JP5911099B2 - Piping system and water supply control method applied to piping system - Google Patents

Description

  The present invention relates to a piping system that is applied to a fire hydrant for fire extinguishing, a sprinkling facility for fire suppression, and the like, particularly when a part of piping is broken by an earthquake so that the entire system does not stop functioning. The present invention relates to a piping system and a water supply control method applied to the piping system.

  One example of a piping system used for public fire extinguishing equipment is one that responds to a fire that occurs in a tunnel. In such tunnel application examples, a piping system with main piping is constructed for a plurality of tunnels that exist via bridges, etc., and centralized management is performed by a central control panel, so that fire hydrants arranged in a distributed manner Water is supplied to the watering equipment via the main pipe (see, for example, Patent Document 1).

JP 2010-5240 A

However, the prior art has the following problems.
In a system in which main piping is provided via a plurality of tunnels or a plurality of bridges, it is conceivable that the piping provided in the bridge portion is broken due to the occurrence of an earthquake. When such a rupture occurs, water leakage occurs at the ruptured portion of the piping system, and it is considered that the entire system is in a function stop state.

  The present invention has been made to solve the above-described problems. When piping such as a bridge portion is broken by an earthquake, a fire extinguishing system (fire hydrant for fire extinguishing, watering equipment for fire suppression, etc.) ) The purpose is to obtain a water supply control method applied to a piping system and piping system that minimizes the piping malfunction range so that the entire system does not stop functioning.

  The piping system according to the present invention is provided in a plurality of locations of the main piping for supplying pressurized water from the pressurized water supply source to the fire extinguishing equipment or the watering device installed for each of the plurality of fire prevention sections, and the main piping, Provided on the upstream side of multiple emergency shut-off valves and multiple emergency shut-off valves that can switch between shutoff / distribution of pressurized water supply flowing through the main pipe by opening and closing control, and detects the pressure of pressurized water supply When identifying the location where the breakage occurred in the multiple pressure sensors and main piping, after closing all of the multiple emergency shut-off valves, open the emergency shut-off valves sequentially in order from the vicinity of the pressurized water supply source. As the rupture occurrence location is specified by monitoring the detection value of the pressure sensor and the rupture occurrence location is specified, a plurality of pressure supply waters are not supplied to the specified rupture occurrence location. Emergency shielding In which a control unit for controlling the respective open and closed states of the valve.

  In addition, the water supply control method applied to the piping system according to the present invention includes a main pipe for supplying pressurized water from a pressurized water supply source to a fire extinguishing facility or a watering device installed for each of a plurality of fire prevention sections, Provided at multiple locations on the main pipe and on the upstream side of each of the multiple emergency shut-off valves and the multiple emergency shut-off valves that can be switched between shut-off / circulation of pressurized feed water flowing through the main pipe by opening and closing control , A plurality of pressure sensors for detecting the pressure of the pressurized water supply, and a control unit for identifying the breakage occurrence point in the main pipe by monitoring the detection results by the plurality of sensors while switching the open / close state of the plurality of emergency shut-off valves A method for controlling the water supply applied to a piping system comprising: a step of closing all of the plurality of emergency shut-off valves in a control unit; Steps to identify the location where the rupture occurred by sequentially opening the emergency shut-off valves sequentially from the vicinity of the water supply source and monitoring the detection value of the pressure sensor, and when the location where the rupture occurred is identified And a step of controlling the open / closed state of each of the plurality of emergency shut-off valves so that the pressurized water supply is not supplied to the specified breakage occurrence location.

  According to the piping system and the water supply control method applied to the piping system according to the present invention, an emergency shut-off valve that can be controlled to open and close is provided at a plurality of locations, and a pressure sensor is provided on each primary side of the plurality of emergency shut-off valves. In response to the detection status of the pressure sensor, the emergency shut-off valve is controlled to open and close so that when the piping (bridge piping, etc.) breaks due to an earthquake, the entire fire extinguishing system will not stop functioning. A piping system that minimizes the range and a water supply control method applied to the piping system can be obtained.

It is a whole lineblock diagram of a piping system in Embodiment 1 of the present invention. It is a figure for demonstrating the detail of the on-off valve mechanism part in Embodiment 1 of this invention. It is a specific layout figure of the piping system in Embodiment 1 of the present invention. In the piping system which concerns on Embodiment 1 of this invention, it is the flowchart which showed the series of processes regarding the opening / closing control of the emergency shut-off valve performed by the integrated control panel. In the piping system which concerns on Embodiment 1 of this invention, it is the flowchart which showed the series of processes regarding the opening / closing control of the emergency shut-off valve performed by the integrated control panel. In the piping system which concerns on Embodiment 1 of this invention, it is the flowchart which showed the series of processes regarding the opening / closing control of the emergency shut-off valve performed by the integrated control panel. In the piping system which concerns on Embodiment 1 of this invention, it is the flowchart which showed the series of processes regarding the opening / closing control of the emergency shut-off valve performed by the integrated control panel. In the piping system which concerns on Embodiment 1 of this invention, it is the flowchart which showed the series of processes regarding the opening / closing control of the emergency shut-off valve performed by the integrated control panel.

