JP3748182B2 - Fire alarm system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fire alarm facility including terminal devices provided for each of a plurality of districts and a fire receiver that monitors fires in all districts while controlling these terminal devices in an integrated manner.
[0002]
[Prior art]
A general configuration of a fire alarm facility provided in a building or the like is simply shown in FIG. The fire alarm system 1 shown in FIG. 11 includes a fire receiver 2 provided in a building manager room and the like, and a fire detector connected to the fire receiver 2 via the L ′ line and the common line C ′. 4 and the like, a transmitter 3 connected to the fire receiver 2 via the L ′ line, the common line C ′ and the A ′ line, and a fire receiver 2 connected to the fire receiver 2 via the bell line B ′. Consists of 5 district bells.
[0003]
In such a fire alarm facility 1, a maintenance inspection is periodically performed to confirm whether or not it operates normally.
The maintenance and inspection in the fire alarm facility 1 is performed by, for example, an operator who tests the fire detector 4 and the like and an operator on the fire receiver 2 side as follows. When the worker in charge of the test directs smoke or the like to the fire detector 4 by using a test tool, when the fire detector 4 is simulated, a fire detection signal is sent from the detector 4 via the L ′ line. Is output to the fire receiver 2. Based on the fire detection signal, the fire receiver 2 causes the district bell 5 in the district (for example, one floor) where the fire detector 4 that outputs the signal is installed to ring briefly. Thereby, it can be confirmed that the lines leading to the fire detector 4, the fire receiver 2, and the district bell 5 are normal.
[0004]
In the case of the transmitter 3, when the operator presses the transmitter 3 in the same way as when an actual fire occurs, the transmitter transmits a transmitter to the fire receiver 2 via the L 'line and the A' line, respectively. A signal is output. At the time of maintenance and inspection, the fire receiver 2 makes the district bell 5 ring briefly based on the transmitter output from the L ′ line and the A ′ line. Thereby, it can confirm that the line | wire leading to the transmitter 3, the fire receiver 2, and the district bell 5 is normal.
When the fire detection signal or the transmitter signal is input to the fire receiver 2, an LED (not shown) of a district window (not shown) provided in the fire receiver 2 so as to respond to the ringing of the district bell 5. The light emitting diode) is turned on, and the operator on the fire receiver 2 side can also know the test status. In the case of a transmitter signal, a transmitter indicator light (not shown) of the fire receiver 2 is also turned on by an output from the A 'line.
[0005]
[Problems to be solved by the invention]
By the way, in general, when a fire detector detects a fire during normal fire monitoring, the fire alarm facility is a function that determines that a fire is detected when a fire alarm is detected for the first time and then fired again after a predetermined time ( Storage / reception function).
However, at the time of maintenance inspection as described above, in order to shorten the work time, this accumulation function is canceled and the fire detector is activated once to confirm.
Therefore, at the time of maintenance inspection, the ringing of the district bell 5 and the lighting of the district window are the same in both the sensor 4 and the transmitter 3.
In such a situation, when the transmitter 3 is inspected, if the L 'line is normal even if there is an abnormality such as a disconnection in the A' line, the district bell rings in the same way as normal, The operator on the transmitter 3 side may overlook the abnormality of the A ′ line.
[0006]
Also, at the time of maintenance inspections as described above, whether or not all districts were completed was checked by the workers filling in check sheets etc. There was a possibility, and if there was an entry error, there was a risk of inspection omission.
[0007]
Furthermore, with conventional fire alarm systems, during maintenance inspections, the ringing of district bells in all districts was made much shorter than during normal monitoring, as described above, or in some cases, the ringing was completely stopped. . Even if a fire broke out during such an inspection, the district bell would not ring and residents could not be aware of the actual fire. The failure to report the occurrence of an important fire even during maintenance and inspection was not a response to the actual situation and was a serious problem.
[0008]
In addition, the fire receiver 2 in FIG. 1 is of a type generally called “P-type”, but the P-type fire receiver has been related to fire monitoring and maintenance inspections. There was no function to memorize the history. Therefore, it was not possible to call and analyze the time at the time of a fire or maintenance check and the operation procedure at that time later, and it was not possible to improve by making use of past facts at the time of maintenance check. .
[0009]
As described above, the conventional fire alarm equipment has a number of incomplete parts particularly in the maintenance and inspection function, and it cannot be said that it is sufficient in view of the actual situation.
