JP6784102B2 - lighting equipment - Google Patents

Description

The present invention relates to a luminaire.

Patent Document 1 discloses a technique for providing a detachable communication module in a lighting device that wirelessly receives a command from a user.

Japanese Unexamined Patent Publication No. 2013-235837

Conventionally, as a method of controlling a luminaire by a command from a user, the luminaire and a plurality of luminaires are connected by a signal line, and the lighting circuit of the luminaire is controlled based on the signal from the luminaire. was there. The signal from the lighting control device is, for example, a PWM (Pulse Width Modulation) signal. The light source lighting device included in the luminaire adjusts the current flowing through the light source based on the PWM signal to perform dimming control. According to this method, wiring work of a signal line connecting a lighting control device and a plurality of lighting devices is required. The work of connecting a plurality of lighting fixtures and wiring is complicated. Therefore, for example, it has been difficult to change the lighting equipment controlled by the user.

Therefore, for example, in the technique shown in Patent Document 1, a command from the user is input by a remote controller. Furthermore, the communication method can be switched so that various wireless communication methods can be used between the remote controller and the communication module. Thereby, in the technique shown in Patent Document 1, wiring can be simplified. However, Patent Document 1 does not show a specific configuration of a method of supplying a driving power source for driving a detachable communication module. For example, if a drive power source is constantly supplied to the communication module, there is a problem that power consumption increases.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to obtain a lighting fixture capable of reducing power consumption.

The lighting equipment according to the first invention includes a light emitting element, a lighting circuit for lighting the light emitting element, a control unit for emitting a control signal, a control circuit for controlling the lighting circuit in response to the control signal, and the control. A control power supply circuit that supplies power to the circuit and the control unit, a switch unit provided in a path for supplying power from the control power supply circuit to the control unit, a lighting circuit, the control circuit, and the control power supply. A light source lighting device including a circuit, the switch portion, and a housing to which the light emitting element is attached are provided, and the control unit is detachably attached to the housing , and the switch portion is attached. while interrupting the supply of power from the control power supply circuit to the control unit, the power supply from the control power supply circuit to the control circuit Ru is maintained.

The lighting equipment according to the second invention includes a light emitting element, a lighting circuit for lighting the light emitting element, a control unit for emitting a control signal, a control circuit for controlling the lighting circuit in response to the control signal, and the control. A control power supply circuit for supplying power to the circuit and the control unit, and a switch unit provided in a path for supplying power from the control power supply circuit to the control unit are provided, and the control circuit responds to the control signal. Te blocking the switch unit, in a state in which the switch unit is cut off the power supply to the control unit from the control power supply circuit, the supply of power from the control power supply circuit to the control circuit Ru is maintained.
The luminaire according to the third invention includes a light emitting element, a lighting circuit for lighting the light emitting element, and the like.
A control unit that emits a control signal, a control circuit that controls the lighting circuit in response to the control signal, a control power supply circuit that supplies electric power to the control circuit and the control unit, and the control power supply circuit to the control unit. A switch unit provided in a path for supplying electric power, a lighting circuit, a control circuit, a control power supply circuit, a light source lighting device including the switch unit, and a light emitting element are attached. The control unit includes a housing, and the control unit is detachably attached to the housing, power is supplied to the lighting circuit from an external power supply, and the switch unit is cut off from the external power supply. When the power supply to the lighting circuit from the external power source is started after the power supply to the lighting circuit is cut off, the control circuit makes the switch portion conductive.
The lighting equipment according to the fourth invention includes a light emitting element, a lighting circuit for lighting the light emitting element, a control unit for emitting a control signal, a control circuit for controlling the lighting circuit in response to the control signal, and the control. A control power supply circuit for supplying power to the circuit and the control unit, and a switch unit provided in a path for supplying power from the control power supply circuit to the control unit are provided, and the control circuit responds to the control signal. The switch unit is cut off, power is supplied from the external power supply to the lighting circuit, and in a state where the switch unit is cut off, the power supply from the external power supply to the lighting circuit is cut off, and then the external power supply is cut off. When the power supply from the power source to the lighting circuit is started, the control circuit makes the switch portion conductive.
The lighting equipment according to the fifth invention includes a light emitting element, a lighting circuit for lighting the light emitting element, a control unit for emitting a control signal, a control circuit for controlling the lighting circuit in response to the control signal, and the control. A control power supply circuit that supplies power to the circuit and the control unit, a switch unit provided in a path for supplying power from the control power supply circuit to the control unit, a lighting circuit, the control circuit, and the control power supply. A light source lighting device including a circuit, a switch portion, and a housing to which the light emitting element is attached are provided, and the control unit is detachably attached to the housing and is attached to the housing from an external power source. When the power supply to the lighting circuit is started, the control circuit makes the switch portion conductive after the power is supplied to the control circuit.
The lighting equipment according to the sixth invention includes a light emitting element, a lighting circuit for lighting the light emitting element, a control unit for emitting a control signal, a control circuit for controlling the lighting circuit in response to the control signal, and the control. A control power supply circuit for supplying power to the circuit and the control unit, and a switch unit provided in a path for supplying power from the control power supply circuit to the control unit are provided, and the control circuit responds to the control signal. When the switch unit is shut off and the power supply from the external power source to the lighting circuit is started, the control circuit makes the switch unit conductive after the power is supplied to the control circuit.
The lighting equipment according to the seventh invention includes a light emitting element, a lighting circuit for lighting the light emitting element, a control unit for emitting a control signal, a control circuit for controlling the lighting circuit in response to the control signal, and the control. A control power supply circuit that supplies power to the circuit and the control unit, a switch unit provided in a path for supplying power from the control power supply circuit to the control unit, a lighting circuit, the control circuit, and the control power supply. A light source lighting device including a circuit, a switch portion, and a housing to which the light emitting element is attached are provided, and the control unit is detachably attached to the housing and is attached to the housing from an external power source. When the power supply to the lighting circuit is cut off, the power supply to the control circuit is stopped after the control circuit cuts off the switch unit.
The lighting equipment according to the eighth invention includes a light emitting element, a lighting circuit for lighting the light emitting element, a control unit for emitting a control signal, a control circuit for controlling the lighting circuit in response to the control signal, and the control. A control power supply circuit for supplying power to the circuit and the control unit, and a switch unit provided in a path for supplying power from the control power supply circuit to the control unit are provided, and the control circuit responds to the control signal. When the switch unit is cut off and the power supply from the external power supply to the lighting circuit is cut off, the power supply to the control circuit is stopped after the control circuit cuts off the switch unit.

In the luminaire according to the first invention, the supply of control power to the control unit detachably attached to the housing can be cut off by the switch unit. Therefore, the drive of the control unit can be stopped. Therefore, the power consumption of the lighting equipment can be reduced.
In the luminaire according to the second invention, the supply of the control power supply to the control unit can be cut off by the switch unit. Therefore, the drive of the control unit can be stopped. Therefore, the power consumption of the lighting equipment can be reduced.

It is a block diagram of the lighting equipment which concerns on Embodiment 1 of this invention. It is a circuit block diagram of the light source lighting device and the control unit which concerns on Embodiment 1 of this invention. It is a flowchart which shows the operation of the luminaire which concerns on Embodiment 2 of this invention. It is a time chart which shows the operation sequence of the luminaire which concerns on Embodiment 3 of this invention. It is a circuit block diagram of the light source lighting device and the control unit which concerns on Embodiment 4 of this invention. It is a time chart which shows the operation sequence of the luminaire in Embodiment 4 of this invention.

The lighting equipment according to the embodiment of the present invention will be described with reference to the drawings. The same or corresponding components may be designated by the same reference numerals and the description may be omitted.

Embodiment 1.
FIG. 1 is a block diagram of a lighting fixture according to a first embodiment of the present invention. The luminaire 1 includes a housing 2, a light emitting unit 3, a light source lighting device 4, and a connecting unit 5. The light emitting unit 3 includes a plurality of LEDs as light emitting elements. The light source lighting device 4 lights the light emitting unit 3. The connection portion 5 is provided in the housing 2 and houses the control unit 10. The connection portion 5 is connected to the light source lighting device 4 by wiring. The connection unit 5 electrically connects the control unit 10 housed in the connection unit 5 and the light source lighting device 4. The connection portion 5 includes an opening exposed to the outside of the housing 2.

