JP2020184467A - Control unit for illumination apparatus and illumination apparatus - Google Patents

Abstract

To provide a control unit for an illumination apparatus suitable for controlling a plurality of light sources, the control unit suitably switching a control method depending on the number of light sources to be controlled.SOLUTION: A control unit for an illumination apparatus comprises: a first communication terminal 11 to which a first lighting device 4 for lighting up a first light source is connected; a second communication terminal 12 to which a second lighting device 5 for lighting up a second light source is connected; and a control section 7 for communicating a control signal by serially connecting with the first lighting device 4 and the second lighting device 5 via the first communication terminal 11 and the second communication terminal 12. The control unit for the illumination apparatus further comprises a connection detection circuit 47 and a switching circuit 48 that when the second lighting device 5 is not connected with the second communication terminal 12, function as a bypass circuit for bypassing the second communication terminal 12 to enable the control section 7 and the first lighting device 4 to communicate with each other.SELECTED DRAWING: Figure 3

Description

The present invention relates to a control unit and a luminaire for a luminaire, and more particularly to a control unit and a luminaire suitable for efficiently controlling a plurality of light sources.

Patent Document 1 below discloses a lighting system including a plurality of light sources. The system includes multiple power supply units that power each of the multiple light sources. The plurality of power supply units are controlled by one control unit.

If a plurality of light sources are controlled by different control units, the control timing tends to vary, for example, when all the light sources are turned on from the off state. On the other hand, according to the lighting system described in Patent Document 1, since the control signal emitted from one control unit is equally given to a plurality of light sources, such control timing variation does not occur. Therefore, according to this system, a plurality of light sources can be uniformly controlled without variation.

Japanese Unexamined Patent Publication No. 2016-10875

However, the control unit described in Patent Document 1 operates on the premise that the light sources are connected to all the power supply units included in the lighting system and all of the light sources are functioning normally. The control unit is configured to always supply control signals in parallel to all of these power supply units.

Therefore, in a mode in which the light source is not connected to some power supply units, the lighting system described in Patent Document 1 may not be able to control all the light sources correctly, or may generate a useless control signal. This can lead to wasteful power consumption. A similar problem may occur when an abnormality occurs in a light source that was initially functioning normally and the same situation occurs when the light source is not connected.

The present invention has been made to solve the above-mentioned problems, and one or two light sources can be controlled, and a control method is preferably used according to the number of light sources to be controlled. A primary object is to provide a control unit for a luminaire that can be switched.
A second aspect of the present invention is to provide a luminaire capable of controlling one or two light sources and capable of suitably switching a control method according to the number of light sources to be controlled. The purpose of.

The first invention is a control unit for a lighting fixture, for lighting a first communication terminal to which a first lighting device for lighting a first light source is connected, and a second light source. The second communication terminal to which the second lighting device is connected is serially connected to the first lighting device and the second lighting device via the first communication terminal and the second communication terminal. When the control unit that communicates the control signal and the second lighting device are not connected to the second communication terminal, the second communication terminal is bypassed and the control unit and the first It is characterized by including a bypass circuit that enables communication with a lighting device.

The second invention also comprises one or two light sources, a first lighting device and a second lighting device that control the power supplied to the one light source, respectively, the first lighting device, and the second lighting device. A lighting device including a control unit that communicates with the lighting device of the above, wherein the control unit converts a command signal related to lighting into a control signal that communicates with the first lighting device and the second lighting device. When a DC voltage is supplied from the second lighting device to the control unit, the control unit is serially connected to the first lighting device and the second lighting device to control the control. When the signal is communicated and the DC voltage is not supplied from the second lighting device to the control unit, the control signal is communicated by serially connecting to the first lighting device.

According to the first invention, the first light source is connected to the first communication terminal via the first lighting device, and the second communication terminal is connected to the second communication terminal via the second lighting device. When the second light source is connected, the control unit serially provides a control signal to the first lighting device and the second lighting device. As a result, the first light source and the second light source are appropriately controlled by the control signal. Further, according to the first invention, when the second lighting device is not connected to the second communication terminal, the second communication terminal is bypassed and the control signal is provided only to the first lighting device. To. In this case, the control unit can appropriately control the first light source to be controlled without wasteful power consumption.

According to the second invention, the command signal related to lighting is converted into a control signal in the control unit. When the second lighting device is operating normally, a DC voltage is supplied from the second lighting device to the control unit. Then, in this case, the control signal generated by the control unit is serially provided to the first lighting device and the second lighting device. As a result, the first light source and the second light source are appropriately controlled by the control signal. On the other hand, if the DC voltage is not supplied from the second lighting device to the control unit because the second lighting device is not connected or the second lighting device is not operating normally, control is performed. The control signal generated by the unit is provided only to the first lighting device. As a result, the control unit can appropriately control the first light source to be controlled without wasteful power consumption.

