JP2007214037A - Lighting device and illumination module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable to confirm easily abnormality of a battery or an emergency light from a location other than just below the emergency light installed on the ceiling in the emergency light arranged on the ceiling. <P>SOLUTION: The LED battery built-in emergency light, as an emergency light, puts on illumination LEDs 112a-112c by the battery charged at the time of supply of commercial power supply, when the commercial power supply is cut off. On the other hand, when the commercial power supply is supplied, the LED battery built-in emergency light displays whether or not the battery is in normal condition or whether or not the illumination LEDs 112a-112c are normal by a lighting mode (light-on, flashing, light-out, etc.) of an inspection LED 111a. In this LED battery built-in emergency light, the inspection LED 111a and the illumination LEDs 112a-112c are installed on the same installation face side 115 of a substrate 114, and by being covered by an LED lens 113, are made into a package by the substrate 114 and the LED lens 113. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an emergency lighting apparatus that lights a lamp with a battery during a power failure. For example, the present invention relates to an emergency lighting apparatus that displays whether a battery and a lamp are normal.

  Emergency lighting fixtures (sometimes called emergency lights) can be used to safely condemn those who are in the event of a power outage due to a fire, earthquake, or other disaster where an unspecified number of people gather. It is an instrument that illuminates the room and passage. FIG. 2 and FIG. 3 of Patent Document 1 (not attached to the present application) or the like, or FIG. 1 of Patent Document 2 (not attached to the present application) shows the configuration.

  Emergency lighting fixtures are equipped with a battery, which is charged by a commercial power source. Then, for example, when a power failure occurs due to a fire or an earthquake, the room or passage is illuminated so that the person in the place can be safely condemned by turning on the battery. Since the battery is turned on in the event of a power failure such as a disaster, the state of charge of the battery is important. For this reason, the emergency lighting fixture includes a charge monitor that displays a state of charge of the battery (charge monitor lamp 4 in Patent Document 1 and monitor 12 for charge in Patent Document 2). The charge monitor is checked by looking up at the emergency lighting fixture attached to the ceiling.

In this case, according to the conventional technology (for example, Patent Document 1 and Patent Document 2), the hole through which the light of the charging monitor passes is small. It was not easy. In addition to the state of charge of the battery, the reliability of the emergency light can be further improved if it is possible to display whether the lamp that is lit by the battery at the time of power failure is normal.
JP 2005-93250 A JP 2005-129517 A

  The present invention relates to an emergency light installed on a ceiling or an emergency light provided on a lighting device installed on a ceiling, and an abnormality of a battery or an emergency (lighting) lamp is directly below the emergency light installed near the ceiling. The purpose is to provide an emergency light with an inspection monitor that can be easily confirmed from other locations.

The lighting device of this invention is
A secondary battery for charging the power supplied by the commercial power supply;
A lighting unit for inspection that lights with the commercial power source as a power source;
A lighting unit for lighting that uses the secondary battery as a power source;
An inspection circuit for monitoring the state of at least one of the secondary battery and the lighting unit for lighting by operating the commercial power source as a power source, and controlling lighting of the lighting unit for inspection based on a monitoring result When,
An illumination lighting circuit for lighting the lighting unit for lighting using the secondary battery as a power source when the supply of the commercial power supply is interrupted,
The inspection lighting part and the lighting lighting part are:
The substrate is packaged by the substrate and the lens by being installed on the same surface side of the substrate and covered with the lens.

  According to the present invention, it is possible to provide an emergency lighting apparatus including an inspection monitor that can easily check an abnormality of a battery or an emergency lamp even from a position other than directly below an apparatus attached to the ceiling.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS. Embodiment 1 relates to an emergency lighting apparatus that lights a lamp with a battery (sometimes referred to as a secondary battery or a battery) during a power failure, and relates to an emergency lighting apparatus that displays whether the battery and the lamp are normal. . In the following embodiments, a light emitting diode (hereinafter referred to as an LED) will be described as a light emitter that emits light.

