JP5041671B2 - Guide light lighting device - Google Patents

Description

The present invention relates to the induction lamp lighting apparatus that performs guidance display of evacuation routes such as by using a commercial power supply or battery power, and in particular point lamp device using an LED as a light source.

  Conventionally, there is a guide lamp device using a cold cathode lamp (see, for example, Patent Document 1). In recent years, a guide lamp apparatus using a cold cathode lamp has become common.

  In addition, there is an illumination device that turns on a plurality of LEDs (for example, see Patent Document 2). In this lighting device, a plurality of LEDs are lit using a power source having a large fluctuation range such as a battery. That is, with a simple circuit configuration in which a switching element and an LED unit are connected in series to a DC power source such as a battery, the switching element is controlled to be turned on / off so that the integrated value of the current flowing through the LED unit is constant. I have to.

Japanese Patent Laid-Open No. 2001-14909 (page 7, FIG. 1) Japanese Unexamined Patent Publication No. 2004-39289 (page 4, FIG. 1)

  In the above-mentioned guide lamp device, since the cold cathode lamp is lit at a high voltage and high frequency, unless the wiring between the device and the cold cathode lamp is shortened as much as possible, the light output is reduced due to the influence of stray capacitance. There was a problem. In addition, when the cold cathode lamp has an abnormality due to the high voltage, it is necessary to cut off the entire circuit to prevent an accident such as an electric shock, and there is a problem that the lamp cannot be turned on at the time of a disaster such as a power failure. Further, when the circuit inspection is operated by a remote controller (remote control device) or the like, the remote controller or the like may malfunction unless a cold cathode lamp or high voltage noise is taken into consideration.

  By the way, there is a guide lamp device that performs self-inspection and automatic inspection while supplying power from a commercial power source. However, since this guide light device does not have means for indicating that self-inspection or automatic inspection is in progress, whether the guide light device is lit by self-inspection or automatic inspection, power failure, lack of connection, etc. There was a problem that I did not know whether it was very lit. That is, the guide lamp device may be misunderstood or confused as being lit even though it is lit by self-inspection or automatic inspection.

  On the other hand, the guide lamp device is required to be lit in an emergency in order to recognize the location of the evacuation exit and the evacuation passage. Therefore, even if an abnormality occurs in the light source (cold cathode lamp or LED), it is desirable to turn on the light if the abnormality does not destroy the circuit. However, when the above-described illumination device is for lighting a cold cathode lamp, when the abnormality occurs in the light source, the cold cathode lamp is turned off to protect the circuit.

  The present invention has been made to solve the above-described problems. Even when an abnormality occurs in a light source in an emergency such as a power failure or a disaster, a guide light is turned on by turning on the light source in which no abnormality has occurred. It is an object of the present invention to provide a guide lamp lighting device that has the highest priority as a role.

The guide lamp lighting device according to the present invention has a normal power circuit for converting commercial power into DC power and an auxiliary power, and when there is no power supply from the commercial power, two or more from the auxiliary power An emergency power supply circuit for supplying power to a light source configured by connecting LEDs in series and connecting two or more rows in parallel, and connected in series to each series circuit of the LEDs constituting the light source , A current limiting circuit for setting the current flowing through each series circuit to a set current value; a light source state detection circuit for detecting a lighting state of the light source; and a detection output of the light source state detection circuit is an output of the light source. When some of the LEDs indicate a short circuit abnormality , when the power is supplied from the commercial power supply, the current flowing through the current limiting circuit connected in series to the series circuit including the LED of the short circuit abnormality is cut off. to, the light Some of informed that the LED of the abnormality occurs, current to the current limiting circuit when a power supply is connected in series with the series circuit including the LED of the short-circuit abnormality from the auxiliary power source the sink, the series circuit is turned the LED that is not anomalies occurred connected in series, performs the inspection of the light sources are power supplied from the commercial power source and the auxiliary power supply including the LED of the short-circuit abnormality when, temporarily interrupting the supply from the quotient power, that and a control circuit for performing an inspection of the light source and the auxiliary power source by turning on the light source is switched to the power supply from the auxiliary power supply Features.