[0010]
In addition, the district bell 5 provided in the fire alarm facility 1 is caused to ring on the floor where the sensor is installed (the floor concerned) and the floor above it (the floor directly above) by the first notification from the sensor. Some systems use a separate ringing system that rings on all floors of the building (second ringing) with the first alarm or transmitter. However, in both cases, the ringing sound of district bell 5 was the same, so it was clear that a fire had actually occurred, but no further information could be obtained.
In other words, the sounding function of the fire alarm facility so far is only to provide vague information to workers and residents at the time of maintenance inspection as well as at the time of actual fire as described above. It did not inform the detailed information required by workers and residents.
[0011]
The present invention has been made in view of the above circumstances, and provides a fire alarm facility having a maintenance inspection function corresponding to an actual situation and capable of performing more reliable maintenance inspection, and also providing detailed information. It aims at providing the fire alarm equipment which has the sounding function which can do.
[0012]
[Means for Solving the Problems]
  In order to solve the above problems, the invention described in claim 1 of the present invention is, for example, as shown in FIGS.
  Terminal equipment provided for each of several districts,
  District sound (district bell 61) that is set up for each district and emits an alarm,
  A fire receiver (20) that performs fire control and notification of fire occurrence in all districts while comprehensively controlling the terminal device and the district sound in each district,
  As the terminal device, a fire detector (41) that detects a fire and transmits a fire detection signal to the fire receiver via a predetermined one line (L1, L2, or L3 line), and is operated from the outside. Then, a fire alarm system having a transmitter (43) that transmits a transmitter signal to the fire receiver via two lines (L1, L2, L3, and A lines) including the predetermined one line. In (10),
  The fire receiver is
  The fire detectorWhen the fire detection signal is transmitted from the fire detector through the predetermined one line during the maintenance inspection of theWith a ringing time set shorter than the normal monitoring modeRing a certain number of times,
  During maintenance inspection of the transmitter,When the transmitter signal is transmitted from the transmitter via each of the two lines, the district sound is associated with the predetermined one line.With a ringing time set shorter than the normal monitoring modeIn addition to ringing a certain number of times,In response to another lineWith a ringing time set shorter than the normal monitoring modeIt is characterized by sounding a predetermined additional number of times.
[0013]
  According to the invention of claim 1,During maintenance and inspection of the fire detector,When the fire detection signal is transmitted from the fire detector to the fire receiver via the predetermined one line, the district sound is transmitted a predetermined number of times.Only shorter than monitoring modeRinging,During maintenance and inspection of the transmitterWhen the transmitter signal is transmitted from the transmitter to the fire receiver via each of the two lines, the district sound is (predetermined number + predetermined number of additional times).Only shorter than monitoring modeBecause it ringsDepending on whether the line condition is abnormal or normal when testing a sensor or transmitterIf the sound pattern (number of times) of the district sound changes and the person who is actually performing the test work does not sound only a predetermined number of times despite the test of the transmitter, You can immediately notice that one of the two lines that send signals is abnormal.
  Here, the specific numbers for the “predetermined number of times” or the “additional predetermined number of times” are not particularly limited. For example, each of the numbers is set once, and the signal from the fire detector is sounded once. The signal from may be configured to ring twice.
[0014]
  Also,In the invention of claim 1,Invention of Claim 2IsFor example, as shown in FIGS.,
  The fire receiver is used for maintenance and inspection of terminal equipment in each district.Other than empty lineDistricts where maintenance has not been completedNumberIt has the display means (display 73) which displays only.
[0015]
  According to the invention described in claim 2, during the maintenance inspection, the display meansOther than empty lineDistricts where maintenance has not been completedNumberSince it is only displayed, you can be sure of which district has not ended.
  Here, the display form in the display means is not particularly limited. For example, the district name itself such as “1F” may be used, or a number or the like may be attached to each district and displayed. A plurality of districts may be displayed at a time, or only one district may be displayed and the display may be switched by a switch or the like.
[0016]
In the invention according to claim 2, as in the invention according to claim 3, when the fire receiver stops the maintenance inspection halfway, it indicates that there is an area where the maintenance inspection has not been completed. Inspection display means (maintenance indicator lamp 32a) may be provided.
According to the third aspect of the present invention, when maintenance inspection is stopped halfway, an indication that there is an area where maintenance inspection has not been completed is displayed by the non-maintenance inspection display means. It is possible to grasp that there is a district where maintenance inspection has not been completed.
Here, the non-maintenance inspection display means may utilize the display means of claim 2 or may be different from the display means, for example, an indicator lamp.
