JP3880744B2 - Sprinkler fire extinguishing equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a sprinkler fire extinguishing equipment that discharges fire extinguishing water from a sprinkler head in the event of a fire, and more particularly to a sprinkler fire extinguishing equipment with a water loss prevention function that has a function of stopping water discharge during abnormal water discharge.
[0002]
[Prior art]
Conventionally, as this kind of sprinkler fire extinguishing equipment, for example, there is one shown in JP-A-10-5365. The whole structure of this conventional sprinkler fire extinguishing equipment is shown in FIG. In FIG. 3, the sprinkler fire extinguishing equipment mainly discharges water by using each dwelling unit of the apartment house as one fire fighting section, and a closed type sprinkler head 51 is disposed in each room of each fire fighting section. Fire extinguishing water is supplied to the head 51 from a water supply main pipe 53 through a branch pipe 52.
[0003]
One end of the water supply main pipe 53 is connected to a water storage tank 55 via a fire extinguishing pump 54. A pressure tank 56 is branchedly connected to the water supply main pipe 53, and the pressure inside the water supply main pipe 53 is maintained at a specified pressure by the pressure tank 56. The pressure tank 56 is provided with a pressure switch 57. When the pressure switch 57 detects that the sprinkler head 51 is activated and the pressure in the water supply main pipe 53 has dropped below a predetermined level, the pump control panel At 58, the motor 59 is driven to operate the fire extinguishing pump 54, and water for fire extinguishing is supplied to the water supply main pipe 53. As a result, the water discharge continues. The other end of the water supply main pipe 53 is drawn into the elevated water tank 60. And the water for fire extinguishing is supplied with respect to the water supply main 53 from the elevated water tank 60, and the water supply main 53 is always filled with the water for fire extinguishing.
[0004]
The branch pipe 52 is provided with a control valve 61 and a running water detection device 62. Of these, the control valve 61 controls the supply of fire-extinguishing water by opening and closing the branch pipe 52, and is maintained in the open state in the steady monitoring state. Therefore, in the steady monitoring state, the fire extinguishing water is supplied to each sprinkler head 51 via the control valve 61.
[0005]
The flowing water detection device 62 is provided on the secondary side of the control valve 61 and includes a flowing water detection switch 63. In this flowing water detection device 62, when a valve opening or a pressure drop due to the water flow generated by the discharge of fire-extinguishing water when the sprinkler head 51 is operated by receiving heat from a fire is detected, a flowing water signal is output from the flowing water detection switch 63. Is output. This flowing water signal is output to the sprinkler control panel 65 via the fire fighting repeater 64. A control signal for the control valve 61 from the sprinkler control panel 65 is also output via the fire extinguishing repeater 64.
A terminal test valve 66, an orifice 67, and a pressure gauge 68 are provided on the terminal side of the branch pipe 52. When the terminal test valve 66 is opened, an amount of fire-extinguishing water determined by the orifice 67 is supplied to the branch pipe 52. The test operation can be performed by simulating the flow and flowing water detection device 62.
[0006]
A fire detector 70 is arranged in each room of each fire extinguishing section. The fire sensor 70 is connected to a fire alarm repeater 72 via a sensor line 71. When a fire is detected, a fire signal is output by short-circuiting the sensor line 71 at a low impedance. The fire signal output from the fire detector 70 is input to the fire receiving board 73 via the fire relay 72. When the fire signal is input in this way, the fire receiving board 73 outputs a transfer signal to the sprinkler control board 65.
[0007]
Further, the fire receiving board 73 monitors whether or not the sensor line 71 is disconnected, and outputs a failure signal to the sprinkler control panel 65 when the disconnection occurs. Specifically, in the fire receiving board 73, a minute current flowing through the sensor line 71 is constantly detected. When the minute current is no longer detected, it is determined that a disconnection has occurred, and a fault signal is output. The
[0008]
In the sprinkler fire extinguishing equipment configured as described above, the sprinkler control panel 65 maintains the control valve 61 in an open state in a steady monitoring state, the flow signal from the flow detection switch 63 of the flow detection device 62, the fire reception panel 73. The presence or absence of fire signals is monitored.
Thereafter, when the water for fire extinguishing is discharged by operating the sprinkler head 51 in response to heat generated by the fire, the flowing water detection device 62 is operated and a flowing water signal is output to the sprinkler control panel 65. In the sprinkler control panel 65, when a running water signal is output, the presence or absence of a fire signal and a failure signal is confirmed, and the opening and closing of the control valve 61 is controlled based on the result.
