discharge pressure gauge 178 having a pressure display unit is connected, and further, a pressure switch 180 capable of outputting a water discharge signal to the outside when a predetermined pressure is detected in parallel with the water discharge pressure gauge is connected.

  The three-way switching valve 176 has ports a, b, and c, and is a valve that can be manually switched. In the normal monitoring state, the three-way switching valve 176 is in a normal position 176a that is extracted and shown on the left side that connects the ports b and c. In this way, when the water discharge pressure gauge 178 is introduced to the atmospheric open pressure on the hose 50 side, the water discharge pressure is displayed when the fire hydrant valve 56 is opened at the time of fire extinguishing work or inspection, and the water discharge pressure rises to a predetermined pressure In addition, the pressure switch 180 is turned on so that a water discharge signal can be output. The port a of the three-way switching valve 176 is connected to the water supply pipe 22 on the primary side of the water supply valve 54.

  Further, the three-way switching valve 176 can be switched to the inspection position 176b shown by taking out the port a and the port c on the left side when the discharge pressure gauge 178 is inspected, so that the pressure of the water supply pipe 22 can be introduced and displayed. Yes.

  On the other hand, similarly to the embodiment of FIG. 1, a master pressure gauge 124 serving as a reference for pressure display is connected to the water supply pipe 22 at a position close to the center device and the pump equipment.

  The inspection of the discharge pressure gauge 178 in the embodiment of FIG. 7 is performed on the spot. At the time of inspection, first, calibration is performed to adjust the zero point and span of the master pressure gauge 124 connected to the water supply pipe 22 to a correct value by using a pressure inspection device or the like, so that the master pressure gauge 124 can correctly display the pressure. Then, the calibrated master pressure gauge 124 is connected to the water supply pipe, and the displayed water supply pressure Pm is read and recorded.

  After that, we go to the fire hydrant device 10 and check the water discharge pressure gauge 178. The inspection of the discharge pressure gauge 178 is performed by checking the discharge pressure gauge 178 at the normal position 176a of the three-way switching valve 176 in the normal monitoring state and confirming the zero point due to the atmospheric open pressure, and then connecting the three-way switching valve 176 to the port a and the port c. Switching to the calibration position 176b to be performed, the water supply pressure of the primary water supply pipe 22 is introduced into the water discharge pressure gauge 178.

  At this time, if the water discharge pressure gauge 178 is normal, the pressure display is a display approximate to the same pressure Pm as the master pressure gauge 124 already measured as a reference, and the water discharge pressure gauge 178 can be confirmed to be normal. On the other hand, if the display of the feed water pressure of the discharge pressure gauge 178 is displayed with a large error that cannot be ignored from the display pressure Pm of the master pressure gauge 124, the discharge pressure gauge 178 displays the correct pressure. In this case, the water discharge pressure gauge 178 is replaced with a new adjusted pressure gauge.

  At the time of checking the discharge pressure gauge 178 by introducing the feed water pressure by switching the three-way switching valve 176, the feed water pressure is also introduced into the pressure switch 180 at the same time, and the pressure switch 180 is operated to output a discharge check signal to the center side. . Therefore, the operation check of the pressure switch 180 can also be performed at the same time.

  For the water discharge inspection using the inspection valve 160 of FIG. 7, the inspection valve 160 is manually switched from the normal position 160a to the inspection position 160b, and the fire hydrant valve 56 is installed with the inspection valve 160 in communication with the ports a and c. By manually opening and discharging the fire-fighting water through the orifice 72, the pressure value is measured by the pressure gauge 178 from the port b of the three-way switching valve 176 at the normal position 176a through the port c. You can display and check the discharge pressure.

  In the embodiment of the fire hydrant device that enables remote inspection in FIG. 3, only the water discharge pressure sensor 178 is provided for remote inspection, but it is also necessary to check the pressure on site if necessary. Therefore, a pressure gauge may be connected in parallel with the water discharge pressure sensor 178.

  Moreover, although said embodiment has taken the case of calibrating a water discharge pressure sensor prior to the water discharge check of a fire hydrant device as an example, it may be made to perform calibration of a water discharge pressure sensor at an appropriate timing as needed. Good.

  3 and 7 are connected to the secondary side of the automatic pressure regulating valve 58 to detect both the water discharge pressure during fire extinguishing and the inspection. When the pressure detection at the time of fire extinguishing is unnecessary, the port a of the water discharge pressure detection unit 78, 178 may be connected between the port c of the remote check valve 60 or the check valve 160 and the orifice 72. The automatic pressure regulating valve may be a constant flow valve.

