JP4077817B2 - Guidance display system - Google Patents

Description

  The present invention relates to a guide light system that performs evacuation guidance by displaying an abnormality detection direction and an evacuation direction during a disaster such as a fire.

  In a conventional guidance display system, the central controller receives a signal from the sensor to indicate the direction of evacuation with a guide light, and the central controller automatically sends a control signal or power to the guide light based on human judgment. The evacuation direction was displayed.

  However, in the conventional guidance display system, the entire system is not suitable for a single trouble such as absence of a manager for a short time, failure of the central controller due to a fire, or disconnection of a power line or signal line. It wasn't working properly. Further, since the wiring becomes complicated, there is a possibility that it takes time for recovery and maintenance. Also, it was not easy to install. An object of the present invention is to solve the above drawbacks with a simple mechanism.

Guidance display system according to claim 1 is a abnormality detecting means for Ru capture the disconnection or short circuit of wiring including a sensing and fire sensor of a fire by the fire sensor as a change in the input voltage at the comparator, from wiring including the fire sensor to comparator At least a pair of abnormal transmission / cutoff means provided between them for performing abnormal transmission and interruption by switching a relay, and when the abnormality is detected by one abnormality detection means, the other abnormal transmission / cutoff means is cut off. by, characterized by displaying the abnormality detection direction or escape direction guide lights, and the need for central control unit.

The guidance display system according to claim 2 further includes an abnormality detection unit and an abnormality transmission / interruption unit, and displays a plurality of evacuation directions together with information necessary for selecting an evacuation direction .

According to a third aspect of the present invention, the guidance display system comprises a power supply circuit and a spare power supply circuit independently for each unit as power to be supplied to the guide lamp .

The guidance display system according to claim 4 can be made power-saving, long-life, and thin by expressing a large number of LEDs by lighting and blinking so as to indicate the abnormality detection direction and the evacuation direction.

The guidance display system according to claim 5 can evacuate without hesitation even when the guidance display or the emergency exit is not visible by indicating the abnormality detection direction or the evacuation direction by voice or sound.

The guidance display system of the present invention does not require human management or a central control device. Since each is an independent guide light , there is no limit to the number of units installed, making it easy to install and responding to wiring and power outages. The circuit is simple, expandable, power-saving and inexpensive. In addition, the guide light has an effect that it is possible to evacuate more safely by providing information that can cope with unforeseen circumstances such as automatically displaying the direction of the fire source and displaying a plurality of evacuation directions.

  FIG. 1 is a circuit diagram showing an embodiment of the present invention. FIG. 2 is a block diagram of the circuit of FIG. FIG. 3 is a diagram for explaining the operation of the circuit of FIG. As shown in FIG. 2, the structure of the guide light of the present invention includes a switching unit 18a, 18b and a comparison unit 19a. 19b, the control part 15, and the display part 16, and is symmetrical with respect to the control part 15 and the display part 16.

  The circuit of FIG. 1 will be described. The guide lamp 20a is connected from the power source to the resistor 8a, the diode 6a that prevents backflow to the power source, and the break contact of the relay 4a to the common terminal. This is connected to the fire sensor 1a connected in parallel with the sensor unit 17a and the resistor 2a, and is connected from the relay contact of the relay 5a to the common terminal, resistor 9a, and ground. The node between the common terminal of the relay 5a and the resistor 9a is connected to the + input (non-inverting input) of the comparator 13a and the-input (inverting input) of the comparator 14a. The reference voltages V13m and V14p for comparison are connected to the resistors 10, 11, 12 and the ground from the power source, and are generated by dividing the voltages. The junction of resistors 10 and 11 is connected to the-input of comparator 13a, and the junction of resistors 11 and 12 is connected to the + input of comparator 14a. Outputs of the comparators 13a and 14a are connected to the control unit 15, and the control unit 15 performs display control of the display unit 16 and drive control of the relays 4b and 5b of the switching unit 18b. A resistor 7a having the same resistance value as that of the resistor 2a is connected to the make contact of the relay 5a from the coupling point of the cathode of the diode 6a and the break contact of the relay 4a. The make contact of the relay 4a and the break contact of 5a are connected.

