JP5977411B1 - Lighting control device - Google Patents

Abstract

An object of the present invention is to make it possible to easily control lighting of a lighting apparatus that is lit when a power failure occurs. Converters 22a and 22b of a lighting control device 14 convert a commercial AC voltage VAC into a DC voltage. The batteries 23a and 23b are charged by the output voltage VA2 of the converter 22b. The control unit 24 determines whether or not the commercial AC voltage VAC has failed due to the output voltage VA1. The control unit 24 generates a drive voltage VLD to be supplied to the lighting fixtures 15a and 15b based on the output voltage VA1 when the commercial AC voltage VAC is not interrupted, and turns on and off the lighting fixtures 13a and 13b. The lighting fixtures 15a and 15b are turned on and off based on the above operation. The control unit 24 generates a drive voltage VLD based on the output voltage of the batteries 23a and 23b when the commercial AC voltage VAC is out of power, and controls lighting of the lighting fixtures 15a and 15b. [Selection] Figure 1

Description

  The present invention relates to a lighting control device.

  Conventionally, various power supply apparatuses that include a battery and supply power when a commercial power failure occurs have been proposed (see, for example, Patent Document 1). The output power of the power supply device is used to turn on the light source, for example.

JP 2013-172508 A

By the way, it is desired to easily control lighting of a lighting fixture that is turned on at the time of a power failure.
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a lighting control device that can easily control lighting of a lighting fixture that lights up at the time of a power failure.

  A lighting control device that solves the above problem is a lighting control device that controls lighting of a first lighting fixture, and includes a first conversion circuit that converts a commercial AC voltage into a first DC voltage, and the commercial AC voltage. A second conversion circuit for converting to a second DC voltage; a storage battery charged by the second DC voltage; and a control unit for controlling lighting of the first lighting fixture; Determining whether or not the commercial AC voltage is out of power based on the first DC voltage, and determining that the commercial AC voltage is not out of power based on a determination result. The first lighting fixture is turned on based on the operation of an external switch that generates a driving voltage to be supplied to the first lighting fixture based on the first lighting fixture and turns on and off the second lighting fixture different from the first lighting fixture. And extinguish, based on the judgment result before Generating the driving voltage for lighting control of the first lighting fixture based on the output voltage of the battery when the commercial AC voltage is determined to be a power failure.

  According to this configuration, the first lighting fixture is controlled to be lighted by the drive voltage generated based on the output voltage of the storage battery when the commercial AC voltage is interrupted. And the 1st lighting fixture is light-controlled based on operation of the external switch which lights and extinguishes the 2nd lighting fixture when the commercial alternating voltage has not stopped. In this way, it is possible to easily control the lighting of the first lighting fixture.

  In the lighting control device described above, it is preferable that the control unit generates the driving voltage based on the determination result so that the first lighting apparatus is gradually lighted brightly when the commercial AC voltage is interrupted.

According to this structure, since the 1st lighting fixture becomes light gradually at the time of a power failure of a commercial alternating voltage, it is reduced that the 1st lighting fixture feels dazzling.
In the lighting control device, the storage battery includes a first battery and a second battery that are charged by the second DC voltage, and the control unit outputs a first output from the first battery. A battery voltage is compared with a threshold voltage, and when the first battery voltage is equal to or higher than the threshold voltage, the drive voltage supplied to the first lighting fixture is generated based on the first battery voltage. The first lighting device is turned on at the first brightness, and when the first battery voltage is lower than the threshold voltage, the first battery is based on the second battery voltage output from the second battery. It is preferable that the first lighting apparatus is lit at a second brightness that is darker than the first brightness by generating the drive voltage.

  According to this configuration, the first lighting fixture is turned on by the first battery and the second battery. Then, the first battery and the second battery are made darker when the first battery is turned on by the second battery than when the first battery is turned on by the first battery. Compared with the case where the first lighting fixture is turned on with the same brightness as the battery, the time for turning on the first lighting fixture becomes longer.

  In the lighting control device described above, the control unit has a switch unit connected to the control unit, and the control unit turns on / off the first lighting fixture based on a short press of the switch unit, It is preferable to change the brightness of the first lighting fixture based on the long press.

  According to this configuration, the brightness of the first lighting fixture can be easily changed by operating the switch unit. For example, a comfortable brightness can be obtained by turning on the first lighting fixture with the first brightness. In addition, by turning on the first lighting fixture with the second brightness, the first lighting fixture can be turned on over a long period of time.

  In the above lighting control device, the lighting control device has a display unit connected to the control unit, and the control unit controls the lighting of the display unit at a predetermined cycle in accordance with the lighting control of the first lighting fixture. The predetermined cycle includes a first period and a second period shorter than the first period, and the control unit causes the first lighting device to be at the first brightness. When lit, the brightness of the second period is darker than the brightness of the first period, and when the first lighting fixture is lit at the second brightness, It is preferable that the brightness in the first period is darker than the brightness in the second period.

  According to this structure, the brightness of a display part changes according to the lighting state of a 1st lighting fixture. For this reason, it is easily grasped that the brightness of the first lighting fixture can be changed. Further, the direction in which the brightness changes when the setting is changed is easily grasped by the brightness of the display unit.

  In the above lighting control device, the control unit determines whether or not the storage battery is abnormal based on an output voltage of the storage battery, and changes the lighting state of the display unit when the storage battery is determined to be abnormal. Is preferred.

According to this configuration, the control unit determines whether or not the storage battery is abnormal. And the abnormality of a storage battery is easily grasped | ascertained by the display form of a display part.
The lighting control device includes an internal switch, and the control unit determines the first AC based on an operation of the internal switch when the commercial AC voltage is determined to be out of power based on the determination result. It is preferable to turn on / off the lighting fixtures.

  According to this configuration, the first lighting fixture can be easily turned on / off during a commercial AC voltage power failure by the internal switch.

  According to the lighting control device of the present invention, it is possible to easily control lighting of a lighting fixture that lights up at the time of a power failure.

1 is a schematic block diagram of a lighting system. The block circuit diagram of a control part. The schematic front view of a lighting control apparatus. (A)-(c) is explanatory drawing which shows the control form of a display part. (A)-(c) is explanatory drawing which shows the control form of a lighting fixture.