  Moreover, the process of the flowchart in said embodiment demonstrated the schematic example, and the order of a process etc. are not limited to this. In addition, it is possible to take an appropriate form such as providing each process, a delay time between processes, and introducing other determinations.

The present invention includes appropriate modifications that do not impair the objects and advantages thereof, and is not limited by the numerical values shown in the above embodiments.

10: Fire hydrant device 12: Terminal unit 14: Center device 24: Master pressure sensor 55: Remote fire hydrant valve 56: Fire hydrant valve 58: Automatic pressure control valve 60: Remote check valve 72: Orifice 76: Remote three-way switching valve 78: Water discharge pressure sensor 80: Terminal transmission unit 82: Terminal processing unit 84: Center transmission unit 86: Center processing unit 88: Water discharge inspection unit 90: Calibration processing unit 92: Pressure correction unit 124: Master pressure gauge 160: Inspection valve 176: Three-way switching valve 178 : Discharge pressure gauge 180: Pressure switch

Claims (4)

A fire hydrant inspection system that inspects a fire hydrant device connected to a fire hydrant valve that is opened and closed by lever operation between the connection part of the water supply pipe to which pressurized fire-fighting water is supplied and the hose connection part to which a hose with a nozzle is connected. In
In the fire hydrant device,
A remote fire hydrant valve connected in parallel to the fire hydrant valve and opened and closed by an external control signal;
Connected to the secondary side of the fire hydrant valve, and by a switching signal from the outside, a normal position where the secondary side of the fire hydrant valve communicates with the hose side with the nozzle, and a secondary side of the fire hydrant valve via an orifice A remote inspection valve that switches between inspection positions communicating with the drainage side;
A water discharge pressure sensor for detecting the pressure on the primary side of the orifice;
A remote switching valve for switching between a normal position where the secondary side of the fire hydrant valve communicates with the water discharge pressure sensor and a calibration position where the primary side of the fire hydrant valve communicates with the water discharge pressure sensor by an external switching signal; ,
Provided,
A master pressure sensor for detecting a feed water pressure is provided in a feed water pipe for supplying pressurized fire-fighting water to the fire hydrant device,
In the center device,
The feed water pressure detected by the master pressure sensor is measured as a reference span pressure, and the zero point pressure detected by the water discharge pressure sensor in a state where the remote switching valve is switched to the normal position, and the calibration position of the remote switching valve The zero point correction constant and span correction for measuring the span pressure detected by the discharge pressure sensor in the state of switching to the zero pressure and the span pressure of the master pressure sensor are measured. A calibration processor for deriving coefficients;
A pressure correction unit that corrects the pressure value detected by the water discharge pressure sensor based on the zero point correction constant and the span correction coefficient;
A fire hydrant inspection system characterized by comprising
2. The fire hydrant apparatus inspection system according to claim 1, wherein the calibration processing unit measures a reference span pressure detected by the master pressure sensor in a static pressure state where no water flows in a water supply pipe for the fire hydrant apparatus. A fire hydrant inspection system characterized by that.
2. The fire hydrant inspection system according to claim 1, wherein the center device further controls the opening of the remote hydrant valve after switching the remote inspection valve to an inspection switching position, and extinguishes fire to the drain side through the orifice. 3. A fire hydrant apparatus inspection system comprising: an inspection processing unit for remotely performing inspection water discharge for flowing water and measuring the water discharge pressure detected by the water discharge pressure sensor in the water discharge inspection state.
In a fire hydrant inspection system in which a fire hydrant valve that is opened and closed by lever operation is connected between the connection part of the water supply pipe to which pressurized fire-fighting water is supplied and the hose connection part to which a hose with a nozzle is connected.
In addition to the fire hydrant device,
Inspection that is connected to the secondary side of the hydrant valve and switches between a normal position where the secondary side of the hydrant valve communicates with the hose side with the nozzle and an inspection position where the secondary side of the hydrant valve communicates with the drain side A valve,
An orifice that is provided between the check valve and the drain side, and allows a predetermined check flow rate to flow to the drain side;
A water discharge pressure detector for detecting the pressure on the primary side of the orifice as the water discharge pressure;
A switching valve for switching between a normal position where the secondary side of the fire hydrant valve communicates with the water discharge pressure detection unit and a calibration position where the primary side of the fire hydrant valve communicates with the water discharge pressure detection unit;
Provided,
A fire hydrant inspection system comprising a master pressure detection unit for detecting a water supply pressure in a water supply pipe for supplying pressurized fire-fighting water to the fire hydrant device.

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