The guide lamp lighting device according to the present invention has a normal power circuit for converting commercial power into DC power and an auxiliary power, and when there is no power supply from the commercial power, two or more from the auxiliary power An emergency power supply circuit for supplying power to a light source configured by connecting LEDs in series and connecting two or more rows in parallel, and connected in series to each series circuit of the LEDs constituting the light source , A current limiting circuit for setting the current flowing through each series circuit to a set current value; a light source state detection circuit for detecting a lighting state of the light source; and a detection output of the light source state detection circuit is an output of the light source. When some of the LEDs indicate a short circuit abnormality , when the power is supplied from the commercial power supply, the current flowing through the current limiting circuit connected in series to the series circuit including the LED of the short circuit abnormality is cut off. to, the light Some of informed that the LED of the abnormality occurs, current to the current limiting circuit when a power supply is connected in series with the series circuit including the LED of the short-circuit abnormality from the auxiliary power source the sink, the series circuit is turned the LED that is not anomalies occurred connected in series, performs the inspection of the light sources are power supplied from the commercial power source and the auxiliary power supply including the LED of the short-circuit abnormality when, temporarily interrupting the supply from the quotient power supply, so and a control circuit which turns on the light source performs inspection of the light source and the auxiliary power supply is switched to the power supply from the auxiliary power supply, improvement of safety and reliability, can be realized compact device ing.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a front view showing an example of the guide lamp lighting device 50. The guide lamp lighting device 50 includes a display panel ASSY 12 having a built-in lamp 6, a display panel 11 having a light guide property for receiving light from the lamp 6, a display means (display monitor) 8 described later, various circuits described below, and the like. It is comprised with the main body 13 in which the battery 3 etc. are incorporated. Here, a case where the display unit 8 is provided on the upper side of the display board ASSY 12 is shown as an example, but the present invention is not limited to this, and the display unit 8 may be provided on the lateral side or the lower side.

  FIG. 2 is an installation state diagram illustrating an example of an installation state of the guide lamp lighting device 50. Since the guide lamp lighting device 50 is for recognizing the existence of emergency exits and evacuation passages in the event of an emergency when a power outage or disaster occurs, it should be installed in a place where the refugee can easily recognize in an emergency. It is stipulated by law. Here, the case where the guide lamp lighting device 50 is installed on the ceiling is shown as an example, but the present invention is not limited to this and may be installed on a wall or floor.

  FIG. 3 is a circuit diagram showing a circuit configuration of the guide lamp lighting device 50 according to the embodiment of the present invention. The guide lamp lighting device 50 includes a normal power supply circuit 1, a charging circuit 2, a battery 3, an emergency power supply circuit 4, a lamp state detection circuit 5, a lamp 6, a control circuit 7, and display means 8. , And a constant current circuit 9. In the guide lamp lighting device 50 according to the present invention, since an LED is used for the lamp 6 serving as a light source, it is not necessary to light at a high voltage / high frequency, and improvement of safety / reliability and compactness can be realized. It becomes possible. When power cannot be supplied from a commercial power source due to a power failure or disaster, it is called an emergency, and other times are called regular use.

(Normal power circuit 1)
The normal power supply circuit 1 is a step-down circuit, and includes a transformer T1 having a primary winding N1 connected in parallel to a smoothing capacitor C2 via a switching element SW such as an FET, and a secondary winding N2 of the transformer T1. It consists of a secondary side smoothing capacitor C1 connected via a diode D1, and rectifies the alternating current generated on the secondary side by the diode D1 and smoothes it by the capacitor C1 to obtain a DC voltage. Here, a flyback circuit is shown as an example, but the present invention is not limited to this, and a forward circuit may be used, or a regulator power supply system that steps down a commercial power supply with a transformer may be used.

( Normal power-off circuit 10)
In the guide light, it is stipulated by law to switch to emergency lighting between 85 to 40% of the rated power supply voltage. The normal-time power supply circuit 10 monitors the voltage of the normal power supply and forcibly shuts down the normal-time power supply circuit 1 when the power supply drops due to a power failure or the like, and no output is output to the secondary side of the normal-time power supply circuit 1. Thus, a smooth transition to emergency operation is achieved.

(Charging circuit 2)
The battery 3 is charged with a DC voltage rectified and smoothed by the normal power supply circuit 1.

(Battery 3)
The battery 3 is connected in series with the charging circuit 2 and supplies DC power to the emergency power supply circuit 4 that replaces the commercial power supply E when power supply from the commercial power supply E is lost. The battery 3 is not particularly limited as long as it can store a DC power supply. It should be noted that the state of charge such as whether the battery 3 is charged or not is always displayed on a charge monitor described later.

