JP6981906B2 - Signal conversion unit, lighting controller and lighting system - Google Patents

Description

The present invention relates to a signal conversion unit, a lighting control device and a lighting system.

The luminaire described in Patent Document 1 has a communication unit, a signal conversion unit (signal conversion unit), a lighting circuit unit, and a light source. The communication unit receives a control signal including information for controlling the illumination light from an external device. The signal conversion unit converts the control signal received by the communication unit into a lighting control signal. The lighting circuit unit lights the light source based on the lighting control signal.

Japanese Unexamined Patent Publication No. 2015-109196

However, in Patent Document 1, a plurality of lighting fixtures are connected to one external device that transmits a control signal. Each of the plurality of lighting fixtures has a signal conversion unit. Therefore, in Patent Document 1, it is necessary to attach a signal conversion unit for each luminaire, which increases the cost. Further, in recent years, there has been a demand for further improvement in convenience regarding the control of lighting equipment.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a signal conversion unit, a lighting control device, and a lighting system that can reduce costs while improving user convenience.

The signal conversion unit disclosed in the present application can connect a plurality of lighting fixtures to a controllable lighting control unit. The signal conversion unit includes a control unit, a communication unit, a conversion unit, a clock unit, and a storage unit. The communication unit receives the first control signal indicating the control information of the luminaire. The conversion unit converts the first control signal into a second control signal that can be recognized by the lighting control unit. The clock unit indicates the time. The storage unit stores in advance schedule information indicating the control schedule of the lighting fixture. The conversion unit generates a third control signal recognizable by the lighting control unit based on the schedule information. The control unit controls the communication unit so as to transmit the third control signal to the lighting control unit based on the time and the schedule information indicated by the clock unit.

In the signal conversion unit disclosed in the present application, it is preferable that the communication unit receives a storage instruction signal for storing the schedule information in the storage unit. It is preferable that the control unit controls the storage unit so as to store the schedule information according to the storage instruction signal.

In the signal conversion unit disclosed in the present application, it is preferable that the schedule information includes scene information that determines the state of the luminaire according to the scene.

In the signal conversion unit disclosed in the present application, the schedule information preferably includes start time information and fade period information. The start time information preferably indicates the start time at which the luminaire starts lighting in a constant lighting state. The fade period information preferably indicates the fade period during which the fade control is executed. It is preferable that the fade control indicates a control that continuously or stepwise changes the state of the luminaire. The end point of the fade period preferably indicates the start time.

The lighting control device disclosed in the present application includes a signal conversion unit and a lighting control unit. The signal conversion unit includes a first control unit, a first communication unit, a conversion unit for conversion, a clock unit, and a storage unit. The first communication unit receives the first control signal indicating the control information of the luminaire. The conversion unit converts the first control signal into a second control signal that can be recognized by the lighting control unit. The clock shows the time. The storage unit stores in advance schedule information indicating the control schedule of the lighting fixture. The conversion unit generates a third control signal recognizable by the lighting control unit based on the schedule information. The first control unit controls the first communication unit so as to transmit the third control signal to the lighting control unit based on the time and the schedule information indicated by the clock unit. The lighting control unit includes a second communication unit and a second control unit. The second communication unit receives the second control signal or the third control signal. The second control unit controls the luminaire according to the second control signal or the third control signal.

The lighting system disclosed in the present application includes a signal conversion unit, a lighting control unit, and a lighting fixture. The signal conversion unit includes a first control unit, a first communication unit, a conversion unit, a clock unit, and a storage unit. The first communication unit receives the first control signal indicating the control information of the luminaire. The conversion unit converts the first control signal into a second control signal that can be recognized by the lighting control unit. The clock shows the time. The storage unit stores in advance schedule information indicating the control schedule of the lighting fixture. The conversion unit generates a third control signal recognizable by the lighting control unit based on the schedule information. The first control unit controls the first communication unit so as to transmit the third control signal to the lighting control unit based on the time and the schedule information indicated by the clock unit. The lighting control unit includes a second communication unit and a second control unit. The second communication unit receives the second control signal or the third control signal. The second control unit controls the luminaire according to the second control signal or the third control signal.

According to the present invention, it is possible to reduce the cost while improving the convenience of the user.