  FIG. 1 is a diagram showing an appearance of an emergency light (lighting device) with a built-in LED battery, which is an emergency lighting device in the first embodiment. As shown in FIG. 1, the A direction is the ceiling side, and the B direction is the indoor side. The LED battery built-in emergency light 100 is attached to the ceiling side in the A direction, and irradiates light from the LED lens 113 toward the indoor side.

  FIG. 2 is a configuration diagram showing an outline of the configuration of the emergency light 100 with a built-in LED battery. The LED battery built-in emergency light 100 includes a battery 130 (secondary battery) in a main body 150 and is closed by a lid 153. The main body 150 has a device mounting spring 152, which allows the LED battery built-in emergency light 100 to be mounted on the ceiling. Further, the main body 150 has a battery holding spring 151, whereby the battery 130 is attached inside the main body. The main body 150 includes a unit 120 including respective circuits and LEDs.

  FIG. 3 is a block diagram showing the configuration of the emergency light 100 with a built-in LED battery. As illustrated in FIG. 3, the LED battery built-in emergency light 100 includes an LED module 110 (illumination module), a unit 120, and a battery 130. The unit 120 charges the battery 130 with power from a commercial power source.

  FIG. 4 is a diagram illustrating a configuration of the LED module 110. In the LED module 110, the inspection LED 111a constitutes the inspection lighting unit 1000. In the case of FIG. 4, the inspection lighting unit 1000 is configured only by the inspection LED 111 a, but in FIGS. 11 and 12 described later, two LEDs configure the inspection lighting unit 1000. Further, the illumination LED 112a, the illumination LED 112b, and the illumination LED 112c constitute an illumination lighting unit 2000.

  As shown in FIG. 4, the LED module 110 includes an inspection lighting unit 1000, an illumination lighting unit 2000, and a substrate on which the inspection lighting unit 1000 and the illumination lighting unit 2000 are installed on the same mounting surface 115. 114 and the LED lens 113 that covers the inspection lighting unit 1000 and the illumination lighting unit 2000 installed on the substrate 114 are integrally packaged. As shown in FIG. 4, one feature of the LED battery built-in emergency light 100 is to use the LED module 110 that is integrally packaged.

  As shown by the arrow C in FIG. 4, the illumination LED 112a to the illumination LED 112c constituting the illumination lighting unit 2000 are disposed on substantially the same circumference on the mounting surface side 115 of the substrate 114. Also, the inspection LED 111a constituting the inspection lighting unit 1000 is disposed in the vicinity of (near) the approximate center of the circumference where the illumination LED 112a to the illumination LED 112c are disposed.

  FIG. 5 is a block diagram showing the configuration of the emergency light 100 with a built-in LED battery. The LED battery built-in emergency light 100 includes an LED module 110, a unit 120, and a battery 130.

(LED module 110)
As described in the description of FIG. 4, the LED module 110 includes an inspection lighting unit 1000 including at least one inspection LED and an illumination lighting unit 2000 including at least one illumination LED. .

(Unit 120)
The unit 120 includes a rectifier circuit 121, an inspection circuit 122, an illumination lighting circuit 123, a switching circuit 124, a charging circuit 125, and an inspection switch 126.

  The function of each circuit included in the unit 120 will be briefly described by dividing it into a case where commercial power is supplied and a case where no commercial power is supplied (at the time of power failure).