(Emergency power circuit 4)
The emergency power supply circuit 4 supplies direct current power from the battery 3 to the lamp 6 in an emergency. That is, a voltage suitable for lighting the lamp 6 is supplied using the DC power supply of the battery 3 that is charged while the power is supplied from the normal power supply circuit 1.

(Lamp 6)
The lamp 6 serves as a light source, and an LED is used here. The lamp 6 is configured as an LED module in which n LEDs are connected in series (n is an integer of 2 or more) and m rows (m is an integer of 1 or more) connected in parallel. Then, since the light source can be set finely, the brightness of the display panel 11 can be easily adjusted.

  In general, in order to ensure the brightness of the display panel 11, a predetermined number (for example, two) or more LEDs are required. Therefore, when configured as an LED module, it becomes easy to select serial or parallel. That is, if the output voltage is reduced, the number of series is adjusted, and if the output current is reduced, the number of parallels is adjusted, so that the circuit loss can be easily reduced. The lamp 6 is connected to the constant current circuit 9 for each column.

  Thus, since the lamp 6 is configured as an LED module, if even one LED is broken in an open state, other LEDs in the column to which the LED is connected will also disappear. Therefore, in such a case, the power supply to the column is stopped to reduce the power. Moreover, it has the lamp monitor which displays on the display means 8 that abnormality has generate | occur | produced in LED.

  In addition, since the lamp 6 is lit by a DC power source, the influence of the stray capacitance is small and current does not leak to the outside. Therefore, the distance between the lamp 6 and other circuits can be increased. Further, since the lamp 6 is configured to connect n LEDs in series, the necessary voltage is set to be equal to or lower than a specific low voltage. Therefore, when components are arranged on the substrate, the insulation distance between the components can be minimized, and the substrate can be made compact.

(Constant current circuit 9)
The constant current circuit 9 functioning as a current limiting circuit is connected to each column of the lamps 6 and diverts the current value of the DC power source flowing through the lamps 6 to be detected by the control circuit 7 described later. That is, the current flowing through the constant current circuit 9 for each column of the lamp 6 is detected by the control circuit 7 to determine whether the lamp 6 is abnormal. Note that the constant current circuit 9 connected to each column of the lamps 6 may have the same circuit configuration or a different circuit configuration for each column. Details of the constant current circuit 9 will be described later (see FIG. 4).

(Lamp state detection circuit 5)
The lamp state detection circuit 5 functioning as a light source state detection circuit is a general term for the entire constant current circuit 9 connected to each column of the lamps 6. The lamp 6 is configured as an LED module, and the output voltage changes stepwise according to the number of short-circuit broken elements. Therefore, the control circuit 7 detects the change in the output voltage, and determines the state of the lamp 6 based on the change. It should be noted that the control circuit 7 may detect the heat of the component parts to determine the state of the lamp 6.

(Control circuit 7)
The control circuit 7 includes a control device such as a microcomputer, and controls the current flowing through each constant current circuit 9 in accordance with the voltage value detected from the lamp state detection circuit 5. When it is determined that an abnormality has occurred in the lamp 6 based on information from the lamp state detection circuit 5 during normal use, power supply from the normal power supply circuit 1 to the lamp 6 is stopped. Further, in the event of an emergency, when it is determined that an abnormality has occurred in the lamp 6 based on information from the lamp state detection circuit 5, an emergency power supply is turned on so that LEDs other than the LED in which the abnormality has occurred are lit. The power supply from the circuit 4 is continued.

  When a short circuit abnormality occurs in the lamp 6, the components (for example, various resistors and switching elements) of the constant current circuit 9 connected to the lamp 6 may fail. This is because the output voltage changes in a stepwise manner according to the number of LEDs in which the lamp 6 is short-circuited and broken, resulting in a loss larger than usual in the components of the constant current circuit 9. And when the loss of a component becomes large, the temperature of a component will rise (heat generation), and it may cause a failure.

  Therefore, when a short circuit abnormality of the lamp 6 occurs during normal use, the control circuit 7 sets the constant current circuit 9 so that the components of the constant current circuit 9 connected to the lamp 6 where the abnormality has occurred do not fail. The current is not passed. That is, the power supply to the constant current circuit 9 connected to the row of lamps 6 in which an abnormality has occurred is stopped. In this way, priority is given to protection of the constant current circuit 9 during normal use. Further, the occurrence of abnormality is displayed on the display means 8.

  Further, when a short circuit abnormality of the lamp 6 occurs in an emergency, in order to prioritize the role as a guide light over the protection of the constant current circuit 9, LEDs other than the LED in which the abnormality has occurred are turned on. The power supply to the constant current circuit 9 is continued. That is, until the constant current circuit 9 is completely destroyed, the LED having no abnormality is lit.