The control unit 10 is attached to the connection portion 5 through the opening. The control unit 10 is detachably attached to the housing 2. When the control unit 10 is not housed, the opening may be covered with a cover. In the present embodiment, a plurality of control units 10 having different functions or specifications are prepared. The user can attach the desired control unit 10 to the luminaire 1 by selecting a function or a specification. The user referred to here is not limited to the final consumer, but also includes an installer who sets the lighting fixture 1. The light emitting unit 3 may include an organic EL instead of the LED as the light emitting element.

The control unit 10 includes an electrode 11, a sensor unit 12, and a communication control circuit 13. The electrode 11 is electrically connected to the light source lighting device 4 at the connection portion 5. Electric power is supplied to the control unit 10 from the light source lighting device 4 via the electrodes 11. By communicating with an external lighting control device, the sensor unit 12 transmits a command signal from the user and a command signal according to the external state to the communication control circuit 13. The communication control circuit 13 converts the command signal received by the sensor unit 12 into a control signal for commanding the light source lighting device 4. The communication control circuit 13 outputs a control signal from the electrode 11. The light source lighting device 4 receives a control signal via the electrode 11, the connecting portion 5, and the wiring.

The control unit 10 and the light source lighting device 4 are electrically connected by wiring via a connecting portion 5. The light source lighting device 4 controls the light emitting unit 3 by controlling the switching type DC-DC converter circuit included in the light source lighting device 4 according to the control signal received from the communication control circuit 13. Specifically, the light source lighting device 4 can control the amount of current flowing through the light emitting unit 3, the lighting time, and the like.

In the present embodiment, a case where the control unit 10 is a wireless communication unit having a wireless communication function will be described. In this case, the sensor unit 12 includes a wireless communication antenna. The wireless communication antenna receives a signal from the outside and further transmits the signal to the outside. Further, the communication control circuit 13 includes a wireless communication control circuit. The wireless communication control circuit converts a command signal transmitted and received by the wireless communication antenna into a control signal, and exchanges the control signal with the light source lighting device.

Next, for example, the operation of the lighting fixture 1 when the external lighting control device is a dimming controller including wireless communication means will be described. First, an external lighting control device transmits a command signal for changing the brightness of the lighting fixture 1. The wireless communication antenna of the sensor unit 12 receives the command signal. The communication control circuit 13 converts the command signal into a control signal and transmits it to the light source lighting device 4. The light source lighting device 4 controls the amount of current flowing through the light emitting unit 3 according to the control signal.

Further, the control unit 10 may transmit a signal transmitted from the light source lighting device 4 to the control unit 10 from the wireless communication antenna to the lighting control device. Here, the signal transmitted from the light source lighting device 4 to the control unit 10 is a signal including information stored in the light source lighting device 4. The information stored in the light source lighting device 4 is, for example, the power consumption, lighting time, or failure state of the lighting fixture 1. As a result, the power consumption, lighting time, or failure status can be displayed on the display unit of the lighting control device.

Here, the lighting control device is a dimming controller provided with wireless communication means, but the lighting control device may be a remote controller provided with wireless communication means and for setting dimming. Further, the communication means between the lighting control device and the control unit 10 may be other than the wireless system. For example, an infrared communication means may be used. In this case, the control unit 10 includes an infrared light receiving element in the sensor unit 12.

FIG. 2 is a circuit block diagram of the light source lighting device and the control unit according to the first embodiment of the present invention. In a state where the control unit 10 is connected to the connecting portion 5, the electrode 5a included in the connecting portion 5 and the electrode 11 are connected. The electrode 5a is connected to the control circuit 4b and the switch unit 4d included in the light source lighting device 4 by wiring.

The light source lighting device 4 includes a lighting circuit 4a. The lighting circuit 4a includes a rectifier circuit 41. The rectifier circuit 41 is a diode bridge circuit. The rectifier circuit 41 is connected to an external power source 70, which is an AC power source, via a switch SW. In this embodiment, the external power source 70 is a commercial power source. The switch SW is a wall switch for cutting off the power supply from the external power supply 70. A capacitor 44, which is a smoothing capacitor, is connected in parallel to the DC output side of the rectifier circuit 41. One end of the inductor 45 is connected to the positive electrode of the capacitor 44.

The other end of the inductor 45 is connected to the drain of the switching element 46 and the anode of the diode 47. The source of the switching element 46 is connected to the negative electrode of the capacitor 44. Further, the gate of the switching element 46 is connected to the control circuit 4b. The positive electrode of the capacitor 48 is connected to the cathode of the diode 47. The negative electrode of the capacitor 48 is connected to the source of the switching element 46.

The positive electrode of the capacitor 48 is connected to the drain of the switching element 49. The cathode of the diode 51 and one end of the inductor 52 are connected to the source of the switching element 49. The anode of the diode 51 is connected to the negative electrode of the capacitor 48. The gate of the switching element 49 is connected to the control circuit 4b. The positive electrode of the capacitor 53 is connected to the other end of the inductor 52. The anode of the diode 51 is connected to the negative electrode of the capacitor 53.

From the above, the lighting circuit 4a includes a switching type DC-DC converter circuit. By adjusting the on-time of the switching element 46, a constant voltage is generated at the positive electrode of the capacitor 48. Further, the output current of the lighting circuit 4a is changed by changing the on-time of the switching element 49. A light emitting unit 3 is connected in parallel to the output of the lighting circuit 4a. The light emitting unit 3 includes a plurality of light emitting elements 81 connected in series. The lighting circuit 4a lights the light emitting element 81.

Next, the control circuit 4b will be described. The control circuit 4b includes a processing circuit 26. The processing circuit 26 calculates the on-time of the switching element 46 so that the voltage applied to both ends of the capacitor 48 becomes a constant voltage. Further, the processing circuit 26 is connected to the communication control circuit 13 via the electrodes 5a and 11. The processing circuit 26 is notified of the target dimming rate by the control signal 92 emitted by the communication control circuit 13. The processing circuit 26 calculates the on-time of the switching element 49 so that the light emitting unit 3 lights up at the dimming rate notified by the control signal 92.

The control circuit 4b includes a drive circuit 20. The drive circuit 20 outputs a PWM signal according to the on-time of the switching element 46 and the switching element 49 calculated by the processing circuit 26. The PWM signal controls the on / off of the switching element 46 and the switching element 49. Further, a program stored in the storage device 23 is used for the arithmetic processing executed by the processing circuit 26. From the above, the light emitting unit 3 lights up according to the dimming rate notified by the control signal 92.

Next, the control power supply circuit 4c will be described. The control power supply circuit 4c includes a switching element 64. The drain of the switching element 64 is connected to the positive electrode of the capacitor 48. The cathode of the diode 63 and one end of the inductor 62 are connected to the source of the switching element 64. The anode of the diode 63 is connected to the negative electrode of the capacitor 61.

The gate of the switching element 64 is connected to the drive circuit 65. The drive circuit 65 adjusts the on-time of the switching element 64. The positive electrode of the capacitor 61 is connected to the other end of the inductor 62. The positive electrode of the capacitor 61 is connected to the control circuit 4b. Further, the positive electrode of the capacitor 61 is connected to the control unit 10 via the switch unit 4d.

From the above, the control power supply circuit 4c includes a switching type DC-DC converter circuit. The control power supply circuit 4c steps down the voltage generated in the positive electrode of the capacitor 48 and outputs it to the positive electrode of the capacitor 61. The output voltage of the control power supply circuit 4c is adjusted by adjusting the duty ratio of the switching element 64. The output of the control power supply circuit 4c is connected to the control unit 10 via the control circuit 4b and the switch unit 4d. Therefore, the control power supply circuit 4c supplies power to the control circuit 4b and the control unit 10. The output voltage of the control power supply circuit 4c is the control power supply voltage that drives the control circuit 4b and the control unit 10.

Next, the switch unit 4d will be described. The output of the control power supply circuit 4c is connected to one end of the switch unit 4d. Further, the control unit 10 is connected to the other end of the switch unit 4d via the electrodes 5a and 11. Therefore, the switch unit 4d is provided in the path for supplying electric power from the control power supply circuit 4c to the control unit 10. Therefore, the supply of the control power supply to the control unit 10 is cut off by shutting off the switch unit 4d.