(1. When there is a supply from commercial power: Normal operation)
When there is a supply from a commercial power source, the following operations (1) to (4) are performed.
(1) The rectifier circuit 121 supplies DC power to the inspection circuit 122, the switching circuit 124, and the charging circuit 125.
(2) The inspection circuit 122 operates using a commercial power source as a power source, thereby monitoring at least one of the state of the battery 130 and the lighting lighting unit 2000, and lighting the inspection lighting unit 1000 based on the monitoring result. To control. Specifically, the inspection circuit 122 detects the abnormality of the battery 130 and the abnormality of the lighting unit 2000 (illumination LED), controls the lighting of the inspection LED constituting the inspection lighting unit 1000, and controls the battery 130. And the lighting unit 2000 for lighting (LED for lighting) are displayed. The abnormality of the battery 130 can be determined by, for example, whether the charging voltage is a normal value. The abnormality of the lighting unit 2000 for illumination can be determined by, for example, whether or not the voltage of the circuit formed by the lighting LEDs 112a to 112c constituting the lighting unit 2000 for illumination is a normal value in FIG. The inspection circuit 122 monitors these voltages and detects whether or not there is an abnormality. Note that only the battery 130 may be displayed as normal or abnormal. Or you may make it display whether the lighting part 2000 for illumination (LED for illumination) is normal or abnormal.
(3) The switching circuit 124 in the illumination lighting circuit 123 controls the illumination LED not to be lit.
(4) The charging circuit 125 supplies electricity from the commercial power source to the battery 130 and charges the battery 130.

(2. When the commercial power supply stops regardless of the operation of the inspection switch 126)
When the commercial power is not supplied regardless of the operation of the inspection switch 126, the following operations (1) to (4) are performed.
(1) No power is supplied to the inspection circuit 122, the switching circuit 124, and the charging circuit 125 by the rectifier circuit 121.
(2) The inspection circuit 122 does not operate because there is no power supply.
(3) The switching circuit 124 in the illumination lighting circuit 123 supplies electricity from the battery 130 to the illumination LED (illumination lighting unit 2000) to light it.
(4) The charging circuit 125 does not operate because there is no supply from the rectifier circuit 121.

(3. When the inspection switch 126 is set to the inspection mode by a human operation)
When the inspection switch 126 is set to the “inspection mode” by a human operation, the commercial power supply is cut off as in the case of “the supply of the commercial power supply is stopped regardless of the operation of the inspection switch 126”. The operation in that case is the same as the above-mentioned case “when the commercial power supply is stopped regardless of the operation of the inspection switch 126”.

  A specific circuit configuration of the LED module 110 will be described with reference to FIGS.

  FIG. 6 is a circuit diagram showing a circuit configuration of the LED module 110. 6 corresponds to a circuit diagram of the arrangement shown in the arrow C of FIG. The appearance of the LED module 110 shown in FIG. 6 is as shown in FIG. In the example of FIG. 6, the lighting unit 2000 includes an illumination LED 112a, an illumination LED 112b, and an illumination LED 112c. The inspection lighting unit 1000 includes an inspection LED 111a.

  FIG. 7 is a diagram showing a state in which the circuit configuration of FIG. As described above, FIG. 7 is the same as the arrow C in FIG. The inspection LED 111a emits green light. The three lighting LEDs 112a to 112c emit white light.

  As shown in FIG. 7, the illumination LEDs 112a to 112c are arranged on substantially the same circumference on the mounting surface side 115 of the substrate 114, and the illumination LEDs are arranged on the same circumference at intervals of about 120 degrees. Is done. Further, the inspection LED 111a is disposed in the vicinity of the substantial center of the substantial circumference where the illumination LEDs 112a to 112c are disposed.

  FIG. 8 shows a configuration in which there are four illumination LEDs (white) with respect to FIG. The four illumination LEDs are arranged on substantially the same circumference on the mounting surface side 115 of the substrate 114, and the respective illumination LEDs are arranged on the same circumference at intervals of about 90 degrees. As for the color of the LED, the illumination LED is white and the inspection LED is green. However, there is no particular limitation, and the color of light emitted from the illumination LED and the color of light emitted from the inspection LED are different. The color is not limited as long as it can be distinguished.