The operation of the circuit of FIG. 1 will be described. Normally, the input voltages V13p and V14m of the comparators 13a and 14a are determined by the voltage drop of about 0.6V of the backflow prevention diode 6a and the voltage division by the resistors 8a, 2a and 9a. The resistance value of the fire sensor 1 connected in parallel to the resistor 2a is normally infinite (a state close to infinity). Comparator 13a, 14a in the input voltage V13p, V14m a reference voltage V13m, by comparing the V 14p, the output signal V13o, outputs the V14o.

  In the normal state of FIG. 3, since the input voltages of the comparators 13a and 14a are V13m> V13p and V14m> V14p, the output voltages V13o and V14o are both 'L'.

  3, when the wiring connecting the sensor unit 17a and the switching unit 18a is disconnected due to a flame or the like, the voltage applied to the resistor 2a does not reach the comparator 14a, and therefore the input voltage V14m of the comparator 14a is 0 volt. Therefore, V14m <V14p, and the output voltage V14o becomes “H”. And the relay in the control part 15 act | operates, the switch parts 4b and 5b of the relay of the switching part 18b switch, and the right sensor part 17b is interrupted | blocked. The right comparison unit 19b is maintained at the same input voltage as usual by the resistor 7b having the same resistance value as the resistor 2b of the sensor unit 17b. Further, both ends of the right sensor unit 17b are short-circuited.

  In FIG. 3, when the fire sensor 1a detects a fire and both ends are in a short-circuited state (close to a short-circuit state), the input voltage V13p increases to V13m <V13p, and the output voltage V13o of the comparator 13a is also “H”. Become. And the relay in the control part 15 act | operates, the switch part of the relay of the switching part 18b switches, it cuts off from the right sensor part 17b, and the resistance 7b of the same resistance value as the resistance 2b in the switching part 18b The right comparison unit 19b is kept at the same input voltage as usual.

  FIG. 4 is a perspective view showing an example of a display panel applied to the guide light according to the present invention. The abnormality detection direction is displayed by lighting or blinking either the left or right ‘×’ display, and the evacuation direction is displayed by lighting either ‘←’ or ‘→’.

  FIG. 5 is a connection block diagram when a plurality of guide lights and fire sensors are connected. FIG. 6 is a display pattern diagram upon connection of FIG. In FIG. The display panel is normally turned off, but the arrow in the direction of the nearest escape door can be selected and turned on.

  5 in FIG. When the wiring 26a is disconnected, the -input V14m of the comparator 14a in FIG. 1 becomes 0 volt, so that the output V14o becomes 'H'. Then, the control unit 15 gives an instruction to turn on the left ‘×’ display 21 and the ‘→’ display 24 in FIG. 4 and switches the relay of the right switching unit 18b. Then, the comparison unit 19b is maintained at a normal voltage by the resistor 7b of the switching unit 18b, and both ends of the sensor unit 17b are short-circuited. For this reason, the guide lamp 20b has the same input voltage V13p as “H”, which is the same as the fire alarm. The control unit 15 of the guide light 20b instructs the left “×” display 21 to blink and the right “→” display 24 to light up, and switches the relay of the right switching unit 17b. Thereby, the guide light 20c performs the same operation.

  5 in FIG. A case where the wiring 27a is disconnected will be described. As shown in FIG. 2, the structure of the guide light is symmetrical with respect to the control unit 15 and the display unit 16. For this reason, the guide light 20a performs the same operation in the opposite direction as when the wiring 26a is disconnected. As a result, the “←” display 22 and the right “×” display 25 are lit on the guide light 20a. Since the guide light 20b is in a state without the sensor unit 17a and the guide light 20a, that is, in the same state as the sensor unit 17a and the guide light 20a in the normal state, all of the guide light 20b remains in the normal display state. Since the guide light 20c does not sense any abnormality, it is all turned off.

