JP3171658U - Emergency lighting system - Google Patents

Abstract

Provided is an emergency lighting device capable of suppressing waste of electric power by detecting whether there is sufficient light around by an optical sensor. An emergency lighting device has a power supply device, a light sensor, an acceleration sensor, a central processing unit, at least one LED lighting circuit, and an uninterruptible power supply device, and provides lighting in the event of an earthquake or power failure To do. Moreover, when an earthquake is detected by an acceleration sensor and a certain seismic intensity is exceeded, it can be used as a warning alarm facility by turning on the LED lighting device. Furthermore, the uninterruptible power supply device can be activated at the time of a power failure, and can be turned on when the user condemns or loses light to illuminate the evacuation direction. [Selection] Figure 1

Description

  The present invention relates to an emergency lighting device, and more particularly to an emergency lighting device that detects the occurrence of an earthquake and turns on the lighting in the event of a power failure.

  In the event of a natural disaster such as a typhoon, earthquake, or power outage, whether or not an emergency evacuation device is installed in the building is an important key for evacuation. At present, every building has emergency evacuation devices such as emergency lighting devices. The power of a general lighting device is supplied from a power plug, but when an abnormality occurs in the power supply when a disaster occurs, the emergency lighting is turned on and the evacuation direction can be illuminated.

  Some emergency lighting currently used detects earthquakes and smoke. Patent Document 1 describes emergency lighting using an AC power source as a power source for a lighting device. However, the reaction speed of the AC power source is difficult to use for an LED lighting circuit that requires a DC power source, and is higher than the rated output required by the LED lighting circuit, resulting in wasted energy consumption. Therefore, since the sustainability of electric power is inferior to an LED lighting circuit, it cannot be lit for a long time and illuminate the evacuation direction. The emergency lighting using LEDs described in Patent Document 2 can be used as a general LED lighting device by providing an on / off switch, and also includes a power failure detection circuit so that the main lighting is not turned off and When the power supply of the power supply is interrupted, the necessary power is supplied to the lighting fixture from the standby power supply to provide emergency lighting. However, it is described that the power failure detection circuit described above detects whether the power supply from the main power supply is interrupted and determines whether it is switched off or in a power failure state. The ambiguous expression is not clear enough to be easily implemented by those skilled in the art.

  Furthermore, the earthquake detection circuit combined with the conventional emergency lighting equipment uses a seismometer using a weight. Such seismometers cannot adjust the sensitivity afterwards, and when an earthquake that exceeds the level that can be detected by the seismometer, the earthquake occurred uniformly regardless of the magnitude. It will be detected. For this reason, there is a lack of convenience. In addition, the above-mentioned seismometers cannot distinguish between earthquakes and sudden vibrations, so they are also detected by vibrations caused by external forces such as collisions and vibrations caused by passing large vehicles. Cause confusion.

  And although the conventional emergency lighting apparatus can be lit at the time of a power failure by providing an uninterruptible power supply, the LED emergency lighting equipment provided with such an uninterruptible power supply is daytime or sufficient Even when a power failure occurs in a place where natural light is present, the device cannot detect the brightness and turns on the LED illumination. Therefore, power is wasted and the power of the storage battery is consumed. It can be said that it is not known whether sufficient power is secured when lighting is really necessary.

Taiwan Utility Model Notification No. 327945 Taiwan Patent Notice No. M343106

  Therefore, the present invention aims to solve the problems of conventional emergency lighting devices, such as insufficient power, problems that cannot be dealt with in various emergency situations, and problems that seismic intensity cannot be measured by conventional seismometers. To do.

  In order to solve the above-described problems, the emergency lighting device of the present invention is compatible with DC power in which all devices can save power over AC power. In order to prevent power consumption during daylight, an optical sensor is provided to determine whether it is necessary to measure the brightness of the surrounding area and turn it on. Further, when an earthquake occurs, it is determined whether it is necessary to turn on the light by detecting the earthquake with an acceleration sensor and setting the seismic intensity with a central processing unit. In addition, by providing a human sensor, it is possible to turn on when a person passes even in a place where there is little traffic, eliminating the blind spot and further reducing the power consumption. By providing an infrared device, remote operation can be performed.