FIG. 9 is a diagram illustrating an example in which the inspection circuit 122 monitors only the state of the battery 130 in the LED module 110 illustrated in FIGS. 6 to 8. As shown in FIG. 9, the inspection circuit 122 operates using this as a power source when “commercial power is supplied”. 6 to 8 show a plurality of illumination LEDs, at least one illumination LED is sufficient.
(1) When the inspection circuit 122 detects the normal state of the battery 130, the inspection circuit 122 performs control to turn on (green) the inspection LED 111a of the inspection lighting unit 1000. That is, when green light is visible from the LED lens 113 in FIG. 1, the charging voltage of the battery 130 is normal.
(2) The inspection circuit 122 controls to turn off the inspection LED 111a when an abnormal state of the battery 130 is detected. That is, that is, when no light can be seen from the LED lens 113 of FIG. 1, it indicates that the battery 130 has a voltage abnormality. Thus, since the state of the battery 130 can be confirmed by looking at the LED lens 113 that transmits light emitted when the commercial power supply is shut off, it becomes very easy to see.
(3) When the commercial power supply is interrupted (the right column in FIG. 9), the illumination lighting circuit 123 lights the illumination LED 112a (white). Therefore, white light is emitted from the LED lens 113 of FIG.

FIG. 10 shows the LED module 110 shown in FIGS. 6 to 8, when the inspection circuit 122 is “supplied with commercial power”, in addition to the state of the battery 130, further includes an LED 112 a for illumination. It is a figure which shows the example which monitors the lighting part 2000 for illumination.
(1) As shown in FIG. 10, when the normal state of both the battery 130 and the lighting unit 2000 for lighting is detected, the inspection circuit 122 controls to turn on (green) the inspection LED 111a. In other words, in the LED battery built-in emergency light 100, green light is always visible from the LED lens 113 as long as commercial power is supplied and both the battery 130 and the lighting unit 2000 for lighting are normal.
(2) The inspection circuit 122 performs control to blink the inspection LED 111a when detecting any one of the abnormal states of the battery 130 and the lighting unit 2000 for illumination. As shown in FIG. 10, the inspection circuit 122 slowly turns on the inspection LED 111a when the illumination lighting unit 2000 detects an abnormality.
(3) In addition, when the battery 130 detects that the battery 130 is abnormal, the inspection circuit 122 turns on the inspection LED 111a more quickly than when the illumination lighting unit 2000 is abnormal.
(4) When the inspection circuit 122 detects the abnormal state of both the battery 130 and the lighting unit 2000 for lighting, the inspection circuit 122 performs control to turn off the inspection LED 111a (do not turn on or blink).
(5) When the commercial power supply is shut off (the right column in FIG. 10), the illumination lighting circuit 123 lights the illumination LEDs 112a to 112c in the same manner as in FIG.

Embodiment 2. FIG.
Next, a second embodiment will be described with reference to FIGS. The second embodiment is an embodiment in which the inspection lighting unit 1000 includes two inspection LEDs in the LED battery built-in emergency light 100. In the second embodiment, the first embodiment displays an abnormality by blinking the inspection LED 111a (green), whereas the second inspection LED (green and red) displays an abnormality by “color difference”. It is an embodiment.

  FIG. 11 is a diagram illustrating a circuit configuration of the LED module 110 according to the second embodiment, and corresponds to FIG. 6 according to the first embodiment. In the circuit of FIG. 6, the inspection lighting unit 1000 is composed of only one inspection LED 111a, whereas in FIG. 11, the inspection lighting unit 1000 includes the inspection LED 111a (green) and the inspection LED 111b (red). ) And two inspection LEDs.

  FIG. 12 is a diagram showing a state in which the LEDs having the circuit configuration of FIG. 11 are arranged on the substrate 114, and corresponds to FIG. 7 of the first embodiment. As shown in FIG. 12, the inspection LED 111a emits “green” light, and the inspection LED 111b emits “red” light. The three lighting LEDs 112a to 112c emit white light.

