JP4651290B2 - Fire alarm system - Google Patents

Description

  The present invention relates to a fire alarm system capable of efficiently performing an alarm test operation of a fire detector performed for maintenance inspection and the like.

  In order to efficiently perform the fire detector alarm test work performed for maintenance inspection, etc., the fire receiver is equipped with a test recovery switch, and when the test recovery switch is operated, the fire signal received from the fire detector Are stored in order in the storage means, so that the fire signal stored in the storage means can be read out after completing the work of bringing the tester close to the fire detector, the so-called “blown test”. There is something like that.

Further, the fire receiver is provided with a test status confirmation switch and a display means, and when the test status confirmation switch is operated, the display means displays the fire signals stored in the storage means in the order of storage. Thus, the fire signals are displayed in the order in which the alarm tests were performed. (For example, refer to Patent Document 1).
JP-A-12-99842

  Workers need to perform a “blur test” of all fire detectors, but simply looking at the fire detectors can distinguish whether a fire detector has been tested or not yet tested. It was not possible, and it was necessary to check which fire detector had been tested using a fire detector installation drawing, etc., and the alarm test work was complicated.

  Also, if the worker on the fire detector side finds that the alarm test work has been completed in units of sensor lines or all fire detector units, the alarm test work on the fire detector side will be performed. It can be done efficiently. For example, it is possible to smoothly move between floors when sensor lines are provided in units of floors.

  Furthermore, as a method for confirming the alarm test result on the fire receiver side, the fire signals stored in the storage means are only displayed in the order in which they are stored on the display means. It was cumbersome to check the test order of the fire detectors and check if they were displayed in that order. Also, even if the display means had the display order, it was not possible to confirm whether there was a fire detector with an alarm test leak.

  There is also a desire to make it easy to create inspection reports.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to make it possible to efficiently perform an alarm test operation of a fire detector performed for maintenance and inspection.

The present invention includes a sensor line to which a plurality of fire detectors are connected, and a fire receiver to which a plurality of the sensor lines are connected, and a fire signal based on a switching operation from the fire sensor is sent to the fire. In the fire alarm facility received by the receiver, the fire receiver is set to a test mode based on an operation of the test switch and a control means for sending a test mode start signal to the fire detector. A connection number storage unit for storing the number of fire detectors connected for each sensor line, and the number of fire detectors that sent a fire signal for each sensor line in the setting state of the test mode. comprising a storage for alarm number storage unit, and the test results stored switch, test result storage unit, wherein the control means, based on the operation of the test result storage switch, corresponding to the line number of each sensor lines The number of fire detector connections stored in the connection number storage unit and the number of fire detector notifications stored in the notification number storage unit are stored in the test result storage unit, and the fire Upon receiving the test flag storage unit of the nonvolatile memory, the test report flag storage unit of the nonvolatile memory, and the test mode start signal, the sensor turns on the test flag of the test flag storage unit from the initial state OFF. When a fire is detected in the test mode setting state, the test report flag in the test report flag storage unit is turned on from the initial state to the on state and stored. A control unit that determines the state of the test report flag in the test report flag storage unit in the setting state of the test mode, and if the test report flag is off ,display It was controlled to a predetermined lighting state, also, if the test onset report flag is on, and to control the different display states of the display lamp and the predetermined lighting conditions. In addition, the control means, after receiving the fire signal in the setting state of the test mode, cuts off the power supply to the alarm line that has been issued, thereby switching the fire detector that has sent the fire signal. It is made to cancel.

According to the first aspect of the present invention, the operator can easily create an inspection report in the alarm test work using the data stored in the test result storage unit.

  <First Embodiment> FIG. 1 is a system configuration diagram of a fire alarm system showing a first embodiment of the present invention.

  This fire alarm facility includes a plurality of fire detectors SE, a plurality of district bells B, and a fire receiver RE.

  First, the fire receiver RE will be described. The fire receiver RE is provided with a microprocessor MPU 10 for controlling the entire fire receiver RE as a control means. The microprocessor MPU 10 includes a ROM that stores an operation program and the like, and a working RAM. The microprocessor MPU 10 is normally in the normal monitoring mode, but is set to the test mode based on the operation of the test switch 11a described later during the alarm test operation of the fire detector SE. The setting state of these modes is stored in the RAM.

  For the microprocessor MPU10, an operation unit 11, a display unit 12, a connection number storage unit 13, a notification number storage unit 14, a test result storage unit 15, a supply voltage switching circuit 16, and reception circuits 17-1 to 17-n. And district bell circuits 18-1 to 18-n are provided.

  Sensor lines KL1 to KLn are drawn out from the respective receiving circuits 17-1 to 17-n, and a plurality of fires are caused between the common lines (C lines) and line lines (L lines) of the sensor lines KL1 to KLn. Sensors SE are connected in parallel, and termination resistors RL1 to RLn for disconnection monitoring are connected to the terminations. As an example, in this embodiment, it is assumed that the number of connected fire detectors SE in the detector lines KL1, KL2,..., KLn is 10, 5,.