Hereinafter, an embodiment will be described.
As shown in FIG. 1, a commercial AC power supply (system power supply) 11 is connected to lighting fixtures 13 a and 13 b (denoted as “L” in the drawing) via an external switch 12. The external switch 12 is installed, for example, on a wall surface in the room. The lighting fixtures 13a and 13b are, for example, lamps installed on the indoor ceiling. The driving voltage VLA is supplied to the lighting fixtures 13a and 13b by turning on and off the external switch 12. When the external switch 12 is turned on, the commercial AC voltage VAC is supplied as the drive voltage VLA to the lighting fixtures 13a and 13b. When the external switch 12 is turned off, the driving voltage VLA based on the commercial AC voltage VAC is not supplied to the lighting fixtures 13a and 13b. The lighting fixtures 13a and 13b are turned on by the commercial AC voltage VAC supplied based on the ON operation of the external switch 12, and are turned off based on the OFF operation of the external switch 12.

  The commercial AC power supply 11 is connected to the lighting control device 14. The lighting control device 14 is connected to lighting fixtures 15a and 15b (denoted as “L” in the drawing). The lighting control device 14 is installed, for example, on a wall surface in the room. The lighting fixtures 15a and 15b are installed, for example, on the indoor ceiling, similarly to the lighting fixtures 13a and 13b. The lighting fixtures 15a and 15b are, for example, LED (Light Emitting Diode) lamps. The lighting fixtures 15a and 15b are lit based on the DC drive voltage VLD supplied from the lighting control device 14.

  The lighting control device 14 includes batteries 23a and 23b described later. The lighting control device 14 charges the batteries 23 a and 23 b based on the commercial AC voltage supplied from the commercial AC power supply 11. And the lighting control apparatus 14 operate | moves based on the commercial alternating voltage or the output voltage of battery 23a, 23b.

  The lighting control device 14 is connected to the external switch 12. The lighting control device 14 detects whether or not the commercial AC voltage VAC (drive voltage VLA) is supplied to the lighting fixtures 13 a and 13 b in accordance with the operation of the external switch 12. Then, the lighting control device 14 turns on / off the lighting fixtures 15a and 15b based on the detection result. For example, when the external switch 12 is turned on and the commercial AC voltage VAC (driving voltage VLA) is supplied to the lighting fixtures 13a and 13b, that is, when the lighting fixtures 13a and 13b are turned on, the lighting control device 14 sets the lighting fixture 15a. , 15b are lit. On the other hand, when the external switch 12 is turned off and the commercial AC voltage VAC (driving voltage VLA) is not supplied to the lighting fixtures 13a and 13b, that is, when the lighting fixtures 13a and 13b are turned off, the lighting control device 14 turns on the lighting fixture 15a. , 15b are turned off. That is, the lighting fixtures 13a, 13b, 15a, and 15b are turned on / off by turning on / off the external switch 12.

  The lighting control device 14 has a function of detecting a power failure of the commercial AC voltage VAC. When the commercial AC voltage VAC fails, the lighting control device 14 operates based on the output voltages of the batteries 23a and 23b. When the commercial AC voltage VAC fails, the lighting fixtures 13a and 13b are turned off. When the lighting control device 14 detects a power failure of the commercial AC voltage VAC, the lighting fixtures 15a and 15b are turned on. Therefore, at the time of a power failure, the room is illuminated by the lighting fixtures 15a and 15b that the lighting control device 14 lights.

The lighting control device 14 will be described in detail.
The lighting control device 14 includes a main switch 21, converters 22 a and 22 b, batteries 23 a and 23 b, a control unit 24, and an operation switch 27. The control unit 24 includes a control circuit 25 and a switch circuit 26. The operation switch 27 has a switch unit 28 and a display unit 29.

  As shown in FIG. 3, the casing 20 of the lighting control device 14 is formed in a rectangular parallelepiped shape and is installed on a wall surface in the room. A main switch 21 and an operation switch 27 are disposed on the front panel 20F of the housing 20. The housing 20 accommodates converters 22a and 22b shown in FIG.

As shown in FIG. 1, the input side terminal of the main switch 21 is connected to the commercial AC power supply 11, and the output side terminal of the main switch 21 is connected to converters 22a and 22b.
The main switch 21 is, for example, a circuit protector and has a switch function and a protection function. When the main switch 21 is turned on, commercial AC voltage is supplied to the converters 22a and 22b. Further, the supply of the commercial AC voltage to the converters 22a and 22b is stopped by turning off the main switch 21. The main switch 21 is turned off by the overcurrent protection function and stops supplying the commercial AC voltage.

  The converter 22a is a so-called AC-DC converter (AC / DC converter) that converts a commercial AC voltage into a predetermined DC voltage. The output voltage VA1 of the converter 22a is supplied to the control unit 24. That is, the output voltage VA1 of the converter 22a is a drive voltage of the control unit 24. In the following description, the drive voltage VA1 may be used.

  The converter 22b is a so-called AC-DC converter (AC / DC converter) that converts a commercial AC voltage into a predetermined DC voltage. The output voltage VA2 of the converter 22b is supplied to the batteries 23a and 23b. Battery 23a, 23b is secondary batteries, such as a lithium ion storage battery, for example. Batteries 23a and 23b store output voltage VA2 of converter 22b. That is, the output voltage VA2 of the converter 22b is a charging voltage for the batteries 23a and 23b. In the following description, the charging voltage VA2 may be used.

  The batteries 23a and 23b charge the output voltage VA2 of the converter 22b. The batteries 23a and 23b do not perform a charging operation when the output voltage VA2 of the converter 22b is equal to or higher than a predetermined voltage. The batteries 23a and 23b charge the output voltage VA2 when the output voltage VA2 becomes equal to or higher than a predetermined voltage after the output voltage VA2 of the converter 22b becomes equal to or lower than the predetermined voltage.

  In the present embodiment, the batteries 23a and 23b have the same characteristics. That is, in full charge, the output voltages VB1 and VB2 of the batteries 23a and 23b are equal to each other. Output voltages VB1 and VB2 of the batteries 23a and 23b are supplied to the control unit 24. These output voltages VB1 and VB2 may be referred to as battery voltages VB1 and VB2 in the following description. That is, the drive voltage VA1 and the battery voltages VB1 and VB2 are supplied to the control unit 24.