  On the other hand, if an abnormality in the open state occurs in one of the LEDs constituting the lamp 6, no current flows through other LEDs connected in series with the LED. Therefore, in such a case, the control circuit 7 stops the power supply to the constant current circuit 9 to which the LED is connected, whether in normal use or in emergency. That is, unlike the case of the short circuit abnormality, the power supply is only consumed in vain, so the power supply is stopped in order to reduce the waste.

  Further, the control circuit 7 performs an inspection to detect the state of the lamp 6 and the battery 3 even during normal use. This inspection is not particularly limited as long as the state of the lamp 6 and the battery 3 can be detected. For example, self-inspection that is automatically performed at a preset time interval in the control circuit 7, manual inspection that is directly operated by an operator, inspection that is indirectly operated from a remote control device, or the like may be used. . By doing so, you can prepare for emergencies when you do not know when it will occur.

By the way, since the lamp 6 is lit by a DC power source, no noise is emitted from the lamp, and even if a remote control device is provided, an infrared signal or the like transmitted from the remote control device There is no interference. Further, if the remote control device is provided, the battery 3 can be easily inspected even if the guide lamp lighting device 50 is installed at a high place such as a ceiling. Accordingly, it is possible to improve the reliability and facilitate model development using the remote control device.

(Display means 8)
The display means 8 displays the state of the lamp 6 and the battery 3 detected by the control circuit 7. In addition, the lamp 6 and the battery 3 are being inspected. Here, a case where a charge monitor a, a lamp monitor b, and an inspection monitor c are provided is shown as an example. The charge monitor a is lit when the charging circuit 2 is charging the battery 3. The lamp monitor b is turned on when the lamp 6 is abnormal or has a lifetime. The inspection monitor c is lit when checking the battery 3 or the state of the lamp 6.

In this way, the inspection monitor c can easily determine whether the lamp 6 is lit because it is an emergency or whether it is lit because it is inspecting, which may cause misunderstandings and confusion. Absent. Note that the color of the monitor may be any number, and is not particularly limited. Further, it may be blinked or represented by characters. Furthermore, when notifying an abnormality, all monitors may be blinked or an alarm may be given by a sound such as a buzzer.

FIG. 4 is a circuit diagram showing a configuration example of the constant current circuit 9.
In the constant current circuit 9a shown in FIG. 4A, the LEDs connected in series constituting the lamp 6 are connected in series to the collector of the switching element Q1. This will be the V _R. The resistor R7 is connected in parallel with the LED and the switching element Q1, and is connected in series with the resistor R6. The control circuit 7 is connected to a connection point (point A) between the resistor R7 and the resistor R6. That is, the control circuit 7 determines whether or not the lamp 6 is abnormal by detecting the voltage at the point A. The lamp 6 is supplied with a DC power source Vin from the normal power circuit 1 or the emergency power circuit 4.

  The emitter of the switching element Q1 is connected to the collector of the switching element Q2. The bases of the switching element Q1 and the switching element Q2 are connected to the control circuit 7, respectively. That is, the control circuit 7 performs current control based on the voltage at point A. A resistor R2 is connected in series between the switching element Q1 and the switching element Q2. The resistor R3 is connected in parallel with the resistor R2. The emitter of the switching element Q2, the resistor R3, and the resistor R6 are connected to the Zener diode DZ1. A resistor R1 is connected in series to the Zener diode DZ1.

If comprised in this way, the control circuit 7 can judge the presence or absence of abnormality in the lamp | ramp 6 only by detecting the voltage of A point. When the abnormality occurs in the lamp 6 in the very time, the control circuit 7 controls the current of the switching elements Q1 and Q2, to light the lamp 6 in the extent of the current the constant current circuit 9a is not broken It is possible. The constant current circuit 9a may be used for all the columns constituting the lamp 6, or each column may be configured separately.

In the constant current circuit 9b shown in FIG. 4B, the LEDs connected in series constituting the lamp 6 are connected to the collector of the switching element Q4. This point is V _R as in FIG. The resistor R12 is connected between the LED and the switching element Q4, and is connected in series with the resistor R13. The control circuit 7 is connected to a connection point (point B) between the resistor R12 and the resistor R13. That is, the control circuit 7 determines whether or not the lamp 6 is abnormal by detecting the voltage at the point B.