  Hereinafter, preferred embodiments of a piping system and a water supply control method applied to the piping system of the present invention will be described with reference to the drawings.

Embodiment 1 FIG.
FIG. 1 is an overall configuration diagram of a piping system according to Embodiment 1 of the present invention. In the piping system according to the first embodiment, one integrated control panel 10 is interconnected with a plurality of distributed control panels 30 via an IP network 20. In FIG. 1, a case where a total of six distributed control panels 30 of A1 to A4 and B1 and B2 are provided is illustrated.

  Each of the distributed control panels 30 includes an on-off valve mechanism 31 having an emergency shut-off valve that can be electrically opened and closed to switch off / flow of water flowing in the pipe, and a primary side of the emergency shut-off valve. And a pressure sensor 32 that detects the pressure in the pipe of the supplied water.

  FIG. 2 is a view for explaining details of the on-off valve mechanism 31 in Embodiment 1 of the present invention. The on-off valve mechanism 31 includes a motor 31a, an electric butterfly valve V1 electrically driven by the motor 31a, manual butterfly valves V2 and V3 provided on both sides of V1, and a manual butterfly valve V4 provided on the bypass path. And is configured.

  Here, in the normal state, the manual butterfly valves V2 and V3 are in a fully open state, the manual butterfly valve V4 is in a fully closed state, and the electric butterfly valve V1 is controlled to open and close, so that the water flowing in the pipe Can be switched off / distributed. Therefore, in the following description, the on-off valve mechanism 31 is referred to as an emergency shut-off valve as a general term for the operation by the electric butterfly valve V1 that can be controlled to open and close, and the on-off valve mechanism 31 that can be controlled to open and close by each distributed control panel 30. The emergency shutoff valves A1 to A4, B1, and B2 will be referred to.

  The pressure sensors 32 are provided as a pair on one of the electric butterfly valves V1 (hereinafter referred to as the upstream side), and can detect the pressure in the pipe. Therefore, the pressure sensor 32 is a pipe internal pressure that is blocked on the upstream side when the electric butterfly valve V1 is closed, or a pipe that passes through the upstream side when the electric butterfly valve V1 is open. The internal pressure can be detected. The valve V1 is not limited to the electric butterfly valve as long as it can be remotely controlled, and may be an electromagnetic valve or the like.

  Next, a specific piping system in the first embodiment will be described. FIG. 3 is a specific layout diagram of the piping system according to Embodiment 1 of the present invention. FIG. 3 shows a case where there are a total of six distributed control panels 30 corresponding to FIG. 1, and A1 to A4 representing the on-off valve mechanism 31 that each distributed control panel 30 has. 6 emergency shut-off valves B1, B2 are illustrated.

  Further, the piping system shown in FIG. 3 exemplifies emergency facilities installed in a tunnel, in which two tubes, an upstream line and a downstream line, are used as one water distribution system. That is, the emergency cutoff valves A1 to A4 are provided on the upstream line of the two tubes, and the emergency cutoff valves B1 and B2 are provided on the downstream line of the two tubes. Although not clearly shown in FIG. 3, there is a tunnel or bridge between adjacent emergency shutoff valves, and there is a fire extinguishing facility or the other end of the branch pipe connected to the main pipe. Watering equipment (watering equipment) is connected. Fire extinguishing equipment or sprinkling equipment is provided in each necessary fire prevention zone.

  Also, as shown in FIG. 3, the six emergency shutoff valves are connected by a main pipe constituting a loop pipe, and the main pipe includes a fire extinguishing pump P1 as a pressurized water supply source, or an automatic water supply device P2, The water stored in the main water tank WT is supplied by P3. Here, the automatic water supply apparatuses P2 and P3 always pressurize the inside of the main pipe at a constant pressure, and are operated alternately every 8 hours, for example. The fire pump P1 is a pump that is operated to supply a large amount of water in an emergency such as fire extinguishing, and has a capability of supplying a larger volume of water than the automatic water supply devices P2 and P3.

  Further, as shown in FIG. 2, each emergency shut-off valve is on the upstream side (specifically, on the downstream side of the upstream manual butterfly valve V2 and on the upstream side of the electric butterfly valve V1). The pressure sensor 32 is provided, and on the paper surface of FIG. 3, the right side position (that is, the side close to the main water tank WT) of each emergency shutoff valve is the upstream side.

  Thus, the present application has a technical feature of configuring a piping system in which emergency shut-off valves are provided at a plurality of locations with respect to the main piping. And in such a piping system, for example, considering the case where the main piping breaks between the emergency shut-off valve A3 and the emergency shut-off valve A4 due to the influence of an earthquake, it has such a technical feature. Thus, the following effects can be obtained.

  That is, when the main pipe breaks between the emergency cutoff valve A3 and the emergency cutoff valve A4, only the emergency cutoff valves A3, A4 are closed and the remaining emergency cutoff valves A1, A2, B1, B2 are closed. The open state prevents the entire piping system from being in a function stop state, and the piping malfunction range can be limited to the range between the emergency shutoff valves A3 and A4.