  The fire detector SE will be described in detail with reference to FIG. 2. However, when heat, smoke, etc. due to a fire are detected, the C line and the L line of the sensor line KL are short-circuited to a low impedance to cause a fire. The alarm current is sent as a signal. And the receiving circuits 17-1 to 17-n are adapted to receive the fire signal sent from the fire detector SE.

  From each of the district bell circuits 18-1 to 18-n, district bell lines BL1 to BLn are drawn out, and a district bell B is connected to each of the district bell lines BL1 to BLn. The district bell circuits 18-1 to 18-n are controlled by the microprocessor MPU10 so as to ring each district bell B connected to the district bell lines BL1 to BLn. Here, the sensor lines KL1 to KLn and the district bell lines BL1 to BLn installed in the building have the same line numbers 1 to n installed in the same warning area 1 to n (for example, the same floor). Has been.

  The operation unit 11 includes a test switch 11a for switching the setting state of the microprocessor MPU 10 to a normal monitoring mode or a test mode, a test result confirmation switch 11b for the alarm test operation of the fire detector SE, and an alarm test operation of the fire detector SE. The test result storage switch 11c is provided.

  The connection number storage unit 13 is a non-volatile memory that stores the number of connections of the fire detectors SE connected to the sensor lines KL1 to KLn. In this embodiment, the sensor lines KL1, KL2,. Corresponding to the line numbers 1, 2,..., N of KLn, 10, 5,.

  The number-of-reports storage unit 14 is controlled by the microprocessor MPU10 so as to store the number of reports of the fire detector SE that has sent out a fire signal for each of the sensor lines KL1 to KLn in the test mode setting state of the microprocessor MPU10. In the initial state, the number of notifications in each of the sensor lines KL1 to KLn is stored as zero. Each time each of the receiving circuits 17-1 to 17-n receives a fire signal, the number of fire detectors SE in the corresponding sensor lines KL1 to KLn is incremented by one and stored. Yes.

  When the test result storage switch 11c is turned on, the test result storage unit 15 stores in the connection number storage unit 13 as an alarm test result corresponding to the line numbers 1 to n of the sensor lines KL1 to KLn. It is a non-volatile memory controlled by the microprocessor MPU 10 so as to store the number of connected fire detectors SE and the number of fire detectors SE stored in the number-of-reports storage unit 14. The test result storage unit 15 is a removable storage medium such as a flexible disk or a memory card. For example, the test test is performed in a CSV file format so that it can be used by general-purpose spreadsheet application software such as Excel. The result is memorized. Therefore, the worker who performs the alarm test work of the fire detector SE can easily create an inspection report anywhere using the test result storage unit 15.

  The display unit 12 is provided with district indicator lights 19-1 to 19-n corresponding to the sensor lines KL1 to KLn. The district indicator lights 19-1 to 19-n are controlled by the microprocessor MPU10 to display the fire status of the corresponding sensor lines KL1 to KLn when the microprocessor MPU10 is in the normal monitoring mode setting state. However, when the microprocessor MPU 10 is in the test mode setting state, the sensor lines KL1 to KLn are based on the stored contents of the connection number storage unit 13 and the notification number storage unit 14 as the notification test result. Control is performed so as to display whether or not there is a fire detector SE of the alarm test leak every time. That is, for each of the sensor lines KL1 to KLn, the number of fire detectors SE stored in the connection number storage unit 13 and the number of fire detectors SE stored in the report number storage unit 14 are compared. Control is performed so that the display states of the corresponding district indicator lights 19-1 to 19-n are different depending on whether they match or not. For example, in consideration of the disconnection of the district indicator lights 19-1 to 19-n, the lighting is controlled so as to be continuously lit when they coincide with each other and to blink when they do not coincide with each other. Therefore, on the fire receiver side, the operator can check the alarm test result for each sensor line by looking at the indication of the district indicator light, and the fire detector for the alarm test leak for each sensor line. You can check if there is.

  In addition, when the test result confirmation switch 11b is turned on, the district indicator lamps 19-1 to 19-n display corresponding district indications in the order of the line numbers 1 to n of the sensor lines KL1 to KLn. The lights 19-1 to 19-n are blinked by the number of connected fire detectors SE stored in the connected number storage unit 13, and the number of fire detectors SE stored in the reported number storage unit 14 is flashed. It is controlled by the microprocessor MPU 10 so as to blink only for minutes. Therefore, on the fire receiver side, the operator can check the result of the alarm test for each sensor line, and can check how many fire detectors have the alarm test leak for each sensor line.

  The district indicators 19-1 to 19-n are blinked as many times as there are remaining notifications, and are turned off when there is no remaining information so that the remaining number can be more easily confirmed. Good.