[0009]
Specifically, when a fire signal is output, the open state of the control valve 61 is maintained as normal water discharge. When the water is discharged by the sprinkler head 51 in this way, it is detected by the pressure switch 57 that the pressure inside the water supply main pipe 53 has dropped below a predetermined value, and the pump control panel 58 drives the motor 59 to extinguish the fire pump 54. To drive. By operating the fire pump 54 in this way, water discharge by the sprinkler head 51 is continuously performed. When the fire is extinguished, the sprinkler control panel 65 controls the control valve 61 to close.
[0010]
On the other hand, if the fire signal is not output even though the running water signal is output, the control valve 61 is further controlled by confirming the presence or absence of the failure signal.
Specifically, when the fire signal is not output and the failure signal is not output, the sprinkler control panel 65 outputs the control signal to the control valve 61 via the fire extinguishing relay 64, and this control valve 61 is controlled to be closed. Therefore, even if the sprinkler head 51 has been damaged even though no fire has occurred, the water discharge is automatically stopped to minimize damage caused by water damage. Can do.
[0011]
On the other hand, when the failure signal is output when the fire signal is not output, the control valve 61 is maintained in the open state, and the water discharge is continuously performed. Therefore, if a fire signal is not output due to the disconnection of the sensor line 52 in spite of the occurrence of a fire, it is prohibited to stop water discharge carelessly.
[0012]
[Problems to be solved by the invention]
However, in such conventional sprinkler fire extinguishing equipment, the presence or absence of a failure in the fire detection system is detected only by the presence or absence of a failure signal from the fire receiving board 73, so there are cases where sufficient detection cannot always be performed. It was. That is, when the power of the fire receiving board 73 is cut off or when there is a malfunction in the control CPU or the like inside the fire receiving board 73, not only the fire signal is output but also the failure signal is not output. In such a case, the sprinkler control panel 65 outputs both the fire signal and the failure signal from the fire receiving panel 73 even if the sprinkler 70 is normally operated by the heat of the fire and the water is discharged and the flowing water signal is output. Therefore, the control valve 61 is controlled to be closed, and there is a risk that the water discharge is stopped despite the occurrence of a fire.
[0013]
In particular, fire receiving panels for ordinary houses are often simply configured without a backup power source from the viewpoint of cost reduction, and are not necessarily excellent in reliability. The possibility of power cut-off of a fire receiving panel was not negligible. In addition, since there is a great demand for reducing the cost of the fire receiving board, it has been desired to solve the above problem without changing the configuration of the fire detector or the fire receiving board itself.
[0014]
The present invention has been made in view of the problems in such conventional sprinkler fire extinguishing equipment, and with a simple configuration, a sprinkler fire extinguishing equipment that can continue water discharge without stopping carelessly when a fire receiving panel is abnormal. The purpose is to provide.
[0015]
[Means for Solving the Problems]
  In order to solve the problems in the conventional sprinkler fire extinguishing equipment, the present invention according to claim 1 provides a closed sprinkler head and a fire sensor arranged in each fire extinguishing section, and supplies fire water to the sprinkler head. A sprinkler control panel for controlling the control valve; and a fire receiving panel for receiving a fire signal from the fire detector and outputting the fire signal to the sprinkler control panel. When fire extinguishing water is supplied to the sprinkler head, and the fire water supplied to the sprinkler head is detected, and there is no fire signal from the fire sensor corresponding to the sprinkler head detected The sprinkler control panel is for extinguishing the sprinkler head with the control valve closed. The supply of the sprinkler fire extinguishing equipment to stop,The fire receiving board detects the disconnection state of the sensor line by detecting the presence / absence of current flowing through the sensor line, and when the disconnection state is detected, a fault signal corresponding to the disconnection state is detected. Output to the sprinkler control panel,The sprinkler control panel uses a sensor line for sending the fire signal from the fire sensor to the fire receiving panel,By setting the sensor line to a disconnected state at predetermined intervals at a predetermined timing, the current flowing through the sensor line is set to a predetermined pulse state, and the failure signal sent from the fire receiving board corresponds to the predetermined pulse state. By determining whether or not toA function detecting means for detecting whether or not the fire receiving board is normal, and the fire detecting board is not normal in the function detecting means when the flowing water is detected and there is no fire signal; If this is detected, the control valve is maintained in an open state and the supply of fire-extinguishing water to the sprinkler head is continued.