  In FIG. When the wiring 26b is disconnected, the guide lights 20b and 20c are in the same state as the guide lights 20a and 20b when the wiring 26a is disconnected. Since the guide light 20a is in the same state as the absence of the guide light 20b, it remains in a normal state. In FIG. When the wiring 27b is disconnected, the guide lights 20b and 20c are in the same state as the guide lights 20a and 20b when the wiring 27a is disconnected, and the '←' display 22 lights up in conjunction with the guide light 20b. The right “×” display 25 flashes. 5 in FIG. When the wiring 26c is disconnected, the guide lamp 20c is in the same state as the guide lamp 20b when the wiring 26b is disconnected, and the guide lamps 20a and 20b are in the same state as usual. 5 in FIG. When the wiring 27c is disconnected, the guide lights 20b and 20c are in the same state as the guide lights 20a and 20b when the wiring 27b is disconnected. The guide lamp 20a operates in the same manner as the guide lamp 20b in conjunction with the guide lamp 20b.

  5 in FIG. When the fire sensor 1a of the sensor unit 17a reacts at the time of fire, the input voltage V13p becomes larger than the fire reference voltage V13m and the output voltage V13o becomes 'H' in the guide light 20a. As a result, the control unit 15 blinks the left ‘×’ display 21, issues an instruction to light the ‘→’ display 24, and switches the right relays 4 b and 5 b. When the common terminal and make contact of the relay 4b are closed, the fire sensor 1b is short-circuited in the same manner as when a fire is detected, and the input voltage of the guide light 20b becomes V13p> V13m, and the same operation as the guide light 20a is performed. In addition, the guide light 20c performs the same operation in conjunction with it. In FIG. When the sensor unit 17b senses a fire, the guide lights 20b and 20c perform the same operation as 20a and 20b when the sensor unit 17a senses a fire. The guide light 20a performs the same operation in the reverse direction, and the “←” display 22 lights up, and the right “×” display 25 flashes. 5 in FIG. When the sensor unit 17c detects a fire, the guide lights 20b and 20c perform the same operation as the guide lights 20a and 20b when the sensor unit 17b detects a fire. The guide lamp 20a operates in the same manner as the guide lamp 20b in conjunction with the guide lamp 20b.

  When wiring trouble or equipment breaks down, the sensor is skipped and the guide lights are connected with a connector with a wire connected in the same way as the resistor 2a between the two wires, or the sensor is connected with a connector with a wire by skipping the guide light If you take emergency measures, you can easily restore the system and prevent troubles from spreading to the entire system.

  FIG. 7 is a block diagram for power supply. Normally, a relay in the power supply switching circuit 30 operates, and a current obtained by converting an alternating current from the commercial power supply 28 into a direct current for a guide lamp by the power supply circuit 29 is supplied to the DC power supply line 32. At this time, the standby power supply 31 is disconnected from the DC power supply line 32. However, when the standby power supply 31 uses a secondary battery, it is charged by electricity supplied from the power supply circuit 29. When electricity is not supplied from the commercial power supply 28, the relay in the power supply switching circuit 30 does not operate, and the DC power supply line 32 is disconnected from the power supply circuit 29 and connected to the standby power supply 31. As a result, even if the commercial power supply 28 is cut off or disconnected, the function of this guide light is continued.

  In order to save power in preparation for a long-time power outage, an LED display is used. FIG. 8 shows an arrangement example of the LED of the guide light at this time. This is the same display as in FIG. 4 and corresponds to the left side “×” displays 21 and 33, the “←” displays 22 and 34, the “→” displays 24 and 36, and the right “×” displays 25 and 37, respectively. . Further, by using an electronic switch such as a CMOS analog switch instead of the relay as the switching unit, it is possible to further save power. Thereby, it becomes long life and thin.