It is a figure which shows the electric power system which concerns on embodiment of this invention. It is a figure which shows the lighting system which concerns on embodiment of this invention. It is a flowchart which shows the processing of the signal conversion unit and the lighting control unit of the lighting system which concerns on embodiment of this invention. It is a figure which shows an example of the schedule information of the lighting system which concerns on embodiment of this invention. It is a flowchart which shows the other processing of the signal conversion unit and the lighting control unit of the lighting system which concerns on embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention is not limited to the following embodiments. In the figure, the same or corresponding parts are designated by the same reference numerals and the description is not repeated. In order to make it easier to understand, the drawings schematically show each component as a main body.

The electric power system 100 according to the embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG. 1 is a diagram showing a power system 100. FIG. 2 is a diagram showing a lighting system 200. As shown in FIG. 1, the electric power system 100 is a system related to electric power in a predetermined facility. A facility is, for example, a building such as a house, a building, a factory, or a train station. In the present embodiment, the electric power system 100 is a system related to electric power in a house. Further, in the present embodiment, the electric power system 100 includes a lighting system 200, a distribution board 7, a plurality of home appliances 8, and a communication terminal 9.

The lighting system 200 includes a system control device 1, a router 2, a lighting control device 3, and a plurality of lighting fixtures 6. The router 2 is included in, for example, a home network. The home network refers to, for example, a LAN (Local Area Network) environment of a communication system constructed in a home. In the present embodiment, the router 2 is connected to each of the lighting control device 3, the distribution board 7, and the communication terminal 9 via wireless communication. The router 2 may be connected to each of the lighting control device 3, the distribution board 7, and the communication terminal 9 via wired communication.

The system control device 1 is, for example, a terminal capable of connecting to a predetermined network. In this embodiment, the system control device 1 is connected to a home network including a router 2. The system control device 1 generates a first control signal indicating the control information of the lighting fixture 6 and / or a control signal for the home appliance showing the control information of the home appliance 8. Specifically, the system control device 1 executes communication conforming to the first communication protocol. Therefore, the system control device 1 generates a first control signal and / or a control signal for home appliances having a signal format conforming to the first communication protocol.

The system control device 1 functions as, for example, a HEMS (Home Energy Management System) controller. In the present embodiment, the system control device 1 is connected to the lighting control device 3, the distribution board 7, and / or the communication terminal 9 via the router 2.

The lighting control device 3 can control a single or a plurality of lighting fixtures 6. Therefore, the lighting control device 3 controls one or more lighting fixtures 6. The lighting control device 3 includes a signal conversion unit 4 and a plurality of lighting control units 5. The signal conversion unit 4 can be connected to each of the lighting control units 5. Therefore, the signal conversion unit 4 is connected to each of the lighting control units 5. In the present embodiment, the signal conversion unit 4 and the lighting control unit 5 are connected by wire. The lighting control device 3 may include a single lighting control unit 5.

As shown in FIG. 2, the signal conversion unit 4 includes a first communication unit 41, a control unit CU, a notification unit 43, a sensor 44, an input unit 45, a clock unit 46, and a first storage unit 47. To prepare for. The control unit CU includes a conversion unit 42a and a first control unit 42b. The first communication unit 41 corresponds to an example of the "communication unit". The first storage unit 47 corresponds to an example of the “storage unit”. The first control unit 42b corresponds to an example of a “control unit”.

The first communication unit 41 receives the first control signal from the system control device 1 via the router 2. That is, the first communication unit 41 receives the first control signal via wireless communication. The conversion unit 42a converts the first control signal into a second control signal that can be recognized by the lighting control unit 5. Specifically, the lighting control unit 5 executes communication conforming to a second communication protocol different from the first communication protocol. Therefore, the conversion unit 42a converts the first control signal into a second control signal having a signal format conforming to the second communication protocol. Then, the first communication unit 41 transmits the second control signal to the lighting control unit 5.

The lighting control unit 5 can control a single or a plurality of lighting fixtures 6. Therefore, the lighting control unit 5 controls a single or a plurality of lighting fixtures 6. Specifically, the lighting control unit 5 controls, for example, one or a plurality of lighting fixtures 6 toning and / or dimming. The lighting control unit 5 switches, for example, the state of the lighting fixture 6 between a lighting state and a lighting state. The lighting control unit 5 includes a second communication unit 51, a second control unit 52, an operation unit 53, and a second storage unit 54. The second communication unit 51 receives the second control signal from the signal conversion unit 4 via wired communication. The second control unit 52 controls a plurality of lighting fixtures 6 according to the second control signal.