[0016]
  Further, the present invention described in claim 2 is the present invention described in claim 1,A switch for disconnecting the sensor line is provided on the terminal side of the sensor line, and the function detecting means generates the predetermined pulse state via the switch.As a feature.
[0018]
  The sprinkler control panel of the present invention comprises a function detection means for detecting whether or not the fire receiving board is normal by using a sensor line for sending a fire signal from the fire detector to the fire receiving board. If fire water is detected and there is no fire signal, or if it is detected that the fire reception panel is not normal, it is configured to continue supplying fire-fighting water to the sprinkler head. If there is a functional abnormality such as a power shutdown of the panel or a CPU malfunction, the control valve will remain open and water will continue to be discharged. Fire extinguishing can be performed more reliably and safely.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of a sprinkler fire extinguishing facility of the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram showing the overall configuration of the sprinkler fire extinguishing equipment, and FIG. 2 is a flowchart of sprinkler control.
In FIG. 1, the sprinkler fire extinguishing equipment of the present embodiment mainly discharges water as a fire extinguishing section for each dwelling unit of an apartment house, and a sprinkler head 1 is arranged in each room of each fire extinguishing section. This sprinkler head 1 is configured as a closed type, and when it receives heat from a fire, it is automatically opened by melting the metal inside thereof and starts water discharge.
[0020]
The sprinkler head 1 is connected to a water supply main pipe 3 via a branch pipe 2, and fire-extinguishing water is supplied to the sprinkler head 1 via the water supply main pipe 3 and the branch pipe 2.
One end of the water supply main 3 is drawn into the basement of the building and connected to the water storage tank 5 via the fire pump 4. A pressure tank 6 is branched and connected to the water supply main pipe 3, and the pressure inside the water supply main pipe 3 is maintained at a specified pressure by pressurizing the water supply main pipe 3 with the pressure tank 6. The pressure tank 6 is provided with a pressure switch 7, and when the pressure switch 7 detects that the sprinkler head 1 is activated and the pressure in the water supply main pipe 3 has dropped below a predetermined level, the pump control panel At 8, the motor 9 is driven to operate the fire extinguishing pump 4, and the fire extinguishing water in the water storage tank 5 is continuously supplied to the water supply main pipe 3. As a result, the water discharge continues. When the fire pump 4 is in operation, a pump operation signal indicating that fact is output from the pump control panel 8 to a later-described residential building reception panel 24.
Further, the other end of the water supply main 3 is drawn into an elevated water tank 10 disposed at a high place such as a building rooftop. And the water for fire extinguishing is supplied from the elevated water tank 10 to the water supply main 3 by its own weight, and the water supply main 3 is always filled with the water for fire extinguishing.
[0021]
The branch pipe 2 drawn from the water supply main pipe 3 is provided with a control valve 11 and a flowing water detection device 12.
Among these, the control valve 11 controls the water supply of the fire extinguishing water by opening and closing the branch pipe 2, and is specifically an electric valve that is motor-driven by the control of the control unit 28 of the sprinkler control panel 25 described later. It is configured as. The control valve 11 is kept open in a steady monitoring state described later. Therefore, in the steady monitoring state, the fire extinguishing water is supplied to each sprinkler head 1 via the control valve 11 and is in the same pressurized water supply state as the wet sprinkler equipment.
[0022]
A bypass valve 13 is connected to the control valve 11 in parallel, and when the control valve 11 becomes uncontrollable, the supply of fire-fighting water is stopped by manually opening and closing the bypass valve 13. Can do. The bypass valve 13 is closed in the steady monitoring state. The pressure detection device 14 provided on the secondary side of the control valve 11 outputs a pressure signal when the pressure in the branch pipe 2 is equal to or higher than a specified pressure.
[0023]
The flowing water detection device 12 is provided on the primary side of the control valve 11 and detects valve opening or pressure drop due to water flow generated by the discharge of fire-extinguishing water when the sprinkler head 1 is activated by receiving heat from a fire. . When this valve opening or pressure drop is detected by the flowing water detection device 12, the flowing water detection switch 15 is turned on, and a flowing water signal is output from the flowing water detection switch 15.