[0017]
In Claims 1-3, as a terminal device, for example, in addition to a fire detector and a transmitter, there are a smoke prevention device, a fire hydrant, a gas detector, and the like, and a plurality of the same terminal devices are provided in one district. May be.
[0025]
Here, the “history information” is information related to various activities of the fire receiver. For example, information on the control signal output from the fire receiver to each terminal device and the response signal input from the terminal device. Information, and further, instructions etc. input by an operator or the like via an operation switch or the like.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a configuration of a fire alarm facility 10 which is an example of a fire alarm facility according to the present invention. The fire alarm facility 10 mainly includes a fire receiver 20, a terminal device group 40, and a district bell group. 60. For example, the fire alarm facility 10 is installed in a building having a plurality of floors, and one floor of this building is regarded as one district, and is related to fire monitoring and fire notification or fire extinguishing work of the entire building. Responsible for all disaster prevention activities.
[0027]
The fire receiver 20 is installed, for example, in a disaster prevention center of a building, a manager's room, etc., and supervises and controls the entire fire alarm system 10, and is called a so-called P-type receiver. FIG. 2 shows a front view of the fire receiver 20.
As shown in FIG. 1, the fire receiver 20 includes a CPU (Central Processing Unit) 21, a ROM (Read Only Memory) 27, a RAM (Random Access Memory) 22, a display unit 28, and a terminal connected to the CPU 21. The interface 29 includes a bell interface 30, a PC interface 26, a history storage unit 25, an acoustic unit 24, and an operation unit 23.
[0028]
The ROM 27 stores various control programs and control data for operating the fire receiver 20, and the RAM 22 temporarily stores data and the like. The CPU 21 follows the control programs and control data in the ROM 27. The operation of the fire receiver 20 is controlled while using the RAM 22 as a work area.
[0029]
The display unit 28 is for displaying the current status of the fire alarm system 10, and is provided in front of the fire receiver 20, as shown in FIG. 2, and includes a first display unit 28a and a second display unit. 28b and a third display unit 28c. FIG. 3 shows details of the second display unit 28b and the third display unit 28c.
The first display unit 28a is provided with district windows 70, 70... For each district, and each district window 70 is provided with one LED 71, and a signal is sent from the terminal device in each district to the fire receiver 20. When the input is made, the LED 71 is turned on to notify an operator in the vicinity of the fire receiver 20 of the occurrence of an event in the area. In FIG. 2, 20 district windows 70, 70... Are shown for convenience. Reference numeral 70a denotes a floor plate on which a district name such as “first floor” is written.
[0030]
The second display portion 28b is provided with an LED group 32 that displays whether various functions attached to the fire alarm facility 10 are operating. For example, in the maintenance inspection state (maintenance inspection mode), the in-maintenance indicator light 32a blinks, and this in-maintenance indicator light 32a is in a state where there is an area where maintenance inspection has not been completed. When the maintenance / inspection mode is canceled, the blinking state is maintained. That is, the maintenance light display lamp 32a is the non-maintenance inspection display means of the present invention.
[0031]
  Further, when any transmitter 42 (FIG. 1) in the fire alarm facility 10 is activated, the transmitter indicator light 32b is turned on. Further, when it is detected by the sensor 41 (FIG. 1) that a fire has occurred, the fire alarm fire representative lamp 32e is turned on.
  The second display unit 28b includes an alarm buzzer unit (sound unit) 72a that emits an alarm sound and a telephone jack.72cA telephone speaker unit 72b for a telephone connected to is provided. In the fire receiver 20, when the district bell 61 (FIG. 1) in any of the districts rings, an alarm sound is also emitted from the alarm buzzer 72a.
[0032]
The third display unit 28c is provided with a three-digit seven-segment display 73, and an error code or the like is displayed on the display 73.
Further, an up switch 74 and a down switch 75 are provided below the display unit 73. In the fire alarm system 10, a number is assigned to each circuit (district circuit) constituting each district, and the maintenance inspection is completed in the maintenance inspection mode, not an empty line (a circuit that does not contribute to fire monitoring). The number of the district circuit that is not present is displayed on the display 73. That is, the display device 73 is the display means of the present invention.
[0033]
Therefore, the display on the display 73 can display the numbers of all district circuits other than the empty line immediately after the start of the maintenance inspection. With regard to this number display, a large number can be displayed one by one for the district circuit that can be displayed by operating the up switch 74, and a small number is displayed one by one in the same manner by operating the down switch 75. It can be made to.
Then, when the maintenance inspection mode is left and the normal monitoring mode is returned from the maintenance inspection mode, the display of the untested area in the display unit 73 remains.