  The control unit 24 operates based on the drive voltage VA1 and the battery voltages VB1 and VB2. For example, the control unit 24 operates based on the highest voltage among the drive voltage VA1 and the battery voltages VB1, VB2. Converter 22a generates drive voltage VA1 higher than output voltages VB1 and VB2 of batteries 23a and 23b. For example, the drive voltage VA1 is 24 volts (V), and the output voltages VB1, VB2 of the batteries 23a, 23b are 21V.

The control unit 24 includes a control circuit 25 and a switch circuit 26.
The control circuit 25 is supplied with a drive voltage VA1 and battery voltages VB1 and VB2. The control circuit 25 operates based on any one of the drive voltage VA1 and the battery voltages VB1 and VB2.

  The switch circuit 26 is supplied with a drive voltage VA1 and battery voltages VB1 and VB2. Switch circuit 26 includes a switch unit corresponding to drive voltage VA1 and battery voltages VB1, VB2. Each switch unit is turned on / off in response to a control signal supplied from the control circuit 25. A driving voltage VLD based on the voltage supplied to the switched switch unit is supplied to the lighting fixtures 15a and 15b. The lighting fixtures 15a and 15b are turned on based on the supplied drive voltage VLD.

  An operation switch 27 is connected to the control circuit 25. The operation switch 27 includes a switch unit 28 and a display unit 29. The switch unit 28 is, for example, a push switch. The display unit 29 is disposed so as to illuminate the operation surface of the switch unit 28.

  The control circuit 25 changes the operation information based on the on / off operation of the switch unit 28. The operation information of the control circuit 25 is information for setting the operation of the lighting fixtures 15a and 15b at the time of a power failure. The control circuit controls the switch circuit 26 according to the operation information and the configuration and state of the own device (lighting control device 14). The configuration of the own device is, for example, the number of mounted batteries and the number of connected lighting fixtures. The state of the device itself is, for example, the remaining battery level (remaining voltage).

  The control circuit 25 controls turning on / off the display unit 29 according to the operation information. For example, the control circuit 25 controls the lighting interval and the lighting luminance according to the operation information. Therefore, the operation information can be grasped according to the state of the display unit 29. When the operation information is changed, the change of the operation information can be confirmed by the state of the display unit 29.

FIG. 2 is a block circuit diagram illustrating an example of the configuration of the control unit 24.
The control unit 24 includes a control circuit 25 and a switch circuit 26.
The control circuit 25 includes a central processing unit (CPU) 31, a regulator 32, voltage dividing circuits 33 a to 33 c, a detection voltage generation circuit 34, and a switch connection circuit 35. The control part 24 is comprised by the electronic component mounted in the single or several printed circuit board, for example. Further, a connector connected to the converter 22a and the batteries 23a and 23b shown in FIG. 1 is mounted on the printed board.

  The drive voltage VA1 is supplied to the first terminal of the connector CN11 of the control unit 24, and the second terminal of the connector CN11 is connected to the ground GND. The battery voltage VB1 is supplied to the first terminal of the connector CN12 of the control unit 24, and the second terminal of the connector CN12 is connected to the ground GND. The battery voltage VB2 is supplied to the first terminal of the connector CN13 of the control unit 24, and the second terminal of the connector CN13 is connected to the ground GND.

  The first terminal of the connector CN11 is connected to the anode of the diode D11. The first terminal of the connector CN12 is connected to the anode of the diode D12. The first terminal of the connector CN13 is connected to the anode of the diode D13. The cathodes of the diodes D <b> 11 to D <b> 13 are connected to each other, and the connection point is connected to the input terminal of the regulator 32. Therefore, the highest voltage among the drive voltage VA1 and the battery voltages VB1 and VB2 is supplied to the regulator 32 as the DC voltage VS1.

  The regulator 32 is a constant voltage circuit, and generates a constant power supply voltage Vcc based on the DC voltage VS1. The power supply voltage Vcc is supplied to a central processing unit (CPU) 31. That is, the regulator 32 generates the power supply voltage Vcc having a voltage value corresponding to the CPU 31. The voltage value of power supply voltage Vcc is, for example, 5V. The CPU 31 operates with this power supply voltage Vcc.

The first terminals of the connectors CN11, CN12, and CN13 are connected to the voltage dividing circuits 33a, 33b, and 33c, respectively.
The voltage dividing circuit 33a includes a plurality of resistance elements connected in series between the first terminal of the connector CN11 and the ground GND. The voltage dividing circuit 33a divides the drive voltage VA1 at a predetermined ratio according to the resistance value of the resistance element to generate a divided voltage Vda. Similarly, the voltage dividing circuits 33b and 33c each include a plurality of resistance elements connected in series between the first terminals of the connectors CN12 and CN13 and the ground GND. The voltage dividing circuits 33b and 33c divide the battery voltages VB1 and VB2 at a ratio corresponding to the resistance value of the resistance element to generate the divided voltages Vd1 and Vd2. For example, the voltage dividing ratios of the voltage dividing circuits 33a to 33c are set to be equal to each other.

  The divided voltages Vda, Vd1, and Vd2 are supplied to the CPU 31. The CPU 31 detects the voltage values of the drive voltage VA1 and the battery voltages VB1, VB2 based on the divided voltages Vda, Vd1, Vd2. For example, the CPU 31 has an analog-digital conversion circuit (ADC), and obtains a digital value by conversion. The CPU 31 detects a power failure of the commercial AC voltage VAC based on the detected voltage value of the drive voltage VA1.

  The CPU 31 detects the remaining amount of the battery 23a shown in FIG. 1 based on the detected voltage value of the battery voltage VB1. Similarly, the CPU 31 detects the remaining amount of the battery 23b shown in FIG. 1 based on the detected voltage value of the battery voltage VB2. Further, the CPU 31 determines abnormality of the batteries 23a and 23b based on the detected voltage values of the battery voltages VB1 and VB2.

The switch circuit 26 includes three switch circuits SW21, SW22, SW23, three diodes D21, D22, D23, and a protection element F21.
Drive voltage VA1 and battery voltages VB1, VB2 are supplied to switch circuits SW21, SW22, SW23, respectively. The output terminals of the switch circuits SW21 to SW23 are connected to the anodes of the diodes D21 to D23, respectively. The cathodes of the diodes D21 to D23 are connected to each other, the connection point is connected to the first terminal of the protection element F21, and the second terminal of the protection element F21 is connected to the first terminal of the connector CN2. The protective element F21 is, for example, a self-reset type fuse. A second terminal of the connector CN2 is connected to the ground GND. The lighting fixtures 15a and 15b shown in FIG. 1 are connected to the connector CN2.