  Therefore, next, the integrated control panel 10 shown in FIG. 1 controls the on-off valve mechanism 31 connected to each emergency shutoff valve based on information from the pressure sensor 32 connected to each distributed control panel 30. A specific processing procedure for preventing the entire piping system from being in a function stop state by controlling will be described in detail with reference to the flowcharts of FIGS.

  4 to 8 are flowcharts showing a series of processes related to the opening / closing control of the emergency shut-off valve performed by the overall control panel 10 in the piping system according to Embodiment 1 of the present invention. 5 to 8 correspond to flowcharts in which the contents processed separately for each case in the abnormal state are collectively displayed as a subroutine in the main flowchart shown in FIG.

  Moreover, in the following description, it describes as each process of FIGS. 4-8 performed by the control part 11 (not shown) in the integrated control panel 10. FIG. At that time, in the configuration shown in FIG. 1, the control unit 11 exchanges information with each distributed control panel 30 via the IP network 20. However, the system configuration by the IP network 20 is not essential, and in the following description, the control unit 11 directly reads the detection result of the pressure sensor 32 and directly controls each emergency shut-off valve in order to simplify the description. Describe in form.

First, the main flowchart shown in FIG. 4 will be described.
In step S401, the control unit 11 monitors the pressure sensor 32 provided upstream of each of the emergency shutoff valves A1 to A4, B1, and B2, and any one of the pressure sensors 32 has become a pressure equal to or lower than a predetermined value. Is detected, it is determined that a pressure abnormality has occurred in the main pipe, and the processing from step S402 is performed. That is, it is determined that there is a possibility that the main pipe has been broken due to the influence of an earthquake or the like, and the pressure has decreased, and the processing after step S402 is performed.

  After proceeding to Step S402, the control unit 11 maintains all the automatic shutoff valves A1 to A4, B1, and B2 in a closed state in Step S403 while maintaining the operation of the automatic water supply devices P2 and P3. In step S404, pressurized water is supplied to the main pipe.

  In step S405, the control unit 11 waits until the pressure sensor 32 provided on the primary side of the emergency shutoff valve A1 in the closed state reaches a pressure equal to or higher than a predetermined value, and determines that the pressure sensor 32 has reached. In step S406, the emergency shutoff valve A1 is opened.

  Next, in step S407, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency shut-off valve A2 that is in the closed state is a predetermined time after the emergency shut-off valve A1 is opened. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency cutoff valve A2 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves A1-A2. It is determined that a break has occurred, and the process proceeds to step S500. The series of processing in step S500 will be described later with reference to FIG.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve A2 is equal to or higher than a predetermined value within a predetermined time and is in a normal state, the main unit between the emergency cutoff valves A1-A2 is determined. It is determined that no breakage has occurred in the piping, and the process proceeds to step S408 to open the emergency shutoff valve A2.

  Note that the pressure equal to or higher than a predetermined value is a pressure at which it is possible to determine that the location (in this case, the main piping between the emergency shut-off valves A1 and A2) for determining whether or not the main piping is broken, and the automatic water supply device P2. Based on the water supply pressure of P3 and the height difference between the automatic water supply devices P2 and P3 and the breakage determination portion of the main pipe, the overall control panel 10 (control unit 11) is set as appropriate.

  In addition, the predetermined time can be determined that if the pressure of a predetermined value or more is not reached, the location where the main piping is determined to be broken (in this case, the main piping between the emergency shutoff valves A1 and A2) is broken. It is time, and is appropriately set in the overall control panel 10 (control unit 11) or the like based on the water supply pressure of the automatic water supply devices P2 and P3, the internal volume of the breakage determination portion of the main pipe, and the like. The overall control panel 10 (control unit 11) has a timer (not shown) that measures a predetermined time.

  Next, in step S409, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency cutoff valve A3 that is in the closed state is a predetermined time after the emergency cutoff valve A2 is opened. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency shut-off valve A3 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency shut-off valves A2-A3. It is determined that a break has occurred, and the process proceeds to step S600. The series of processes in step S600 will be described later with reference to FIG.

  On the other hand, when the control unit 11 determines that the primary pressure of the emergency cutoff valve A3 is equal to or higher than a predetermined value within a predetermined time, the controller 11 is in a normal state. It is determined that no breakage has occurred in the piping, the process proceeds to step S410, and the emergency shutoff valve A3 is opened.

  Next, in step S411, the control unit 11 includes a pressure sensor 32 provided on the primary side of the emergency cutoff valve A4 in the closed state while a predetermined time elapses after the emergency cutoff valve A3 is opened. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency cutoff valve A4 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves A3-A4. It is determined that a break has occurred, and the process proceeds to step S700. The series of processes in step S700 will be described later with reference to FIG.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve A4 is equal to or higher than a predetermined value within a predetermined time and is in a normal state, the main unit between the emergency cutoff valves A3-A4. It is determined that no breakage has occurred in the piping, and the process proceeds to step S412 to open the emergency shutoff valve A4.