  An emergency lighting device according to one aspect of the present invention includes a power supply device, a light sensor, a central processing unit, at least one LED lighting circuit, and an uninterruptible power supply device. The power supply device includes at least one transformer that converts AC power into DC power, and the transformer supplies the converted DC power to the central processing unit, the LED lighting circuit, and the uninterruptible power supply. The optical sensor is activated when an external power supply fails, and detects a change in the light source. The optical sensor transfers the detected change of the light source as a signal to the central processing unit, and the central processing unit controls on / off of the LED illumination circuit based on the signal. The LED lighting circuit includes at least one LED light and is electrically connected to the central processing unit and the uninterruptible power supply. The uninterruptible power supply has a charger and at least one storage battery. The uninterruptible power supply supplies power to the photosensor, the central processing unit, and the LED illumination circuit when an external power supply fails. The central processing unit adjusts the brightness of the LED lighting circuit by PWM control.

  An emergency lighting device according to another aspect of the present invention includes a power supply device, an acceleration sensor, a central processing unit, and at least one LED lighting circuit. The power supply device includes at least one transformer that converts AC power into DC power, and the transformer supplies the converted DC power to the acceleration sensor, the central processing unit, and the LED lighting circuit. The acceleration sensor is provided for measuring seismic intensity, and transfers the measured information to the central processing unit. The central processing unit drives the LED illumination circuit based on a signal from the acceleration sensor when the signal is larger than a predetermined value. The LED lighting circuit includes at least one LED light and is electrically connected to the central processing unit and the power supply device. The emergency lighting device further includes a human sensor, and when the human location is detected, the LED lighting circuit is driven by transferring a signal to the central processing unit. The emergency lighting device further includes an infrared receiving unit electrically connected to the central processing unit and the power supply device. The infrared receiver is used together with a remote controller. The central processing unit adjusts the brightness of the LED lighting circuit by PWM control.

  An emergency lighting device according to still another aspect of the present invention includes a power supply device, a light sensor, an acceleration sensor, a central processing device, at least one LED lighting circuit, and an uninterruptible power supply device. The power supply device includes at least one transformer that converts AC power into DC power, and the transformer supplies the converted DC power to the central processing unit, the LED lighting circuit, and the uninterruptible power supply. The optical sensor is activated when an external power supply fails, and detects a change in the light source. The optical sensor transfers the detected change in the light source as a signal to the central processing unit. The acceleration sensor is provided for measuring seismic intensity, and transfers the measured information to the central processing unit. The central processing unit controls on / off of the LED lighting circuit based on a signal from the photosensor. The LED lighting circuit includes at least one LED light and is electrically connected to the central processing unit and the uninterruptible power supply. The uninterruptible power supply has a charger and at least one storage battery. The uninterruptible power supply supplies power to the photosensor, the central processing unit, and the LED illumination circuit when an external power supply fails. The emergency lighting device further includes a human sensor, and when the human location is detected, the LED lighting circuit is driven by transferring a signal to the central processing unit. The emergency lighting device further includes an infrared receiving unit electrically connected to the central processing unit and the power supply device. The infrared receiver is used together with a remote controller. The central processing unit adjusts the brightness of the LED lighting circuit by PWM control.

  According to the present invention, it is possible to provide an emergency lighting device that can save electric power than a conventional emergency lighting device and can detect only when an earthquake really occurs. Therefore, it can be expected to be used in a wider range than the conventional one, and it is possible to respond to any emergency situation.

It is the schematic block diagram which showed the emergency illuminating device of this invention. It is a flowchart showing the operation | movement at the time of the earthquake occurrence of the emergency illuminating device of this invention. It is a flowchart showing the operation | movement at the time of the power failure which does not depend on the earthquake of the emergency illuminating device of this invention.