A terminal test valve 16, an orifice 17, and a pressure gauge 18 are provided on the terminal side of the branch pipe 2. When the terminal test valve 16 is opened, an amount of fire extinguishing water determined by the orifice 17 is supplied to the branch pipe 2. The test operation can be performed by simulating the flow and flowing water detection device 12.
[0024]
A fire detector 20 is arranged in each room of each fire extinguishing section. This fire detector 20 is connected to a fire receiving board 23 through a sensor line 21 and a terminal box 22 which are double lines, and when a fire is detected, a fire signal is generated by short-circuiting the sensor line 21 at a low impedance. Is output. This fire signal is input to the fire receiving board 23 and simultaneously input to the residential building receiving board 24 to indicate the occurrence of a fire.
[0025]
This fire receiving board 23 is provided for each dwelling unit that becomes a fire extinguishing section, and outputs the fire signal output from the fire detector 20 to the sprinkler control board 25 as a transfer signal.
In the fire receiving board 23, the disconnection of the sensor line 21 is monitored. If a failure has occurred, a failure signal is output from the fire receiving panel 23 to the sprinkler control panel 25. Specifically, in the fire receiving board 23, a very small current flowing through the sensor line 21 is constantly detected. When the very small current is not detected, it is determined that a failure has occurred and a failure signal is output. The The fault signal is continuously output while the minute current is not detected, and the output is stopped when the minute current is detected again. That is, the failure signal is output with a pulse corresponding to a minute current.
[0026]
Next, the configuration of the sprinkler control panel 25 will be described.
As described above, the pressure signal output from the pressure detector 14, the flowing water signal output from the flowing water detection switch 15, the fire signal and the failure signal output from the fire receiver 23 are input to the sprinkler control panel 25. .
The sprinkler control panel 25 is provided for each dwelling unit serving as a fire extinguishing section, and controls the control valve 11 based on the pressure signal, the flowing water signal, the fire signal, the failure signal, and the like.
[0027]
In order to realize such a function, the sprinkler control panel 25 includes a switch 26 for disconnecting the sensor line 21 and a function detection means function detecting means for detecting whether or not the fire receiving panel 23 is normal. The control part 28 provided with the part 27 is provided.
[0028]
Among them, the switch 26 is disposed in the sensor line 21 and is turned on / off at a predetermined interval at a predetermined timing by the control of the function detection unit 27, so that the sensor line 21 is disconnected or connected. As a result, a minute current flowing through the sensor line 21 is brought into a predetermined pulse state. In particular, in the present embodiment, the switch 26 is provided on the downstream side of the terminating resistor R1 of the sensor line 21 disposed in the sprinkler control panel 25. Therefore, the fire signal output from the fire detector 20 reaches the fire receiving board 23 via the sensor line 21 regardless of the on / off state of the switch 26, and does not prevent fire detection carelessly.
[0029]
Further, the function detection unit 27 drives the switch 26 on and off as described above, and monitors a failure signal output from the fire receiving board 23 at this time. Then, it is determined whether or not the failure signal output from the fire receiving board 23 corresponds to a predetermined pulse state (a pulse state generated when the switch 26 is turned on / off). If the failure signal corresponds to a predetermined pulse state, it is determined that the fire receiving board 23 is normal. On the other hand, when no failure signal is output or when the output failure signal does not correspond to a predetermined pulse state, the fire reception board 23 has a functional abnormality such as power shutdown or CPU abnormality (fire reception board 23 is Judge that it is not normal.
[0030]
Further, from the sprinkler control panel 25, state signals relating to various states such as an operating state of the flowing water detection device 12 and an open / close state of the control valve 11 are output to a later-described housing building receiving panel 24 via a terminal box 29. The sprinkler control panel 25 is provided with an emergency stop switch 30. When the emergency stop switch 30 is pushed, the control valve 11 is closed and water discharge is stopped. The sprinkler control panel 25 is supplied with power from a power line 32 of AC 100 volts to the pump control panel 8 via a terminal box 31.
[0031]
The residence building receiving board 24 is arranged in, for example, a manager's room or the like. When the pump operation signal is outputted from the pump control board 8, the fire signal from the fire detector 20, or the status signal is outputted from the sprinkler control board 25, these are received. An indicator lamp (not shown) indicating that a signal is being output is turned on. As a result, the manager can centrally monitor the operation status of the sprinkler fire extinguishing equipment.