It is a figure for demonstrating the structure of the luminaire of Embodiment 1 of this invention. It is a figure for demonstrating the structure of the 1st lighting apparatus shown in FIG. It is a figure for demonstrating the structure of the control unit shown in FIG. It is a figure for demonstrating the signal path realized when the 1st lighting device and the 2nd lighting device are connected to the control unit shown in FIG. It is a figure for demonstrating the signal path realized when the first lighting device is connected to the control unit shown in FIG. 1 and the second lighting device is not connected. It is a figure for demonstrating the structure of the control unit included in the luminaire of Embodiment 2 of this invention. 6 is a flowchart for explaining the flow of the circuit switching process executed by the control unit shown in FIG. 6 in the initial setting. It is a flowchart for demonstrating the flow of the circuit switching process which the control unit shown in FIG. 6 periodically executes during operation. It is a figure for demonstrating the structure of the control unit included in the luminaire of Embodiment 3 of this invention. It is a figure for demonstrating the structure of the control unit included in the luminaire of Embodiment 4 of this invention.

Embodiment 1.
Hereinafter, the lighting fixture according to the embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing a configuration of a lighting fixture according to a first embodiment of the present invention. The luminaire 1 of the present embodiment includes a first light source 2 and a second light source 3. The first lighting device 4 is connected to the first light source 2. A second lighting device 5 is connected to the second light source 3. The first lighting device 4 and the second lighting device 5 supply drive signals to the first light source 2 or the second light source 3 to bring them into a desired lighting state, respectively.

The luminaire 1 of the present embodiment includes a control unit 6. The control unit 6 is a unit configured on a board separate from the first lighting device 4 and the second lighting device 5, and includes a first communication terminal 11 and a second communication terminal 12. .. The first communication terminal 11 is connected to the third communication terminal 13 included in the first lighting device 4. Further, the second communication terminal 12 is connected to the fourth communication terminal 14 included in the second lighting device 5.

The control unit 6 further includes a dimming signal terminal 15. A lighting control device 9 arranged outside the control unit 6 is connected to the dimming signal terminal 15. The lighting control device 9 can exchange signals with the control unit 6 via the dimming signal terminal 15. More specifically, the lighting control device 9 gives the control unit 6 a signal instructing the lighting state required for the first light source 2 and the second light source 3 via the dimming signal terminal 15. Further, the lighting control device 9 can receive a signal or the like indicating the operating state of the first light source 2 and the second light source 3 from the control unit 6.

FIG. 2 shows the configuration of the first lighting device 4 shown in FIG. Since the configuration of the second lighting device 5 is the same as the configuration of the first lighting device 4, the configuration of the first lighting device 4 will be described here as a representative example thereof. In FIG. 2, the same elements as those shown in FIG. 1 are designated by common reference numerals, and duplicate description will be omitted.

The first lighting device 4 includes a rectifier circuit 37 that rectifies an AC power source and converts it into a direct current. Further, the first lighting device 4 includes a lighting circuit 38 that lights the first light source 2 by using the direct current generated by the rectifier circuit 37. The operation of the lighting circuit 38 is controlled by the control circuit 41.

The first lighting device 4 further includes a first power supply circuit 39 and a second power supply circuit 40. The first power supply circuit 39 generates a DC voltage Vdd that the first lighting device 4 outputs to the outside. This DC voltage Vdd is provided to the control unit 6 shown in FIG. 1 from the Vdd3 terminal of the third communication terminal 13. Further, the second power supply circuit 40 generates the operating voltage Vcc of the control circuit 41.

The third communication terminal 13 includes an Rx3 terminal, a Tx3 terminal, and a GND3 terminal in addition to the Vdd3 terminal described above. The Rx3 terminal is a terminal for receiving a serial signal provided by the control unit 6. On the other hand, the Tx3 terminal is a terminal for outputting a serial signal from the first lighting device 4 to the control unit 6. Further, the GND3 terminal is a terminal for sharing the ground of the first lighting device 4 and the ground of the control unit 6.

The first lighting device 4 receives a control signal in the form of a serial signal from the Rx3 terminal. Specifically, this control signal includes a dimming command signal for adjusting the brightness of the first light source 2, a power monitor signal for confirming the power consumption of the first lighting device 4, and the like. It has been. The first lighting device 4 that receives the control signal controls the first light source 2 to a desired state, and returns the first response signal from the Tx3 terminal to the control unit 6. Here, the first response signal includes a serial signal captured by the first lighting device 4 from the Rx3 terminal and a response generated by the first lighting device 4 itself in response to a power monitor signal or the like in that order. It is a serial signal of 2 frames or more.