  Next, in step S413, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency cutoff valve B1 that is in the closed state while the predetermined time has elapsed since the emergency cutoff valve A4 is opened. It is determined whether or not the pressure is a predetermined value or more.

  That is, since the controller 11 does not have the pressure sensor 32 on the secondary side of the emergency cutoff valve B2, the main piping between the emergency cutoff valves A4 and B2 is broken after the emergency cutoff valve A4 is opened. Is determined by monitoring the pressure state on the primary side of the emergency shutoff valve B1 on the most upstream side of the down line.

  And when the control part 11 judges that it is the abnormal state which the pressure of the primary side of emergency cutoff valve B1 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves A4-B2. It is determined that a break has occurred, and the process proceeds to step S800. The series of processing in step S800 will be described later with reference to FIG.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency shut-off valve B1 is equal to or higher than a predetermined value within a predetermined time, the controller 11 is in a normal state. It is determined that no breakage has occurred in the piping, and the process proceeds to step S414 to open the emergency shutoff valve B1.

  Next, in step S415, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency shut-off valve B2 that is in the closed state while the predetermined time elapses after the emergency shut-off valve B1 is opened. It is determined whether or not the pressure is a predetermined value or more. If the controller 11 determines that the primary pressure of the emergency cutoff valve B2 is in an abnormal state where the pressure does not become a predetermined value or more within a predetermined time, the control unit 11 proceeds to step S417, and the emergency cutoff valve B1-B2 It is determined that a break has occurred in the main pipe between them, the emergency shutoff valve B1 is closed, and the series of processes is terminated.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve B2 is in a normal state because the pressure on the primary side becomes a pressure equal to or higher than a predetermined value within a predetermined time, the main unit between the emergency cutoff valves B1-B2 is determined. It is determined that no breakage has occurred in the piping, the process proceeds to step S416, the emergency shut-off valve B2 is opened, and the series of processes ends.

  That is, in step S416, since there is a possibility that the main pipe may be broken due to the influence of an earthquake or the like, a series of processing of the flowchart in FIG. 4 was performed, and as a result, it was determined that the main pipe was not broken, All emergency shut-off valves are open.

  However, since a pressure abnormality is detected in the previous step S401, it may not be set in principle that the process proceeds to step S416 and all emergency shut-off valves are opened to end the series of processes. For example, the process may return to step S401 to confirm that no pressure abnormality is detected, and the process may be terminated. If a pressure abnormality is detected at that time, the flowchart of FIG. A series of processing may be performed.

  Next, a series of processes in step S500 of FIG. 4 will be described with reference to FIG. In the case where the process of step S500 is called, when only the emergency shut-off valve A1 is opened in the up-line check, the pressure on the primary side of the emergency shut-off valve A2 is equal to or higher than a predetermined value within a predetermined time. This corresponds to a case where it is determined that a break has occurred in the main pipe between the emergency shut-off valves A1 and A2 because an abnormal condition that does not occur is detected.

  Therefore, the control unit 11 closes the emergency shut-off valve A1 in step S501. In step S502, the control unit 11 waits until the pressure sensor 32 provided on the primary side of the emergency cutoff valve B1 in the closed state reaches a pressure equal to or higher than a predetermined value, and determines that the pressure sensor 32 has reached. In step S503, the emergency shutoff valve B1 is opened.

  Next, in step S504, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency cutoff valve B2 that is in the closed state is a predetermined time after the emergency cutoff valve B1 is opened. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency cutoff valve B2 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves B1-B2. It is determined that a break has occurred, and the process proceeds to step S506, the emergency shutoff valve B1 is closed, and the series of processes is terminated.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve B2 is in a normal state because the pressure on the primary side becomes a pressure equal to or higher than a predetermined value within a predetermined time, the main unit between the emergency cutoff valves B1-B2 is determined. It is determined that no breakage has occurred in the piping, and the process proceeds to step S505 to open the emergency cutoff valve B2 and the emergency cutoff valve A4.

  That is, since the controller 11 does not have the pressure sensor 32 on the secondary side of the emergency shutoff valve A4, the emergency shutoff valve A4 is opened together with the emergency shutoff valve B2, and then only between the emergency shutoff valves B2 and A4. In addition, whether or not the main piping between the emergency shutoff valves B2 and A3 including the upstream emergency shutoff valves A4 and A3 is broken is located downstream of the emergency shutoff valve A3 in the closed state. The judgment is made by monitoring the primary pressure state of the emergency shutoff valve A4 after the emergency shutoff valve A4 is opened.

  Next, in step S507, the control unit 11 is provided on the primary side of the emergency cutoff valve A4 that is in the open state while a predetermined time has elapsed since the emergency cutoff valve B2 and the emergency cutoff valve A4 are in the open state. The pressure sensor 32 determines whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is a normal state because the pressure of the primary side of emergency cutoff valve A4 becomes a pressure more than predetermined value within predetermined time, between emergency cutoff valve B2-A4 and emergency It is determined that no breakage has occurred in the main pipe between the shutoff valves A4 and A3, and the process proceeds to step S508 to open the emergency shutoff valve A3.