Directly above the up switch 74 and the down switch 75 are provided line selection indicator lights 76, 76 for indicating that these switches are operable.
[0034]
The operation unit 23 includes various switches for an operator to instruct various operations in the fire alarm facility 10 and restoration of terminal equipment. The appearance of the operation unit 23 is not provided solely by the operation unit 23, but is provided in the second display unit 28b and the third display unit 28c of the display unit 28 as shown in FIG.
That is, the operation unit 23 includes an acoustic stop switch 77 provided in the second display unit 28b, a district acoustic stop switch 78, and a switch group 33 provided in the third display unit 28c.
[0035]
The sound stop switch 77 stops the alarm buzzer 72a of the fire receiver 20 when it is sounding. The district sound stop switch 78 sounds when the district bell 61 (FIG. 1) of each district sounds. This is what you want to stop.
The switch group 33 is for turning on / off various functions performed in the fire alarm facility 10, and includes, for example, a whole building ringing switch 33a that is operated when ringing a district bell of the whole building (entire building).
Also, a maintenance switch (not shown) is provided on the board inside the fire receiver for switching the entire building to the maintenance / inspection function (maintenance / inspection mode) or returning the maintenance / inspection mode to the normal monitoring state.
Furthermore, an indicator lamp (for example, indicator lamp 33aa) is provided on each switch to indicate whether or not the switch is operating as necessary.
[0036]
The acoustic unit 24 controls ringing of the district bells 61, 61 (see FIG. 1), and the district bell group 60 and the acoustic unit 24 are connected via the bell interface 30.
[0037]
The history storage unit 25 is a storage unit of the present invention, and is generated in the fire receiver 20 such as event information input from the terminal device of each district circuit to the fire receiver 20 and various switch operations in the operation unit 23. Information on all operations (hereinafter referred to as history information) is recorded together with the time. The number of writable data items is about 10,000. When the capacity is exceeded, the data items are erased from the oldest and the latest data is always stored.
Specifically, the history storage unit 25 includes a history collection board 80 (FIG. 4) attached in the fire receiver 20. As shown in FIG. 5, the fire storage activity of the fire receiver 20 is functionally functional. Can be said to be an independent storage medium, and by connecting an external PC (personal computer) 100, the history information of the fire receiver 20 can be read as data from the history collection board 80. Yes.
[0038]
The history collection board 80 is provided with a CPU 81, a memory 82, a clock unit 83, a capacitor 84, a dip switch 85, and the like.
The CPU 81 has a communication port 81a for receiving history information from the fire receiver 20 and a communication port 81b for outputting history information data to the external PC 100, and controls the input / output of history information. is there. Information input from the fire receiver 20 is input via the receiver interfaces 87 and 88. Note that communication with the fire receiver 20 via the communication port 81a is clock synchronous communication, and communication with the external PC 100 via the communication port 81b employs start-stop synchronous communication.
[0039]
The memory 82 is an area in which history information of the fire receiver 20 is stored. The memory 82 includes an SRAM (static RAM), and data is retained as long as the fire receiver 20 is turned on. Even when the power is not supplied due to a power failure or the like, the backup capacitor 84 provides backup for 72 hours or more.
The clock section 83 is a 4-digit 7-segment display that measures the time and can be adjusted with a ± key 86. The dip switch 85 sets a communication state.
The PC interface 26 (FIG. 1) is attached to the history collection board 80, and the history information stored in the memory 82 can be taken out to the PC 100 by connecting the external PC 100 to the PC interface 26. It is like that. For example, RS232 or RS485 I / F is used as the PC interface 26.
[0040]
The terminal device group 40 includes each terminal device installed for each district.
A circuit (district circuit) constituting one district is formed by connecting sensors 41 and 41 as a terminal device and a transmitter 42 in parallel to a common line C and an L1 line (or L2 line or L3 line). The common line C and L1 line (L2 line, L3 line) are connected to the fire receiver 20 via the terminal interface 29, and a control signal from the fire receiver 20 is connected to each terminal via the common line C. The response signal from each terminal device is output to the fire receiver 20 via the L1 line (L2 line, L3 line). In this specification, when the L1 line, L2 line, and L3 line are not distinguished, it may be referred to as the L line, and the L1 line, the L2 line, the L3 line, or the L line as a generic name thereof is used in the invention. “Predetermined one track”.
[0041]
In FIG. 1, three districts are shown for convenience. In FIG. 1, detectors 41 and 41 are well-known smoke-type fire detectors. When a fire is detected, a fire detection signal is transmitted to the fire receiver 20 via the L1 line (L2 line, L3 line). .