  By the way, in apartments and the like, the source of fire is often indoors, and functions are rarely exhibited in corridors where guide lights are installed. There may be a plurality of evacuation directions depending on the installation location, and it may be necessary to select the direction of evacuation at the site according to the situation of the evacuation exit. In such a case, not only the left and right but also a guide panel guide light showing a number of directions as shown in FIG. 9 is effective. FIG. 10 is a block diagram of the circuit of this guide light. The '×' displays 21, 25, 38 and the sensor units 17a, 17b, 17c correspond to each other, and the display direction is the same as the direction in which the sensor is located or the evacuation direction. Further, as information necessary for selecting the evacuation direction, display of distances 40a and 40b to the evacuation exits, display of names 40c and 40d, and the like are displayed.

  In FIG. 10, the circuits 17c, 18c, and 19c may be the same as those of 17a, 18a, and 19a, but the lighting / flashing pattern of the display unit 16 is set by the control unit 15 at the time of installation. Further, when another guide light is not connected to 17c as shown in FIG. 10 or when no abnormality is transmitted to the adjacent guide light, the control of the relay in the control unit 15 is changed.

  FIG. 11 shows an example of the panel display of the indicator lamp installed on the emergency staircase. The display panel is the left side “×” display 21 and “upper floor” display 41, the center “×” display 38 and “this floor” display 42, the right side “×” display 25 and “lower floor” in FIG. This corresponds to the display 43.

  FIG. 12 is a circuit diagram of a system in which individual guide lights are electrically cut off. The details of the comparison unit 19b are omitted because they are the same as those in FIG. FIG. 13 is a connection block diagram when a plurality of sensor units and guide lights of this system are connected. When the connector 47a of the guide light 20e and the connector 48b of the adjacent guide light 20d are connected, and the connector 48a of the guide light 20e and the connector 47b of the adjacent guide light 20d are connected, the relay 46b of the guide light 20d and the relay of the guide light 20e 46a is electrically interrupted. This utilizes the fact that the relay drive section in the control section 15 and the switch section of the output section 49a are electrically disconnected.

  The power source of the guide light 20e is connected to the resistor 8a, the relay 46b and the resistor 45b connected in parallel in the output portion 49b of the adjacent guide light 20d, the resistor 9a of the guide light 20e, and the ground. The opposite side of the ground of the resistor 9a is connected to the + input V13p of the comparator 13a and the -input 14m of the comparator 14a. The comparison unit 19a is the same as that in the first embodiment. In this embodiment, the sensor unit is connected to an independent switching unit 18e and comparison unit 19e separately from transmitting a signal to the adjacent guide light. Since no other guide light is connected to the sensor unit 17e, the switching unit 18c does not require the relay 4a in FIG. The outputs of the comparators 13e and 14e are connected to the control unit 15, and display control of the display unit 16 and drive control of the relays 46a and 46b of the output units 49a and 49b are performed. A resistor 7e having the same resistance value as that of the resistor 2e is connected from the cathode of the diode 6e to the make contact of the relay 5e.

  The operation will be described. However, the operation of the display unit 16 is omitted. Under normal conditions, the input voltage is V13m> V13p, V14m <V14p, due to the divided voltage of the resistor 8a of the comparison unit 19a of the guide lamp 20e, the resistor 45b of the output unit 49b of the adjacent guide lamp 20d, and the resistor 9a of the comparison unit 19a. Therefore, the comparator outputs V13o and V14o are 'L'.

  When the connection between the connector 47a of the guide light 20e and the connector 48b of the adjacent guide light 20d is broken, the input voltage V14m of the comparison unit 19a of the guide light 20e becomes 0 volt and V14p> V14m. The comparator output V14o becomes ‘H’ and the control unit 15 controls the disconnection issue, drives the relay 46b of the output unit 49b, and transmits the abnormality to the adjacent guide light 20f. Further, the relay 5e of the switching unit 18e is driven so that no signal is input from the sensor unit 17e, and the comparison unit 19e is set to the same input voltage as usual by the resistor 7e having the same resistance value as the resistor 2e.