  A control signal SCa is supplied from the CPU 31 to the switch circuit SW21. The switch circuit SW21 includes a transistor (bipolar transistor, MOS transistor) and a resistor. The switch circuit SW21 is turned on / off based on the control signal SCa. A voltage corresponding to the drive voltage VA1 is supplied to the diode D21 through the switched switch circuit SW21.

  Control signals SC1 and SC2 are supplied from the CPU 31 to the switch circuits SW22 and SW23. The switch circuits SW22 and SW23 are turned on / off based on the control signals SC1 and SC2, similarly to the switch circuit SW21. Voltages corresponding to the battery voltages VB1 and VB2 are supplied to the diodes D22 and D23 via the switch circuits SW22 and SW23 that are turned on. The voltage that has passed through the diodes D21 to D23 is output as the drive voltage VLD to the connector CN2 via the protective element F21. The drive voltage VLD is supplied to the lighting fixtures 15a and 15b (see FIG. 1) connected to the connector CN2.

  CPU31 controls the voltage supplied to lighting fixture 15a, 15b (refer FIG. 1) based on divided voltage Vda, Vd1, Vd2. For example, the CPU 31 controls the switch circuit SW21 of the switch circuit 26 by the control signal SCa when the commercial AC voltage VAC is supplied based on the divided voltage Vda, that is, when the commercial AC voltage VAC has not failed.

  The CPU 31 is connected to the connector CN3 via the detection voltage generation circuit 34. The connector CN3 is connected to the external switch 12 shown in FIG. A commercial AC voltage VAC (drive voltage VLA) is supplied to the connector CN3 in accordance with the operation of the external switch 12. The detection voltage generation circuit 34 generates a detection voltage Vk corresponding to the commercial AC voltage VAC.

  The first terminal of the connector CN3 is connected to the first terminal of the resistor R31, and the second terminal of the resistor R31 is connected to the anode of the diode D31. The cathode of the diode D31 is connected to the input terminal of the photocoupler PC31. Photocoupler PC31 includes a light emitting element (light emitting diode) and a light receiving element (phototransistor). The first output terminal of the photocoupler PC31 is pulled up to the power supply voltage Vcc via the resistor R32, and the second output terminal of the photocoupler PC31 is connected to the ground GND. The first output terminal of the photocoupler PC31 is connected to the base of the transistor T31.

  Transistor T31 is, for example, an npn transistor. The collector of the transistor T31 is pulled up to the power supply voltage Vcc via the resistor R33, and the emitter of the transistor T31 is connected to the ground GND. The collector of the transistor T31 is connected to the anode of the diode D32. The cathode of the diode D32 is connected to the first electrode of the capacitor C31, and the second electrode of the capacitor C31 is connected to the ground GND. Capacitor C31 is, for example, an electrolytic capacitor. The cathode of the diode D32 is connected to the first terminal of the resistor R34, and the second terminal of the resistor R34 is connected to the ground GND. Further, the cathode of the diode D32 is connected to the CPU 31.

  The CPU 31 inputs the detection voltage Vk rectified by the diode D32 and smoothed by the capacitor C31. The voltage value of the detection voltage Vk changes according to the state of the external switch 12 shown in FIG. For example, when the external switch 12 is turned on, the voltage value of the detection voltage Vk is, for example, 3V. On the other hand, when the external switch 12 is turned off, the voltage value of the detection voltage Vk is 0V.

  The CPU 31 obtains a digital value obtained by converting the detection voltage Vk, similarly to the divided voltage Vda and the like. The CPU 31 determines the state (on state / off state) of the external switch 12 based on the voltage value of the detection voltage Vk. When the external switch 12 is in the on state, the CPU 31 lights the lighting fixtures 15a and 15b shown in FIG. Further, when the commercial AC voltage VAC is supplied and the external switch 12 is in the OFF state, the CPU 31 turns off the lighting fixtures 15a and 15b shown in FIG.

  The CPU 31 is connected to the connector CN4 via the switch connection circuit 35. The CPU 31 is connected to the first terminal of the connector CN4 and inputs the detection signal S28. The first terminal of the connector CN4 is pulled up to the power supply voltage Vcc by a resistor R41. A second terminal of the connector CN4 is connected to the ground GND. The switch unit 28 shown in FIG. 1 is connected between the first terminal and the second terminal of the connector CN4. When the switch unit 28 is off, the detection signal S28 is at the power supply voltage Vcc level (H level). When the switch unit 28 is turned on, the detection signal S28 becomes the ground GND level (L level). The CPU 31 determines the state (on state / off state) of the switch unit 28 shown in FIG. 1 based on the level of the detection signal S28.

  The CPU 31 is connected to the base of the transistor T41 and outputs a drive signal SC41 to the base. Transistor T41 is, for example, an NPN transistor. The collector of the transistor T41 is connected to the third terminal of the connector CN4 via the resistor R42.

  The CPU 31 is connected to the base of the transistor T42 and outputs a drive signal SC42 to the base. The transistor T42 is, for example, an NPN transistor. The collector of the transistor T42 is directly connected to the third terminal of the connector CN4. The DC voltage VS1 is supplied to the fourth terminal of the connector CN4. A display unit 29 shown in FIG. 1 is connected between the third terminal and the fourth terminal of the connector CN4.

  The CPU 31 turns on the transistor T41 by the drive signal SC41. Then, current flows from the display unit 29 shown in FIG. 1 via the connector CN4, the resistor R42, and the transistor T41, and the display unit 29 is lit. Further, the CPU 31 turns on the transistor T42 by the drive signal SC42. Then, current flows from the display unit 29 shown in FIG. 1 via the connector CN4 and the transistor T42, and the display unit 29 is lit.

  When the transistor T41 is turned on, the amount of current flowing through the display unit 29 in FIG. 1 is smaller than that when the transistor T42 is turned on. Therefore, by selectively turning on the transistors T41 and T42, the brightness (luminance) when the display unit 29 shown in FIG. 1 is turned on can be changed.