FIG. 3 is a diagram showing a detailed configuration of the control unit 6 shown in FIG. As described above, the control unit 6 includes a dimming signal terminal 15 for obtaining a connection with an external device. A dimming signal conversion unit 8 is connected to the dimming signal terminal 15. The dimming signal conversion unit 8 converts the signal input from the external device to the dimming signal terminal 15 into a High / Low digital signal and provides it to the control unit 7.

The communication specification of the dimming signal terminal 15 includes, for example, a PWM signal or a wired signal such as a DALI (Digital Addressable Lighting Interface (registered trademark)) signal defined by IEC62386. The communication specifications of the first communication terminal 11 and the third communication terminal 13 are bidirectional serial communication methods.

The control unit 7 converts the digital signal received from the dimming signal conversion unit 8 into a control signal for supplying the first lighting device 4 and the second lighting device 5. This control signal is supplied from the Tx terminal of the control unit 7 to the Tx1 terminal of the first communication terminal 11. The control unit 7 further includes an Rx terminal and a GND terminal. The Rx terminal is a terminal for receiving the serial signal returned from the first lighting device 4 and the second lighting device 5. The GND terminal is a terminal for obtaining grounding of the control unit 7.

As shown in FIG. 1 or 2, the first lighting device 4 is connected to the first communication terminal 11 of the control unit 6. The first communication terminal 11 includes an Rx1 terminal, a GND1 terminal, and a Vdd1 terminal in addition to the Tx1 terminal described above. The Tx1 terminal is a terminal for providing the above control signal to the first lighting device 4. The Rx1 terminal is a terminal for receiving the serial signal returned from the first lighting device 4. Further, the GND terminal is a terminal for sharing the ground of the first lighting device 4 and the control unit 6.

The DC voltage Vdd generated by the first lighting device 4 is supplied to the Vdd1 terminal of the first communication terminal 11. Then, this DC voltage Vdd is supplied to the first voltage generation unit 10 via the Vdd1 terminal. The first voltage generation unit 10 receives the supply of the DC voltage Vdd to generate the first operating voltage Vcc1. This first operating voltage Vcc1 is used not only as the operating voltage of the control unit 7, but also as the driving voltage of the first photocoupler PC1 described later.

As shown in FIG. 1, a second lighting device 5 is connected to the second communication terminal 12 of the control unit 6. The second communication terminal 12 includes a Vdd2 terminal, a Tx2 terminal, an Rx2 terminal, and a GND2 terminal. A second voltage generation unit 16 is connected to the Vdd2 terminal. The second voltage generation unit 16 receives the DC voltage Vdd provided by the second lighting device 5 and generates the second operating voltage Vcc2. The second operating voltage Vcc2 is used as a driving voltage for the second photocoupler PC2 and the third photocoupler PC3, which will be described later. The Tx2 terminal is a terminal for providing a serial signal from the control unit 6 to the second lighting device 5. The Rx2 terminal is a terminal for receiving the serial signal returned from the second lighting device 5. Further, the GND terminal is a terminal for sharing the ground of the second lighting device 5 and the control unit 6.

The control unit 6 also includes an insulation circuit 49. The operation of the insulation circuit 49 will be described in detail later, but for enabling communication between the first lighting device 4 and the control unit 6 and the second lighting device 5 while maintaining the insulation between the two. It is a circuit. In other words, it is a circuit for delivering the signal input to the Rx1 terminal to the Tx2 terminal in a state of being insulated from the voltage of the Vdd1 terminal. The insulation circuit 49 is composed of PC1, PC2, Q3 which is an n-type MOSFET, Q4 which is an n-type MOSFET, and peripheral components.

The control unit 6 further includes a connection detection circuit 47 and a switching circuit 48. The connection detection circuit 47 is a circuit for generating a signal according to whether or not the second lighting device 5 is connected to the second communication terminal 12. The connection detection circuit 47 is composed of a PC 3 and peripheral components. The switching circuit 48 determines a state in which the Rx1 terminal and the Rx terminal are cut off and a state in which both are directly connected, depending on whether or not the second lighting device 5 is connected to the second communication terminal 12. It is a circuit for switching. The switching circuit 48 is composed of Q1 which is an n-type MOSFET, Q2 which is a p-type second MOSFET, and peripheral components.

Next, the operation when two units, the first lighting device 4 and the second lighting device 5, are connected to the control unit 6 will be described.

When the second lighting device 5 is properly connected to the second communication terminal 12, the DC voltage Vdd is provided to the Vdd2 terminal, so that the second voltage generation unit 16 generates the second operating voltage Vcc2. Will be done. In this case, a current flows through the light emitting element side of the PC3, the transistor side thereof turns on, and as a result, Q1 turns off. When Q1 is turned off, Q2 is always turned off, so that the Rx1 terminal and the Rx terminal are cut off.