Further, the transmitter 42 is provided with a push button (not shown), and is a signal that a fire has occurred to the fire receiver 20 when a resident or the like notices that a fire has occurred and presses the push button. The transmitter signal is transmitted. The transmitters 42 in each area are connected not only to the common line C and L1 line (L2 line, L3 line) but also to the A line connecting all the districts. When the transmitter 42 is pressed, the L1 line ( The transmitter signal is output to the fire receiver 20 via the A line as well as the L2 line and the L3 line. That is, the transmitter 42 in each district transmits a transmitter signal to the fire receiver 20 through two lines of L1 line (L2 line, L3 line) and A line.
[0042]
During normal times, a constant voltage (for example, 24V) is applied between the common line and the L line of each district circuit. When the sensor 41 detects a fire, the voltage drops to a certain voltage (for example, 6V). Becomes a fire detection signal. On the other hand, when the push button of the transmitter 42 is pressed, a short circuit is established, and the voltage drops to a value close to 0V, which becomes a transmitter signal.
Further, a terminal unit 43 is provided at the end of each district circuit. A predetermined voltage signal is periodically output from the terminal unit 43 to the fire receiver 20, so that the fire receiver 20 It is possible to monitor the disconnection of the district circuit.
[0043]
The district bell group 60 includes a district bell 61 which is a district sound for warning installed in each district. The district bell 61 in each district is connected to a bell common line BC common to all districts and a bell line B1 (or B2) for each district. The bell common line BC and the bell line B1 (B2) are connected to the fire receiver 20 via the bell interface 30, and a control signal from the fire receiver 20 is transmitted to each district bell 61 via the bell common line BC. The response signal from each district bell 61 is output to the fire receiver 20 via the bell line B1 (B2). The district bell connected to the bell line B1 (B2) rings according to a control signal from the fire receiver 20.
In FIG. 1, for convenience, a bell line for two districts and three district bells 61 for each bell line are shown.
[0044]
The fire receiver 20 has data (linked data) for linking one of the district circuits and one of the bell lines in the ROM 27. When an event occurs in one district, the fire receiver 20 corresponds to that district. The district bell 61 of the location is ringed.
That is, when the first fire detection signal is input from the detector 41, the fire receiver 20 is based on the interlocking data, and the district bell 61 on the district (the floor concerned) and the directly above floor where the detector 41 is provided. After that, when the second fire detection signal is input, the district bell 61 of the entire building is ringed regardless of the interlocking data (section ring method).
[0045]
In the segmented sound system, the sound corresponding to the first fire detection signal is continuous sound, and the sound corresponding to the second fire detection signal is intermittent sound.
FIG. 6 shows an outline of a circuit for causing the district bell group 60 to ring. FIG. 6 shows a bell common line BC, lines BC1, BC2,. ... sn and terminals b1, b2, ... bn are shown.
[0046]
Each of the terminals b1, b2,..., Bn is connected to the district bell 61 (FIG. 1). To be exact, the line BC1 has a plurality of terminals b1, but only one is shown in FIG. 6 for convenience. The same applies to the lines BC2,... BCn.
The bell common line BC is provided with a relay rb.
In FIG. 6, when the relay rb and the switch s1 of the line BC1 are closed, the district bell 61 connected to the terminal b1 rings. In this case, continuous ringing is performed by holding the relay rb in a closed state, and intermittent ringing is performed by intermittently opening and closing the relay rb. The same applies to the line BC2 and the line BC3.
[0047]
In the fire alarm facility 10, a maintenance switch (not shown) is operated to switch from the normal fire monitoring mode to the maintenance / inspection mode.
Even in the maintenance / inspection mode, as in the normal fire monitoring mode, the terminal device group 40 and the district bell group 60 are linked based on the linkage data. However, unlike the normal monitoring mode, the ringing time is set shorter in the maintenance inspection mode.
[0048]
During maintenance and inspection, if there is no abnormality in the sensor 41, a fire detection signal is transmitted to the fire receiver 20 via the L line, and the fire receiver 20 receives the signal and responds based on the interlocking data. Ring the district bell once. If there is no abnormality in the transmitter 42, a transmitter signal is transmitted to the fire receiver 20 via the L line and the A line, and the fire receiver 20 responds to the transmitter signal from each line. The corresponding district bell is ringed once, ie, twice in total, based on the interlocking data.
Note that the ringing by the transmitter signal from the transmitter 42 is likely to be a fire, so the entire building is suddenly ringing.