  The supply voltage switching circuit 16 supplies a power supply voltage, for example, 24 V to the fire detector SE via the reception circuits 17-1 to 17-n when the microprocessor MPU10 is in the normal monitoring mode setting state. It is controlled by the microprocessor MPU10. When the microprocessor MPU10 is set to or released from the test mode by turning on / off the test switch 11a, the test mode start signal and test mode end signal are It is controlled to supply a voltage different from 24V, for example, 36V for a certain period.

  When the microprocessor MPU 10 receives a fire signal from the fire detector SE in the test mode setting state, the microprocessor MPU 10 corresponds to the sensor line KL of the fire detector SE in order to notify the worker of the fire signal reception. A predetermined ringing (ringing pattern 1) for a certain period is made to the district bell B of the district bell line BL. In addition, for each of the sensor lines KL1 to KLn, the number of fire detectors SE stored in the connection number storage unit 13 and the number of fire detectors SE stored in the report number storage unit 14 are compared. When they match, the predetermined ringing (ringing pattern 2) for a certain period different from the ringing pattern 1 is caused to be made to the local bell B of the corresponding district bell lines BL1 to BLn. Therefore, it is possible to notify the worker that the alarm test work for each sensor line has been completed.

  Further, in the test mode setting state, the microprocessor MPU 10 stores the number of connected fire detectors SE and the number of reported alarms 14 stored in the connection number storage unit 13 for all the sensor lines KL1 to KLn. If the numbers of fire alarms detected by the fire detectors SE match, the predetermined ringing (ringing pattern) for a predetermined period different from the ringing patterns 1 and 2 is applied to the local bell B of the predetermined local bell lines BL1 to BLn. 3). Therefore, it is possible to notify the worker that the alarm test work for all the fire detectors has been completed.

  Further, in the test mode setting state, the microprocessor MPU 10 automatically restores the fire detector SE that has sent the fire signal.

FIG. 2 is a block diagram of the fire detector SE.
The fire detector SE is provided with a microprocessor MPU 30 for controlling the entire fire detector SE. The microprocessor MPU 30 receives the test signal (test mode start signal, test mode end signal) from the fire receiver RE, and receives the test mode start signal or test mode end signal. A non-volatile memory test flag storage unit 32 is provided for storing the test flag on or off. The microprocessor MPU 30 is set to the normal monitoring mode and the mode under test based on the test flag being turned off or on.

  For the microprocessor MPU 30, the sensor circuit 33 for detecting a fire, the light emission control circuit 35 for controlling the light emission of the indicator lamp 34, and the microprocessor MPU 30 are set to the mode under test, and the sensor circuit 33 detects the fire. Then, the test notification flag storage unit 38 of the nonvolatile memory for storing the test notification flag from the initial state OFF to the ON state, the microprocessor MPU 30, the test signal receiving circuit 31, the test flag storage unit 32, the sensor circuit 33, the light emission The control circuit 35, the constant voltage circuit 36 for supplying a constant voltage to the test notification flag storage unit 38, and connected between the C line and the L line of the sensor line KL, and when the sensor circuit 33 detects a fire, A fire signal output circuit 37 is provided in which the L line is short-circuited to a low impedance, and the alarm current as a fire signal flows.

  The microprocessor MPU 30 controls the light emission control circuit 35 differently for each of the normal monitoring mode and the mode under test. In the setting state of the normal monitoring mode, the light emission control circuit 35 is controlled to turn off the indicator lamp 34 in the normal state, and the light emission control circuit 35 is turned on to turn on the indicator lamp 34 when the sensor circuit 33 detects a fire. The indicator lamp 34 is controlled to function as a so-called fire confirmation lamp. Further, in the setting state of the mode under test, the light emission control circuit 35 is controlled so that the indicator lamp 34 is lit in a predetermined lighting state, for example, normally, and the indicator lamp 34 is turned on when the sensor circuit 33 detects a fire. The light emission control circuit 35 is controlled so that a display state different from the predetermined lighting state, for example, continuous lighting (may be turned off) is performed.

  With this configuration, if the operator operates the test switch of the fire receiver at the start of the alarm test operation, the indicator light of the fire detector that is not performing the alarm test will be in the predetermined lighting state, The indicator lamp of the fire detector that has been subjected to the alarm test is in a display state different from the predetermined lighting state. Therefore, the operator can distinguish between fire detectors that have not performed a warning test and fire detectors that have already been subjected to a warning test simply by looking at the display state of the indicator lamp. This makes it easy for the operator to search for a fire detector that has not performed an alarm test.

Next, the operation of this fire alarm facility will be described.
First, in the normal monitoring state, the test switch 11a, the test result confirmation switch 11b, and the test result storage switch 11c of the operation unit 11 of the fire receiver RE are off. Since the test switch 11a is off, the microprocessor MPU10 is set to the normal monitoring mode, and controls the supply voltage switching circuit 16 to connect the fire detector SE through the receiving circuits 17-1 to 17-n. Is supplied with a power supply voltage, for example, 24V.

