JPH0727592B2 - Guidance device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an evacuation guidance device which operates according to an abnormal signal and stops when a sensor such as heat or smoke provided in an evacuation route is in operation.

(Background Art) In order to safely guide a person to the outside of a building in the event of a disaster such as a fire, a flashing guide light, a flashing device using a xenon lamp, or a voice synthesizer is used as a guide device. Is widely used. These guidance devices are generally configured to start their operation by an abnormal signal such as a fire alarm signal. Also, if you cannot safely evacuate because the evacuation route becomes hot or full of smoke,
It is dangerous to guide you to the evacuation route, so install a sensor that detects heat, smoke, flame, etc. in the evacuation route in advance, and if the sensor operates, guide on the evacuation route where the sensor is installed. It is known that the operation of the device is stopped to prevent misleading.
See 60-712).

FIG. 4 is a block circuit diagram of a conventional example. In this conventional example, a power source B ₁ is connected to a guidance device A via a switch S ₁ that turns on in response to an abnormal signal such as a fire alarm signal, and when an abnormal signal is input, the switch S ₁ turns on. By doing
The guidance device A starts operating. When the sensor S detects an abnormality such as heat or smoke, it gives a stop signal to the guiding device A to stop the guiding device A. The sensor S is always operated by the power source B ₂ . However, in the case of this conventional example, since the power source B ₁ of the induction device A and the power source B _{2 of the} sensor S are separately required, there is a problem that the cost becomes expensive.

Therefore, as shown in FIG. 5, it is conceivable that the power source B ₁ of the induction device A is also used as the power source of the sensor S. However, since the power source B ₁ of the induction device A uses a battery power source or a private power generation facility so that it can operate even during a power failure,
The power supply capacity is limited, and if power is supplied to the sensor S that is constantly operating, a large power supply capacity is required, which is inconvenient.

Incidentally, instead of the sensor S which requires a power source for operation as shown in FIG. 4 or FIG.
As disclosed in Japanese Patent No. 0, a temperature-sensitive element that has a low resistance at room temperature and a high resistance when the temperature rises is connected in series with an acoustic device, and this is connected to a power source via a switch that is turned on in an emergency. It is also possible to do it. However, in that case, it is not possible to use a self-holding type sensor such as a smoke detector described later in FIG. 3 in which a small current flows when there is no smoke and a large current flows when there is smoke. Since the self-holding type sensor is very often used in the field of disaster prevention sensor, it is extremely inconvenient to be unable to use this type of sensor.

(Object of the Invention) The present invention has been made in view of the above points,
It is an object of the invention to provide a guidance device capable of safely guiding evacuation in the event of a disaster and effectively utilizing an operating power supply.

DISCLOSURE OF THE INVENTION The guiding device according to the present invention will be described with reference to FIG. 1 embodiment. When the guidance device F operates when it receives a fire alarm signal F, and the sensor S provided on the evacuation route detects heat, smoke, or the like. In the induction device A which is stopped at the same time, the DC voltage boosted by receiving the DC voltage from the battery power supply B ₁ lower than the predetermined operable voltage of the induction device A and the sensor S is supplied in parallel to the induction device A and the sensor S. The DC-DC converter CV is formed so as to perform the DC-DC converter CV when the fire alarm signal F is received.
The sensor S is characterized in that the sensor S has a high resistance when heat or smoke is not detected, and has a low resistance when it is detected.

Examples of the present invention will be described below.

FIG. 1 is a block circuit diagram of an induction device according to an embodiment of the present invention. In this embodiment, as the guidance device A, a guidance sound device for guiding evacuation by voice synthesis is used. When the fire alarm signal F is received, the switch S ₁ is closed and the power source B ₁ is connected to the DC-DC converter CV by the operation of the fire signal receiving unit A ₁ . DC voltage of power supply B ₁ is DC-DC converter CV
The voltage is boosted by and is converted into a predetermined operable voltage of the induction device A and the sensor S. The output part of the DC-DC converter CV is supplied to the induction device A and the sensor S in parallel. DC
When the power is supplied from the -DC converter CV, the guidance device A synthesizes and amplifies the audio signal for evacuation guidance, and outputs it as an evacuation guidance sound from the speaker. Also,
The sensor S installed on the evacuation route starts monitoring for the presence of heat and smoke. When an injury such as heat or smoke occurs in the evacuation route, the sensor S operates. When the sensor S operates, a stop signal is given to the guidance device A, and the generation of the guidance sound is stopped.

On the other hand, during normal times, since the switch S ₁ is off, neither the induction device A nor the sensor S is supplied with power. Therefore, it is possible to reduce the power consumption of the power supply B ₁ in normal times.