The control circuit 4b turns on / off the switch unit 4d. For the switch unit 4d, for example, a semiconductor switching element such as a MOSFET (Metal-Oxide-Semiconductor Field-Effective Transistor) or a bipolar transistor can be used.

The user can adjust the brightness of the light emitting unit 3 to a desired brightness by operating the dimming controller which is the lighting control device 90. The procedure for the user to change the dimming rate will be described below. When the user changes the brightness of the light emitting unit 3, the switch unit 4d is in a conductive state. At this time, the control power supply is supplied to the control unit 10 from the control power supply circuit 4c. Therefore, the control unit 10 is in the operating state. At this time, the control unit 10 is in a state where it can receive the command signal 91 from the lighting control device 90.

First, the user inputs the desired brightness of the light emitting unit 3 to the lighting control device 90. The lighting control device 90 transmits the input brightness as a command signal 91. As a result, the sensor unit 12 receives the command signal 91. The communication control circuit 13 converts the command signal 91 into a control signal 92 for commanding the light source lighting device 4. The communication control circuit 13 notifies the control circuit 4b of the control signal 92. Here, the communication control circuit 13 may convert the brightness input by the user into a dimming rate and transmit it as a control signal 92. As a result, the control circuit 4b controls the lighting circuit 4a to light the light emitting unit 3 with the brightness set by the user from the lighting control device 90.

Next, a case where the user does not need to change the brightness of the light emitting unit 3 will be described. At this time, the light emitting unit 3 keeps lighting in a state of constant brightness. At this time, the user performs an operation of stopping the operation of the control unit 10 from the lighting control device 90. As a result, the lighting control device 90 transmits a command signal 91 for stopping the operation of the control unit 10. As a result, the control signal 92 for turning off the switch unit 4d is transmitted from the control unit 10.

The control circuit 4b shuts off the switch unit 4d in response to the control signal 92. As a result, the supply of the control power supply to the control unit 10 is cut off. Therefore, the control unit 10 stops operating and does not accept the command signal 91 from the lighting control device 90. In the present embodiment, the operation of the control unit 10 can be stopped when the user does not need to change the brightness of the light emitting unit 3. Therefore, the power consumption of the control unit 10 can be reduced.

Further, when the switch unit 4d is cut off while the light emitting element 81 is lit, the control circuit 4b controls the lighting circuit 4a so as to maintain the dimming rate before the switch unit 4d is turned off. As a result, the control circuit 4b keeps the light emitting unit 3 lit at the brightness set immediately before the operation of the control unit 10 is stopped. As a result, the light emitting unit 3 can be lit with a constant brightness regardless of whether the control unit 10 is turned on or off. That is, the power consumption of the control unit 10 can be reduced while the light emitting unit 3 maintains a constant brightness.

Next, a case where the brightness of the light emitting unit 3 is changed by operating the lighting control device 90 again after the user stops the operation of the control unit 10 will be described. In a state where power is supplied from the external power source 70 to the lighting circuit 4a and the switch unit 4d is cut off, the power supply from the external power source 70 to the lighting circuit 4a is cut off by the switch SW. After that, the switch SW is turned on, and the power supply from the external power source 70 to the lighting circuit 4a is started. By the above operation, the control circuit 4b brings the switch unit 4d into a conductive state.

As a result, the control power supply is supplied to the control unit 10 again from the control power supply circuit 4c. In the present embodiment, the control unit 10 is restarted by turning off the switch SW and then turning it on. Therefore, an additional circuit for restarting the control unit 10 becomes unnecessary, and the circuit of the luminaire 1 can be simplified. After the control unit 10 is restarted, the light emitting unit 3 lights up based on the command signal 91 transmitted from the lighting control device 90.

The lighting circuit 4a includes voltage dividing resistors 42 and 43 on the DC output side of the rectifier circuit 41. The control circuit 4b can detect the on / off of the switch SW by reading the voltage applied to the voltage dividing resistors 42 and 43. When the processing circuit 26 detects that the switch SW is turned on and then turned on after the switch SW is turned off in a state where the switch unit 4d is cut off, the processing circuit 26 puts the switch unit 4d into a conductive state.

Here, the user may always want to stop the operation of the control unit 10. In the above-mentioned operation method, every time the external power source 70 is turned on by the switch SW, the operation of stopping the operation of the control unit 10 from the lighting control device 90 must be executed, which is troublesome. Therefore, a method of constantly stopping the operation of the control unit 10 will be described.

First, when the switch unit 4d is in a conductive state, the user transmits a command signal 91 for stopping the operation of the control unit 10 from the lighting control device 90. As a result, the control signal 92 for turning off the switch unit 4d is transmitted from the control unit 10. Next, the control circuit 4b stores the information in which the control signal 92 for turning off the switch unit 4d is received in the storage device 23. The storage device 23 includes a non-volatile memory. It is assumed that the information received from the control signal 92 for turning off the switch unit 4d is maintained even if the external power supply 70 is cut off.

Next, it is assumed that the user shuts off the switch SW and then turns on the switch SW again. The processing circuit 26 detects that the switch SW is turned on again after being shut off. At this time, the processing circuit 26 reads from the storage device 23 whether or not the supply of the control power supply to the control unit 10 has been cut off before the switch SW is cut off, and determines. When the supply of the control power supply to the control unit 10 is cut off, the processing circuit 26 keeps the switch unit 4d in a conductive state for a predetermined period of time. Here, the fixed period for keeping the switch unit 4d in the conductive state is, for example, 10 seconds.

The control power is supplied to the control unit 10 during a certain period in which the switch unit 4d is in a conductive state. Therefore, the control unit 10 can receive the command signal 91 from the lighting control device 90. If the lighting control device 90 does not transmit the command signal 91 for starting the operation of the control unit 10 to the control unit 10 during this fixed period, the control circuit 4b cuts off the supply of the control power supply to the control unit 10 again. That is, when the processing circuit 26 does not receive the control signal 92 that releases the cutoff of the switch unit 4d for a certain period of time, the processing circuit 26 shuts off the switch unit 4d again.

Here, the control circuit 4b includes a counter 24. The counter 24 counts 10 seconds, which is a fixed period during which the switch unit 4d is kept in a conductive state. When the processing circuit 26 detects that the switch SW is turned on again after being shut off, the counter 24 starts counting. When the counter 24 notifies that 10 seconds have passed without receiving the control signal 92 for releasing the cutoff of the switch unit 4d, the processing circuit 26 shuts off the switch unit 4d again. From the above, the user does not need to perform an operation of stopping the operation of the control unit 10 from the lighting control device 90 every time the external power supply 70 is turned on.

Further, the storage device 23 stores in advance the dimming rate immediately before the user cuts off the supply of the control power supply to the control unit 10. If the command signal 91 for starting the operation of the control unit 10 is not transmitted within a predetermined fixed period, the switch unit 4d is shut off again. After that, the processing circuit 26 reads out the dimming rate stored in the storage device 23. Based on this dimming rate, the control circuit 4b controls the lighting circuit 4a. Therefore, the control circuit 4b controls the current flowing through the light emitting unit 3 so as to maintain the dimming rate at the time of the previous lighting. Therefore, the light emitting unit 3 can be lit at a dimming rate that is the same as that at the time of the previous lighting. From the above, it is not necessary to perform the operation of setting the dimming rate in the lighting control device 90 every time the user turns on the external power supply 70.

From the above, once the user sets the stop of operation of the control unit 10 and the dimming rate, the light emitting unit 3 can be turned on with the same setting every time even if the switch SW is turned on and off. Therefore, the power consumption of the control unit 10 can be reduced while eliminating the troublesomeness of operating the lighting control device 90. This is effective, for example, in an application in which the brightness of the light emitting unit 3 is rarely adjusted by a dimming controller.