4A to 4C show the state of the display unit 29. FIG.
For example, when the transistors T41 and T42 are turned off, the display unit 29 is turned off as shown in FIG. When the transistor T41 is turned on and the transistor T42 is turned off, as shown in FIG. 4B, the display unit 29 is lit. When the transistor T41 is turned off and the transistor T42 is turned on, as shown in FIG. 4C, the display unit 29 is lit brighter than the state shown in FIG.

Next, processing executed by the CPU 31 will be described.
The CPU 31 has a memory 41 and a timer 42.
The memory 41 includes a program memory and a data memory. An operation program for the CPU 31 is stored in the program memory. The data memory includes a rewritable volatile memory and an electrically rewritable nonvolatile memory. In the volatile memory, temporary data in the execution of the CPU 31 is stored. The work information is stored in the nonvolatile memory. The CPU 31 executes an operation program stored in the program memory. Then, the CPU 31 controls the lighting fixtures 15 a and 15 b and the display unit 29 shown in FIG. 1 based on the work information stored in the memory 41. Further, the CPU 31 changes the work information based on the operation of the switch unit 28 shown in FIG.

  The CPU 31 controls the drive voltage VLD supplied to the lighting fixtures 15a and 15b via the switch circuit SW21 to which the drive voltage VA1 is supplied. The CPU 31 supplies, for example, a pulsed control signal SCa to the switch circuit SW21. Operation information is stored in the memory 41 of the CPU 31. The operation information includes the first illuminance information for lighting the luminaires 15a and 15b shown in FIG. 1 at a predetermined brightness, and the luminaires 15a and 15b at a lower brightness (darker) than the first illuminance information. 2nd illumination intensity information to light is included. The CPU 31 outputs a control signal SCa having a pulse width corresponding to the first illuminance information or the second illuminance information. The switch circuit SW21 is turned on / off in response to the control signal SCa. Thereby, the pulsed drive voltage VLD is supplied to the lighting fixtures 15a and 15b shown in FIG. 1, and the lighting fixtures 15a and 15b are turned on by the driving voltage VLD.

  Similarly, the CPU 31 controls the drive voltage VLD supplied to the lighting fixtures 15a and 15b via the switch circuits SW22 and SW23 to which the battery voltages VB1 and VB2 are supplied. The CPU 31 outputs control signals SC1 and SC2 having a pulse width (duty) corresponding to the first illuminance information or the second illuminance information. The switch circuits SW22 and SW23 are turned on / off in response to the control signals SC1 and SC2. Thereby, the pulsed drive voltage VLD is supplied to the lighting fixtures 15a and 15b shown in FIG. 1, and the lighting fixtures 15a and 15b are turned on.

  That is, when the commercial AC voltage VAC is supplied, the CPU 31 performs on / off control of the switch circuit SW21 to which the drive voltage VA1 is supplied by the control signal SCa, and generates the drive voltage VLD. The lighting fixtures 15a and 15b shown in FIG. 1 are turned on by the drive voltage VLD.

  When the commercial AC voltage VAC is not supplied, that is, when there is a power failure, the switch circuits SW22 and SW23 to which the battery voltages VB1 and VB2 are supplied are on / off controlled by the control signals SC1 and SC2 to generate the drive voltage VLD. With this drive voltage VLD, the lighting fixtures 15a and 15b shown in FIG. 1 are lit with brightness according to the first illuminance information or the second illuminance information.

Fig.5 (a) shows the light extinction state of the lighting fixture 15a.
FIG.5 (c) shows the lighting fixture 15a lighted based on 1st illumination intensity information, and FIG.5 (b) shows the lighting fixture 15a lighted based on 2nd lighting information. The same applies to the lighting fixture 15b shown in FIG.

  By lighting the lighting fixture 15a in the state shown in FIG. 5C (referred to as “full lighting”), the room is brightly illuminated. This makes it possible to spend comfortably indoors. When the lighting fixture 15a is turned on in the state shown in FIG. 5B (referred to as “eco-lighting”), the power consumption is reduced compared to the state shown in FIG. For this reason, compared with the state shown in FIG.5 (c), the lighting time of the lighting fixture 15b becomes long in the state (eco lighting) shown in FIG.5 (b).

  The CPU 31 controls lighting of the lighting fixtures 15 a and 15 b based on the operation of the switch unit 28. For example, the CPU 31 monitors the time when the switch unit 28 is turned on. Then, the CPU 31 determines that the ON time is shorter than the predetermined threshold value as a short press, and determines that the ON time is longer than the threshold value as a long press. And CPU31 switches lighting fixture 15a, 15b lighting and light extinction, when it determines with a short press. That is, every time the switch unit 28 is operated, the CPU 31 alternately switches on and off the lighting fixtures 15a and 15b. Thereby, the lighting fixtures 15a and 15b can be turned on or off at an arbitrary timing.

  Moreover, CPU31 switches the brightness of lighting fixture 15a, 15b based on operation of the switch part 28. FIG. That is, every time the switch unit 28 is operated, the CPU 31 switches the parameter (illuminance information) used for controlling the lighting fixtures 15a and 15b alternately between the first illuminance information and the second illuminance information.

  For example, when the lighting fixture 15a is turned off (see FIG. 5A), the state is changed to the state shown in FIG. When the lighting fixture 15a is turned on in the state shown in FIG. 5C (full lighting), the state shown in FIG. 5A, that is, the lighting fixture 15a is turned off by short pressing of the switch unit 28. .

  Further, when the lighting fixture 15a is turned on in the state shown in FIG. 5C, the state is changed to the state shown in FIG. When the lighting fixture 15a is turned on in the state shown in FIG. 5B (eco-lit), the state shown in FIG. 5A, that is, the lighting fixture 15a is turned off by pressing the switch unit 28 for a short time. . The same applies to the lighting fixture 15b.