[0032]
Next, the sprinkler control in the sprinkler fire extinguishing equipment configured as described above will be described with reference to FIG.
First, at the start of control (step S <b> 1), the control valve 11 is controlled to be in an open state by the initial control set as default in the control unit 28, and the fire-extinguishing water is filled up to the sprinkler head 1. Thereafter, the presence or absence of a running water signal and a fire signal is monitored (steady monitoring state, steps S2 and S3). Here, the pressure detection device 14 detects that the pressure in the branch pipe 2 is equal to or higher than the specified pressure, and outputs a pressure signal. At this time, no fire has occurred, so no fire signal is output. Therefore, the open state of the control valve 11 is maintained by steps S2, S3, and S7.
[0033]
First, when a fire signal is detected in step S3, the control unit 28 determines that a fire has occurred and maintains the open state of the control valve 11 (step S4). Then, the sprinkler head 1 is automatically operated by the heat of the fire, so that water is discharged to the fire extinguishing section.
When the pressure switch 7 detects that the sprinkler head 1 has been actuated in this manner and the pressure inside the water supply main pipe 3 has fallen below a predetermined level, the pump control panel 8 drives the motor 9 to turn off the fire pump 4. It is operated and the water discharge continues.
[0034]
Thereafter, it is monitored whether or not the emergency stop switch 30 has been pressed (step S5). When the emergency stop switch 30 is pushed, it is not necessary to perform further water discharge, so that a control signal is output from the control unit 28 to the control valve 11 and the control valve 11 is closed (step S6). This stops water discharge by the sprinkler head 1 and prevents water discharge more than necessary. In addition to the water discharge stop, the operator can also stop the water discharge by closing the valve of the water flow detection device 12. As will be described later, when the fire signal is turned off, the control valve 11 is controlled to be closed and the water discharge is stopped.
[0035]
In step S7, the presence or absence of the pressure signal is confirmed in order to prevent the hunting operation of the control valve 11. That is, when the sprinkler head 1 malfunctions due to damage or the like, if the control valve 11 is closed because the fire signal is not output, the water discharge from the sprinkler head 1 stops and the water flow signal is turned off as in the conventional case. It becomes. Since this is the same state as the steady monitoring state, when it is determined that the recovery condition is satisfied and the control valve 11 is controlled to open, water discharge is started again from the damaged sprinkler head 1. Accordingly, the water discharge is repeatedly opened and closed, and water is intermittently discharged from the damaged head. In order to prevent such an adverse effect, when the pressure signal is output, it is determined that the sprinkler head 1 has been replaced and the restoration condition has been satisfied after the steady monitoring state or water discharge, and the control valve 11 is controlled to open. On the other hand, when the pressure signal is not output, it is determined that the fire signal after the operation of the sprinkler head 1 is on standby or the sprinkler head is damaged, and the control valve 11 is closed.
[0036]
On the other hand, when the running water signal is detected in step S2 before the fire signal is detected in the steady monitoring state, the control unit 28 first checks whether or not the fire signal is output (step S9). If a fire signal is output here, it is determined that a fire has occurred and the sprinkler head 1 has a normal water discharge, and the process proceeds to step S4 to keep the control valve 11 open. Continue to discharge water. The subsequent steps are the same as steps S5 and S6 described above.
[0037]
If the fire signal is not output in step S9, there is a possibility that the detector line 21 is disconnected and the fire signal is not output despite the fact that a fire has occurred. In order to confirm this possibility, the control part 28 confirms the presence or absence of the output of the failure signal from the fire receiving board 23 (step S10). If a fault signal is output, it can be determined that the sensor line 21 is disconnected, and it can be determined that there is actually a possibility that a fire has occurred. 11 is maintained in an open state and water discharge is continued. The subsequent steps are the same as steps S5 and S6 described above. Therefore, even when the sensor line 21 is disconnected, the water discharge is not inadvertently stopped.
[0038]
On the other hand, if the output of the failure signal is not confirmed in step S10, in addition to the possibility that the fire has not actually occurred, the power of the fire receiving panel 23 is shut off in spite of the fact that the fire has actually occurred. There is a possibility that a fire signal or a failure signal is not output due to a functional abnormality such as a CPU abnormality. In order to confirm this possibility, the function detection unit 27 of the control unit 28 drives the switch 26 on and off at a predetermined interval at a predetermined timing, so that the sensor line 21 is disconnected or connected (step S11). As a result, a minute current flowing through the sensor line 21 is brought into a predetermined pulse state.