When the user turns on the switch SW again after shutting off the switch SW, the switch unit 4d becomes conductive for a predetermined period of time. If the lighting control device 90 transmits a command signal 91 for starting the operation of the control unit 10 during this fixed period, the supply of the control power supply to the control unit 10 is continued. That is, when the processing circuit 26 receives the control signal 92 for releasing the cutoff of the switch unit 4d before the counter 24 notifies the processing circuit 26 of the passage of 10 seconds, the processing circuit 26 is in a conductive state of the switch unit 4d. To maintain. At this time, the operation by the dimming controller is effective while the switch SW is in the ON state.

Here, a case where the lighting control device 90 is a dimming controller and the lighting device 1 includes a control unit 10 having a wireless communication function has been described. On the other hand, for example, the lighting control device 90 may be equipped with an illuminance sensor or a motion sensor. Next, a case where the lighting control device 90 is equipped with an illuminance sensor and the lighting device 1 is provided with a control unit 10 having a wireless communication function will be described.

The lighting control device 90 equipped with the illuminance sensor is installed on the ceiling, for example. The lighting control device 90 detects the external brightness with an illuminance sensor. Further, the lighting control device 90 converts the detected brightness into a command signal 91 for transmitting by wireless communication means. Further, the lighting control device 90 transmits a command signal 91 to the control unit 10. Next, the control unit 10 converts the received command signal 91 into a control signal 92 for transmission to the control circuit 4b by the communication control circuit 13 and transmits the control signal 92.

Here, the communication control circuit 13 may transmit a signal indicating the brightness detected by the illuminance sensor as a control signal 92. Further, the communication control circuit 13 may calculate a dimming rate suitable for the external brightness and transmit it as a control signal 92. Further, the communication control circuit 13 may notify the control circuit 4b of a lower dimming rate as the external brightness becomes brighter. The control circuit 4b controls the lighting circuit 4a according to the received control signal 92. As a result, the amount of current flowing through the light emitting unit 3 is adjusted, and the brightness of the light emitting unit 3 is controlled.

For example, when the luminaire 1 is installed on the window side where the outside light enters, the dimming rate of the luminaire 1 is controlled to be about 50% in the daytime and about 100% at night. Is also good. On the other hand, when the luminaire 1 is installed in a room where outside light does not enter, the dimming rate of the luminaire 1 may be controlled to be about 100% day and night.

In this way, the lighting control device 90 equipped with the illuminance sensor can control the brightness of the light emitting unit 3 according to the external environment in which the lighting fixture 1 is installed. Therefore, the current consumed by the light emitting unit 3 can be reduced by reducing the dimming rate when the external environment is bright. Therefore, the energy consumption of the lighting fixture 1 can be reduced. It should be noted that one lighting control device may simultaneously control a plurality of lighting fixtures 1 installed in the same external environment. In this case, the control unit 10 attached to each of the lighting fixtures 1 receives the command signal 91 transmitted by one lighting control device 90. As a result, the plurality of lighting fixtures 1 can be dimmed simultaneously by one lighting control device 90.

Next, a case where the user turns off the function of the illuminance sensor and turns on the luminaire 1 regardless of the brightness of the external environment will be described. The user sets the lighting control device 90 to turn off the function of the illuminance sensor. As a result, the lighting control device 90 transmits a command signal 91 for stopping the operation of the control unit 10 to the control unit 10. As a result, the control signal 92 that shuts off the switch unit 4d is transmitted from the control unit 10 to the control circuit 4b.

The control circuit 4b receives the control signal 92 and turns off the switch unit 4d. Therefore, the supply of the control power supply to the control unit 10 is cut off. As a result, the control unit 10 stops operating. Therefore, the power consumption of the control unit 10 can be reduced. The lighting control device 90 may include an illuminance sensor and a remote controller. In this case, the setting for turning off the function of the control unit 10 may be performed from the remote controller. In this case, the command signal 91 for stopping the operation of the control unit 10 is transmitted from the remote controller to the control unit 10.

Here, an example in which an illuminance sensor is mounted on the lighting control device 90 has been described. On the other hand, the illuminance sensor may be mounted on the control unit 10. Next, a case where the control unit 10 includes an illuminance sensor will be described. At this time, the control unit 10 becomes an illuminance sensor unit. The control unit 10 equipped with the illuminance sensor includes an electrode 11, a sensor unit 12, and a communication control circuit 13. The electrode 11 is connected to the connecting portion 5. The sensor unit 12 includes an illuminance sensor that detects brightness. The communication control circuit 13 is an illuminance control circuit that converts the brightness detected by the illuminance sensor into a control signal 92 and transmits it to the control circuit 4b.

The control circuit 4b controls the lighting circuit 4a in response to the control signal 92. As a result, the amount of current flowing through the light emitting unit 3 is adjusted, and the brightness is controlled. When the control unit 10 includes an illuminance sensor, the external lighting control device 90 may include a remote controller. At this time, the sensor unit 12 further includes a wireless communication antenna. The user performs an operation of turning off the function of the control unit 10 from the remote controller. As a result, a command signal 91 for stopping the operation of the control unit 10 is transmitted from the remote controller to the control unit 10.

Further, the lighting control device 90 may be an infrared remote controller. At this time, the sensor unit 12 further includes an infrared light receiving unit. When the infrared remote controller transmits a command signal 91 for turning off the function of the control unit 10, the control unit 10 transmits a control signal 92 based on the command signal 91 from the infrared remote controller to the control circuit 4b. As a result, the control circuit 4b turns off the switch unit 4d and cuts off the supply of the control power supply to the control unit 10.

Next, a case where the lighting control device 90 is equipped with a motion sensor and the lighting device 1 is provided with a control unit 10 having a wireless communication function will be described. The lighting control device 90 provided with a motion sensor is installed on the ceiling, for example. The motion sensor includes a pyroelectric element that detects the presence / absence of a person. Further, the motion sensor includes a motion control circuit that converts the presence / absence determination result of the person detected by the pyroelectric element into a command signal 91 and transmits it to the control unit 10.

When the pyroelectric element detects a person, the lighting control device 90 transmits a command signal 91 notifying that the person is present to the control unit 10. The control unit 10 transmits a control signal 92 instructing lighting to the control circuit 4b based on the command signal 91. The control circuit 4b controls the lighting circuit 4a in response to the control signal 92 to light the light emitting unit 3.

Further, if the pyroelectric element does not detect a person for a predetermined period after detecting the presence of a person, the human sensation control circuit determines that the person is absent. When the absence of a person is determined, the lighting control device 90 transmits a command signal 91 notifying the absence of the person to the control unit 10. Based on the command signal 91, the control unit 10 transmits a control signal 92 instructing to turn off the light to the control circuit 4b. The control circuit 4b controls the lighting circuit 4a based on the control signal 92, and turns off the light emitting unit 3. Alternatively, the control circuit 4b may reduce the dimming rate of the light emitting unit 3 based on the control signal 92.

From the above, it is possible to detect the presence / absence of a person by the motion sensor and control the lighting / extinguishing or dimming of the lighting fixture 1. By turning off the light emitting unit 3 or lowering the dimming rate when a person is absent, it is possible to reduce the power consumption of the luminaire 1.

Next, a case where the user turns off the function of the motion sensor and turns on the light emitting unit 3 regardless of the presence / absence of a person will be described. The user sets the lighting control device 90 to turn off the function of the motion sensor. As a result, a command signal 91 for stopping the operation of the control unit 10 is transmitted from the lighting control device 90 to the control unit 10. The control unit 10 receives the command signal 91 and transmits a control signal 92 that shuts off the switch unit 4d to the control circuit 4b. The control circuit 4b turns off the switch unit 4d in response to the control signal 92, and cuts off the supply of the control power supply to the control unit 10. Therefore, the operation of the control unit 10 can be stopped and the power consumption of the control unit 10 can be reduced.

Here, an example in which a motion sensor is mounted on the lighting control device 90 has been described. On the other hand, the motion sensor may be mounted on the control unit 10. At this time, the control unit 10 becomes a motion sensor unit. In this case, the control unit 10 includes an electrode 11, a sensor unit 12, and a communication control circuit 13. The electrode 11 is connected to the connecting portion 5. The sensor unit 12 includes a pyroelectric element that detects the presence / absence of a person. The communication control circuit 13 includes a human sensory control circuit. The human sensory control circuit converts a signal for determining the presence / absence of a person detected by the pyroelectric element, and generates a control signal 92. Further, the human sensory control circuit transmits the control signal 92 to the control circuit 4b.