  As shown in FIG. 12, the illumination LEDs 112a to 112c are arranged on the substantially same circumference on the mounting surface side 115 of the substrate 114, and the respective illumination LEDs are arranged at intervals of about 120 degrees on the same circumference. Is done. Further, the inspection LED 111a and the inspection LED 111b are disposed in the vicinity of the substantial center of the substantial circumference where the illumination LEDs 112a to 112c are disposed.

  FIG. 13 shows a configuration in which there are four illumination LEDs (white) with respect to FIG. The four illumination LEDs are arranged on substantially the same circumference on the mounting surface side 115 of the substrate 114, and the respective illumination LEDs are arranged on the same circumference at intervals of about 90 degrees. In addition, about the color development of LED, although LED for illumination is white and two LED for inspection is green and red, it does not specifically limit. Any color can be used as long as the color of the light emitted from the illumination LED, the color of the light emitted from the inspection LED 111a, and the color of the light emitted from the inspection LED 111b can be distinguished.

FIG. 14 shows an example of monitoring the state of the battery 130 and the state of the lighting unit 2000 for lighting when the inspection circuit 122 is “supplied with commercial power” in the LED module 110 shown in FIGS. 11 to 13. FIG. When the inspection circuit 122 detects a normal state of at least one of the lighting unit 2000 and the battery 130, at least one of the inspection LED 111a and the inspection LED 111b is set according to a predetermined setting. Control to turn on the inspection LED. In addition, when the inspection circuit 122 detects an abnormal state of both the lighting unit 2000 for illumination and the battery 130, neither the inspection LED 111a nor the inspection LED 111b is lit. A specific example will be described with reference to FIG.
(1) As shown in FIG. 14, when the inspection circuit 122 detects the normal state of both the battery 130 and the lighting unit 2000 for lighting, only the inspection LED 111a is turned on according to a predetermined setting ( (Green). In other words, as long as the commercial power is supplied to the emergency light 100 with a built-in LED battery and both the battery 130 and the lighting unit 2000 for lighting are normal, green light can always be seen from the LED lens 113.
(2) When the inspection lighting circuit 122 detects that the lighting lighting unit 2000 including the lighting LED 112a and the like out of the battery 130 and the lighting lighting unit 2000 is abnormal, according to a predetermined setting, Both the inspection LED 111a and the inspection LED 111b are turned on. For this reason, yellow-orange light is visible from the LED lens 113.
(3) When the battery 130 detects that the battery 130 is abnormal, the inspection circuit 122 turns on the inspection LED 111b (red) according to a predetermined setting. For this reason, red light can be seen from the LED lens 113.
(4) When the inspection circuit 122 detects the abnormal state of both the battery 130 and the lighting unit 2000 for lighting, the inspection circuit 122 performs control to turn off the inspection LED 111a (do not turn on or blink).
(5) When the commercial power supply is interrupted (the right column in FIG. 14), the illumination lighting circuit 123 lights the illumination LEDs 112a to 112c (white) as in the case of FIG. .

  The LED battery built-in emergency light 100 has been described as a ceiling-embedded type, but the LED battery built-in emergency light 100 is not limited to this. An embodiment in which the lighting fixture includes the emergency light 100 with a built-in LED battery may be used. That is, an embodiment of a lighting fixture including the fixture main body and the LED battery built-in emergency light 100 may be used.

  In the LED module 110 of the above embodiment, since the inspection lighting unit 1000 and the lighting lighting unit 2000 are housed in one package, the lighting state of the inspection lighting unit 1000 can be easily confirmed from the LED lens 113. be able to.

  In the LED module 110 of the above embodiment, each of the inspection lighting unit 1000 and the lighting lighting unit 2000 is composed of at least one LED, so that the module can be reduced in size and power can be saved. it can.

  In the LED module 110 according to the above embodiment, the lighting unit 2000 for illumination is composed of a plurality of illumination LEDs, and the plurality of illumination LEDs are arranged on the substrate 114 on substantially the same circumference. In addition, the inspection LED constituting the inspection lighting unit 1000 is disposed in the vicinity of the substantial center of the substantially circumference where the plurality of illumination LEDs are disposed, so that the brightness for illumination is secured, The LED lens 113 can be easily viewed.