[0039]
In addition, when the switch 26 is driven in this way, the function detection unit 27 monitors the failure signal output from the fire receiving board 23, whether or not the failure signal is output, and the output failure signal is a predetermined value. It is determined whether or not it corresponds to the pulse state (step S12).
If a failure signal is not output, or if it does not correspond to a predetermined pulse state even if it is output, it is determined that there is a functional abnormality such as power interruption of the fire receiving panel 23 or CPU abnormality. In this case, it transfers to step S4 and maintains the control valve 11 in an open state, and continues water discharge. The subsequent steps are the same as steps S5 to S8 described above. Therefore, even when the fire receiving board 23 is out of order, the water discharge is not stopped carelessly.
[0040]
On the other hand, when a failure signal is output in step S12 and it is confirmed that the failure signal corresponds to a predetermined pulse state, there is no functional abnormality such as power interruption of the fire receiving board 23 or CPU abnormality. In fact, since it can be determined that no fire has occurred, and it can be determined that the water discharge is due to sprinkler breakage or water leakage, the process proceeds to step S6 and the control valve 11 is controlled to be closed. Therefore, as in the conventional case, when water discharge is started despite the fact that no fire has actually occurred, water discharge can be stopped automatically to minimize damage to water. Further, when the fire receiving panel 23 is restored during the water discharge by the sprinkler head 1 and the output of the fire signal is stopped, the control valve 11 is controlled to be closed by steps S2, S9, S10, S11, S12, and S6, and the water discharge is stopped. The
Through such steps S1 to S12, the sprinkler control is performed by monitoring the state of the three signals of the flowing water signal, the fire signal, and the pressure signal and the state of the fire receiving panel 23.
[0041]
Although one embodiment of the present invention has been described so far, the present invention is not limited to the above-described embodiment, and may be implemented in various forms within the scope of the technical idea. These different forms will be described.
First, the sprinkler fire extinguishing equipment that is the subject of the present invention is not limited to a general dwelling unit. Good. Further, as the overall configuration of the sprinkler fire extinguishing equipment, a different configuration other than the illustrated configuration may be adopted. For example, the control valve 11 may be provided on the primary side of the flowing water detection device 12.
[0042]
Moreover, the normality detection of the fire receiving board 23 by the function detection unit 27 may be performed by any method other than setting the sensor line 21 to a disconnected state. For example, it may be performed by inputting a current of a specific frequency to the sensor line 21 and determining whether the frequency of the fault signal corresponds to the specific frequency. Alternatively, a resistance may be intermittently connected to the sensor line 21 to increase the resistance value of the line, thereby reducing the line current and creating a specific pulse state as a pseudo disconnection state. In addition, various signals for indicating the normality of the fire receiving board 23 itself can be output from the fire receiving board 23 to the sprinkler control board 25. However, in general, the fire receiving board 23 is simply configured from a low cost viewpoint, and it is difficult to add a new configuration. In addition, it is the simplest configuration to make the sensor line 21 in a disconnected state as in the above embodiment. Therefore, according to the above embodiment, the normality detection system for the fire receiving board 23 having the lowest cost and the highest reliability. Can be built.
[0043]
Further, in the above embodiment, it has been described that when a minute current from the sensor line 21 is no longer detected, it is determined that a failure has occurred and a failure signal is output from the fire receiving board 23. However, in order to improve the reliability of failure determination, the fire receiving board 23 may be provided with a so-called storage function. This accumulation function is a function that outputs a failure signal only when a minute current is detected continuously for a predetermined time (for example, T1) or longer. When such a storage function is provided in the fire receiving board 23, the function detection unit 27 drives the switch 26 corresponding to the storage function. Specifically, the function detection unit 27 drives the switch 26 at an interval of T1 or more. In this case, a failure signal corresponding to the pulse state created by driving the switch 26 can be reliably output from the fire receiving board 23. Accordingly, it is possible to reliably detect the normality of the fire receiving board 23 having a storage function. Further, such a storage function may be employed as appropriate when detecting the normality of the fire receiving board 23 in the function detection unit 27 or making other determinations.