When the first lighting device 4 is properly connected to the first communication terminal 11, the first voltage generation unit 10 provides the control unit 7 with the first operating voltage Vcc1. Upon receiving the provision of the first operating voltage Vcc1, the control unit 7 transmits a control signal according to the command of the lighting control device 9 shown in FIG. 1 from the Tx terminal. This control signal is received by the first lighting device 4 via the Tx1 terminal included in the first communication terminal 11.

When the first lighting device 4 receives the control signal, as described above, the first lighting device 4 outputs the first response signal including the control signal and the response generated by itself from the Tx3 terminal in the form of a serial signal. Then, the control unit 6 receives the serial signal at the Rx1 terminal of the first communication terminal.

The signal input to the Rx1 terminal is supplied to the source of Q2 and the gate of Q3. Since Q2 is OFF as described above, the input signal does not reach the Rx terminal of the control unit 7. On the other hand, Q3 is turned ON / OFF according to the input signal. Then, when Q3 is ON, a current flows to the light emitting element side of the PC1 and the transistor side thereof is ON, so that the Tx2 terminal becomes High. Further, when Q3 is OFF, the Tx2 terminal becomes Low because no current flows through the PC1. That is, in this case, the same signal as the signal input to the Rx1 terminal arrives at the Tx2 terminal of the control unit 6.

The second lighting device 5 operates in the same manner as the first lighting device 4, and returns a serial signal including the serial signal received from the Tx2 terminal and the response generated by itself to the Rx2 terminal in that order. Hereinafter, this reply signal will be referred to as a "second response signal". The signal input to the Rx2 terminal of the control unit 6 reaches the gate of Q4. Therefore, Q4 is turned ON / OFF according to the second response signal. Then, when Q4 is turned ON, a current flows to the light emitting element side of the PC2, and the state is transmitted to the transistor side, so that the Rx terminal becomes High. Further, if Q4 is OFF, no current flows through the PC2, so the Rx terminal becomes Low. That is, in this case, the same signal as the signal input to the Rx2 terminal of the second communication terminal 12, that is, the second response signal is input to the Rx terminal of the control unit 7.

As described above, according to the lighting fixture of the present embodiment, in a situation where two units of the first lighting device 4 and the second lighting device 5 are connected to the control unit 6, the insulation circuit 49 is used. , The first lighting device 4 and the control unit 6 and the second lighting device 5 can communicate with each other while maintaining an insulated state.

Next, the operation when only the first lighting device 4 is connected to the control unit 6, that is, when the second lighting device 5 is not connected to the second communication terminal 12, will be described.

If the second lighting device 5 is not connected, the DC voltage Vdd is not supplied to the Vdd2 terminal, and the second operating voltage Vcc2 is not generated. In this case, since no current flows through the PC2 of the insulation circuit 49, the potential of the Rx terminal is determined by the drain potential of Q2.

If the second operating voltage Vcc2 is not generated, no current flows through the PC3 of the connection detection circuit 47. Therefore, in this case, Q1 of the switching circuit 48 is always ON. If the source of Q2 becomes High while Q1 is ON, Q2 becomes ON and the High potential is supplied to the Rx terminal of the control unit 7. On the other hand, when the source of Q2 becomes Low, Q2 becomes OFF and the Rx terminal becomes Low. That is, in a situation where the second lighting device 5 is not connected, the signal input to the Rx1 terminal of the first communication terminal 11 reaches the Rx terminal of the control unit 7 as it is.

As described above, the control unit 6 of the present embodiment detects the situation in the connection detection circuit 47 under the situation where the two lighting devices are connected, and the control unit 7 and the first lighting device 4 It is possible to create a situation in which the second lighting device 5 is substantially serially connected. On the other hand, in a situation where the second lighting device 5 is not connected to the second communication terminal 12, the situation is detected, the second communication terminal 12 is bypassed, and the first lighting device 4 is alone. It is possible to create a situation in which communication with the control unit 7 can be performed.

The control unit 6 of the present embodiment can automatically switch between them, and enables bidirectional communication between the lighting device and the control unit 7 regardless of the number of connected lighting devices. Therefore, according to the control unit 6 of the present embodiment, the control unit for connecting and using one lighting device and the control unit for connecting and using two lighting devices are standardized. be able to.

FIG. 4 shows a signal realized when the lighting control device 9, the first lighting device 4, and the second lighting device 5 are connected to the control unit 6 in the luminaire according to the first embodiment of the present invention. Indicates the communication path.

As described above, the control unit 7 of the control unit 6 receives the dimming command provided by the lighting control device 9 and outputs the control signal of the digital signal from the Tx terminal. This signal is transmitted as a control signal 33 from the Tx1 terminal of the control unit 6 to the Rx3 terminal of the first lighting device 4. When the first lighting device 4 receives the control signal 33, the first lighting device 4 returns the first response signal 34 from the Tx3 terminal. The first response signal 34 includes the same signal as the control signal 33 and a response indicating the operating state of the first lighting device 4. The first response signal 34 is transmitted to the Rx1 terminal of the control unit 6.