[0049]
Further, during the maintenance inspection mode of the fire alarm system 10, when a fire detection signal from another area is input to the fire receiver 20 during the maintenance inspection of one area, the monitoring mode is automatically switched. Yes. In other words, a fire alarm system with a P-type receiver is a relatively small disaster prevention system, and maintenance and inspection are often performed with a minimum number of people. It is thought that maintenance inspection work will be carried out by two persons with a person. Therefore, there is only one person who tests the terminal equipment, and if a fire detection signal is input to the fire receiver from multiple district lines, it is considered that a fire has actually occurred. Is interrupted and switched to the normal monitoring mode.
[0050]
Hereinafter, various control processes performed by the fire receiver 20 in the monitoring mode or the maintenance / inspection mode (maintenance mode) will be described with reference to flowcharts.
[0051]
FIG. 7 shows a flowchart of the ringing process in the normal monitoring mode.
In the normal monitoring mode, in step S <b> 1, it is determined whether or not a fire detection signal from the sensor 41 is input to the fire receiver 20. If it is determined in step S1 that a fire detection signal has been input, the process proceeds to step S2. If it is determined that no input has been made, the determination in step S1 is repeated.
In step S2, the line (district circuit) connected to the sensor 41 that has issued the fire detection signal is searched, and in the next step S3, the bell line corresponding to the district circuit obtained as a result of the search is searched based on the interlocking data. To select. As already described, the floor selected here is the same floor as the district circuit where the fire was detected and the floor immediately above it.
Next, in step S4, a process for determining whether or not the fire detection signal in step S1 is the first report is performed. If it is the first report, the process proceeds to step S5 to continuously ring the selected district circuit. If it is determined in step S4 that it is not the first report, the process proceeds to step S6 and the entire building is intermittently sounded.
After the steps S5 and S6, the ringing process ends.
[0052]
FIG. 8 shows a flowchart of display processing of an uninspected area at the time of maintenance inspection.
First, this process starts from the normal monitoring mode, and it is determined in step S12 whether or not the mode has been switched to the maintenance mode. If it is determined in step S12 that the maintenance switch (not shown) has been operated to switch to the maintenance mode, the process proceeds to step S13, and the determination in step S12 is repeated unless switched.
In step S13, a process of blinking the maintenance indicator lamp 32a (FIG. 3) is performed. Next, in step S14, line data of the district circuit to be inspected other than the empty line is acquired, and the process proceeds to step S15. In step S15, a process of displaying on the display 73 the number assigned to the line of the district circuit for which maintenance inspection has not been completed from the line data acquired in step S14 is performed. With this processing, when the up switch 74 and the down switch 75 are operated, the numbers assigned to the district circuits that have not been subjected to the maintenance inspection are displayed on the display unit 73 in order.
[0053]
Next, in step S16, a process for determining whether or not the maintenance mode is released is performed. If the maintenance mode is not released, the process proceeds to step S17. In step S17, it is determined whether or not a maintenance inspection test in a certain district has been executed (finished). If it is determined that the test has been executed, a process is performed in step S18 to indicate that the circuit of the district circuit that has been tested has been tested, and then in step S19, an untested (maintenance inspection has been completed) (Not) is updated, and the process returns to step S15. In step S15, processing for displaying only untested district circuits at this time is performed.
If it is determined in step S17 that the test has not been executed, the process returns to step S15.
[0054]
If it is determined in step S16 that the maintenance mode is released, the process proceeds to step S20. In step S20, it is determined whether or not an untested district circuit remains when the maintenance mode is released. If it remains, the process proceeds to step S21. In step S21, the maintenance indicator lamp 32a is kept blinking. Processing is performed. If it is determined in step S20 that there are no untested district circuits remaining, the process proceeds to step S22, and a process of turning off the maintenance indicator lamp 32a is performed.
After step S21 and step S22, the normal monitoring mode is restored.
[0055]
FIG. 9 shows a flowchart of the process of ringing the district bell during the maintenance mode.
When this process starts, it is determined in step S31 whether or not a signal has been input to the fire receiver 20 from the L line. If it determines with having input, it will transfer to step S32. In step S32, it is further determined whether or not a signal is input from the A line to the fire receiver 20. If it determines with having input, it will transfer to step S34, ie, the process which makes the district bell ring twice shortly that it is a test of the transmitter 42 is performed.