Further, when the control unit 10 includes a motion sensor, the external lighting control device 90 may include a remote controller. At this time, the sensor unit 12 further includes a wireless communication antenna. When turning off the motion sensor function, the user performs an operation of turning off the motion sensor function from the remote controller. As a result, a command signal 91 for stopping the operation of the control unit 10 is transmitted from the remote controller to the control unit 10.

The lighting control device 90 may be an infrared remote controller. In this case, the sensor unit 12 further includes an infrared light receiving unit. When the infrared remote controller transmits a command signal 91 that turns off the motion sensor function to the control unit 10, the control unit 10 transmits a control signal 92 based on the command signal 91 to the control circuit 4b. As a result, the control circuit 4b turns off the switch unit 4d and cuts off the supply of the control power supply to the control unit 10.

The procedure for returning the function of the illuminance sensor or the motion sensor again after the user stops the operation of the control unit 10 is the same as when the lighting control device 90 is a dimming controller. The user shuts off the external power supply 70 with the switch SW, and then turns it on again. As a result, the control circuit 4b turns on the switch unit 4d again. As a result, the control power is supplied to the control unit 10, and the function of the illuminance sensor or the motion sensor is restored.

Further, the control when the user always stops the function of the illuminance sensor or the motion sensor is the same as when the lighting control device 90 is a dimming controller. As a result, it is not necessary to stop the function of the illuminance sensor or the motion sensor from the lighting control device 90 every time the external power supply 70 is turned on. Therefore, the troublesomeness of operating the lighting control device 90 can be eliminated.

In the present embodiment, the switch unit 4d is provided in the light source lighting device 4. On the other hand, the control unit 10 may be provided with the switch unit 4d. Further, in the present embodiment, the switch unit 4d is provided between the output of the control power supply circuit 4c and the control unit 10. Therefore, by shutting off the switch unit 4d, the supply of the control power supply to the control unit 10 is cut off. On the other hand, the method of shutting off the control power supply is not limited to this.

In the present embodiment, power is supplied from the common control power supply circuit 4c to the control unit 10 and the control circuit 4b. On the other hand, power may be supplied to the control circuit 4b and the control unit 10 from independent control power supply circuits. In this case, the supply of the control power supply to the control unit 10 may be cut off by stopping the operation itself of the control power supply circuit that supplies power to the control unit 10. In this case, the switch unit 4d is provided on the input side of the control power supply circuit that supplies power to the control unit 10.

Further, in the present embodiment, the switch unit 4d is shut off by operating the lighting control device 90. As a result, the supply of the control power supply to the control unit 10 was cut off. On the other hand, the switch unit 4d may be, for example, a switch or a drawstring provided in the housing of the control unit 10 or the lighting fixture 1. In this case, the supply of the control power supply to the control unit 10 is cut off by the user operating the switch or the drawstring.

Further, the control circuit 4b may automatically determine the type of the control unit 10 connected to the connection unit 5. When the control circuit 4b determines the type of the control unit 10, the control may be automatically switched so that the control is performed according to the type of the control unit 10. As a result, it is possible to reduce the time and effort required for the user to set the device when the control unit 10 is attached. The type of the connected control unit 10 can be easily determined by communication between the control unit 10 and the control circuit 4b.

The processing circuit 26, the storage device 23, and the counter 24 may be built in the microcomputer. At this time, the control circuit 4b includes a microcomputer. Further, the processing circuit 26 may be a CPU (Central Processing Unit) that executes a program stored in the storage device 23. The CPU is also referred to as a central processing unit, a processing unit, an arithmetic unit, a microprocessor, a microcomputer, a processor or a DSP. Further, the processing circuit 26 may be dedicated hardware.

When the processing circuit 26 is a CPU, the function of the processing circuit 26 is realized by software, firmware, or a combination of software and firmware. The software and firmware are described as programs and stored in the storage device 23. The processing circuit 26 reads and executes the program stored in the storage device 23. As a result, the function of the luminaire 1 is realized. Further, it can be said that these programs cause the processing circuit 26 to execute the procedure and method of controlling the lighting circuit 4a and the switch unit 4d by the control circuit 4b. Here, the storage device 23 corresponds to, for example, a non-volatile or volatile semiconductor memory such as RAM, ROM, flash memory, EPROM, EEPROM, a magnetic disk, a flexible disk, an optical disk, a compact disk, a mini disk, a DVD, or the like. To do.

These modifications can be appropriately applied to the lighting fixtures according to the following embodiments. Since the lighting fixtures according to the following embodiments have much in common with the first embodiment, the differences from the first embodiment will be mainly described.

Embodiment 2.
The configuration of the lighting fixture 1 according to the second embodiment of the present invention is the same as that of the first embodiment. In the first embodiment, a case where the supply of the control power supply to the control unit 10 is cut off at an arbitrary timing has been described. In the present embodiment, a case where the control power supply to the control unit 10 is intermittently supplied will be described.

Here, a case where the lighting control device 90 is equipped with an illuminance sensor and the lighting device 1 is provided with a control unit 10 having a wireless communication function will be described. Since the function of the illuminance sensor is the same as that of the first embodiment, the description thereof will be omitted. Consider a case where the brightness of the light emitting unit 3 is controlled according to the outside light by using the illuminance sensor.

For example, from daytime to nighttime, the outside light gradually darkens. The lighting fixture 1 installed on the window side where the outside light enters increases in brightness as the outside light becomes darker in response to the command signal 91 from the illuminance sensor. Here, the outside light does not change suddenly, and the rate of change is extremely slow. Therefore, for example, if the light source lighting device 4 takes in the control signal 92, which is information from the illuminance sensor, and reflects it in the brightness of the light emitting unit 3, the purpose can be sufficiently achieved.

In the luminaire 1 according to the present embodiment, the control circuit 4b intermittently captures the control signal 92. Further, during the period when the control signal 92 is not received from the control unit 10, the supply of the control power supply to the control unit 10 is cut off. As a result, the standby power of the control unit 10 can be reduced. Here, in the present embodiment, the interval at which the control circuit 4b captures the control signal 92 is, for example, a 10-minute interval.

FIG. 3 is a flowchart showing the operation of the lighting fixture according to the second embodiment of the present invention. An operation example of this embodiment will be described with reference to FIG. A switch SW, a lighting control device 90, or the like is used to give a lighting instruction to the lighting fixture 1. As a result, the light source lighting device 4 lights the light emitting unit 3. Next, the processing circuit 26 resets the counter 24 that measures the time inside the control circuit 4b. As a result, the count value of the counter 24 becomes zero. Next, the processing circuit 26 turns on the switch unit 4d. As a result, control power is supplied to the control unit 10.

As a result, the control unit 10 starts operation. Next, the communication control circuit 13 requests the lighting control device 90 to transmit the illuminance information detected by the illuminance sensor. The request signal requesting the transmission of the illuminance information is transmitted from the sensor unit 12 according to the instruction of the communication control circuit 13. When the lighting control device 90 receives the request signal, it transmits a command signal 91 notifying the illuminance detected by the illuminance sensor to the control unit 10.

When the control unit 10 receives the command signal 91, the control unit 10 converts the command signal 91 into a control signal 92 for transmitting to the control circuit 4b. Next, the control unit 10 transmits the control signal 92 to the control circuit 4b. The control circuit 4b controls the lighting circuit 4a based on the received control signal 92 to adjust the amount of current in the light emitting unit 3. As a result, the dimming rate notified by the control signal 92 is reflected in the light emitting unit 3.

Upon receiving the control signal 92, the processing circuit 26 turns off the switch unit 4d. As a result, the supply of the control power supply to the control unit 10 is cut off. Next, the control circuit 4b starts the time count using the counter 24. The control circuit 4b is composed of, for example, a microcomputer. As the counter 24, a counter inside the microcomputer can be used. When the predetermined time has elapsed, the counter 24 stops counting. The specified time is, for example, 10 minutes. After that, the processing circuit 26 resets the counter again. After that, the control circuit 4b repeats a series of operations from the counter reset to the count stop.