  Since the LED module 110 of the above embodiment includes a plurality of inspection LEDs, it can correspond to various display modes.

  In the emergency light 100 with built-in LED battery according to the above embodiment, the inspection circuit monitors at least one of the battery 130 and the lighting unit 2000 for lighting, and lights the inspection LED in a predetermined lighting mode according to the monitoring result. Or control to turn off the light. Further, since the light of the inspection LED comes out of the LED lens 113 that transmits the light of the illumination LED, the battery 130 or the lighting unit 2000 for illumination becomes easy to see, and the visibility of these states is improved.

  In the above embodiment, a secondary battery, a charging circuit for converting the power of a commercial power source to charge the secondary battery, an LED module having an inspection LED element and an illumination LED element, and the secondary battery An inspection circuit that detects the voltage or current of the battery and lights the inspection LED element to display the state of the secondary battery, and an illumination that converts the power supplied from the power source to light the lighting LED element An emergency lighting device that includes a lighting circuit and a switching circuit that supplies power of the secondary battery to the lighting circuit during a power failure has been described.

  In the above embodiment, the emergency lighting device is described as an LED module in which the inspection LED elements are arranged in a substantially center and the inspection LED elements are arranged in a substantially arc shape centering on the inspection LED elements. did.

  In the above embodiment, the lighting fixture provided with the fixture main body and the emergency lighting device was demonstrated.

1 is an external view of an LED battery built-in emergency light 100 according to Embodiment 1. FIG. FIG. 3 is an assembly diagram of the LED battery built-in emergency light 100 according to the first embodiment. 1 is a block diagram of an LED battery built-in emergency light 100 according to Embodiment 1. FIG. FIG. 3 is a configuration diagram of an LED module 110 in the first embodiment. 1 is a block configuration diagram of an LED battery built-in emergency light 100 according to Embodiment 1. FIG. FIG. 3 is a circuit diagram of the LED module 110 in the first embodiment. FIG. 3 is a layout diagram of LEDs in the first embodiment. FIG. 6 is another example of a substrate layout diagram of LEDs in the first embodiment. FIG. 6 shows LED display by the inspection circuit 122 in the first embodiment. FIG. 10 shows another example of LED display by the inspection circuit 122 in the first embodiment. FIG. 5 is a circuit diagram of an LED module 110 in the second embodiment. The board | substrate arrangement | positioning figure of LED in Embodiment 2. FIG. FIG. 12 is another example of a substrate layout diagram of LEDs in the second embodiment. FIG. 10 shows LED display by the inspection circuit 122 in the second embodiment.

Explanation of symbols

  100 LED battery built-in emergency light, 110 LED module, 111a, 111b inspection LED, 112a, 112b, 112c illumination LED, 113 LED lens, 114 substrate, 115 mounting surface side, 120 unit, 121 rectifier circuit, 122 inspection circuit , 123 illumination lighting circuit, 124 switching circuit, 125 charging circuit, 126 inspection switch, 130 battery, 150 main body, 151 battery holding spring, 152 device mounting spring, 153 lid, 1000 inspection lighting section, 2000 lighting lighting section.

Claims (11)