FIG. 2 shows a specific circuit diagram of this embodiment. The fire alarm signal F is created by the series circuit of the power source F ₁ and the transfer terminal F _2, and the transfer terminal F ₂ is closed under normal conditions, and the transfer terminal F ₂ is opened during a fire. There is. Also, switch S ₂
Is an inspection switch, which can be turned off only during inspection. Therefore, in the normal state, the relay Ry in the fire alarm signal receiving unit A ₁ is excited, and the switch S ₁ including its contact is switched to the NO side shown. In this state, the battery B is charged by being supplied with the voltage obtained by stepping down the AC power supply AC by the step-down transformer Tf and rectifying it by the rectifier DB through the resistor R ₁ . As the battery B, a rechargeable battery such as a Ni-Cd battery is used. Battery B is torque-charged so as to always maintain a fully charged state while compensating for self-discharge. In addition, the voltage drop of the resistor R ₁ caused by the charging current is applied to the light emitting diode (LED) through the resistor R ₂ to turn on the light emitting diode (LED) and display the charge.

When the transfer terminal F ₂ opens in the event of a fire, or when the inspection switch S ₂ opens during inspection, the relay Ry in the fire alarm signal receiver A ₁ is de-energized and the switch S consisting of its contacts is released. ₁ is switched to the NC side, and power is supplied from the battery B to the DC-DC converter CV. In the converter CV, the sensor S normally operates in the 24V DC system, while the battery B is N
Since i-Cd battery is used and it is difficult to supply DC24V directly, it is boosted. That is, Ni
-The rated voltage of a Cd battery is DC 1.2V, and if a large number of cells are directly connected, the battery life will be adversely affected by variations in the capacity of each cell.
CV is used. The voltage boosted to an appropriate voltage by this converter CV is supplied to the induction device A and the sensor S,
These work.

FIG. 3 is an operation explanatory view showing the applied voltage and the energizing current of the smoke sensor used as the sensor S in the present embodiment. This smoke detector is about 10 when there is no smoke.
A small current of 0 μA or less flows, and when smoke is present, a large current of about several tens to 100 mA flows. Even if the smoke disappears from this operating state, the smoke detector has a self-holding function, so that a large current continues to flow.

When such a sensor S is used in this embodiment, since the sensor S is not supplied with power in normal times, there is no unnecessary power consumption, and even when a disaster occurs, the sensor S consumes power while the guidance device A is operating. The electric power is small, and since the guiding device A is stopped after the sensor S detects the injury of the evacuation route and performs the self-holding operation, the guiding device A can be operated by the power source capacity of the guiding device A alone. Is.

The guide device A is not limited to the guide sound device, and may be, for example, a flash device using a xenon lamp or an interior lighting guide lamp.

(Effects of the Invention) As described above, in the present invention, in the guidance device that operates when an abnormal signal is received and stops when a sensor such as heat or smoke provided in the evacuation route operates, A DC-DC converter is provided which receives a DC voltage from a power source lower than a predetermined operable voltage of the sensor and supplies a boosted DC voltage to the induction device and the sensor in parallel, and an abnormal signal is generated. Since it is configured to supply power to the DC-DC converter when receiving it, it is possible to reduce power consumption in normal times, and since the sensor power supply is unnecessary, the configuration is simple and inexpensive, and further,
Compared with a conventional example in which a temperature sensitive element that has low resistance at room temperature and high resistance when temperature rises is connected in series with an audio device, the present invention uses a sensor for stopping the induction device when smoke or heat is not sensed. There is an advantage that a sensor that has low resistance when smoke or heat is detected with high resistance can be used.

[Brief description of drawings]

FIG. 1 is a block circuit diagram of an embodiment of the present invention, FIG. 2 is a detailed circuit diagram of the same as above, FIG. 3 is an operation explanatory diagram of a sensor used therefor, and FIG. 4 is a block circuit diagram of a conventional example. FIG. 5 is a block circuit diagram of another conventional example. A is an induction device, B ₁ is a power supply, F is a fire alarm signal, S is a sensor, S ₁ is a switch, and CV is a DC-DC converter.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-60-245098 (JP, A) JP-A-51-44900 (JP, A) Jitsuko Sho-60-712 (JP, Y2)

Claims (1)

[Claims] 1. An induction device, which operates when an abnormal signal is received and stops when a sensor provided in an evacuation route detects heat, smoke, or the like, a battery having a voltage lower than a predetermined operable voltage of the induction device and the sensor. A DC-DC converter is provided that receives a DC voltage from a power supply and supplies a boosted DC voltage to an induction device and a sensor in parallel, and supplies a power to the DC-DC converter when an abnormal signal is received. An induction device, characterized in that it is configured to supply, and the sensor has a high resistance when it does not detect heat, smoke, etc., and has a low resistance when it detects it.