  In the fire detector SE, the test flag stored in the test flag storage unit 32 is off in the initial state. Therefore, the microprocessor MPU 30 is set to the normal monitoring mode, and the light emission control circuit 35 is controlled and displayed. The lamp 34 is turned off.

  Here, for example, when the sensor circuit 33 of the fire detector SE connected to the sensor line KL1 detects a fire, the microprocessor MPU30 switches the fire output circuit 37 to output a fire signal to the sensor line KL1. At the same time, the light emission control circuit 35 is controlled so that the indicator lamp 34 is continuously lit.

  On the fire receiver RE side, the reception circuit 17-1 receives a fire signal generated by the switching operation of the fire detector SE. Thereby, the microprocessor MPU10 notifies that the fire detector SE connected to the detector line KL1 has detected a fire. That is, the main acoustic device (not shown) is sounded, the district indicator lamp 19-1 corresponding to the sensor line KL1 is blinked, and the predetermined district bell circuit 18 is controlled to connect to the predetermined district bell line BL. Ring the district bell B. For example, the district bell circuits 18-1 and 18-2 are controlled to cause the district bell B connected to the district bell lines BL1 and BL2 to ring and to ring the floor immediately above the fire floor.

  In this state, when a restoration switch (not shown) of the operation unit 11 is turned on, the microprocessor MPU 10 restores the fire detector SE and the fire receiver RE. In other words, the fire detector SE is restored by shutting off the power supply to the alarm line KL1, which has been reported, and the district indicator lamp 19-1 of the alarm line KL1, which has been alarmed, is turned off, and the main acoustic device (Not shown) and the ringing of the district bell B is stopped to restore the fire receiver RE.

  The restoration of the fire detector SE means that the microprocessor MPU 30 releases the switching operation of the fire detection circuit 37 by controlling the power supply to the detector line KL1, and controls the light emission control circuit 35 to display the indicator lamp. 34 is turned off.

  Next, the operation of the fire alarm facility during the alarm test of the fire detector SE will be described.

  At the time of maintenance inspection or the like, an operator who performs an alarm test operation of the fire detector SE first turns on the test switch 11a of the fire receiver RE. Then, the microprocessor MPU 10 enters a test mode setting state, and sends a test mode start signal to the fire detector SE. In other words, the microprocessor MPU 10 controls the supply voltage switching circuit 16 so that a voltage different from the normal 24V, for example, a signal voltage as a test mode start signal of 36V is passed through the receiving circuits 17-1 to 17-n. Then, each fire detector SE is supplied for a predetermined time. In addition, for each of the sensor lines KL1 to KLn, the number of fire detectors SE stored in the connection number storage unit 13 and the number of fire detectors SE stored in the report number storage unit 14 match. Therefore, the district indicator lights 19-1 to 19-n are blinked.

  In each fire sensor SE, the test signal receiving circuit 31 receives the signal voltage (test mode start signal) via the sensor lines KL1 to KLn. Then, the microprocessor MPU 30 stores the test flag in the test flag storage unit 32 from the initial state OFF to the ON state, and since the test flag is ON, the microprocessor MPU 30 is set to the mode under test. Then, the state of the test report flag in the test report flag storage unit 38 is determined. Since the test report flag in the test report flag storage unit 38 is off in the initial state, the light emission control circuit 35 is controlled, The indicator lamp 34 is blinked.

  Next, the worker travels to the place where the fire detector SE is installed, and performs an alarm test operation of the fire detector SE. First, of the fire detectors SE in the sensor lines KL1 to KLn, for example, the alarm test operation of the fire detector SE connected to the sensor line KL1 is performed. At this time, the worker looks at the display state of the indicator lamp 34 of the fire detector SE, and performs the alarm test operation on the fire detector SE that has not performed the alarm test. In other words, the operator makes a report on the fire detector SE whose indicator lamp 34 is blinking by directly applying heat or smoke using a tester (not shown).

  Then, in the fire detector SE, the sensor circuit 33 detects a fire, and the microprocessor MPU 30 first stores the test report flag in the test report flag storage unit 38 from off in the initial state. Then, the fire output circuit 37 is switched to output a fire signal, and since the test mode is set, the indicator lamp 34 is continuously lit.

  In the fire receiver RE, the receiving circuit 17-1 receives the fire signal from the sensor line KL1. Then, since the microprocessor MPU 10 is in the test mode setting state, the number of reports corresponding to the line number 1 of the sensor line KL1 in the report number storage unit 14 is changed from the initial value “0” to “1”. Increment by one and memorize. Further, in order to notify the worker that the fire signal has been received, the district bell B of the district bell line BL1 corresponding to the sensor line KL1 is caused to ring with a predetermined ringing pattern 1 for a certain period.