Thus, the lighting state of the lighting fixtures 15a and 15b can be easily changed by operating the switch unit 28.
And CPU31 changes the brightness of the display part 29 based on the parameter (illuminance information) used for control of lighting fixture 15a, 15b. For example, the lighting fixtures 15a and 15b are turned on according to the first illuminance information. At this time, the CPU 31 darkens the display unit 29 for a predetermined time (for example, 1 second) every predetermined interval (for example, every 15 seconds). As shown in FIG. 2, the CPU 31 is connected to transistors T41 and T42. The CPU 31 turns on the transistor T42 and turns off the transistor T41. Thereby, the display part 29 lights in the state shown in FIG.4 (c). Next, the CPU 31 turns off the transistor T42 and turns on the transistor T41. Thereby, the display part 29 lights in the state shown in FIG.4 (b).

  Further, the lighting fixtures 15a and 15b are turned on according to the second illuminance information. At this time, the CPU 31 brightens the display unit 29 for a predetermined time (for example, 1 second) every predetermined interval (for example, 15 seconds).

  That is, when the lighting fixtures 15a and 15b are lit brightly, the display unit 29 is periodically darkened. At this time, when the switch unit 28 is pressed long, the lighting fixtures 15a and 15b are lit darkly. When the lighting fixtures 15a and 15b are lit darkly, the display unit 29 is periodically brightened. At this time, when the switch unit 28 is pressed for a short time, the lighting fixtures 15a and 15b are lit brightly. Therefore, the CPU 31 indicates that the brightness of the lighting fixtures 15a and 15b can be changed by periodically changing the brightness of the display unit 29.

  Thus, it can be understood that the brightness of the lighting fixtures 15a and 15b can be adjusted by changing the brightness of the display unit 29. Further, the direction in which the brightness of the lighting fixtures 15a and 15b changes (whether it becomes darker or brighter) can be easily grasped by the brightness of the display unit 29.

When the power failure is detected, the CPU 31 sequentially uses the two batteries 23a and 23b to turn on the lighting fixtures 15a and 15b.
More specifically, when the CPU 31 detects a power failure of the commercial AC voltage VAC based on the divided voltage Vda, the CPU 31 first turns on the lighting fixtures 15a and 15b based on the battery voltage VB1 of the battery 23a. At this time, the CPU 31 changes the pulse width of the control signal SCa from a predetermined value (for example, 0) to a value corresponding to the first illuminance information. For example, the CPU 31 changes the pulse width of the control signal SCa in stages. In this embodiment, the brightness of the lighting fixtures 15a and 15b is changed in two stages. Thereby, lighting fixture 15a, 15b becomes bright in steps. For example, when a power failure occurs at night, it may feel dazzling if the lighting fixtures 15a and 15b are lit brightly. On the other hand, in this embodiment, since the lighting fixtures 15a and 15b become bright gradually, it is less likely to feel dazzling.

  Then, the CPU 31 detects the remaining amount of the battery 23a based on the divided voltage Vd1. When the remaining amount of the battery 23a becomes lower than a predetermined value, the CPU 31 outputs a control signal SC1 of a predetermined level (eg, ground GND level), and turns off the switch circuit SW22. The predetermined value is set according to the minimum value of the voltage value at which the lighting fixtures 15a and 15b can be turned on by the output voltage VB1 of the battery 23a. Then, the CPU 31 outputs a control signal SC2 with a pulse width corresponding to the second illuminance information. Thereby, CPU31 lights lighting fixture 15a, 15b with the brightness according to 2nd illumination intensity information by output voltage VB2 of the battery 23b.

  Then, the CPU 31 changes the lighting mode of the display unit 29. For example, the CPU 31 periodically turns off the display unit 29. Specifically, the CPU 31 lights the display unit 29 darkly in the state shown in FIG. Then, the CPU 31 turns off the display unit 29 every predetermined interval (for example, 15 seconds) for a predetermined time (for example, 1 second). Since the display unit 29 is periodically turned off in this manner, it is possible to easily grasp that the lighting fixtures 15a and 15b are turned on by the second battery 23b.

  Further, the CPU 31 detects the remaining amount of the battery 23b based on the divided voltage Vd2. When the remaining amount of the battery 23b becomes lower than a predetermined value, the CPU 31 outputs a control signal SC2 of a predetermined level (eg, ground GND level), and turns off the switch circuit SW23. The predetermined value is set according to the minimum value of the voltage value at which the lighting fixtures 15a and 15b can be turned on by the output voltage VB2 of the battery 23b. Then, the CPU 31 changes the lighting mode of the display unit 29.

  For example, the CPU 31 periodically turns off the display unit 29 a plurality of times. Specifically, the CPU 31 lights the display unit 29 darkly in the state shown in FIG. Then, the CPU 31 turns off the display unit 29 a predetermined number of times (for example, twice) every predetermined interval (for example, 15 seconds). The turn-off time is, for example, 0.5 seconds, and the turn-off interval is, for example, 0.5 seconds. As described above, when the display unit 29 is periodically turned off a plurality of times, it is possible to easily grasp that the remaining amount of the battery 23b is reduced and the lighting fixtures 15a and 15b cannot be turned on.

  As described above, the CPU 31 determines whether or not the battery 23a is abnormal. The battery 23a is charged with the output voltage VA2 output from the converter 22b shown in FIG. 1 based on the supply of the commercial AC voltage VAC. The output voltage VB1 of the battery 23a changes according to the charge amount of the battery 23a. The output voltage VB1 of the battery 23a becomes higher than a predetermined threshold voltage when a predetermined time has elapsed from the start of charging. Therefore, the CPU 31 determines that the battery 23a is abnormal when the output voltage VB1 of the battery 23a does not exceed the threshold voltage after a predetermined time has elapsed.

  And CPU31 changes the lighting form of the display part 29, when it determines with the battery 23a being abnormal. For example, the CPU 31 lights the display unit 29 brightly in the state shown in FIG. Then, the CPU 31 turns off the display unit 29 once every predetermined interval (for example, 15 seconds). As described above, the state in which the display unit 29 is lit brightly and the state in which the display unit 29 is turned off are periodically repeated, so that the abnormality of the battery 23a can be easily grasped.

  Similarly, the CPU 31 determines whether or not the battery 23b is abnormal. And CPU31 changes the lighting form of the display part 29, when it determines with the battery 23b being abnormal. For example, the CPU 31 lights the display unit 29 brightly in the state shown in FIG. Then, the CPU 31 turns off the display unit 29 a plurality of times (for example, twice) at predetermined intervals (for example, 15 seconds). The turn-off time is, for example, 0.5 seconds, and the turn-off interval is, for example, 0.5 seconds. As described above, the state in which the display unit 29 is lit brightly and the state in which the display unit 29 is turned off a plurality of times are periodically repeated, so that the abnormality of the battery 23b can be easily grasped.