Under the situation shown in FIG. 4, the control unit 6 transmits the first response signal 34 received at the Rx1 terminal to the Tx2 terminal via the insulation circuit 49. Then, this signal is transmitted from the Tx2 terminal to the Rx4 terminal as a control signal 35 for the second lighting device 5. When the second lighting device 5 receives the control signal 35, the second lighting device 5 returns a second response signal 36 from the Tx4 terminal. The second response signal 36 includes the same signal as the control signal 35 and a response indicating the operating state of the second lighting device 5. The second response signal 36 is input to the Rx2 terminal of the control unit 6 and reaches the Rx terminal of the control unit 7 via the insulation circuit 49.

If the signal input to the Rx terminal is a control signal transmitted from the Tx terminal, the control unit 7 sets the signal sequence as the first frame, sets the second frame as the response of the first lighting device 4, and sets the third frame as the response of the first lighting device 4. It is processed as a response of the second lighting device 5. A fixed time after receiving the first frame is set as a response signal reception period, and a response that does not complete reception within that period is discarded.

As described above, in the present embodiment, the first response signal 34 returned from the first lighting device 4 includes the same signal as the control signal 33 emitted from the Tx terminal of the control unit 7. The response signal 34 of the above can be used as the control signal 35 of the second lighting device 5. Further, in the present embodiment, the response generated by the first lighting device 4 and the response generated by the second lighting device 5 are serially connected and included in the second response signal 36. Therefore, the control unit 7 controls both the first lighting device 4 and the second lighting device 5 by using a set of serial ports Tx and Rx, and is required from those two lighting devices. Information can be obtained.

FIG. 5 shows a signal communication path realized when the lighting control device 9 and the first lighting device 4 are connected to the control unit 6 in the lighting device according to the first embodiment of the present invention.

Even when there is only one lighting device connected to the control unit 6, the control signal generated by the control unit 7 is emitted from the Tx terminal of the control unit 7 and passes through the Tx1 terminal of the first communication terminal 11. , Is transmitted as a control signal 33 to the Rx3 terminal of the first lighting device 4. When the first lighting device 4 receives the control signal 33, it returns the first response signal 34 from the Tx3 terminal to the Rx1 terminal, as in the case shown in FIG. The first response signal 34 includes the same signal as the control signal 33 and a response indicating the operating state of the first lighting device 4.

According to the signal communication path shown in FIG. 5, the first response signal 34 received at the Rx1 terminal is transmitted to the Rx terminal of the control unit 7 via the switching circuit 48. If the signal input to the Rx terminal is a control signal transmitted from the Tx terminal, the control unit 7 processes the signal sequence as the first frame and the subsequent second frame as the response of the first lighting device 4. .. A fixed time after receiving the first frame is set as a response signal reception period, and a response that does not complete reception within that period is discarded. This period is common to the case of connecting two units described with reference to FIG. 4, and when the control signal is received again during the response signal reception period, the period is reset at that time.

Since the response signal reception period when two units are connected and the response signal reception period when one unit is connected are common and the period is reset each time a control signal is received, regardless of the number of connected units, The lighting equipment can always be operated smoothly without causing unnecessary waiting time. As a result, it is not necessary to detect the power connection of the second lighting device 5 and automatically detect that the number of connected devices has been switched by the control unit 7, and control the lighting device and control the lighting device regardless of the number of connected devices. It is possible to properly collect information from the lighting device.

[Modified Example of Embodiment 1]
By the way, in the above-described first embodiment, when the first lighting device 4 and the second lighting device 5 are connected to the control unit 6, a control signal common to both is provided. .. However, the present invention is not limited to this. For example, an address may be individually assigned to the first lighting device 4 and the second lighting device 5, and the control unit 7 may generate a control signal including the address for each lighting device. Then, the first lighting device 4 and the second lighting device 5 are made to process only the control signal that matches their own address, and the other control signals cannot follow the control signal. A response signal of a frame or more may be returned. According to such a method, it is possible to individually control the first lighting device 4 and the second lighting device 5 with the same communication specifications as in the case of the first embodiment.

Further, in the first embodiment described above, the lighting control device 9 only issues a command to the control unit 6, but the present invention is not limited to this. For example, the lighting control device 9 may request the control unit 6 to respond with information regarding the operating state of the first lighting device 4 and the second lighting device 5. Then, when the lighting control device 9 requests a response, the information received by the control unit 7 is converted into a signal corresponding to the communication standard of the lighting control device 9 by the dimming signal conversion unit 8, and the dimming signal terminal 15 is used. It may be output from.

Embodiment 2.
FIG. 6 is a diagram showing the configuration of the control unit 6 according to the second embodiment of the present invention. In FIG. 6, the same or corresponding elements as those shown in FIG. 3 are designated by common reference numerals, and the description thereof will be omitted or simplified.