  When the adjacent guide light 20d issues a report, the relay 46b of the adjacent guide light 20d is driven. Then, the switch part of the relay 46b is closed, the input of the comparator 13a of the comparison part 19a of the guide light 20e becomes V13m <V13p, and the output becomes 'H'. The control unit 15 controls the fire alarm, drives the relay 46b of the output unit 49b, and transmits the abnormality to the guide light 20f on the opposite side. Further, the relay 5e of the switching unit 18e is driven so that no signal is input from the sensor unit 17e, and the comparison unit 19e is set to the same input voltage as usual by the resistor 7e having the same resistance value as the resistor 2e.

  When the sensor unit 17e senses a fire or the wiring is disconnected, an abnormal signal passes through the break contact of the relay 5e and is input to the comparators 13e and 14e and output. The relay in the control unit 15 is driven, and the relays 46a and 46b of the output units 49a and 49b are driven to transmit the abnormality to the adjacent guide lights 20d and 20f.

  14 removes the resistors 2a and 2b that divide the input voltages of the sensor units 17a and 17b in FIG. 1, and instead of the resistance values of the resistors 2a and 2b in the guide light 20a in parallel with the fire sensors 1a and 2b. It is the circuit diagram which attached resistance 50a, 50b.

  The circuit of FIG. 14 will be described. The power source of the guide light 20a is connected to the terminating resistor 50z having the same resistance value as that of 50a. The other parts are the same as in FIG. When only one guide lamp is connected as in the sensor unit 17a, it is necessary to connect a terminating resistor instead of the resistor in the guide lamp.

  The operation of the circuit of FIG. 14 will be described. Normally, the resistance value of the fire sensor 1 is infinite, and the resistance values at both ends of the resistors 50a and 50z are resistances 50a and 50z that are twice the resistance value of the resistor 1a in FIG. This is the same as the resistor 1a in FIG. Therefore, the input voltage of the comparator 19a is the same as that of FIG. 1, and the input voltages of the comparators 13a and 14a are V13m> V13p and V14m> V14p, so the output voltages V13o and V14o are both 'L'.

  At the time of disconnection in FIG. 14, when the wiring connecting the termination resistor 50z and the connector 3a of the guide light 20a is disconnected, no current flows through the termination resistor 50z, and the resistance values at both ends of the resistor 50a are doubled. For this reason, the input voltage V14m of the comparator 14a decreases, V14m <V14p, and the output voltage V14o becomes 'H'. And the relay in the control part 15 act | operates, the switch parts 4b and 5b of the relay of the switching part 18b switch, and the right sensor part 17b is interrupted | blocked. The right comparison unit 19b is maintained at the same input voltage as usual by the resistor 7b having the same resistance value as the resistor 2b of the sensor unit 17b. Further, both ends of the right sensor unit 17b are short-circuited.

  In the event of a fire, when the fire sensor 1a detects a fire and is in a short circuit state, V13m <V13p as in FIG. 1, and the output voltage V13o of the comparator 13a also becomes 'H'. And the relay in the control part 15 act | operates, the switch part of the relay of the switching part 18b switches, it cuts off from the right sensor part 17b, and the resistance 7b of the same resistance value as the resistance 2b in the switching part 18b The right comparison unit 19b is kept at the same input voltage as usual.

  FIG. 15 is a display pattern diagram upon connection of FIG. FIG. Under normal conditions, the display panel is off. In FIG. When the wiring 26a is disconnected, the -input V14m of the comparator 14a in FIG. 14 becomes lower than V14p, so that the output V14o becomes 'H'. Then, the control unit 15 gives an instruction to turn on the left ‘×’ display 21 and the ‘→’ display 24 in FIG. 4 and switches the relay of the right switching unit 18b. Then, the comparison unit 19b is maintained at a normal voltage by the resistor 7b of the switching unit 18b, and both ends of the sensor unit 17b are short-circuited. For this reason, the guide lamp 20b has the same input voltage V13p as “H”, which is the same as the fire alarm. The control unit 15 of the guide light 20b instructs the left “×” display 21 to blink and the right “→” display 24 to light up, and switches the relay of the right switching unit 17b. Thereby, the guide light 20c performs the same operation.