  Next, in step S509, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency shut-off valve A3 that is in the open state is a predetermined time after the emergency shut-off valve A3 is opened. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency cutoff valve A3 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves A3-A2. It is determined that breakage has occurred, and the process proceeds to step S511, the emergency shutoff valve A3 is closed, and the series of processes is terminated.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve A3 is equal to or higher than a predetermined value within a predetermined time and is in a normal state, the main unit between the emergency cutoff valves A3-A2 is determined. It is determined that no breakage has occurred in the piping, the process proceeds to step S510, the emergency shutoff valve A3 is maintained in the open state, and the series of processes is terminated.

  On the other hand, in the previous step S507, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve A4 is in an abnormal state in which the pressure does not become a predetermined value or more within a predetermined time, the emergency cutoff valve B2- It is determined that there is a possibility that a break has occurred in either the main pipe between A4 or the emergency shutoff valve A4-A3, and the process proceeds to step S512 to close the emergency shutoff valve A4.

  Next, in step S513, the control unit 11 includes a pressure sensor 32 provided on the primary side of the emergency cutoff valve B2 that is in an open state while a predetermined time elapses after the emergency cutoff valve A4 is closed. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency cutoff valve B2 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves B2-A4. It is determined that breakage has occurred, and the process proceeds to step S515, the emergency shutoff valve B2 is closed, and the series of processes is terminated.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve B2 is in a normal state because the pressure on the primary side becomes a pressure equal to or higher than a predetermined value within a predetermined time, the main unit between the emergency cutoff valves B2-A4 is determined. It is determined that no breakage has occurred in the piping, and there has been a breakage in the main piping between the emergency shutoff valves A4-A3. The process proceeds to step S514, the emergency shutoff valve B2 is maintained in the open state, and the series of processes is completed. To do.

  That is, the control unit 11 identifies whether the location where the main pipe is broken is between the emergency shut-off valves B2-A4 or between the emergency shut-off valves A4-A3 by the series of processes of steps S512 to S515. can do.

  Next, a series of processes in step S600 of the previous FIG. 4 which is the main flow will be described with reference to FIG. In the case where the process of step S600 is called, when the emergency shut-off valves A1 and A2 are sequentially opened in the upward line check, the pressure on the primary side of the emergency shut-off valve A3 exceeds a predetermined value within a predetermined time. This corresponds to a case where it is determined that a break has occurred in the main pipe between the emergency shut-off valves A2 and A3 because an abnormal state that does not become the pressure is detected.

  Therefore, in step S601, the control unit 11 closes the emergency shutoff valve A2. In step S602, the control unit 11 waits until the pressure sensor 32 provided on the primary side of the emergency cutoff valve B1 in the closed state reaches a pressure equal to or higher than a predetermined value, and determines that the pressure sensor 32 has reached. In step S603, the emergency shutoff valve B1 is opened.

  Next, in step S604, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency shut-off valve B2 that is in the closed state while the predetermined time has elapsed since the emergency shut-off valve B1 is opened. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency cutoff valve B2 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves B1-B2. It is determined that a break has occurred, and the process proceeds to step S606, where the emergency shutoff valve B1 is closed, and the series of processes is terminated.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve B2 is in a normal state because the pressure on the primary side becomes a pressure equal to or higher than a predetermined value within a predetermined time, the main unit between the emergency cutoff valves B1-B2 is determined. It is determined that no breakage has occurred in the piping, and the process proceeds to step S605 to open the emergency cutoff valve B2 and the emergency cutoff valve A4.

  That is, since the controller 11 does not have the pressure sensor 32 on the secondary side of the emergency shutoff valve A4, the emergency shutoff valve A4 is opened together with the emergency shutoff valve B2, and then only between the emergency shutoff valves B2 and A4. In addition, whether or not the main piping between the emergency shutoff valves B2 and A3 including the upstream emergency shutoff valves A4 and A3 is broken is located downstream of the emergency shutoff valve A3 in the closed state. The judgment is made by monitoring the primary pressure state of the emergency shutoff valve A4 after the emergency shutoff valve A4 is opened.

  Next, in step S607, the control unit 11 is provided on the primary side of the emergency cutoff valve A4 that is in the open state while a predetermined time has elapsed since the emergency cutoff valve B2 and the emergency cutoff valve A4 are in the open state. The pressure sensor 32 determines whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is a normal state because the pressure of the primary side of emergency cutoff valve A4 becomes a pressure more than predetermined value within predetermined time, between emergency cutoff valve B2-A4 and emergency It is determined that no breakage has occurred in the main pipe between the shutoff valves A4 and A3, the process proceeds to step S608, the open state of the emergency shutoff valve A4 is maintained, and the series of processes ends.