In the control unit 6 shown in FIG. 6, the control unit 7 has an Out terminal for controlling the state of Q1 of the switching circuit 48. When the control unit 7 receives the supply of the first operating voltage Vcc1 from the first voltage generation unit 10, immediately after that, the control unit 7 detects High / Low of the Rx terminal and outputs the output according to the result from the Out terminal to Q1. To provide.

When the second lighting device 5 is connected to the control unit 6 shown in FIG. 6 together with the first lighting device 4, a current flows to the light emitting element side of the PC 2 when the voltage supply is started. As a result, the transistor side of the PC2 is turned on, and the Rx terminal of the control unit 7 becomes High. On the other hand, when the second lighting device 5 is not connected to the second communication terminal 12, no current flows to the light emitting element side of the PC 2, so that the transistor side is turned off and the Rx terminal of the control unit 7 becomes Low.

Paying attention to the above difference, when the Rx terminal is stable and Low after the start of voltage supply, the control unit 7 does not connect the second lighting device 5, and the number of connected lighting devices is 1. Judge that it is a stand. On the other hand, if High appears at the Rx terminal after the start of voltage supply, the control unit 7 determines that the control unit 6 is connected to the first lighting device 4 and the second lighting device 5. ..

In the present embodiment, when the second lighting device 5 is not connected to the second communication terminal 12, the transistor side of the PC 2 is always turned off as described above. Therefore, in this case, the potential of the Rx terminal of the control unit 7 is determined by the drain potential of Q2. Then, when the control unit 7 determines that the second lighting device 5 is not connected, the Out terminal is set to High. As a result, Q1 of the switching circuit 48 is turned ON. When Q1 is ON, Q2 is ON if its source potential is High, and OFF if its source potential is Low. Therefore, in this case, the signal received by the Rx1 terminal of the control unit 6 is directly applied to the Rx terminal of the control unit 7. That is, in the present embodiment, in the situation where the second lighting device 5 is not connected, the control unit 6 is the first lighting device as in the case where the first embodiment is described with reference to FIG. The response signal returned from 4 to the Rx1 terminal can be directly received by the Rx terminal of the control unit 7.

On the other hand, when the control unit 7 determines that the number of connected lighting devices is two, the Out terminal is set to Low. When the Out terminal becomes Low, Q1 of the switching circuit 48 is turned OFF. Then, when Q1 is turned off, Q2 is always turned off, and the potential of the Rx terminal of the control unit 7 is determined by ON / OFF of the PC2. Then, the operation of the control unit 6 in this case is the same as the operation in the case of the first embodiment described with reference to FIGS. 3 and 4.

As described above, according to the control unit 6 of the present embodiment, as in the case of the first embodiment, the signal communication path is set according to whether the number of connected lighting devices is one or two. It can be switched automatically. Then, the control unit 6 can appropriately control one or two connected lighting devices by using each signal communication path, and can appropriately collect information on the lighting devices.

Further, the control unit 7 in the present embodiment can appropriately determine whether or not the second lighting device 5 is connected based on the potential appearing at the Rx terminal after the start of voltage supply. Therefore, as compared with the case of the first embodiment, the connection detection circuit 47 becomes unnecessary, and the control unit 6 can be miniaturized. In addition, since the control unit 7 detects whether or not the second lighting device 5 is connected, the control unit 7 can be made to grasp the number of connected lighting devices. If it is stored in 7, the number of connected devices can be collated at any time after the fact.

[Initial setting]
FIG. 7 is a flowchart for explaining the flow of the circuit switching process executed by the control unit 7 in the initial setting in the second embodiment of the present invention. In the circuit configuration shown in FIG. 6, this process is executed by the control unit 7 to set the potential of the Out terminal.

When the first voltage generation unit 10 starts supplying the first operating voltage Vcc1, the control unit 7 starts the process shown in FIG. 7. When this process is activated, first, the initial setting of the control unit 7 is executed (step 100). After the initial setting is completed, the signal input to the Rx terminal is next detected, and it is determined whether or not the potential is Low (step 102).

As a result, when it is determined that the potential of the Rx terminal is Low continuously for a certain period of time, it is determined that the number of connected lighting devices is one (step 104). In this case, Next, High is output from the Out terminal of the control unit 7 (step 106).

On the other hand, when it is determined in step 102 that a High signal is input to the Rx terminal, it is determined that the number of connected lighting devices is two after confirming that the state continues for a certain period of time. (Step 108). Then, in this case, Low is output from the Out terminal of the control unit 7 (step 110).