The luminaire 6 is, for example, a downlight or indirect lighting. The lighting fixture 6 lights up according to the second control unit 52.

The distribution board 7 includes, for example, a branch circuit, a communication device, and a control unit. The branch circuit of the distribution board 7 supplies external power to each of the system control device 1, the router 2, the signal conversion unit 4, the lighting control unit 5, and the plurality of home appliances 8. External power is supplied to the lighting fixture 6 via the lighting control unit 5. The communication device of the distribution board 7 receives a home appliance control signal indicating control information of the home appliance 8 from the system control device 1 via the router 2. Then, the control unit of the distribution board 7 controls the home electric appliance 8 according to the control signal for the home electric appliance.

The home appliance 8 is, for example, an air conditioner (air conditioner), a television, or a refrigerator. The home appliance 8 operates according to the control unit of the distribution board 7.

The communication terminal 9 is, for example, a computer that can be operated by a user. Specifically, the communication terminal 9 is a mobile computer such as a smartphone, a tablet computer, or a personal computer. The communication terminal 9 is connected to, for example, a router 2. Therefore, the communication terminal 9 can be connected to the system control device 1, the lighting control device 3, and / or the distribution board 7 via the router 2.

The communication terminal 9 may control the system control device 1 so as to generate a first control signal and / or a home appliance control signal, for example, via a router 2. In this case, the system control device 1 generates a first control signal and / or a home appliance control signal according to the communication terminal 9. Further, the communication terminal 9 may generate, for example, a first control signal indicating the control information of the lighting fixture 6 or a home appliance control signal indicating the control information of the home appliance 8. Then, the communication terminal 9 may transmit the first control signal to the first communication unit 41 of the signal conversion unit 4 via the router 2 without going through the system control device 1. Further, the communication terminal 9 may transmit the control signal for home appliances to the distribution board 7 via the router 2 without going through the system control device 1. Further, the communication terminal 9 may generate, for example, a second control signal indicating control information of the lighting fixture 6. In this case, the communication terminal 9 transmits the second control signal to the first communication unit 41 of the signal conversion unit 4 via the router 2. Then, the first communication unit 41 of the signal conversion unit 4 transfers the second control signal to the lighting control unit 5.

The external communication terminal 10 of the power system 100 connects to the router 2 via the external network 11. The communication terminal 10 is, for example, a computer that can be operated by a user. Specifically, the external communication terminal 10 is a mobile computer such as a smartphone, a tablet computer, or a personal computer. Further, the external network 11 includes, for example, the Internet and a LAN.

The communication terminal 10 controls the system control device 1 so as to generate a first control signal and / or a home appliance control signal via, for example, an external network 11 and a router 2. Further, the communication terminal 10 may generate, for example, a first control signal and / or a control signal for home appliances. Then, the communication terminal 10 may transmit the first control signal to the signal conversion unit 4 via the external network 11 and the router 2 without going through the system control device 1. Further, the communication terminal 10 may transmit a control signal for home appliances to the distribution board 7 via the external network 11 and the router 2 without going through the system control device 1.

As described above with reference to FIGS. 1 and 2, according to the present embodiment, the signal conversion unit 4 controls the first control signal indicating the control information of the luminaire 6 and the plurality of luminaires 6. The possible lighting control unit 5 converts it into a recognizable second control signal. Therefore, it is possible to control a plurality of lighting fixtures 6 without providing a signal conversion unit for each of the plurality of lighting fixtures. As a result, the cost can be reduced.

Further, according to the present embodiment, the communication terminal 9 generates a first control signal and transmits the first control signal to the signal conversion unit 4. Therefore, the user can directly control the lighting fixture 6 without going through the system control device 1.

Further, according to the present embodiment, the communication terminal 9 controls the system control device 1 so as to generate the first control signal. Therefore, the user can control the lighting fixture 6 by operating the communication terminal 9. For example, when the communication terminal 9 is a smartphone that is used by the user on a daily basis, the user operates the communication terminal 9 in the same manner as in the daily operation to generate a first control signal. 1 can be controlled. As a result, it becomes more convenient for the user.