In FIG. 3. When the wiring 27a is disconnected; A case where the wiring 26b is disconnected will be described. In the circuit of FIG. 14, unlike FIG. 1, the same result is obtained regardless of where the disconnection occurs between the guide lights. As shown in FIG. 2, the structure of the guide light is symmetrical with respect to the control unit 15 and the display unit 16. For this reason, the guide light 20a performs the same operation in the opposite direction as when the wiring 26a is disconnected. Accordingly, the indication of the guide light 20a is turned on by the “←” display 22 and the right “×” display 25. The guide light 20b operates in the same manner as when the wiring 26a is disconnected, and the display is lit with the “←” display 22 and the right “×” display 25. The guide light 20c is interlocked with the guide light 20b, and the display “→” display 24 lights up and the left “×” display 21 flashes.

  In FIG. 4. When the wiring 26b is disconnected The case where the wiring 27b is disconnected will be described. The guide lights 20b and 20c are in the same state as the guide lights 20a and 20b when the wiring 26a is disconnected. In the guide light 20a, the “←” display 22 is lit in conjunction with the guide light 20b, and the right “×” display 25 flashes.

  5 in FIG. When the wiring 27c is disconnected, the guide lights 20b and 20c are in the same state as the guide lights 20a and 20b when the wiring 27b is disconnected. The guide lamp 20a operates in the same manner as the guide lamp 20b in conjunction with the guide lamp 20b.

  5 in FIG. When the fire sensor 1a of the sensor unit 17a reacts at the time of fire, the input voltage V13p becomes larger than the fire reference voltage V13m and the output voltage V13o becomes 'H' in the guide light 20a. As a result, the control unit 15 blinks the left ‘×’ display 21, issues an instruction to light the ‘→’ display 24, and switches the right relays 4 b and 5 b. When the common terminal and make contact of the relay 4b are closed, the fire sensor 1b is short-circuited in the same manner as when a fire is detected, and the input voltage of the guide light 20b becomes V13p> V13m, and the same operation as the guide light 20a is performed. In addition, the guide light 20c performs the same operation in conjunction with it. In FIG. When the sensor unit 17b senses a fire, the guide lights 20b and 20c perform the same operation as 20a and 20b when the sensor unit 17a senses a fire. The guide light 20a performs the same operation in the reverse direction, and the “←” display 22 lights up, and the right “×” display 25 flashes. 5 in FIG. When the sensor unit 17c detects a fire, the guide lights 20b and 20c perform the same operation as the guide lights 20a and 20b when the sensor unit 17b detects a fire. The guide lamp 20a operates in the same manner as the guide lamp 20b in conjunction with the guide lamp 20b.

  Since the sensor unit, switching unit, and output unit are simple, it is easy to interface with other devices. For example, the sensor unit is replaced with a commercially available fire alarm with a transfer contact. Connecting an alarm sound generator can be a fire alarm. Further, the sensor can be a resistance type element such as a CTR thermistor or a switch type element such as a thermostat, and can be used as another alarm device such as an emergency alarm device when an emergency push button is used. In addition, by using an interface circuit having a function of short-circuiting by an output from another device, information other than a fire can be obtained and transmitted.

  As a method of guiding to an evacuation site, there is guidance not only by display but also by voice or warning sound in order to cope with a case of poor visibility due to smoke or a visually impaired person. “Please evacuate to the right” and “Evacuate to the left”. A rule is determined for the alarm sound, and the length, number of times, tone, etc. of the alarm sound are changed, such as “Peep” when the evacuation direction is right and “Popp” when it is left. This can be realized by the control unit 15 instructing a circuit that emits a voice or sound indicating the left / right evacuation direction in the same manner as the control unit 15 instructs the display unit 16 to display left / right.