[Periodic confirmation processing]
FIG. 8 is a flowchart of a circuit switching process that the control unit 7 periodically executes after the start of the operation in the second embodiment of the present invention. This process is executed in order to detect an abnormality such as a failure of the lighting device and a disconnection related to serial communication in a situation where two lighting devices are connected to the control unit 6 shown in FIG. 6 for operation. To.

The failure of the lighting device is detected based on the potential of the signal input to the Rx terminal of the control unit 7. Specifically, first, it is determined whether or not Low appears continuously for a certain period of time at the Rx terminal (step 112). For example, when the voltage supply to the Vdd2 terminal is turned off due to the failure of the second lighting device 5, the second operating voltage Vcc2 is not supplied to the light emitting element side of the PC2. In this case, the transistor side of the PC2 is turned off, and the Rx terminal is turned off. In this step 112, when the duration of Low exceeds the communication time of one frame of the serial signal communicating with the lighting device, it is determined that the second lighting device 5 has a failure (step 114). When the failure is determined, the output of the Out terminal is set to High (step 116). As a result, the signal communication path of the control unit 6 is switched to a path assuming the connection of one lighting device.

If it is determined in step 112 that the Low potential of the Rx terminal does not continue for a certain period of time, it can be determined that a voltage is being supplied to the Vdd2 terminal of the control unit 6 from the second lighting device 5. In this case, it is further determined whether or not the Rx terminal of the control unit 7 properly receives the response signal (step 118). Specifically, it is determined whether or not the response signal corresponding to the control signal output from the Tx terminal is correctly received by the Rx terminal. In this step 118, if the Rx terminal receives the response signal before the number of retransmissions of the control signal from the Tx terminal reaches the specified number of times, it is determined that the response signal has been normally received.

As a result of the above, when it can be determined that the Rx terminal has normally received the response signal, it is determined that the luminaire is operating normally (step 120). On the other hand, in step 118, if it cannot be determined that the Rx terminal has normally received the response signal, it is determined that a disconnection abnormality has occurred in the serial communication path (step 122). As described above, according to the present embodiment, the failure of the second lighting device 5 and the abnormality of the serial communication path can be detected by the above processing.

Further, in the lighting fixture of the present embodiment, when the first lighting device 4 fails, the voltage supply from the first lighting device 4 to the Vdd1 terminal is stopped. If no voltage is supplied to the Vdd1 terminal, the first operating voltage Vcc1 is not generated, so that the control unit 7 does not operate. Therefore, in this case, the control unit 6 and the lighting control device 9 cannot communicate with each other, and from that situation, the system side can detect the failure of the first lighting device 4. The point that such failure detection is possible is the same in the case of connecting one unit.

By executing the circuit switching process described above, the control unit 6 of the present embodiment fails during the operation of the luminaire, the first lighting device 4 and the second lighting device 5, and the control unit. It is possible to detect a disconnection of the communication path with 6 and the like. In addition, the control unit 6 can automatically control the switching circuit 48 to an appropriate state when it detects a failure of the lighting device. Therefore, according to the control unit 6 of the present embodiment, the lighting device that is operating normally until the failed lighting device or the like is repaired or replaced is appropriate while properly acquiring the information of the device. Can be controlled to.

Embodiment 3.
FIG. 9 is a diagram showing the configuration of the control unit 6 according to the third embodiment of the present invention. In FIG. 9, the same or corresponding elements as the components in the first embodiment or the second embodiment are designated by common reference numerals, and the description thereof will be omitted or simplified.

The control unit 6 of the present embodiment includes a wireless transmission / reception unit 43 for transmitting / receiving wireless signals to / from an external device. The user transmits an instruction to the wireless controller 42 by a data setting device 44 such as a remote controller. The wireless controller 42 transmits a signal according to the received instruction. The signal received by the wireless transmission / reception unit 43 is converted into data that can be received by the control unit 7. The converted signal is provided as a serial signal from the Tx1 terminal to the first lighting device 4. The data setting device 44 transmits a signal to the wireless controller 42, for example, by infrared communication.

The lighting fixture 1 of the third embodiment of the present invention acquires response information regarding the operating state and the like from the first lighting device 4 and the second lighting device 5 as in the case of the first or second embodiment. can do. Then, in the present embodiment, such information can be transmitted from the wireless transmission / reception unit 43 to the wireless controller 42.

If the response information acquired from the first lighting device 4 and the second lighting device 5 is information related to power consumption, the response information can be managed and analyzed by the host system of the wireless controller 42. As a result, it becomes possible to manage the energy of the facility, and it is possible to save energy by setting the dimming rate according to the environment.

If the wireless controller 42 is connected to the Internet and the data setting device 44 can also be connected to the network, the data setting device 44 does not have to be in the space where the wireless controller 42 is installed. It is possible to remotely control the lighting fixture 1 from 44.