In the present embodiment, the control circuit 4b intermittently makes the switch unit 4d conductive. As a result, the control unit 10 intermittently communicates with the light source lighting device 4. Further, during the period when communication is not performed, the supply of the control power supply to the control unit 10 is cut off. Therefore, the power consumption of the control unit 10 can be reduced.

Here, the configuration in which the illuminance sensor is mounted on the lighting control device 90 has been described. On the other hand, for example, the control unit 10 may be equipped with an illuminance sensor. Next, the operation of the luminaire 1 including the control unit 10 equipped with the illuminance sensor will be described.

First, the control circuit 4b turns on the switch unit 4d to supply control power to the control unit 10. As a result, the control unit 10 is activated. Next, the control unit 10 transmits a control signal 92 based on the illuminance detected by the built-in illuminance sensor to the control circuit 4b. The control circuit 4b receives the control signal 92. The control circuit 4b controls the lighting circuit 4a in response to the control signal 92, and adjusts the amount of current in the light emitting unit 3. Next, the control circuit 4b cuts off the supply of the control power supply to the control unit 10. The control circuit 4b counts the time with the counter 24. When the predetermined predetermined time elapses, the control circuit 4b starts supplying the control power supply to the control unit 10 again. Here, the specified time is, for example, 10 minutes. After that, the control circuit 4b repeats a series of operations.

In this way, the light source lighting device 4 intermittently takes in the control signal 92 based on the illuminance detected by the illuminance sensor directly from the control unit 10. Further, during the period when communication is not performed, the supply of the control power supply to the control unit 10 is cut off. Therefore, the power consumption of the control unit 10 can be reduced. Further, when the control unit 10 equipped with the illuminance sensor is used, the external lighting control device 90 and the control unit 10 do not have to have a wireless communication function. Therefore, the lighting system can be formed with a simple configuration.

Here, for example, the luminaire 1 equipped with the control unit 10 having a built-in illuminance sensor may transmit data based on the illuminance sensor to the luminaire not equipped with the illuminance sensor. In this case, the control unit 10 includes a wireless communication unit. One luminaire 1 equipped with a control unit 10 having a built-in illuminance sensor notifies a plurality of luminaires provided in the vicinity which do not have an illuminance sensor of illuminance by wireless communication. Therefore, it is possible to control a plurality of lighting fixtures having no illuminance sensor so as to be lit with an appropriate brightness. However, it is necessary to attach a control unit having a wireless communication function to a lighting fixture that does not have an illuminance sensor.

Here, an operation example when the lighting control device 90 is provided with an illuminance sensor is shown. On the other hand, the lighting control device 90 may include other types of sensors. For example, the sensor included in the lighting control device 90 may be a motion sensor that detects the presence / absence of a person. In this case, the lighting control device 90 equipped with the motion sensor is installed on the ceiling or the like. The control unit 10 and the light source lighting device 4 communicate with each other at shorter intervals than when the lighting control device 90 includes an illuminance sensor. Here, the interval at which the control unit 10 and the light source lighting device 4 communicate with each other is, for example, a few seconds interval.

During the period when communication is not performed, the control circuit 4b cuts off the supply of the control power supply to the control unit 10. When the supply of the control power supply to the control unit 10 is resumed, the control unit 10 transmits a signal requesting notification of the human detection result to the lighting control device 90. The lighting control device 90 transmits a command signal 91 according to the detection result. In response to the command signal 91, the control unit 10 transmits the control signal 92 to the control circuit 4b. The control circuit 4b controls lighting or extinguishing of the light emitting unit 3 according to the control signal 92.

While the control power supply of the control unit 10 is cut off, the lighting control device 90 stores information on the presence / absence of a person. Upon receiving a signal from the control unit 10 requesting notification of the detection result of a person, the lighting control device 90 transmits the stored information as a command signal 91.

The light source lighting device 4 may automatically determine the type of the control unit 10 connected to the connection unit 5 by the control circuit 4b. Further, the control circuit 4b may change the interval for automatic communication according to the type of the control unit 10 connected to the connection unit 5. For example, when the control unit 10 for communicating with the illuminance sensor is connected, the communication interval is set to 10 minutes. Further, when the control unit 10 for communicating with the motion sensor is connected, the communication interval is set to several seconds. As a result, it is possible to reduce the trouble of setting the device by the user.

Embodiment 3.
The configuration of the lighting fixture 1 according to the third embodiment of the present invention is the same as that of the first embodiment. In the present embodiment, the timing of supplying and shutting off the control power supply to the control unit 10 when the external power supply 70 is turned on to the light source lighting device 4 and when the external power supply 70 is shut off will be described. FIG. 4 is a time chart showing an operation sequence of the luminaire according to the third embodiment of the present invention. First, the operation sequence of the luminaire 1 when the external power source 70 is turned on to the light source lighting device 4 will be described with reference to FIG.

(Time t0 to t1)
By turning on the switch SW at time t0, the external power supply 70 is turned on to the light source lighting device 4. When the external power supply 70 is turned on, the voltage generated at the positive electrode of the capacitor 48 is input to the control power supply circuit 4c. The control power supply circuit 4c starts generating a control power supply voltage having a preset magnitude. The control power supply voltage is, for example, 10V. The generated control power supply voltage is applied to the control circuit 4b, and the control circuit 4b is activated. At this time, the switch unit 4d is in the off state. Therefore, the control power supply voltage is not applied to the control unit 10.

(Time t1 to t2)
When the control circuit 4b starts operating, the control circuit 4b turns on the switch unit 4d. As a result, the control power supply is supplied from the control power supply circuit 4c to the control unit 10. As a result, the control unit 10 is activated.

(Time t2 to t3)
When the control unit 10 starts operating, the control circuit 4b drives the switching element 49 to supply a current to the light emitting unit 3. As a result, the light emitting unit 3 starts lighting. The control circuit 4b controls the lighting circuit 4a according to the control signal 92 from the control unit 10, and adjusts the light source current flowing through the light emitting unit 3.

From the above, when the control power supply circuit 4c is activated, the control power supply is first supplied to the control circuit 4b. Further, the control power is not supplied to the control unit 10 until the start of the control circuit 4b is completed. For example, when the control circuit 4b is composed of a semiconductor circuit such as a microcomputer, if a signal is input from the control unit 10 or the like before the control circuit 4b is activated, the signal may not be received correctly. Therefore, the microcomputer may malfunction.

Further, for example, consider a case where control power is supplied to the control circuit 4b and the control unit 10 from independent control power circuits. In this case, if the start-up time is different in each control power supply circuit, the control power supply may be supplied to the control unit 10 before the control power supply is supplied to the control circuit 4b. In this case, there is a possibility that a signal from the control unit 10 is input to each port of the microcomputer in a state where the control power is not supplied to the microcomputer included in the control circuit 4b. In this case, the microcomputer may cause a latch-up phenomenon and fail.

In the present embodiment, when the power supply from the external power source 70 to the lighting circuit 4a is started, the control circuit 4b makes the switch unit 4d conductive after the power is supplied to the control circuit 4b. Therefore, the control power is supplied to the control unit 10 after the start of the control circuit 4b is completed. Therefore, it is possible to prevent a signal from being input to the control circuit 4b before the control circuit 4b completes the activation. Therefore, the malfunction of the microcomputer and the latch-up phenomenon can be prevented.

Next, the operation sequence of the luminaire 1 when the external power source 70 is cut off will be described with reference to FIG.

(Times t3 to t4)
At time t3, turning off the switch SW cuts off the power supply from the external power source 70 to the light source lighting device 4. Here, the lighting circuit 4a and the control power supply circuit 4c have a capacitor 48 and a capacitor 61 which are smoothing capacitors. Therefore, after the external power supply 70 is cut off, the control power supply circuit 4c can output the control power supply voltage for a certain period of time. Therefore, the control circuit 4b can operate even after the external power supply 70 is cut off. Further, when the switch SW is turned off, the light emitting unit 3 is turned off.

(Time t4 to t5)
When the control circuit 4b detects that the external power supply 70 is cut off, the control circuit 4b turns off the switch unit 4d. As a result, the supply of the control power supply to the control unit 10 is cut off. As a result, the control unit 10 stops operating. Note that, for example, the control circuit 4b can read the voltage applied to the voltage dividing resistors 42 and 43 to determine whether the external power supply 70 is cut off.