If it is determined in step S32 that no signal is input from the A line, the process proceeds to step S33. In step S33, it is determined whether or not the signal input to the L line determined in step S31 is a fire detection signal (a signal having the same level as that), and if it is a fire detection signal, the process proceeds to step S35. As the test of 41, the process of ringing the district bell once is performed.
[0056]
If it is determined in step S31 that no signal is input to the L line, or if it is determined in step S33 that it is not a fire detection signal, the process returns to step S31 after steps S34 and S35.
[0057]
FIG. 10 is a flowchart showing the processing when a fire actually occurs in another district during the maintenance mode in one district.
When the maintenance mode starts, first, in step S41, it is determined whether or not there is a fire alarm, that is, whether or not a fire detection signal from the sensor is input to the fire receiver 20, and if it is determined that there is a fire alarm. The process proceeds to step S42. If there is no fire alarm, the determination in step S41 is repeated.
In step S42, it is determined whether or not the fire report that has been determined in step S41 is the first report. If it is the first report, it is determined that there is no problem because it is a test during maintenance and inspection, and the process returns to step S41 again.
However, if it is determined in step S42 that it is not the first report, a fire detection signal has been issued from a district other than the area where maintenance inspection is being performed. Return to monitoring mode.
[0058]
According to the above fire alarm system 10, as shown in FIG. 7, the ringing of the district bell corresponding to the first fire detection signal is continuous and the ringing of the district bell corresponding to the second and subsequent fire detection signals. Because of the intermittent ringing, residents can distinguish whether the fire has spread or the fire has spread by listening to the ringing of the district sound. In particular, the use of a segmented sound system, it can be seen that the risk of fire has further increased due to changes in the sound of the district sound, and it is understood that urgent evacuation is required.
[0059]
Further, as shown in FIG. 9, during maintenance inspection, the fire receiver 20 tests the transmitter 42, that is, when a signal is input to the fire receiver 20 from both the L line and the A line. Makes the district bell 61 ring intermittently twice, and when the sensor 41 is tested, that is, when the fire detection signal is input once from the L line, the district bell 61 rings once, depending on the test object. The pattern is changing. Therefore, the person who is actually performing the test work can surely know that there is an abnormality in one of the lines if it rings only once even though the transmitter 42 is tested.
[0060]
As described above, it can be said that the fire alarm system 10 according to the present embodiment has a ringing function that provides detailed information as compared with the conventional case both during maintenance inspection and during normal fire monitoring.
[0061]
Furthermore, in the fire alarm system 10, as shown in FIG. 8, when the maintenance inspection mode is set, the number of the area where the maintenance inspection has not been completed can be displayed on the display unit 73. It can be easily confirmed whether there is an inspection omission.
Further, when switching to the normal monitoring mode with the untested area remaining, the blinking display of the maintenance indicator lamp 32a is maintained, so that the operator can grasp that the maintenance inspection has not ended. Furthermore, since the display of the untested area on the display device 73 remains even after the inspection is completed, it can be easily confirmed which maintenance inspection has not been completed.
[0062]
In addition, as shown in FIG. 10, the fire alarm system 20 automatically switches to the maintenance mode when the maintenance mode is not the first report, that is, when there is a second or subsequent fire report. Since the operation is canceled and the operation returns to the normal monitoring mode, the various operations of the fire alarm system 10 are in a monitoring state. Specifically, the district bell 61 that has been ringing briefly at the time of maintenance and inspection is ringing for a long time as usual. Occurrence of fire can be notified to residents and the like, and it becomes a fire alarm facility having a maintenance inspection function corresponding to the actual situation.
[0063]
Furthermore, the fire receiver 20 includes a history storage unit 25 and relates to all of the events that occur in the fire receiver 20 such as event information input from each district to the fire receiver 20 and various switch operations in the operation unit 23. Since history information is recorded along with the time, by extracting data from the history storage unit 25, it is possible to analyze the detailed time at the time of a fire or maintenance and the operation procedure at that time later. In addition, the subsequent processing and operation can be improved, and when a non-fire report is issued, it is possible to check the district and time zone in which the non-fire report is likely to occur. In this way, various matters can be improved from past facts.
[0064]
As described above, the fire alarm system 10 according to the present invention is more useful than the conventional one, and particularly in the maintenance / inspection function, it can perform reliable maintenance / inspection and sufficiently cope with the actual situation. is there.
[0065]
Note that the fire alarm system of the present invention is not limited to the above-described embodiment, and it is needless to say that the specific configuration or the like can be changed as appropriate.
For example, the maintenance indicator lamp may be turned on during maintenance, and may be switched to blinking when maintenance inspection is completed with an unmaintained line remaining.