As described above, according to the present embodiment, the following effects can be obtained.
(1) The lighting control device 14 includes converters 22a and 22b, batteries 23a and 23b, a control unit 24, and operation switches 27. The operation switch 27 has a switch unit 28 and a display unit 29. Converter 22a converts commercial AC voltage VAC into drive voltage VA1. Converter 22b converts commercial AC voltage VAC into output voltage VA2. The batteries 23a and 23b are charged by the output voltage VA2 of the converter 22b. The control unit 24 determines whether or not the commercial AC voltage VAC has failed due to the drive voltage VA1, and based on the drive voltage VA1 when determined that the commercial AC voltage VAC has not failed based on the determination result. Drive voltage VLD to be supplied to the lighting fixtures 15a and 15b. The lighting fixtures 15a and 15b are turned on and off based on the operation of the external switch 12 that turns on and off the lighting fixtures 13a and 13b. Further, when the control unit 24 determines that the commercial AC voltage VAC has failed due to the determination result, the control unit 24 generates the drive voltage VLD based on the output voltage of the batteries 23a and 23b, and controls the lighting fixtures 15a and 15b to be turned on. To do.

  Accordingly, the lighting fixtures 15a and 15b are controlled to be turned on by the drive voltage VLD generated based on the output voltages of the batteries 23a and 23b when the commercial AC voltage VAC is interrupted. The lighting fixtures 15a and 15b are controlled to be turned on based on the operation of the external switch 12 that turns on and off the lighting fixtures 13a and 13b when the commercial AC voltage VAC is not interrupted. In this way, it is possible to easily control lighting of the lighting fixtures 15a and 15b.

  (2) Based on the determination result, the control unit 24 generates the drive voltage VLD so that the lighting fixtures 15a and 15b are lit gradually and brightly at the time of a power failure of the commercial AC voltage VAC. Therefore, since the lighting fixtures 15a and 15b gradually become bright at the time of a power failure of the commercial AC voltage VAC, it can be reduced that the lighting fixtures 15a and 15b are felt dazzling.

  (3) The batteries 23a and 23b include a battery 23a and a battery 23b that are charged by the output voltage VA2. The control unit 24 compares the battery voltage VB1 output from the battery 23a with a threshold voltage, and when the battery voltage VB1 is equal to or higher than the threshold voltage, the drive voltage supplied to the lighting fixtures 15a and 15b based on the battery voltage VB1. VLD is produced | generated and lighting fixture 15a, 15b is lighted by 1st brightness. In addition, when the battery voltage VB1 is lower than the threshold voltage, the control unit 24 generates the drive voltage VLD based on the battery voltage VB2 output from the battery 23b, so that the second brightness is darker than the first brightness. The lighting fixtures 15a and 15b are turned on. Therefore, the lighting fixtures 15a and 15b can be turned on by the battery 23a and the battery 23b. And the brightness when lighting the lighting fixtures 15a and 15b with the battery 23b is made darker than the brightness when the lighting fixtures 15a and 15b are turned on with the battery 23a, so that the battery 23a and the battery 23b have the same brightness. Compared with the case where the lighting fixtures 15a and 15b are turned on, the time for lighting the lighting fixtures 15a and 15b can be lengthened.

  (4) Based on the operation of the switch unit 28, the control unit 24 turns on and off the lighting fixtures 15a and 15b, and the brightness of the lit lighting fixtures 15a and 15b every time the switch unit 28 is pressed for a long time. The first brightness and the second brightness are alternately switched. Therefore, the brightness of the lighting fixtures 15a and 15b can be easily changed by operating the switch unit 28. A comfortable brightness can be obtained by lighting the lighting fixtures 15a and 15b with the first brightness. Moreover, lighting fixture 15a, 15b can be lighted over a long period of time by lighting lighting fixture 15a, 15b with 2nd brightness.

  (5) The control unit 24 controls the lighting of the display unit 29 at a predetermined cycle in accordance with the lighting control of the lighting fixtures 15a and 15b. The predetermined cycle includes a first period and a second period shorter than the first period. The control unit 24 makes the brightness in the second period darker than the brightness in the first period when the lighting fixtures 15a and 15b are lit at the first brightness. Moreover, the control part 24 makes the brightness of a 1st period darker than the brightness of a 2nd period, when the lighting fixtures 15a and 15b are lighted by 2nd brightness. Therefore, the brightness of the display unit 29 changes according to the lighting state of the lighting fixtures 15a and 15b. For this reason, it can grasp | ascertain easily that the brightness of lighting fixture 15a, 15b can be changed. Further, the direction in which the brightness changes when the setting is changed can be easily grasped by the brightness of the display unit 29.

  (6) The control unit 24 turns on / off the lighting fixtures 15a and 15b based on the operation of the switch unit 28 during a power failure of the commercial AC voltage VAC. Therefore, the luminaires 15a and 15b can be easily turned on / off by the switch unit 28 at the time of a power failure of the commercial AC voltage VAC. Then, by turning off the lighting fixtures 15a and 15b, the power consumption of the batteries 23a and 23b is reduced, and it is possible to lengthen the period during which the lighting fixtures 15a and 15b are turned on.

  (7) The CPU 31 outputs control signals SC1 and SC2 having pulse widths corresponding to the first illuminance information, and controls the switch circuits SW22 and SW23 to be turned on / off. By lighting the lighting fixture 15a in the state shown in FIG. 5C, the room is illuminated brightly. This makes it possible to spend comfortably indoors. When the lighting fixture 15a is turned on in the state shown in FIG. 5B, the power consumption is reduced compared to the state shown in FIG. That is, the power of the batteries 23a and 23b shown in FIG. 1 can be saved. And compared with the state shown in FIG.5 (c), the lighting time of the lighting fixture 15b becomes longer in the state shown in FIG.5 (b), ie, the lighting fixture 15a can be lighted for a long time.

In addition, you may implement each said embodiment in the following aspects.
-It is good also as one battery or three or more batteries. Further, the battery 23a shown in FIG. 1 may be configured by two or more batteries (battery packs) connected in parallel. Similarly, you may comprise by two or more batteries (battery pack) which connected the battery 23b in parallel.