  On the other hand, in the previous step S607, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve A4 is in an abnormal state that does not become a pressure higher than a predetermined value within a predetermined time, the emergency cutoff valve B2- It is determined that there is a possibility that the main pipe between A4 and the emergency shutoff valve A4-A3 has been broken, and the process proceeds to step S609 to close the emergency shutoff valve A4.

  Next, in step S610, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency shut-off valve B2 that is in the open state while the predetermined time has elapsed since the emergency shut-off valve A4 is closed. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency cutoff valve B2 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves B2-A4. It is determined that breakage has occurred, and the process proceeds to step S612, the emergency shutoff valve B2 is closed, and the series of processes is terminated.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve B2 is in a normal state because the pressure on the primary side becomes a pressure equal to or higher than a predetermined value within a predetermined time, the main unit between the emergency cutoff valves B2-A4 is determined. It is determined that no breakage has occurred in the piping, and there has been a breakage in the main piping between the emergency shutoff valves A4-A3. The process proceeds to step S611, the emergency shutoff valve B2 is maintained in the open state, and the series of processes is completed. To do.

  That is, the control unit 11 identifies whether the location where the main pipe is broken is between the emergency shut-off valves B2-A4 or between the emergency shut-off valves A4-A3 by the series of processing from step S609 to step S612. can do.

  Next, a series of processes in step S700 of FIG. 4 as the main flow will be described with reference to FIG. In the case where the process of step S700 is called, when the emergency shutoff valves A1, A2, and A3 are sequentially opened in the upward line check, the primary pressure of the emergency shutoff valve A4 is predetermined within a predetermined time. This corresponds to a case where it is determined that a break has occurred in the main pipe between the emergency shutoff valves A3 and A4 because an abnormal state that does not result in a pressure higher than the value is detected.

  Therefore, the control unit 11 closes the emergency shutoff valve A3 in step S701. In step S702, the control unit 11 waits until the pressure sensor 32 provided on the primary side of the emergency cutoff valve B1 in the closed state reaches a pressure equal to or higher than a predetermined value, and determines that the pressure sensor 32 has reached. In step S703, the emergency shutoff valve B1 is opened.

  Next, in step S704, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency shut-off valve B2 that is in the closed state is a predetermined time after the emergency shut-off valve B1 is opened. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency cutoff valve B2 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves B1-B2. It is determined that a break has occurred, and the process proceeds to step S706, the emergency shutoff valve B1 is closed, and the series of processes is terminated.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve B2 is in a normal state because the pressure on the primary side becomes a pressure equal to or higher than a predetermined value within a predetermined time, the main unit between the emergency cutoff valves B1-B2 is determined. It is determined that no breakage has occurred in the piping, and the process proceeds to step S705 to open the emergency shutoff valve B2.

  Here, the control unit 11 breaks in the main pipe between the emergency shut-off valves B2-A4 because the main pipe between the emergency shut-off valves A3-A4 is broken (because the emergency shut-off valve A4 is closed). Is determined by monitoring the pressure state on the primary side of the emergency shutoff valve B2.

  Next, in step S707, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency shut-off valve B2 that is in the open state is a predetermined time after the emergency shut-off valve B2 is opened. It is determined whether or not the pressure is a predetermined value or more. When the control unit 11 determines that the primary side pressure of the emergency cutoff valve B2 is in a normal state because the pressure is equal to or higher than a predetermined value within a predetermined time, the main part between the emergency cutoff valves B2-A4 is determined. It is determined that no breakage has occurred in the piping, the process proceeds to step S708, the emergency shut-off valve B2 is kept open, and the series of processes ends.

  On the other hand, in the previous step S707, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve B2 is in an abnormal state where the pressure does not become a predetermined value or more within a predetermined time, the emergency cutoff valve B2- It is determined that a break has occurred in the main pipe between A4, the process proceeds to step S709, the emergency shutoff valve B2 is closed, and the series of processes is terminated.

  Next, a series of processes in step S800 of FIG. 4 as the main flow will be described with reference to FIG. In the case where the process of step S800 is called, when the emergency shut-off valves A1, A2, A3, and A4 are sequentially opened in the upward line check, the pressure on the primary side of the emergency shut-off valve B1 is within a predetermined time. This corresponds to a case where it is determined that a break has occurred in the main pipe between the emergency shutoff valves B2 and A4 because an abnormal state that does not result in a pressure exceeding a predetermined value is detected.

  Therefore, the control unit 11 closes the emergency shutoff valve A4 in step S801. In step S802, the control unit 11 waits until the pressure sensor 32 provided on the primary side of the emergency cutoff valve B1 in the closed state reaches a pressure equal to or higher than a predetermined value, and determines that the pressure sensor 32 has reached. In step S803, the emergency shutoff valve B1 is opened.

  Next, in step S804, the control unit 11 detects that the pressure sensor 32 provided on the primary side of the emergency cutoff valve B2 that is in the closed state is a predetermined time after the emergency cutoff valve B1 is opened. It is determined whether or not the pressure is a predetermined value or more. And when the control part 11 judges that it is the abnormal state where the pressure of the primary side of emergency cutoff valve B2 does not become a pressure more than predetermined value within predetermined time, it is the main piping between emergency cutoff valves B1-B2. It is determined that a break has occurred, and the process proceeds to step S806, the emergency shutoff valve B1 is closed, and the series of processes is terminated.