[0066]
  According to the invention of claim 1,During maintenance and inspection of the fire detector,When the fire detection signal is transmitted from the fire detector to the fire receiver via the predetermined one line, the district sound is transmitted a predetermined number of times.Only shorter than monitoring modeRinging,During maintenance and inspection of the transmitterWhen the transmitter signal is transmitted from the transmitter to the fire receiver via each of the two lines, the district sound is (predetermined number + predetermined number of additional times).Only shorter than monitoring modeBecause it ringsDepending on whether the line condition is abnormal or normal when testing a sensor or transmitterIf the sound pattern (number of times) of the district sound changes and the person who is actually performing the test work does not sound only a predetermined number of times despite the test of the transmitter, You can immediately notice that one of the two lines that send signals is abnormal.
  Here, the specific numbers for the “predetermined number of times” or the “additional predetermined number of times” are not particularly limited. For example, each of the numbers is set once, and the signal from the fire detector is sounded once. The signal from may be configured to ring twice.
[0067]
  According to the invention described in claim 2, during the maintenance inspection, the display meansOther than empty lineDistricts where maintenance has not been completedNumberSince it is only displayed, you can be sure of which district has not ended.
  Therefore, more reliable maintenance inspection is possible.
[0068]
According to the invention described in claim 3, in addition to the effect described in claim 2, when the maintenance inspection is stopped halfway, an indication that there is an area where the maintenance inspection is not completed by the non-maintenance inspection display means Therefore, it can be understood that there is a district where the maintenance inspection has not been completed even after the maintenance inspection state is released.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an example of a fire alarm facility of the present invention.
2 is a front view of a fire receiver provided in the fire alarm facility of FIG. 1. FIG.
FIG. 3 is an enlarged view showing a part of the display unit of the fire receiver of FIG. 2;
4 is a plan view of a history collection board in the fire receiver of FIG. 2. FIG.
5 is a schematic diagram showing the relationship between the history collection board of FIG. 4 and a fire receiver. FIG.
6 is a diagram showing an outline of a bell common line of the district bell group in FIG. 1. FIG.
FIG. 7 is a flowchart showing ringing processing in a normal monitoring mode.
FIG. 8 is a flowchart showing display processing for an uninspected area in the maintenance mode.
FIG. 9 is a flowchart showing a process for ringing a district bell in the maintenance mode.
FIG. 10 is a flowchart showing maintenance mode release processing when a fire actually occurs during the maintenance mode.
FIG. 11 shows a general configuration of a fire alarm facility.
[Explanation of symbols]
10 Fire alarm equipment
20 Fire receiver
21 CPU
22 RAM
23 Operation unit
24 Sound part
25 History storage unit (storage means)
26 PC interface
27 ROM
28 Display section
32a Indicator light during maintenance (unmaintenance inspection display means)
73 Display (display means)
29 Interface for terminal
30 bell interface
40 Terminal equipment group
41 Sensor (terminal equipment)
42 Transmitter (terminal equipment)
60 district bells
61 District Bell (District Sound)
70 district window

Claims (3)

Terminal equipment provided for each of several districts,
The district sound that is set up for each district and issues a warning,
A fire receiver for monitoring the fire of all the districts and reporting the occurrence of the fire while controlling the terminal equipment and the district sound in each district,
The terminal device includes a fire detector that detects a fire and transmits a fire detection signal to the fire receiver via a predetermined line, and a transmitter signal that includes the predetermined line when operated from the outside. In a fire alarm facility having a transmitter that transmits to the fire receiver via a track,
The fire receiver is
During maintenance of the fire detector, predetermined by the predetermined set ringing time shorter than the normal monitoring mode of the local sound and the fire detection signal is transmitted through the first line from said fire detector Ring several times,
When the transmitter signal is transmitted from the transmitter via each of the two lines at the time of maintenance and inspection of the transmitter, the local sound is made shorter than the normal monitoring mode corresponding to the predetermined one line. in addition to the predetermined number of times ringing at a set ring time, fire alarm system, characterized in that for a predetermined number of additional sound at a set ring time shorter than the normal monitoring mode in response to another first line. The said fire receiver has a display means which displays only the number of the district where maintenance inspection other than an empty line is not completed at the time of maintenance inspection of the terminal equipment in each district. Fire alarm equipment.   The fire alarm according to claim 2, wherein the fire receiver is provided with a non-maintenance inspection display means for displaying that there is an area where the maintenance inspection is not completed when the maintenance inspection is stopped halfway. Facility.

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