    Embodiments of the present invention will be described below with reference to the accompanying drawings.

  FIG. 1 is a schematic block diagram of an emergency lighting device according to an embodiment of the present invention. The emergency lighting device 100 includes a power supply device 1, an optical sensor 4, an acceleration sensor 5, a human sensor 6, an infrared receiver 7, a central processing device 3, at least one LED lighting circuit 8, and an uninterruptible power supply device 2. Have. The power supply device 1 includes at least one transformer that converts AC power into DC power, and the transformer converts the converted DC power into the central processing unit 3, the acceleration sensor 5, the LED illumination circuit 8, and the uninterruptible power supply device. 2 is supplied. The optical sensor 4 is activated when the external power supply fails and detects a change in the light source. The optical sensor 4 transfers the detected change of the light source as a signal to the central processing unit 3. The acceleration sensor 5 is provided for measuring the seismic intensity, and transfers the measured information to the central processing unit 3. The human sensor 6 drives the LED illumination circuit 8 by transferring a signal to the central processing unit 3 when detecting the human location. The infrared receiver 7 is electrically connected to the central processing unit 3 and the power supply device 1. The infrared receiving unit 7 is used together with a remote controller, and it is possible to control the on / off of the LED lighting circuit 8 or change the setting by remotely operating the central processing unit 3 with the remote controller. Based on the signal from the acceleration sensor 5, the central processing unit 3 drives the LED illumination circuit 8 when the signal is larger than a set constant value. The central processing unit 3 activates the switch of the LED light 82 when the power supply from the outside fails, based on the signal from the optical sensor 4 when the brightness is insufficient. When there is sufficient brightness, the switch of the LED light 82 is not activated. The LED lighting circuit 8 has at least one LED light 81 and one power failure LED light 82 and is electrically connected to the central processing unit 3 and the uninterruptible power supply 2. The uninterruptible power supply 2 includes a charger 21 and at least one storage battery 22. The uninterruptible power supply 2 supplies power to the optical sensor 4, the central processing unit 3, and the LED illumination circuit 8 when the external power supply fails. The central processing unit 3 adjusts the brightness of the LED illumination circuit 8 by PWM control.

  FIG. 2 is a flowchart showing the operation of the emergency lighting device according to the embodiment of the present invention when an earthquake occurs. When an earthquake occurs, if a power failure occurs, the optical sensor 4 is activated and detects whether the surrounding brightness is sufficient. If the brightness is sufficient, the LED lighting circuit 8 is not turned on. If the brightness is not enough, the LED lighting circuit 8 is driven and turned on until the power is restored or the power of the storage battery 22 is exhausted. When an earthquake occurs, if electric power is supplied, the acceleration sensor 5 is activated and the set seismic intensity is not reached. If the LED lighting circuit 8 is not turned on and the set seismic intensity is reached. By turning on the LED lighting circuit 8, it can be used as an emergency alarm facility. Then, after the earthquake stops, the LED lighting circuit 8 is turned off after a certain time.

  FIG. 3 is a flowchart showing the operation of the emergency lighting device according to the embodiment of the present invention at the time of a power failure that is not caused by an earthquake. At the time of a power failure, the optical sensor 4 is activated and detects whether the surrounding brightness is sufficient. If the brightness is sufficient, the LED lighting circuit 8 is not turned on. If the brightness is not enough, the LED lighting circuit 8 is driven and turned on until the power is restored or the power of the storage battery 22 is exhausted. Here, during a power failure, the optical sensor 4 is always activated regardless of whether an earthquake has occurred. If the brightness is insufficient, the LED illumination circuit 8 is driven to secure light.

  In the above description, the best embodiments have been described for the convenience of description of the present invention. However, these embodiments do not limit the scope of the present invention, and the gist of the present invention based on the present invention. All modifications that do not depart from the scope of the present invention are covered by the claims.