A secondary battery for charging the power supplied by the commercial power supply;
A lighting unit for inspection that lights with the commercial power source as a power source;
A lighting unit for lighting that uses the secondary battery as a power source;
An inspection circuit for monitoring the state of at least one of the secondary battery and the lighting unit for lighting by operating the commercial power source as a power source, and controlling lighting of the lighting unit for inspection based on a monitoring result When,
An illumination lighting circuit for lighting the lighting unit for lighting using the secondary battery as a power source when the supply of the commercial power supply is interrupted,
The inspection lighting part and the lighting lighting part are:
A lighting device, wherein the lighting device is packaged by the substrate and the lens by being installed on the same surface side of the substrate and being covered with a lens. The inspection lighting part is:
Consists of at least one inspection LED,
The lighting unit for lighting is:
The lighting device according to claim 1, wherein the lighting device includes at least one LED for illumination. The lighting unit for lighting is:
The plurality of illumination LEDs are configured on the substantially same circumference on the surface side of the substrate, and are configured from the plurality of illumination LEDs.
At least one of the inspection LEDs constituting the inspection lighting unit is:
The lighting device according to claim 2, wherein the lighting device is disposed in a vicinity of a substantially center of the substantially circumference where the plurality of LEDs for illumination are disposed. The inspection lighting part is:
The plurality of inspection LEDs are arranged in the vicinity of a substantial center of the substantial circumference where the plurality of illumination LEDs are disposed, and the plurality of inspection LEDs are configured from a plurality of the inspection LEDs. Item 4. The lighting device according to Item 3. The inspection lighting part is:
It is composed of one inspection LED,
The inspection circuit is
The state of the secondary battery is monitored, and when the normal state of the secondary battery is detected as a result of monitoring, the inspection LED is controlled to be turned on, and the abnormal state of the secondary battery is detected. 3. The lighting device according to claim 2, wherein control is performed to turn off the inspection LED. The inspection lighting part is:
It is composed of one inspection LED,
The inspection circuit is
While monitoring both the state of the secondary battery and the lighting unit for lighting, as a result of monitoring, when the normal state of both the secondary battery and the lighting unit for lighting is detected, the inspection LED And when the abnormal state of any one of the secondary battery and the lighting unit for lighting is detected, the inspection LED is caused to blink, and the secondary battery and the lighting unit are controlled. The lighting device according to claim 2, wherein when the abnormal state of both of the lighting units is detected, the inspection LED is controlled to be turned off. The inspection lighting part is:
It consists of a plurality of the inspection LEDs,
The inspection circuit is
It monitors both the state of the secondary battery and the lighting unit for lighting, and is determined in advance when a normal state of at least one of the secondary battery and the lighting unit for lighting is detected as a result of monitoring. When control is performed to turn on at least one of the plurality of inspection LEDs according to the set setting, and an abnormal state of both the lighting unit for lighting and the secondary battery is detected 3. The lighting device according to claim 2, wherein control is performed to turn off all of the plurality of inspection LEDs. A secondary battery for charging the power supplied by the commercial power supply;
By operating with the commercial power source as a power source, at least one of the state of the secondary battery and the lighting unit for lighting that uses the secondary battery as a power source is monitored, and based on the monitoring result, the commercial power source is powered An inspection circuit that controls the lighting of the inspection lighting section that lights up as
In a lighting module used in a lighting device including an illumination lighting circuit that turns on the lighting lighting unit using the secondary battery as a power source when the supply of the commercial power supply is interrupted,
The inspection lighting part;
The lighting unit for lighting;
The inspection lighting unit and the lighting lighting unit are installed on the same surface side, and
An illumination module, wherein the inspection lighting unit installed on the substrate and a lens covering the lighting lighting unit are packaged integrally. The inspection lighting part is:
Consists of at least one inspection LED,
The lighting unit for lighting is:
The illumination module according to claim 8, comprising at least one LED for illumination. The lighting unit for lighting is:
The plurality of illumination LEDs are configured on the substantially same circumference on the surface side of the substrate, and are configured from the plurality of illumination LEDs.
At least one of the inspection LEDs constituting the inspection lighting unit is:
The illumination module according to claim 9, wherein the illumination module is disposed in a vicinity of a substantial center of the substantial circumference where the plurality of illumination LEDs are disposed. The inspection lighting part is:
The plurality of inspection LEDs are arranged in the vicinity of a substantially center of the substantially circumference where the plurality of illumination LEDs are arranged. The illumination module according to 10.

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