  On the other hand, when the control unit 11 determines that the primary side pressure of the emergency cutoff valve B2 is in a normal state because the pressure on the primary side becomes a pressure equal to or higher than a predetermined value within a predetermined time, the main unit between the emergency cutoff valves B1-B2 is determined. It is determined that no breakage has occurred in the piping, and the process proceeds to step S805, where the emergency shut-off valve B1 is kept open, and the series of processes ends.

As described above with reference to the flowcharts of FIGS. 4 to 8, in the piping system according to the first embodiment, the control unit 11 in the overall control panel 10 controls the opening and closing of each emergency shut-off valve according to the following procedure. Thus, the breakage point in the main pipe is specified, and the emergency shutoff valve is partially closed to minimize the piping malfunction range.
(Procedure 1) All emergency shut-off valves are closed due to a pressure drop in the main piping.
(Procedure 2) The emergency shut-off valves are sequentially opened in the order of A1, A2, A3, A4, and B1 (this order is hereinafter referred to as the first order). Identify the pipe breaks.
(Procedure 3) When the fracture location of the main pipe is identified by the operation in the first order according to Procedure 2, the emergency shut-off valve on the upstream side of the identified fracture location is closed.
(Procedure 4) When the break point is specified by the first order, the emergency shut-off valves are sequentially opened in the order of B1 → B2 → A4 → A3 (this order is hereinafter referred to as the second order). Then, the fracture location of the main pipe is specified from the state of the pressure sensor 32 at that time.
(Procedure 5) When the fracture location of the main pipe is identified by the operation in the second order according to Procedure 4, the emergency shutoff valve upstream of the identified fracture location is closed. In other words, this second order is performed in order to specify another breakage point.

  By performing such a series of treatments, the emergency shutoff valves at both ends of the portion where the break has occurred in the main pipe are closed, and water can be supplied to the portion where the break has not occurred. As a result, it is possible to realize a piping system and a water supply control method applied to the piping system that minimize the piping malfunction range so that the entire fire extinguishing system does not stop functioning.

  In the first embodiment described above, in step S405, the control unit 11 waits until the pressure sensor 32 provided on the primary side of the emergency shutoff valve A1 in the closed state reaches a pressure equal to or higher than a predetermined value. However, if the pressure does not reach the predetermined value within the predetermined time, the main pipe upstream from the emergency shutoff valve A1 and the emergency shutoff valve B1 (the main pipe from the automatic water supply devices P2 and P3) is broken. It may be determined that it has occurred, the emergency shutoff valve A1 and the emergency shutoff valve B1 may be closed, and the series of processes in the flowcharts of FIGS.

  Moreover, in Embodiment 1 mentioned above, the operation | movement which specifies the fracture | rupture location of the main piping from the up line side is performed as said 1st order, and when the fracture location of the main piping is not specified on the up line side, after that The operation of specifying the breakage point of the main line on the down line side is performed, but the operation of specifying the break point of the main pipe from the down line side may be started.

  In addition, when the operation for specifying the breakage point of the main pipe on either the up line or the down line is completed and the operation for specifying the break point of the main pipe on the other side of the up line or the down line is started. The operation of specifying the fracture location of the main pipe may be started not from the upstream side (near the pressurized water supply source) but from the downstream side.

  And when performing the operation | movement which specifies the fracture | rupture location of main piping from the down line side as said 1st order, the operation | movement which pinpoints the fracture location of main piping from the up line side is performed as said 2nd order. Like that.

  In Embodiment 1 described above, the determination that the main pipe may have been broken due to the influence of an earthquake or the like in Step S401 is made based on the pressure drop by the pressure sensor 32. Judgment may be made based on earthquake information from a seismoscope or the like, and those judgment criteria may be used in combination.

  In addition, in Embodiment 1 mentioned above, although the control method of the emergency shut-off valve was explained in detail, in order to reduce the piping malfunction range as much as possible so that the entire fire extinguishing system is not in a function stop state, in terms of structure, The following ideas can be considered. That is, as the location of the main piping that is likely to break due to the influence of an earthquake, for example, a piping portion that passes through the bridge portion can be considered. Therefore, in the piping system under such an environment, by providing the expansion and contraction flexible pipes on both sides of the main pipe passing through the bridge portion, by providing the emergency shut-off valves on both outer sides of the two expansion and contraction flexible pipes, It is conceivable to monitor the state of breakage of the main pipe between the two telescopic flexible pipes.

  Moreover, although Embodiment 1 mentioned above illustrated the case where the pressure sensor 32 was provided only in the upstream about all the emergency shut-off valves, this invention is not limited to this. Depending on the required location, it is possible to more reliably monitor the pressure state by providing the pressure sensor 32 on the downstream side.