(Time t5 to t6)
The control power supply voltage output by the control power supply circuit 4c decreases with the passage of time. As a result, the operation of the control circuit 4b is stopped.

In the present embodiment, when the power supply from the external power source 70 to the lighting circuit 4a is cut off, the control circuit 4b cuts off the switch unit 4d, and then the power supply to the control circuit 4b is stopped. Therefore, when the external power supply 70 is cut off, the supply of the control power supply to the control unit 10 is first cut off, and the operation of the control unit 10 is stopped. After that, the supply of the control power supply to the control circuit 4b is stopped, and the operation of the control circuit 4b is stopped. As a result, it is possible to prevent the control signal 92 from being input from the control unit 10 after the control circuit 4b has stopped operating. Therefore, the malfunction of the control circuit 4b and the latch-up phenomenon can be prevented.

Embodiment 4.
FIG. 5 is a circuit block diagram of the light source lighting device and the control unit according to the fourth embodiment of the present invention. The configuration of the lighting fixture 1 according to the present embodiment is the same as that of the first embodiment. In the present embodiment, the voltage of the control power supply supplied to the control unit 10 while the light emitting unit 3 is off is set to be lower than the voltage supplied to the control unit 10 when the light emitting unit 3 is in the lighting state. Thereby, a method for reducing the energy consumption of the control unit 10 will be described.

The control circuit 4b includes a drive circuit 20, a microcomputer 21, and a step-down circuit 22 for driving the switching elements 46 and 49. Here, the microcomputer 21 includes the processing circuit 26, the storage device 23, and the counter 24 in FIG. Further, the step-down circuit 22 is omitted in FIG. Further, the control unit 10 includes a microcomputer 30 and a step-down circuit 31. The microcomputer 30 includes the communication control circuit 13 in FIG. Further, in FIG. 2, the step-down circuit 31 is omitted. Further, in FIG. 5, for convenience, the sensor unit 12 and the voltage dividing resistors 42 and 43 are omitted.

The drive circuit 20 drives the switching elements 46 and 49 according to the instructions of the microcomputer 21. The step-down circuit 22 supplies the drive power for the microcomputer 21. The step-down circuit 22 converts the control power supply voltage, which is the output voltage of the control power supply circuit 4c, into a voltage suitable for the operation of the microcomputer 21.

The microcomputer 30 acquires information from various sensors and the like transmitted from the lighting control device 90 and converts it into a control signal 92 for transmission to the control circuit 4b. The step-down circuit 31 supplies a drive power source for the microcomputer 30. The step-down circuit 31 converts the output voltage of the control power supply circuit 4c into a voltage suitable for the operation of the microcomputer 30. Here, the step-down circuit 22 and the step-down circuit 31 include, for example, a circuit that performs step-down with a 3-terminal regulator, a series regulator using transistors, a Zener diode, or the like.

FIG. 6 is a time chart showing an operation sequence of the luminaire according to the fourth embodiment of the present invention. First, the operation of the control power supply circuit 4c when the light emitting unit 3 is changed from the lit state to the extinguished state by the command signal 91 from the external lighting control device 90 will be described with reference to FIG. In the present embodiment, a case where the lighting control device 90 is a dimming controller will be described.

(Time t0 to t1)
At times t0 to t1, the LED unit, which is the light emitting unit 3, is lit. For example, 10 V is applied to the control circuit 4b and the control unit 10 as a control power supply voltage. In order to drive the switching elements 46 and 49, the drive circuit 20 needs to be supplied with a power supply of 10 V. On the other hand, in order to drive the microcomputer 21, it is necessary to supply a power supply of, for example, 3.3 V.

Therefore, the control power supply voltage of 10 V is stepped down to 3.3 V by the step-down circuit 22 and applied to the microcomputer 21. On the other hand, 10V is applied to the drive circuit 20. Similarly, in the control unit 10, it is necessary to supply a power supply of 3.3 V in order to drive the microcomputer 30. The control power supply voltage is stepped down to 3.3V by the step-down circuit 31 and applied to the microcomputer 30.

(Time t1 to t2)
At time t1, a command signal 91 for turning off the light emitting unit 3 is output from the dimming controller. In the present embodiment, the command signal 91 from the dimming controller represents a lighting signal in LOW and a lighting signal in HIGH. When the control unit 10 receives the HIGH signal, it transmits a control signal 92 for turning off the light emitting unit 3 to the light source lighting device 4. As a result, the light source current flowing through the light emitting unit 3 becomes zero, and the light emitting unit 3 is turned off. At this time, power is always supplied to the lighting circuit 4a from the external power source 70.

When the light emitting unit 3 is turned off, the control power supply circuit 4c changes the control power supply voltage from 10V to, for example, 5V. In the control power supply circuit 4c, the output voltage is changed by adjusting the duty ratio of the switching element 64 by the drive circuit 65. Here, the control circuit 4b may control the drive circuit 65 so as to lower the control power supply voltage in response to the control signal 92. Further, the control power supply circuit 4c may control the drive circuit 65 so as to lower the control power supply voltage by receiving the control signal 92 instructing the control power supply circuit 4c to turn off.

At this time, the switch unit 4d is in the ON state. The step-down circuit 31 generates 3.3V from 5V. The microcomputer 30 is driven by supplying 3.3 V from the step-down circuit 31. Similarly, the step-down circuit 22 produces 3.3V from 5V. The microcomputer 21 is driven by supplying 3.3 V from the step-down circuit 22. That is, even when the light emitting unit 3 is off, the output voltages of the step-down circuits 22 and 31 are the same as when they are on. When the light emitting unit 3 is in the extinguished state, it is not necessary to drive the switching elements 46 and 49. Therefore, it is not necessary to supply a control power supply voltage of 10 V to the drive circuit 20.

Next, the operation of the control power supply circuit 4c when the light emitting unit 3 is changed from the off state to the on state by the command signal 91 from the dimming controller will be described with reference to FIG.

(Time t2 to t3)
At time t2, the dimming controller outputs a LOW signal, which is a command signal 91 for lighting the light emitting unit 3. When the control unit 10 receives the LOW signal, it transmits a control signal 92 for lighting the light emitting unit 3 to the light source lighting device 4. When the light source lighting device 4 receives the control signal 92, the light source lighting device 4 changes the output voltage of the control power supply circuit 4c from 5V to 10V.

(Times t3 to t4)
When the output voltage of the control power supply circuit 4c reaches 10V, the drive circuit 20 drives the switching elements 46 and 49 based on the command of the microcomputer 21. As a result, the light emitting unit 3 lights up. At this time, the step-down circuits 22 and 31 generate 3.3V from the output voltage of the control power supply circuit 4c, which is 10V. Here, the control circuit 4b may include a voltage detection circuit that detects the output voltage of the control power supply circuit 4c.

(Time t4 ~)
A command signal 91 that cuts off the supply of the control power supply to the control unit 10 is output from the dimming controller. Based on the command signal 91, the control circuit 4b turns off the switch unit 4d. As a result, the output voltage of the step-down circuit 31 becomes zero, and the supply of electric power to the microcomputer 30 is cut off. Further, the control power supply circuit 4c maintains an output voltage of 10V. Therefore, the step-down circuit 22 generates 3.3V from 10V to maintain the driving of the microcomputer 21. Further, since the supply of the control power supply voltage to the drive circuit 20 is maintained, the lighting circuit 4a keeps the light emitting unit 3 lit.

In the present embodiment, the voltage generated by the control power supply circuit 4c when the light emitting element 81 is off is lower than the voltage generated by the control power supply circuit 4c when the light emitting element 81 is on. That is, when the light emitting unit 3 is lit, it is necessary to drive the switching elements 46 and 49. Therefore, a high voltage of 10 V is required as the control power supply voltage. At this time, the voltage stepped down from 10V to 3.3V is supplied to the circuits driven by the low voltage such as the microcomputers 21 and 30 by the step-down circuits 22 and 31.

On the other hand, when the light emitting unit 3 is off, the switching elements 46 and 49 are not driven. Therefore, a high voltage of 10V is not required. Further, the control circuit 4b is in a state of waiting for reception of a signal instructing lighting. At this time, the voltage supplied to the control circuit 4b and the control unit 10 may be a voltage of 3.3 V for driving the microcomputer 21 and the microcomputer 30.