Embodiment 4.
FIG. 10 is a diagram showing the configuration of the control unit 6 according to the fourth embodiment of the present invention. In FIG. 10, the elements common to or corresponding to the components of the control units according to the first to third embodiments are designated by the same reference numerals, and the description thereof will be omitted or simplified.

The control unit 6 of the present embodiment includes an external state acquisition sensor 45 that acquires the state of the external environment of the luminaire. The external state acquisition sensor 45 includes, for example, a pyroelectric sensor, a Doppler sensor, an illuminance sensor, and the like.

In the present embodiment, the information acquired by the external state acquisition sensor 45 is transmitted to the control unit 7. Based on the information, the control unit 7 can transmit instructions such as turning on, turning off, and dimming the light source to the first lighting device 4 and the second lighting device 5.

According to the lighting fixture 1 of the present embodiment, the dimming rate and the like of the first lighting device 4 and the second lighting device 5 are simultaneously adjusted according to the information on the external environment acquired by the single external state acquisition sensor 45. Can be controlled. At this time, since the plurality of lighting devices are controlled by a set of serial ports provided in the control unit 7, there is no deviation in the dimming timing of the first light source 2 and the second light source 3. Moreover, the dimming rates of a plurality of light sources are not set differently.

In the above-described first to fourth embodiments, when the second lighting device 5 is not connected to the second communication terminal 12, the connection detection circuit 47 that detects the situation and the signal communication path are switched. The switching circuit 48 to be performed forms the "bypass circuit" in the first invention.

1 lighting equipment, 2 first light source, 3 second light source, 4 first lighting device, 5 second lighting device, 6 control unit, 7 control unit, 8 dimming signal conversion unit, 9 lighting control device, 10 1st voltage generator, 11 1st communication terminal, 12 2nd communication terminal, 13 3rd communication terminal, 14 4th communication terminal, 15 dimming signal terminal, 16 2nd voltage generator, 33; 35 control signal, 34 first response signal, 36 second response signal, 37 rectifier circuit, 38 lighting circuit, 39 first power supply circuit, 40 second power supply circuit, 41 control circuit, 42 wireless controller, 43 wireless transmitter / receiver, 44 data setter, 45 external state acquisition sensor, 46 communication terminal, 47 connection detection circuit, 48 switching circuit, 49 insulation circuit

Claims (9)

The first communication terminal to which the first lighting device for lighting the first light source is connected,
A second communication terminal to which a second lighting device for lighting the second light source is connected,
A control unit that communicates a control signal by serially connecting to the first lighting device and the second lighting device via the first communication terminal and the second communication terminal.
A bypass circuit that bypasses the second communication terminal and enables communication between the control unit and the first lighting device when the second lighting device is not connected to the second communication terminal. When,
A control unit for luminaires, characterized by being equipped with. With one or two light sources,
A first lighting device and a second lighting device that control the power supplied to one light source, respectively.
A control unit that communicates with the first lighting device and the second lighting device is provided.
The control unit
It is provided with a control unit that converts a command signal for commanding a lighting state into a control signal that communicates with the first lighting device and the second lighting device.
The control unit
When a DC voltage is supplied to the control unit from the second lighting device, the control signal is communicated by serially connecting to the first lighting device and the second lighting device.
A lighting fixture characterized in that when a DC voltage is not supplied from the second lighting device to the control unit, it is serially connected to the first lighting device to communicate the control signal. The control unit receives a first response signal including the same signal as the control signal from the first lighting device, and receives the first response signal.
The luminaire according to claim 2, wherein when a DC voltage is supplied from the second lighting device, the same signal as the first response signal is transmitted to the second lighting device. .. The first response signal includes the response of the first lighting device to the control signal.
3. The control unit receives the first response signal from the first lighting device when a DC voltage is not supplied from the second lighting device to the control unit. Lighting equipment described in. When a DC voltage is supplied from the second lighting device to the control unit, the control unit receives a second response signal from the second lighting device.
Any one of claims 2 to 4, wherein the second response signal includes a response of the first lighting device to the control signal and a response of the second lighting device. Lighting equipment described in the section. The luminaire according to any one of claims 2 to 5, wherein the control unit operates by receiving a voltage supply from at least one of the first lighting device and the second lighting device. .. The first lighting device and the second lighting device each have an address.
The control signal includes an address that identifies a control target.
When the first lighting device and the second lighting device each respond to a control signal including their own address, the control unit separates the first lighting device and the second lighting device. The lighting equipment according to any one of claims 2 to 6, wherein the lighting equipment is controlled. The control signal includes a command for controlling the light source, and the first lighting device and the second lighting device control the power supplied to the light source in response to the control signal. The lighting equipment according to any one of Items 2 to 7. The control signal includes a command requesting a signal indicating the state of the first lighting device and the second lighting device, and the first lighting device and the second lighting device respond to the control signal. The lighting device according to any one of claims 2 to 8, wherein a signal indicating the state is returned.

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