The number of lighting fixtures connected to the lighting control device 14 may be one or three or more.
FIG. 2 shows one circuit example of the control unit 24, and the control unit 24 may be changed as appropriate. For example, drive voltage VA1 and battery voltages VB1, VB2 are supplied to the anodes of diodes D21, D22, D23. The cathodes of the diodes D21 to D23 are connected to each other, and the connection point is connected to the protective element F21 through one switch circuit. One switch circuit is on / off controlled by the CPU 31 to generate a drive voltage VLD.

  In the above embodiment, the lighting device 15a is switched off (FIG. 5 (a)) and fully lit (FIG. 5 (c)) alternately by pressing the switch unit 28 for a short time. On the other hand, the brightness state when the light is turned off may be stored, and the lighting fixture 15a may be turned on in the stored brightness state by pressing the switch unit 28 for a short time.

  In contrast to the above-described embodiment, when the lighting fixture 15a is turned on in the state shown in FIG. 5B (eco-lit), the switch unit 28 is operated (for example, long-pressed) as shown in FIG. You may make it light the lighting fixture 15a in a state (full lighting).

  In the above embodiment, when a power failure is detected, the lighting fixtures 15a and 15b are gradually brightened in stages (two stages). In contrast, the lighting fixtures 15a and 15b may be gradually brightened in a plurality of stages of three or more stages. Moreover, you may make it light up the lighting fixtures 15a and 15b gradually.

-With respect to the said embodiment, you may make it change the brightness of lighting fixture 15a, 15b in three steps or more.
In the above embodiment, the lighting control device 14 controls lighting of the lighting fixtures 15a and 15b disposed on the ceiling in the room. However, lighting control of outdoor lights such as parking lot lights and street lights may be performed. .

  In the above embodiment, the lighting control device 14 is installed on the wall surface in the room, but may be installed in other locations. For example, you may install in the pole of outdoor lights, such as a parking lot light and a street light. Moreover, you may install in the switchboard etc. which supply electric power to a parking lot light, a street light, etc.

  -Although the lighting control apparatus 14 of the said embodiment controlled lighting lighting 15a, 15b according to operation of the external switch 12 arrange | positioned on the wall surface, you may change the external switch 12 suitably. For example, a sensor (illuminance sensor) that detects brightness may be used. When the commercial AC voltage VAC is supplied, the lighting fixtures 13a, 13b, 15a, 15b can be automatically turned on / off according to the brightness. And when commercial AC voltage VAC carries out a power failure, lighting fixture 15a, 15b can be lighted.

  DESCRIPTION OF SYMBOLS 11 ... Commercial alternating current power supply, 12 ... External switch, 13a, 13b ... Lighting fixture (2nd lighting fixture), 14 ... Lighting control apparatus, 15a, 15b ... Lighting fixture (1st lighting fixture), 22a ... Converter (1st) 1 conversion circuit), 22b ... converter (second conversion circuit), 23a ... battery (first battery, storage battery), 23b ... battery (second battery, storage battery), 24 ... control unit, 28 ... switch unit (Internal switch), 29 ... display unit, VAC ... commercial AC voltage, VA1 ... first DC voltage, VA2 ... second DC voltage, VB1, VB2 ... output voltage, VLD ... drive voltage.

Claims (7)

A lighting control device that controls lighting of the first lighting fixture,
A first conversion circuit for converting a commercial AC voltage into a first DC voltage;
A second conversion circuit for converting the commercial AC voltage into a second DC voltage;
A storage battery charged by the second DC voltage;
A controller for controlling lighting of the first lighting fixture;
Have
The control unit determines whether or not the commercial AC voltage has a power failure based on the first DC voltage, and determines that the commercial AC voltage has not failed based on a determination result. Based on an operation of an external switch that generates a driving voltage to be supplied to the first lighting fixture based on a direct current voltage of 1 and turns on and off a second lighting fixture different from the first lighting fixture. The lighting apparatus is turned on and off, and the drive voltage is generated based on the output voltage of the storage battery and the first lighting apparatus is turned on when it is determined that the commercial AC voltage is out of power based on the determination result. Controlling,
A lighting control device characterized by. The lighting control device according to claim 1,
The control unit generates the drive voltage so that the first lighting fixture is gradually turned on brightly at the time of a power failure of the commercial AC voltage based on the determination result;
A lighting control device characterized by. In the lighting control device according to claim 1 or 2,
The storage battery includes a first battery and a second battery that are charged by the second DC voltage,
The controller is
The first battery voltage output from the first battery is compared with a threshold voltage, and when the first battery voltage is equal to or higher than the threshold voltage, the first battery voltage is based on the first battery voltage. Generating the driving voltage to be supplied to the lighting fixture of the first lighting of the first lighting fixture at a first brightness,
When the first battery voltage is lower than the threshold voltage, the driving voltage is generated based on the second battery voltage output from the second battery, and the second voltage is darker than the first brightness. Lighting the first lighting fixture with brightness;
A lighting control device characterized by. In the lighting control device according to claim 3,
A switch unit connected to the control unit;
The control unit turns on / off the first lighting fixture based on a short press of the switch unit, and changes the brightness of the first illumination based on a long press of the switch unit,
A lighting control device characterized by. In the lighting control device according to claim 3 or 4,
A display unit connected to the control unit;
The control unit controls the lighting of the display unit at a predetermined cycle according to the lighting control of the first lighting fixture,
The predetermined cycle includes a first period and a second period shorter than the first period;
The controller is configured to make the brightness of the second period darker than the brightness of the first period when the first lighting fixture is lit at the first brightness. When the lighting device of 1 is turned on at the second brightness, the brightness of the first period is made darker than the brightness of the second period;
A lighting control device characterized by. In the lighting control device according to claim 5,
The control unit determines whether or not the storage battery is abnormal based on an output voltage of the storage battery, and changes the lighting state of the display unit when the storage battery is determined to be abnormal.
A lighting control device characterized by. In the lighting control device according to any one of claims 1 to 6,
Has an internal switch,
The control unit turns on / off the first lighting fixture based on the operation of the internal switch when it is determined that the commercial AC voltage has a power failure based on the determination result;
A lighting control device characterized by.