  Thereafter, the microprocessor MPU10 automatically restores the fire detector SE. That is, the power supply to the alarmed sensor line KL1 is cut off. Then, in the fire detector SE that has issued the test, the switching operation of the fire detection circuit 37 is canceled by the microprocessor MPU 30 by cutting off the power supply to the detector line KL1. However, the display state of the indicator lamp 34 of each fire detector SE connected to the detector line KL1 including the fire detector SE that has made a test report is the state of the test report flag in the test report flag storage unit 38, respectively. Therefore, the fire detector SE that has been informed of the test is in a continuously lit state, and the fire detector SE that has not been informed of the test remains in a blinking state.

  The worker continues to perform the alarm test operation of the fire sensor SE that has not been tested in the sensor line KL1, that is, the fire sensor SE in which the indicator light 34 is flashing, in each fire sensor SE. When the test report is issued and the indicator lamp 34 changes from blinking to continuous lighting, and the fire receiver RE receives a fire signal in the sensor line KL1, the sensor line KL1 in the notification number storage unit 14 is received. The number of notifications corresponding to the line number 1 is incremented by one and stored. Further, the ringing of the district bell B in the ringing pattern 1 and automatic restoration of the fire detector SE are also performed as needed.

  When the alarm test work for all ten fire detectors SE in the sensor line KL1 is completed, the microprocessor MPU10 of the fire receiver RE stores the fire stored in the connection number storage unit 13 in the sensor line KL1. Since the connection number “10” of the sensor SE matches the number of fire alarms SE stored in the alarm number storage unit 14, the corresponding district indicator lamp 19-1 is continuously turned on, for example. Further, the district bell B of the corresponding district bell line BL1 is caused to ring for a certain period of time with a predetermined ringing pattern 2 different from the ringing (ringing pattern 1) indicating the end of the alarm test operation of the individual fire detector.

  The operator can understand that the alarm test work for all the fire detectors SE on the sensor line KL1 has been completed by listening to the sound of the ring pattern 2 of the district bell B on the district bell line BL1. The alarm test operation of the fire sensor SE connected to the subsequent sensor lines KL2 to KLn is performed.

  In this way, when the alarm test work of all the fire detectors SE is completed, the microprocessor MPU10 of the fire receiver RE stores the fires stored in the connection number storage unit 13 in all the detector lines KL1 to KLn. Since the number of connected detectors SE and the number of fire detectors SE stored in the number-of-reports storage unit 14 match, all the district indicator lights 19-1 to 19-n are in a state of being continuously lit, for example. In addition, a ring (ring pattern 1) that indicates the end of the alarm test work of an individual fire detector is sent to the district bell B of a predetermined district bell line BL (for example, all the district bell lines BL1 to BLn), a detector A predetermined ringing pattern 3 that is different from the ringing (ringing pattern 2) that indicates the end of the line-by-line alarm test work is ringed for a certain period.

  The operator confirms that the alarm test work of all the fire detectors SE in all the sensor lines KL1 to KLn is completed by listening to the sound of the sound pattern 3, and then the fire receiver RE. Ask to the side.

  Here, the operator looks at the indications of the district indicator lights 19-1 to 19-n and confirms that the alarm test work for all the fire detectors SE in all the detector lines KL1 to KLn has been completed. I can confirm. For example, even if it is forgotten to confirm the ringing of the district bell B (ringing pattern 3) indicating the end of the reporting test work of all the fire detectors, it is possible to confirm the leakage of the reporting test work. If there is a fire detector SE that is not reporting test, there is a flashing district indicator light 19, so it goes to the alert area of the corresponding sensor line KL and the fire detector SE whose indicator light 34 is flashing. And the alarm test work can be performed, and the alarm test work of all the fire detectors SE can be surely performed.

  Further, when the operator turns on the test result confirmation switch 11b, the microprocessor MPU10 connects the corresponding district indicator lights 19-1 to 19-n in the order of the line numbers 1 to n of the sensor lines KL1 to KLn. The number of fire detectors SE stored in the storage unit 13 is flashed for the number of connections, and the number of fire detectors SE stored in the report number storage unit 14 is flashed.

  For example, the number of connections in line number 1 is 10 and the number of reports is 10, the number of connections in line number 2 is 5 and the number of reports is 5, ..., and the number of connections in line number n is 7 If the number is 7, first, the district indicator light 19-1 of line number 1 blinks 10 times as many as the number of connections, then blinks 10 times as many as the number of alarms after a certain period of time, The area indicator 19-2 for line number 2 flashes five times for the number of connections, then flashes five times for the number of alerts after a certain period, and finally, the area indicator 19-n for line number n Flashes seven times as many as the number of connections and then flashes seven times as many as the number of reports after a certain period.

  The operator can confirm the alarm test result of the fire detector SE for each of the detector lines KL1 to KLn on the fire receiver RE side by looking at this display, and each district indicator light 19-1 to 19-19. Based on the difference between the number of connections and the number of flashes of the number of alarms at -n, the number of fire detectors SE that have not performed the alarm test can be known. As a result, the fire detector SE is again turned to the fire detector SE where the indicator light 34 is flashing and the test leak is detected and reported. Can be performed reliably.