[0044]
【The invention's effect】
  As described above, according to the present invention, the sprinkler control panel uses a sensor line for sending a fire signal from the fire sensor to the fire reception panel. Supplying fire-extinguishing water to the sprinkler head when a function detection means is provided to detect whether there is water flow, when there is no fire signal, when there is no fire signal, or when it is detected that the fire reception panel is not normal Since the control valve is kept open and water discharge continues when there is a functional abnormality such as a power interruption of the fire reception board or a CPU abnormality, the water discharge is continued. It is forbidden to stop water discharge in preparationAndTherefore, fire extinguishing can be performed more reliably and safely.
[0045]
  AlsoIn the present invention, the fire receiving panel outputs a failure signal to the sprinkler control panel when a disconnection state is detected, and the function detecting means sets the current flowing through the sensor line to a predetermined pulse state, A new configuration is added to the fire reception panel by detecting whether or not the fire reception panel is normal by judging whether the failure signal sent from the panel corresponds to a predetermined pulse state. The normality of the fire reception board can be detected without doing so. In addition, since it is the simplest configuration to place the sensor line in a disconnected state, it is possible to construct a fire receiving panel normality detection system that is the lowest and most reliable.
[0046]
  And claims2The invention described isA switch for disconnecting the sensor line is provided on the terminal side of the sensor line, and the function detection means generates a predetermined pulse state via the switch, so that the fire signal output from the fire detector is Regardless of the on / off state of the switch, it reaches the fire reception panel and does not prevent fire detection.
[Brief description of the drawings]
FIG. 1 is a diagram showing an overall configuration of a sprinkler fire extinguishing facility according to an embodiment of the present invention.
FIG. 2 is a flowchart of sprinkler control.
FIG. 3 is a diagram showing an overall configuration of a conventional sprinkler fire extinguishing facility.
[Explanation of symbols]
1,51 Sprinkler head
2,52 Branch pipe
3, 53 Water supply main
4, 54 Fire pump
5,55 water tank
6, 56 Pressure tank
7, 57 Pressure switch
8, 58 Pump control panel
9, 59 Motor
10, 60 elevated tank
11, 61 Control valve
12, 62 Flowing water detection device
13 Bypass valve
14 Pressure detector
15, 63 Flowing water detection switch
16, 66 End test valve
17, 67 Orifice
18, 68 Pressure gauge
20, 70 Fire detector
21, 71 Sensor line
22, 29, 31 Terminal box
23, 73 Fire reception board
24 dwelling reception board
25, 65 Sprinkler control panel
26 switch
27 Function detector
28 Control unit
30 Emergency stop switch
32 Power line
64 Fire fighting repeater
72 Fire Report Repeater

Claims (2)

Closed sprinkler heads and fire detectors located in each fire fighting compartment;
A sprinkler control panel for controlling a control valve for supplying water for fire extinguishing to the sprinkler head;
A fire receiving panel that receives a fire signal from the fire detector and outputs the fire signal to the sprinkler control panel;
In the steady monitoring state, the control valve is opened to supply fire fighting water to the sprinkler head,
When the fire water supplied to the sprinkler head is detected and there is no fire signal from the fire sensor corresponding to the sprinkler head where the water is detected, the sprinkler control panel controls the control valve. In the sprinkler fire extinguishing equipment that stops the supply of fire-fighting water to the sprinkler head in a closed state,
The fire receiver is
A disconnection state of the sensor line is detected by detecting the presence or absence of a current flowing through the sensor line, and when the disconnection state is detected, a fault signal corresponding to the disconnection state is sent to the sprinkler control panel. Output,
The sprinkler control panel is
Using the sensor line for sending the fire signal from the fire sensor to the fire receiving board, the sensor line is disconnected at a predetermined interval at a predetermined timing. Detect whether the fire receiving board is normal by setting the flowing current to a predetermined pulse state and judging whether or not a failure signal sent from the fire receiving board corresponds to the predetermined pulse state Function detecting means for
When the flowing water is detected and there is no fire signal, when the function detecting means detects that the fire receiving board is not normal, the control valve is maintained in an open state to Continuing to supply fire water to the sprinkler head,
Sprinkler fire extinguishing equipment characterized by   2. The switch for setting the sensor line to a disconnected state is provided on the terminal side of the sensor line, and the function detecting means generates the predetermined pulse state via the switch. The sprinkler fire extinguishing equipment described.

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