Therefore, when the light emitting unit 3 is off, the output voltage of the control power supply circuit 4c is set to 5V, which is lower than the output voltage of 10V during lighting. As a result, the loss in the step-down circuits 22 and 31 can be reduced. For example, in order to generate 3.3V from 10V, 6.7V, which is a difference between 10V and 3.3V, is applied to the step-down circuits 22 and 31. On the other hand, when the control power supply voltage is set to 5V, the voltage applied to the step-down circuits 22 and 31 is reduced to 1.7V. Here, the loss of the step-down circuit is determined by the product of the voltage applied to the step-down circuit and the current flowing through the step-down circuit. Therefore, if the current values are the same, the loss of the step-down circuits 22 and 31 can be significantly reduced by lowering the control power supply voltage.

As described above, in the present embodiment, the control power supply voltage supplied to the control unit 10 is set lower than the control power supply voltage supplied when the light emitting unit 3 is lit while the light emitting unit 3 is off. Therefore, the power consumption of the control unit 10 can be reduced. The technical features described in each embodiment may be used in combination as appropriate.

1 Lighting equipment, 2 housings, 4 light source lighting device, 4a lighting circuit, 4b control circuit, 4c control power supply circuit, 4d switch unit, 10 control unit, 12 sensor unit, 70 external power supply, 81 light emitting element

Claims (18)

Light emitting element and
A lighting circuit that lights the light emitting element and
A control unit that emits control signals and
A control circuit that controls the lighting circuit in response to the control signal,
A control power supply circuit that supplies power to the control circuit and the control unit,
A switch unit provided in a path for supplying electric power from the control power supply circuit to the control unit,
A housing to which a light source lighting device including the lighting circuit, the control circuit, the control power supply circuit, the switch unit, and the light emitting element are attached.
With
The control unit is detachably attached to the housing and is attached to the housing .
A lighting fixture characterized in that the supply of electric power from the control power supply circuit to the control circuit is maintained in a state where the switch unit cuts off the supply of electric power from the control power supply circuit to the control unit . Light emitting element and
A lighting circuit that lights the light emitting element and
A control unit that emits control signals and
A control circuit that controls the lighting circuit in response to the control signal,
A control power supply circuit that supplies power to the control circuit and the control unit,
A switch unit provided in a path for supplying electric power from the control power supply circuit to the control unit,
With
The control circuit shuts off the switch unit in response to the control signal .
A lighting fixture characterized in that the supply of electric power from the control power supply circuit to the control circuit is maintained in a state where the switch unit cuts off the supply of electric power from the control power supply circuit to the control unit . A housing to which a light source lighting device including the lighting circuit, the control circuit, the control power supply circuit, the switch unit, and the light emitting element is attached is provided.
The lighting fixture according to claim 2, wherein the control unit is detachably attached to the housing. The luminaire according to claim 1 or 3, wherein the control circuit determines the type of the control unit. Any of claims 1 to 4, wherein the control unit includes a sensor unit for communicating with an external lighting control device, and emits the control signal in response to a signal emitted by the lighting control device. The lighting equipment according to item 1. The control circuit is characterized in that when the switch unit is shut off while the light emitting element is lit, the control circuit controls the lighting circuit so as to maintain the dimming rate before the switch unit is cut off. The lighting equipment according to any one of 1 to 5. The luminaire according to any one of claims 1 to 6 , wherein the control circuit intermittently brings the switch portion into a conductive state. The luminaire according to claim 7 , wherein the control unit emits the control signal in response to a signal emitted by the illuminance sensor. The luminaire according to claim 7 , wherein the control unit emits the control signal in response to a signal emitted by the motion sensor. Any one of claims 1 to 9 , wherein the voltage generated by the control power supply circuit when the light emitting element is off is lower than the voltage generated by the control power supply circuit when the light emitting element is on. Lighting equipment described in. Light emitting element and
A lighting circuit that lights the light emitting element and
A control unit that emits control signals and
A control circuit that controls the lighting circuit in response to the control signal,
A control power supply circuit that supplies power to the control circuit and the control unit,
A switch unit provided in a path for supplying electric power from the control power supply circuit to the control unit,
A housing to which a light source lighting device including the lighting circuit, the control circuit, the control power supply circuit, the switch unit, and the light emitting element are attached.
With
The control unit is detachably attached to the housing and is attached to the housing.
In a state where power is supplied from the external power supply to the lighting circuit and the switch unit is cut off, the power supply from the external power supply to the lighting circuit is cut off, and then the power supply from the external power supply to the lighting circuit is cut off. A lighting fixture characterized in that when power supply is started, the control circuit makes the switch portion conductive. Light emitting element and
A lighting circuit that lights the light emitting element and
A control unit that emits control signals and
A control circuit that controls the lighting circuit in response to the control signal,
A control power supply circuit that supplies power to the control circuit and the control unit,
A switch unit provided in a path for supplying electric power from the control power supply circuit to the control unit,
With
The control circuit shuts off the switch unit in response to the control signal.
In a state where power is supplied from the external power supply to the lighting circuit and the switch unit is cut off, the power supply from the external power supply to the lighting circuit is cut off, and then the power supply from the external power supply to the lighting circuit is cut off. A lighting fixture characterized in that when power supply is started, the control circuit makes the switch portion conductive. A claim, wherein the control circuit shuts off the switch unit when it does not receive the control signal for releasing the cutoff of the switch unit within a certain period of time after the switch unit becomes conductive. The lighting fixture according to 11 or 12. The control circuit maintains the dimming rate at the time of the previous lighting when the control signal for releasing the cutoff of the switch unit is not received within the fixed period after the switch unit becomes conductive. The lighting equipment according to claim 13, wherein the lighting circuit is controlled. Light emitting element and
A lighting circuit that lights the light emitting element and
A control unit that emits control signals and
A control circuit that controls the lighting circuit in response to the control signal,
A control power supply circuit that supplies power to the control circuit and the control unit,
A switch unit provided in a path for supplying electric power from the control power supply circuit to the control unit,
A housing to which a light source lighting device including the lighting circuit, the control circuit, the control power supply circuit, the switch unit, and the light emitting element are attached.
With
The control unit is detachably attached to the housing and is attached to the housing.
A lighting fixture characterized in that when power is supplied from an external power source to the lighting circuit, the control circuit makes the switch unit conductive after the power is supplied to the control circuit. Light emitting element and
A lighting circuit that lights the light emitting element and
A control unit that emits control signals and
A control circuit that controls the lighting circuit in response to the control signal,
A control power supply circuit that supplies power to the control circuit and the control unit,
A switch unit provided in a path for supplying electric power from the control power supply circuit to the control unit,
With
The control circuit shuts off the switch unit in response to the control signal.
A lighting fixture characterized in that when power is supplied from an external power source to the lighting circuit, the control circuit makes the switch unit conductive after the power is supplied to the control circuit. Light emitting element and
A lighting circuit that lights the light emitting element and
A control unit that emits control signals and
A control circuit that controls the lighting circuit in response to the control signal,
A control power supply circuit that supplies power to the control circuit and the control unit,
A switch unit provided in a path for supplying electric power from the control power supply circuit to the control unit,
A housing to which a light source lighting device including the lighting circuit, the control circuit, the control power supply circuit, the switch unit, and the light emitting element are attached.
With
The control unit is detachably attached to the housing and is attached to the housing.
A lighting fixture characterized in that when the power supply from an external power source to the lighting circuit is cut off, the power supply to the control circuit is stopped after the control circuit cuts off the switch unit. Light emitting element and
A lighting circuit that lights the light emitting element and
A control unit that emits control signals and
A control circuit that controls the lighting circuit in response to the control signal,
A control power supply circuit that supplies power to the control circuit and the control unit,
A switch unit provided in a path for supplying electric power from the control power supply circuit to the control unit,
With
The control circuit shuts off the switch unit in response to the control signal.
A lighting fixture characterized in that when the power supply from an external power source to the lighting circuit is cut off, the power supply to the control circuit is stopped after the control circuit cuts off the switch unit.

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