  In this state, when it is desired to record and save the alarm test result of the fire detector SE, the operator turns on the test result saving switch 11c. Then, the microprocessor MPU 10 stores the number of connected fire detectors SE in the connection number storage unit 13 and the notification number storage unit 14 in correspondence with the line numbers 1 to n of the sensor lines KL1 to KLn. The number of fire alarms SE that have been made is stored in the test result storage unit 15.

  An example of data stored in the test result storage unit 15 is shown in FIG. In FIG. 3, the number of connections in line number 1 is 10 and the number of reports is 10, the number of connections in line number 2 is 5 and the number of reports is 5, ..., the number of connections in line number n is 7 This is an example of stored data when the number of reports is 7. In this case, as a typical stored data example, a CSV data format in which individual data such as a sensor line number, the number of connections, the number of reports, etc. are separated by commas.

  The operator needs to create an inspection report for the report test work, but using the stored data in the test result storage unit 15 makes it easy to create an inspection report. Moreover, since the test result storage unit 15 is a removable storage medium, an inspection report can be created anywhere by taking it back to the company, and the stored data is in a CSV data format or the like. Because it is a file format that can be used in general-purpose spreadsheet applications such as Excel, an inspection report can be created without the need for special equipment.

  Finally, the operator turns off the test switch 11a to return the fire alarm facility to the normal monitoring state. Then, the microprocessor MPU 10 cancels the setting of the test mode and enters the setting state of the normal monitoring mode, turns off the district indicator lights 19-1 to 19-n, and sends a test mode end signal to the fire detector SE. In other words, the microprocessor MPU 10 controls the supply voltage switching circuit 16 so that a voltage different from the normal 24V, for example, a signal voltage as a test mode end signal of 36V is passed through the receiving circuits 17-1 to 17-n. Then, it supplies to each fire detector SE for a fixed period.

  In each fire sensor SE, the test signal receiving circuit 31 receives the signal voltage (test mode end signal) via the sensor lines KL1 to KLn. Then, the microprocessor MPU 30 stores the test flag stored in the test flag storage unit 32 with the initial state turned off, and since the test flag is off, the mode under test is canceled and normal monitoring is performed. Set to mode.

  Therefore, the microprocessor MPU 30 stores the test report flag in the test report flag storage unit 38 with the initial state turned off, and controls the light emission control circuit 35 to turn off the indicator lamp 34. In this way, the fire alarm facility returns to the normal monitoring state.

  The microprocessor MPU10 of the fire receiver RE sets the corresponding district indicator lights 19-1 to 19-n in the order of the line numbers 1 to n of the sensor lines KL1 to KLn based on the operation of the test result confirmation switch 11b. The number of fire detectors SE stored in the number-of-reports storage unit 14 may be flashed only for the number of reports. In other words, if the number of fire detectors SE connected to each of the detector lines KL1 to KLn is known in the drawings, the operator can confirm the alarm test results for each detector line on the fire receiver RE side. In addition, it is possible to confirm how many fire detectors are missing the alarm test for each sensor line.

  Second Embodiment The first embodiment is a so-called P-type system including a fire detector SE that outputs a fire signal by a switching operation and a fire receiver RE that receives the fire signal in units of sensor lines. Although it was a fire alarm system, this second embodiment is a so-called R-type system fire alarm system, and although not shown, signal transmission by a polling operation is performed between the fire receiver RE2 and the individual fire detector SE2. Can be done.

  The difference between the fire detector SE2 of the second embodiment and the fire detector SE of the first embodiment includes a test signal and a fire signal instead of the test signal receiving circuit 31 and the fire signal output circuit 37. This is that a transmission / reception circuit capable of transmitting and receiving various signals is provided, a self-address storage unit is provided, and the test flag storage unit 32 and the test report flag storage unit 38 are omitted.

Further, the difference between the fire receiver RE2 of the second embodiment and the fire receiver RE of the first embodiment is that various types of test signals and fire signals are included instead of the receiver circuits 17-1 to 17-n. Corresponding to the line number of the sensor line in the connection number storage unit 13 that the transmission / reception circuit capable of transmitting and receiving signals is provided, the supply voltage switching circuit 16 is omitted and the test signal is transmitted by signal transmission. The address of the connected fire detector SE2 is also stored, and the address of the fire detector SE2 that has issued the test is also stored in the notification number storage unit 14 in correspondence with the line number of the sensor line. This is what I did.
The fire receiver RE2 includes a test switch 11a for setting the normal monitoring mode or the test mode, and mode storage means (RAM) for storing the setting state of the normal monitoring mode or the test mode based on the operation of the test switch 11a. , A notification address storage means (report number storage section 14) for storing the address of the fire detector that sent the fire signal in the test mode setting state, a mode storage means (RAM) and a notification address storage means Means (microprocessor MPU10 and transmission / reception circuit) for sending a predetermined light emission control command to each fire detector SE2 based on the stored contents of the (reporting number storage section 14), and the fire detector SE2 Is provided with control means (microprocessor MPU30) for controlling the lighting state of the indicator lamp 34 based on a predetermined light emission control command. And has a configuration was.