  The emitter of the switching element Q4 is connected to the resistor R11. The base of the switching element Q4 is connected to the output terminal of the operational amplifier IC. The switching element Q4 and the resistor R11 are connected to the inverting input terminal of the operational amplifier IC. The control circuit 7 is connected to the base of the switching element Q5 and performs current control. The collector of the switching element Q5 is connected to the resistor R9. The resistor R9 is connected in series with the resistor R8.

  The non-inverting input terminal of the operational amplifier IC is connected between the resistor 8 and the resistor 9. The non-inverting input terminal is connected to the resistor R10 so as to be in parallel with the resistor R9. The emitter of the switching element Q5, the resistor R10, the resistor R11, and the resistor R13 are connected to the Zener diode DZ2.

If comprised in this way, the control circuit 7 can judge the presence or absence of abnormality in the lamp | ramp 6 only by detecting the voltage of B point. When the abnormality occurs in the lamp 6 in the very time, the control circuit 7 can be controlled only current of the switching element Q5, the constant current circuit 9b is to light the lamp 6 on the order of current that does not destroy It has become. The constant current circuit 9b may be used for all the columns constituting the lamp 6, or each column may be configured separately.

  In the constant current circuit 9c shown in FIG. 4C, the LEDs connected in series constituting the lamp 6 are connected to the collector of the switching element Q6. The emitter of the switching element Q6 is connected to the resistor R15, and the base is connected to the control circuit 7. The resistor R15 is connected to the Zener diode DZ3. A resistor R14 is connected in series to the Zener diode DZ3. Here, temperature detection means SR1 is provided in the vicinity of the switching element Q6, and information of the temperature detection means SR1 is detected by the control circuit 7.

  That is, the control circuit 7 determines whether there is an abnormality in the lamp 6 by detecting the temperature information of the temperature detecting means SR1. The temperature detecting means SR1 is not particularly limited as long as it can detect the temperatures of the components of the constant current circuit 9c. For example, a thermistor or the like may be used. Moreover, although the case where one is provided in the vicinity of the switching element Q6 is shown as an example, the present invention is not limited to this, and a plurality may be provided.

If comprised in this way, the control circuit 7 can judge the presence or absence of abnormality in the lamp | ramp 6 only by detecting the temperature of the temperature detection means SR1. When the abnormality occurs in the lamp 6 in the very time, the control circuit 7 can be controlled only current of the switching element Q6, a constant current circuit 9c is to light the lamp 6 on the order of current that does not destroy It has become. The constant current circuit 9c may be used for all the columns constituting the lamp 6, or each column may be configured separately.

  Although the case where the switching elements Q1 to Q6 provided in the constant current circuit 9 are transistors has been described as an example, the present invention is not limited thereto. For example, you may comprise by switching elements, such as MOSFET. Moreover, although the case where the example of a structure of the constant current circuit 9 was provided independently was demonstrated to the example, it is not limited to this. For example, each may be combined to form one constant current circuit 9, or another component may be added.

Next, the operation of the guide lamp lighting device 50 will be described.
In normal use, the commercial power supply E is stepped down, rectified and smoothed by the normal use power supply circuit 1 to be supplied to the lamp 6 as a DC power supply. At the same time, the battery 3 is charged by being supplied to the charging circuit 2. The control circuit 7 controls the DC power supply. At this time, the control circuit 7 turns on / off / flashes the charge monitor (a) and the lamp monitor (b) of the display means 8. Therefore, it is possible to grasp the current state of the guide lamp lighting device 50 at a glance.

  When the lamp 6 is normally lit, a current flows through the constant current circuit 9 at a predetermined voltage, so that the control circuit 7 determines that no abnormality has occurred in the lamp 6. Further, when a short circuit abnormality occurs in one of the LEDs constituting the lamp 6, the output voltage changes in the constant current circuit 9, so that the control circuit 7 can determine that an abnormality has occurred in the lamp 6. . If a stepwise threshold is provided for this output voltage in advance, the abnormal lamp 6 can be easily specified and dimming / extinguishing control can be easily performed.

  Further, when an abnormality in an open state occurs in one of the LEDs constituting the lamp 6, no current flows through other LEDs because n LEDs are connected in series. The power supply to is wasted. Therefore, the control circuit 7 stops the power supply to the constant current circuit 9 connected to the column where the open state abnormality has occurred. In this way, control according to the type of abnormality occurring in the LED is possible, and efficient power consumption can be realized.