  For example, since the pressure sensor 32 is not provided between the emergency shutoff valves A4 and B2 located at the most downstream in the upstream line and the downstream line (the loop portion of the main piping), the downstream side of the emergency shutoff valves A4 and B2 Alternatively, the pressure sensor 32 may be provided, and the pressure sensor 32 may be used to determine whether or not the main pipe between the emergency shutoff valves A4 and B2 is broken.

  Thus, by providing the pressure sensor 32 on the downstream side with respect to only the emergency shutoff valves A4 and B2 (or only one of the emergency shutoff valves A4 and B2), all the adjacent emergency shutoff valves The breakage determination between the shutoff valves can be performed using the pressure value of the pressure sensor 32 positioned between the adjacent emergency shutoff valves, and the discrimination accuracy can be further improved.

  1 illustrates a system configuration via an IP network. However, this IP network is not an essential configuration requirement, and the control unit 11 directly controls each distributed control panel 30. It is also possible to do.

  Furthermore, in the configuration of FIG. 3, the case where the main pipe is a loop pipe is shown, but this loop pipe is not an indispensable constituent requirement, and the up line and the down line are configured by separate main pipes. It is also possible to apply the water supply control method according to the present invention.

  Furthermore, the predetermined time for specifying the fracture location, or the predetermined pressure value, can be set to an optimum value for each system individually according to the layout of each emergency shut-off valve.

  DESCRIPTION OF SYMBOLS 10 General control board, 11 Control part, 30 Distributed control board, 31 On-off valve mechanism part, 31a Motor, 32 Pressure sensor, A1-A4, B1, B2 Emergency shut-off valve.

Claims (3)

A main pipe for supplying pressurized water from a pressurized water supply source to a fire extinguishing facility or a watering device installed in each of a plurality of fire prevention sections;
A plurality of emergency shut-off valves that are provided at a plurality of locations of the main pipe and can be switched between shut-off / circulation of the pressurized water supply flowing through the main pipe by being controlled to open and close;
A plurality of pressure sensors provided on the upstream side of each of the plurality of emergency shut-off valves, for detecting the pressure of the pressurized water supply;
When specifying the break occurrence point in the main pipe, after closing all the plurality of emergency shut-off valves, the emergency shut-off valves are sequentially opened sequentially from the vicinity of the pressurized water supply source and the By monitoring the detection value of the pressure sensor, the rupture occurrence location is specified, and when the rupture occurrence location is specified, so that the pressurized water supply is not supplied to the specified rupture occurrence location, A piping system comprising: a control unit that controls an open / closed state of each of the plurality of emergency shut-off valves. The piping system according to claim 1,
The main pipe is configured as a loop pipe having one or more emergency shut-off valves provided on the up line and one or more emergency shut-off valves provided on the down line, from the pressurized water supply source to the up line and the It has a configuration for supplying the pressurized water supply to both the down line,
The control unit, when specifying the break occurrence location, after closing all the plurality of emergency shut-off valves,
As a first step, the emergency shut-off valve disposed on either the up line or the down line is sequentially opened from the vicinity of the pressurized water supply source and the detection value of the pressure sensor is monitored. By doing so, identify the location where the break occurs in either the up line or down line,
As the second stage, when the break occurrence location is specified in the first stage, the emergency shut-off valve disposed on either the up line or the down line is from the vicinity of the pressurized water supply source. When the rupture occurrence location is specified in either the up line or the down line by continuously opening the sequel and monitoring the detection value of the pressure sensor, and the rupture occurrence location is not specified Next, with respect to the emergency shut-off valve disposed on either the up line or the down line, the detection value of the pressure sensor is monitored while being sequentially opened sequentially from the far side of the pressurized water supply source. By doing so, identify the location where the break occurs in either the up line or down line,
As a third stage, when each rupture occurrence place is specified in the loop pipe by the first stage and the second stage, the pressurized water supply is not supplied to the specified rupture occurrence place. A piping system that controls the open / closed state of each of the plurality of emergency shut-off valves. A main pipe for supplying pressurized water from a pressurized water supply source to a fire extinguishing facility or a watering device installed in each of a plurality of fire prevention sections;
A plurality of emergency shut-off valves that are provided at a plurality of locations of the main pipe and can be switched between shut-off / circulation of the pressurized water supply flowing through the main pipe by being controlled to open and close;
A plurality of pressure sensors provided on the upstream side of each of the plurality of emergency shut-off valves, for detecting the pressure of the pressurized water supply;
Water supply control applied to a piping system comprising: a control unit that identifies a breakage occurrence location in the main piping by monitoring detection results of the plurality of sensors while switching open / closed states of the plurality of emergency shut-off valves A method,
In the control unit,
Closing all of the plurality of emergency shut-off valves;
After the plurality of emergency shut-off valves are all closed, the emergency shut-off valves are sequentially opened sequentially from the vicinity of the pressurized water supply source, and the detection value of the pressure sensor is monitored to generate the breakage. The step of identifying the location,
Controlling the open / closed state of each of the plurality of emergency shut-off valves so that the pressurized water supply is not supplied to the specified break occurrence location when the break occurrence location is specified. A water supply control method applied to a characteristic piping system.

Images