  As the predetermined control command, when the normal monitoring mode is set, the fire command SE2 that has not been issued is a turn-off command, and the fire command SE2 that has been reported is a turn-on command. When the test mode is set, the flash command is issued for the fire detector SE2 that is not informing, and the lighting command is issued for the fire detector SE2 that is informing, That is, since the control command is such that the display state of the indicator lamp 34 is the same as that of the first embodiment, the same effect as the first embodiment can be obtained.

  Further, even if the storage units 32 and 38 are not provided on the fire detector SE2 side, the fire detector SE2 side determines whether the normal monitoring mode is set, the test mode is set, and whether there is a fire detection in these mode states. The display state of the based indicator lamp can be changed.

  In addition, the address of each fire detector SE2 can be displayed on the display unit 12, for example, a display display is provided, and the fire receiver RE2 is configured to perform an unreported test on the display display in the test mode setting state. If the display of the address of the fire detector SE2 that has undergone the alarm test is made different by blinking, continuous lighting, etc., it can be determined whether the alarm test has been performed for each individual fire detector SE2.

  In all the above embodiments, the district indicator lamp and the display are shown as the display unit 12 for displaying the notification test result. However, the display unit 12 is provided with other display units such as a 7-segment display unit to perform the above-described all implementations. The microprocessor MPU 10 may control the same effect as the example. Further, the microprocessor MPU 10 may control the display unit such as the district display lamp, the display unit, and the 7-segment display unit as appropriate so as to obtain the same effect as in the above-described all embodiments.

  In all the above embodiments, the fire receiver is provided with a test function. However, the fire receiver is not provided with a test function, and a dedicated test machine having the same test function is connected to the fire receiver. May be.

  In all the embodiments, the alarm test results based on the stored contents of the connection number storage unit and the alarm number storage unit are stored in the test result storage unit based on the operation of the test result storage switch in the test mode setting state. The test result storage switch may be omitted so that the test mode setting state is automatically stored when the setting is canceled.

  The present invention relates to a fire alarm facility in which a plurality of fire detectors are connected to a detector line from a fire receiver, and the fire receiver receives a fire signal from the fire detector. A switch and means for sending a test mode start signal to the fire detector based on the operation of the test switch, and the fire detector is set to a mode under test when receiving the test mode start signal, Control means for controlling the display lamp to a predetermined lighting state and controlling the display lamp to a display state different from the predetermined lighting state when a fire is detected in the setting state of the mode under test. According to this, if the operator operates the test switch at the start of the alarm test work, the indicator light of the fire detector that is not performing the alarm test will be in the predetermined lighting state, The indicator light of the sensor is in a display state different from the predetermined lighting state. Therefore, the operator can distinguish between fire detectors that have not performed a warning test and fire detectors that have already been subjected to a warning test simply by looking at the display state of the indicator lamp. This makes it easy for an operator to search for a fire detector that has not performed an alarm test.

  The control means causes the indicator lamp to function as a fire confirmation lamp in the normal monitoring mode setting state. According to this, the indicator lamp can also be used as a fire confirmation lamp.

  Further, the present invention provides a fire alarm system in which a plurality of fire detectors are connected to a detector line from a fire receiver, the fire receiver transmits a signal by polling, and receives a fire signal from the fire detector. The fire receiver includes a test switch for setting a normal monitoring mode or a test mode, mode storage means for storing a setting state of the normal monitoring mode or the test mode based on an operation of the test switch, and setting of the test mode. In the state, the alarm address storage means for storing the address of the fire detector that sent the fire signal, and for each fire detector based on the storage contents of the mode storage means and the alarm address storage means, Means for sending a predetermined light emission control command, and the fire detector controls a display state of the indicator lamp based on the predetermined light emission control command. Comprising a control means for. According to this, based on the predetermined light emission control command from a fire receiver, each display state of the indicator lamp of each fire detector can be changed. Since the predetermined light emission control command is based on the stored contents of the mode storage means and the notification address storage means, if the operator operates the test switch at the start of the alarm test operation, the fire detector that is not performing the alarm test The indicator lamp of the fire detector which has been subjected to the alarm test is in a display state different from the predetermined lighting state. Therefore, the operator can distinguish between fire detectors that have not performed a warning test and fire detectors that have already been subjected to a warning test simply by looking at the display state of the indicator lamp. This makes it easy for an operator to search for a fire detector that has not performed an alarm test. Also, the indicator light can be used as a fire confirmation light.