DESCRIPTION OF SYMBOLS 100 Emergency lighting apparatus 1 Power supply apparatus 2 Uninterruptible power supply apparatus 21 Charger 22 Storage battery 3 Central processing unit 4 Optical sensor 5 Acceleration sensor 6 Human sensor 7 Infrared receiver 8 LED lighting circuit 81 LED light 82 LED light for power interruption

Claims (12)

An emergency lighting device,
A power supply device;
An optical sensor;
A central processing unit;
At least one LED lighting circuit;
An uninterruptible power supply,
And the power supply device includes at least one transformer that converts AC power into DC power, and the transformer converts the converted DC power to the central processing unit, the LED lighting circuit, and the uninterruptible power supply. To supply
The optical sensor is activated when an external power supply is interrupted, detects a change in the light source, and transfers the detected change in the light source as a signal to the central processing unit.
The central processing unit controls on / off of the LED lighting circuit based on the signal,
The LED lighting circuit has at least one LED light, and is electrically connected to the central processing unit and the uninterruptible power supply,
The uninterruptible power supply has a charger and at least one storage battery, and supplies power to the photosensor, the central processing unit, and the LED lighting circuit when an external power supply fails. Lighting equipment.   The emergency lighting device according to claim 1, wherein the central processing unit adjusts the brightness of the LED lighting circuit by PWM control. An emergency lighting device,
A power supply device;
An acceleration sensor;
A central processing unit;
At least one LED lighting circuit;
The power supply device includes at least one transformer that converts AC power into DC power, and the transformer supplies the converted DC power to the acceleration sensor, the central processing unit, and the LED lighting circuit. And
The acceleration sensor is provided for measuring seismic intensity, transfers the measured information to the central processing unit,
The central processing unit drives the LED lighting circuit based on a signal from the acceleration sensor when the signal is larger than a set constant value,
The emergency lighting device, wherein the LED lighting circuit includes at least one LED light and is electrically connected to the central processing unit and the power supply device.   The emergency lighting device further includes a human sensor, and when the human location is detected, the LED lighting circuit is driven by transferring a signal to the central processing unit. 3. The emergency lighting device according to 3.   The emergency lighting device according to claim 4, further comprising an infrared receiving unit electrically connected to the central processing unit and the power supply device.   The emergency lighting device according to claim 5, wherein the emergency lighting device further includes a remote controller, and the infrared receiving unit is used together with the remote controller.   The emergency lighting device according to claim 3, wherein the central processing unit adjusts the brightness of the LED lighting circuit by PWM control. An emergency lighting device,
A power supply device;
An optical sensor;
An acceleration sensor;
A central processing unit;
At least one LED lighting circuit;
An uninterruptible power supply,
And the power supply device includes at least one transformer that converts AC power into DC power, and the transformer converts the converted DC power to the central processing unit, the LED lighting circuit, and the uninterruptible power supply. To supply
The optical sensor is activated when an external power supply is interrupted, detects a change in the light source, and transfers the detected change in the light source as a signal to the central processing unit.
The acceleration sensor is provided for measuring seismic intensity, transfers the measured information to the central processing unit,
The central processing unit controls on / off of the LED lighting circuit based on a signal from the light sensor,
The LED lighting circuit has at least one LED light, and is electrically connected to the central processing unit and the uninterruptible power supply,
The uninterruptible power supply has a charger and at least one storage battery, and supplies power to the photosensor, the central processing unit, and the LED lighting circuit when an external power supply fails. Lighting equipment.     The emergency lighting device further includes a human sensor, and when the human location is detected, the LED lighting circuit is driven by transferring a signal to the central processing unit. The emergency lighting device according to 8.   The emergency lighting device according to claim 8, further comprising an infrared receiving unit electrically connected to the central processing unit and the power supply device.   The emergency lighting device according to claim 10, wherein the emergency lighting device further includes a remote controller, and the infrared receiving unit is used together with the remote controller.   The emergency lighting device according to claim 8, wherein the central processing unit adjusts the brightness of the LED lighting circuit by PWM control.