  In an emergency, power is not supplied from the normal power supply circuit 1, so the control circuit 7 switches to the emergency power supply circuit 4 and turns on the lamp 6 by supplying power from the battery 3. At this time, the control circuit 7 turns off the charge monitor (a) of the display means 8 and continuously turns on the lamp 6. At this time, if an abnormality occurs in the lamp 6, the control circuit 7 gives priority to the role as a guide lamp over the protection of the constant current circuit 9.

  That is, if the abnormality occurring in the lamp 6 is such that the constant current circuit 9 is not destroyed, the power supply from the emergency power supply circuit 4 is continuously supplied without being stopped, and the lamp 6 is kept on. . Even if some LEDs out of the lamps 6 are abnormal and no longer illuminate, if the LEDs that are not abnormal are continuously lit, they are guided compared to when all the LEDs are extinguished. This is because it can serve as a light.

For example, a voltage of V _R of the state of the constant current circuit 9 abnormal lamp 6 is not generated by the 5V, if tentatively 3V voltage of LED1 amino lighting component, if LED is all without a 0V, When one of them is short-circuited, the corresponding voltage is superimposed and becomes about 8V. That is, since the voltage changes according to the number of short-circuited LEDs, it is possible to control the current to such an extent that a threshold value is set for the voltage value and the components of the constant current circuit 9 are not destroyed. Therefore, a threshold value is set in advance in a control device (not shown) provided in the control circuit 7, and current control according to the threshold value can be performed quickly.

  During the inspection, the control circuit 7 supplies power to the lamp 6 from the battery 3 and the emergency power supply circuit 4 for a predetermined time, detects the voltage of the current flowing through the constant current circuit 9, and determines whether the lamp 6 is abnormal. In addition to the determination, the abnormality or life of the battery 3 is determined. At this time, the control circuit 7 lights or blinks the inspection monitor (c) of the display means 8. Further, this inspection may be performed at a predetermined interval set in the control circuit 7, or may be performed based on an instruction from a remote control device or a direct instruction from a worker or the like.

It is a front view which shows an example of the guide lamp lighting device which concerns on Embodiment 1. FIG. It is an installation state figure which shows an example of the installation state of a guide light lighting device. It is a circuit diagram which shows the circuit structure of a guide lamp lighting device. It is a circuit diagram which shows the structural example of a constant current circuit.

Explanation of symbols

1 power supply circuit for normal use, 2 charging circuit, 3 battery, 4 emergency power supply circuit, 5 lamp state detection circuit, 6 lamp, 7 control circuit, 8 display means, 9 constant current circuit, 9a constant current circuit, 9b constant current circuit , 9c Constant current circuit, 10 power-off circuit for normal use , 11 display panel, 12 display board ASSY, 13 main body, E commercial power supply, T1 step-down transformer, D1 diode, C1 capacitor, Vin DC power supply, Q1-Q6 switching element, R1 -R16 resistance, DZ1-DZ3 Zener diode, SR1 temperature detection means, 50 guide lamp lighting device.

Claims (2)

A normal-time power circuit that converts commercial power into DC power;
An auxiliary power supply, said from the auxiliary power supply when there is no power supply from the commercial power source, and connecting two or more LED in series, power to the light source that is configured by connecting in parallel two or more rows of said column Emergency power supply circuit to supply,
A current limiting circuit which is connected in series to each series circuit of the LEDs constituting the light source, and makes a current flowing through each series circuit have a set current value;
A light source state detection circuit for detecting a lighting state of the light source;
When the detection output of the light source state detection circuit indicates that some of the LEDs of the light source are in short circuit abnormality , when the power supply is from the commercial power supply, the short circuit abnormality in series with the series circuit including the LEDs and interrupting the flow of current connected to said current limiting circuit, and notifying that an abnormality of some of the LED of the light source occurs, the LED of the short-circuit abnormality when the a power supply from the auxiliary power supply the series circuit to flow a current to the current limiting circuit connected in series comprising turns on the said LED to a series circuit does not occur in the series connected abnormalities including the LED of the short-circuit abnormality,
When power is supplied from the commercial power source and the light source and the auxiliary power source are inspected, supply from the commercial power source is temporarily interrupted and switched to power supply from the auxiliary power source to turn on the light source A control circuit for checking the light source and the auxiliary power source,
Induction lamp lighting apparatus comprising: a. The auxiliary power is
A battery for supplying power to the light source;
The induction lamp lighting device according to claim 1, further comprising a charging circuit that charges the battery.

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