  The present invention further includes a sensor line to which a plurality of fire detectors are connected, and a fire receiver to which a plurality of the sensor lines are connected, and the fire receiver receives a fire signal from the fire sensor. In the fire alarm facility for receiving, the fire receiver stores a test switch, a control means set in a test mode based on the operation of the test switch, and the number of connected fire detectors connected to each detector line. A number-of-connections storage unit that performs the above-described test mode setting state, and a number-of-reports storage unit that stores the number of fire detectors that have transmitted a fire signal for each sensor line. According to this, since the number-of-reports storage unit is provided, it is possible to store the number of reports of the fire detector that has sent out a fire signal for each sensor line.

  In addition, the control means, in the test mode setting state, for each sensor line, the number of fire detector connections stored in the connection number storage unit and the number of fire detector notifications stored in the notification number storage unit Are compared, the district bell corresponding to the matched sensor line is caused to make a predetermined ringing. According to this, it is possible to notify the worker that the alarm test work has been completed for each sensor line. Therefore, the worker can smoothly move between floors when a sensor line is provided in units of floors.

  In addition, the control means sets the number of fire detectors stored in the connection number storage unit and the number of fire detectors stored in the notification number storage unit for all detector lines in the test mode setting state. When the numbers are compared and matched, a predetermined district bell is caused to ring different from the predetermined ringing. According to this, it is possible to notify the worker that the alarm test work for all the fire detectors has been completed.

  In addition, the fire receiver displays whether or not there is a fire detector that has missed the alarm test for each sensor line based on the stored contents of the connection number storage unit and the alarm number storage unit as the alarm test result. A display unit was provided. The display unit is a district indicator lamp provided for each sensor line. In addition, the control means, as an alarm test result, for each sensor line, the number of fire detector connections stored in the connection number storage unit and the number of fire detector notifications stored in the alarm number storage unit. The display states of the district indicator lamps corresponding to the sensor lines are different depending on whether they match or not. According to these, on the fire receiver side, the operator can check the alarm test result for each sensor line, and also check if there is a fire detector for the alarm test leak for each sensor line. it can.

  In addition, as a result of the alarm test, the control means causes the corresponding district indicator lamps to flash for the number of connected fire detectors stored in the connection number storage unit in the order of the line numbers of the sensor lines. Flashes only for the number of fire detectors that are stored in the number memory. According to this, on the fire receiver side, the operator can confirm the alarm test result for each sensor line, and also how many fire detectors have the alarm test leak for each sensor line. I can confirm.

  The fire receiver includes a test result storage switch and a test result storage unit, and the control means corresponds to the line number of each sensor line based on the operation of the test result storage switch. The number of fire detector connections stored in the storage unit and the number of fire detector reports stored in the report number storage unit are stored in the test result storage unit. According to this, the operator can easily create an inspection report in the alarm test work using the data stored in the test result storage unit.

1 is a system configuration diagram of a fire alarm facility showing a first embodiment of the present invention. FIG. FIG. 2 is a block diagram of the fire detector SE. It is a figure which shows the example of the data memorize | stored in a test result memory | storage part.

Explanation of symbols

RE ... Fire receiver SE ... Fire detector B ... District bell KL1-KLn ... Sensor line BL1-BLn ... District bell line 10 ... Microprocessor MPU
11a ... Test switch 11b ... Test result confirmation switch 11c ... Test result storage switch 12 ... Display unit 13 ... Connection number storage unit 14 ... Reported number storage unit 15 ... Test result storage unit 19-1 to 19-n ... District indicator lamp 30 ... Microprocessor MPU
31 ... Test signal receiving circuit 34 ... Indicator light 37 ... Fire signal output circuit

Claims (1)

A detector line connected to a plurality of fire detectors; and a fire receiver connected to a plurality of the detector lines, wherein the fire receiver receives a fire signal based on a switching operation from the fire detectors. In fire alarm equipment to
The fire receiver is set to a test mode based on a test switch, an operation of the test switch, a control means for sending a test mode start signal to the fire detector, and a fire connected to each detector line. A connection number storage unit for storing the number of connections of the sensor, a notification number storage unit for storing the number of notifications of the fire detector that has sent out a fire signal for each sensor line in the test mode setting state, and a test A result storage switch and a test result storage unit, and the control means stores the connection number storage unit in correspondence with the line number of each sensor line based on the operation of the test result storage switch. The number of fire detectors connected and the number of fire detector alarms stored in the alarm number memory unit are stored in the test result memory unit,
Upon receiving the test flag storage unit of the nonvolatile memory, the test report flag storage unit of the nonvolatile memory, and the test mode start signal, the fire detector turns off the test flag of the test flag storage unit in the initial state. If the fire is detected in the setting state of the test mode, the test report flag in the test report flag storage unit is turned on from the initial state to off. And a control unit for storing
The control unit determines the state of the test report flag in the test report flag storage unit in the setting state of the test mode, and if the test report flag is off, the control lamp is turned on in a predetermined lighting state. If the test report flag is on, the indicator lamp is controlled to a display state different from the predetermined lighting state .

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