  So far, the guidance display system for evacuation guide lights has been described. The following describes a guidance display system having a guidance display device in which an arrow indicating a direction in which an abnormality is detected is turned on and blinked by changing display control. For example, when a device generates abnormal heat, it is necessary to immediately stop the device at that location and take measures such as repair. In a device that cannot be seen at a glance, a thermal sensor such as a thermistor attached is short-circuited, and the guidance display device blinks an arrow in the direction in which the sensor is located. And it is transmitted to the next guidance display device and the arrow blinks. The guidance display devices connected in this way are linked one after another. By following the arrow on this guidance display device, you can easily find the abnormal part. When a plurality of locations are abnormal in conjunction with each other, the arrow indicates the location where the abnormality has first occurred. Further, in the conventional indoor signal device for the hearing impaired and the rotating ring light system, it may not be known where the sensor is working and where the sound is being produced. However, in the guidance display system in which a sensor or a sound sensor is connected to the sensor position of the sensor unit, the source of the sensor or sound that has worked can be easily identified by following the arrows of the device.

It is a circuit diagram which shows Example 1 of this invention. It is a block diagram which shows Example 1 of this invention. It is operation | movement explanatory drawing of the circuit of FIG. 1 which shows Example 1 of this invention. It is a perspective view of the display panel of the guide light which shows Example 1 of this invention. It is a connection block diagram of a guide light showing Example 1 of the present invention. It is a display pattern figure at the time of FIG. 5 which shows Example 1 of this invention. It is a block diagram about the power supply which shows Example 2 of this invention. It is a layout view of the LED of the guide light showing Example 3 of the present invention. It is a perspective view of the display panel of the guide light which shows Example 4 of this invention. It is a block diagram which shows Example 4 of this invention. It is a perspective view of the display panel of the guide light which shows Example 5 of this invention. It is a circuit diagram which shows Example 6 of this invention. It is a connection block diagram which shows Example 6 of this invention. It is a circuit diagram which shows Example 7 of this invention. It is operation | movement explanatory drawing of the circuit of FIG. 14 which shows Example 7 of this invention.

Explanation of symbols

1a, 1b, 1e ... Fire sensor (thermostat)
2a, 2b, 2e, 7a, 7b, 7e, 8a, 8b, 8e, 9a, 9b, 9e, 10, 11, 12, 45a, 45b, 50a, 50b, 50z... Resistors 3a, 3b, 47a, 47b , 48a, 48b ... connectors, 4a, 4b, 5a, 5b, 5e, 46a, 46b ... relay switch parts 6a, 6b, 6e ... reverse current prevention diodes 13a, 13b, 13e, 14a, 14b, 14e: Comparator V13p, V14p: Comparator + input voltage V13m, V14m ... Comparator-input voltage V13o, V14o ... Comparator output voltage 21, 25, 38 ... (red) Abnormality detection Direction indication 22, 24, 39 ... (green) Evacuation direction indication 23 ... Guide light indications 26a, 26b, 26c, 27a, 27b, 27c And wiring 33, 37 ... red LED by abnormal detection direction display 35, 36 ... green LED by evacuation direction display 35 ... high-intensity white LED illumination by (display portion of the guide light mark)
39a, 39b ... Distance display to the evacuation exit 39c, 39d ... Name display of abnormal location

Claims (5)

Anomaly detection means for detecting the fire detection by the fire sensor and the disconnection / short circuit of the wiring including the fire sensor as a change in the input voltage by the comparator,
In between the lines containing the fire sensor to a comparator, and abnormal transfer and blocking means for performing transmission and interruption of anomalies in the switching of the relay,
At least a pair ,
An abnormality display system characterized in that when an abnormality is detected by one abnormality detection means, the abnormality detection direction or evacuation direction is displayed on a guide light by blocking the other abnormality transmission / interruption means . The guidance display system according to claim 1, further comprising abnormality detection means and abnormality transmission / interruption means, and displaying a plurality of evacuation directions together with information necessary for selecting the evacuation direction .   The induction display system according to claim 1, further comprising a power supply circuit and a standby power supply circuit independently for each unit as the power supplied to the guide lamp. 2. The guidance display system according to claim 1, wherein a plurality of LEDs are lit and blinked so as to indicate an abnormality detection direction and an evacuation direction. The guidance display system according to claim 1, wherein the abnormality detection direction or the evacuation direction is indicated by voice or sound.

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