Further, according to the present embodiment, the communication terminal 9 can transmit the first control signal to the signal conversion unit 4 without going through the system control device 1. Therefore, the user can control the lighting fixture 6 by operating the communication terminal 9 without operating the system control device 1. As a result, as long as the radio wave of the router 2 reaches the communication terminal 9, the user can control the lighting fixture 6 by operating the communication terminal 9 even in a place other than the place where the system control device 1 is installed.

Further, according to the present embodiment, the first communication unit 41 receives the first control signal via wireless communication. Therefore, the first communication unit 41 can be connected to the system control device 1 without using wiring. As a result, wiring work for connecting the signal conversion unit 4 and the system control device 1 is unnecessary, and the cost can be further reduced.

Further, according to the present embodiment, the signal conversion unit 4 converts the first control signal into a second control signal that can be recognized by the lighting control unit 5. Therefore, even when the luminaire 6 cannot recognize the first control signal, the system control device 1 can control the luminaire 6 via the signal conversion unit 4. As a result, even when the luminaire 6 already installed in the facility cannot recognize the first control signal, the system control device 1 can control the luminaire 6.

Further, according to the present embodiment, the system control device is such that the external communication terminal 10 of the power system 100 generates the first control signal and / or the control signal for home appliances via the external network 11 and the router 2. 1 is controlled. Therefore, the signal conversion unit 4 can convert the first control signal into the second control signal according to the instruction from the user who is away from the facility.

Further, according to the present embodiment, the communication terminal 10 outside the power system 100 can generate the first control signal and transmit the first control signal to the signal conversion unit 4. Therefore, the signal conversion unit 4 can convert the first control signal into the second control signal according to the instruction from the user who is away from the facility.

The first communication unit 41 of the signal conversion unit 4 is, for example, a communication interface. The control unit CU includes a processor such as a CPU (Central Processing Unit). The first storage unit 47 includes a storage device and stores data and computer programs. Specifically, the first storage unit 47 includes a main storage device such as a semiconductor memory and an auxiliary storage device such as a semiconductor memory and / or a hard disk drive. The processor of the control unit CU executes the computer program stored in the storage device of the first storage unit 47, and functions as the conversion unit 42a and the first control unit 42b. The first control unit 42b will be described later. Further, the processor of the control unit CU executes a computer program stored in the storage device of the first storage unit 47 to control each configuration of the signal conversion unit 4.

Further, the second control unit 52 of the lighting control unit 5 includes a processor such as a CPU. The second storage unit 54 includes a storage device and stores data and computer programs. Specifically, the second storage unit 54 includes a main storage device such as a semiconductor memory and an auxiliary storage device such as a semiconductor memory and / or a hard disk drive. The processor of the second control unit 52 executes a computer program stored in the storage device of the second storage unit 54 to control each configuration of the lighting control unit 5.

Next, the lighting system 200 will be described in detail with reference to FIG. The system control device 1 is, for example, a fixed terminal. For example, the system control device 1 generates a first control signal according to a user's instruction. Further, for example, the system control device 1 generates a first control signal according to the time. Further, for example, the system control device 1 includes a detection unit, and the detection unit generates a first control signal in response to detecting a person in the facility. The first control signal generated by the system control device 1 is, for example, a signal according to a communication protocol such as ECHONET Lite (registered trademark). ECHONET Lite is a standard for networks that use wired or wireless systems in facilities.

The first control signal indicates the control information of the lighting fixture 6. The control information of the luminaire 6 indicates, for example, lighting, extinguishing, light amount, and / or light color (for example, correlated color temperature) of the luminaire 6. Further, the system control device 1 may instruct a "scene" as control information of the lighting fixture 6. The system control device 1 stores a plurality of "scenes". In each "scene", the lighting state of the plurality of lighting fixtures 6 is stored. The system control device 1 selects a "scene" according to the time from a plurality of "scenes". Then, the system control device 1 generates a first control signal indicating the amount of light and / or the color of light so that the plurality of lighting fixtures 6 reproduce the lighting state of the selected "scene".

The conversion unit 42a of the signal conversion unit 4 converts, for example, a first control signal according to a communication protocol such as ECHONET Lite into a second control signal according to a protocol recognizable by the lighting control unit 5. Therefore, like the first control signal, the second control signal indicates the control information of the luminaire 6. That is, the control information of the luminaire 6 indicated by the second control signal indicates, for example, lighting, extinguishing, light amount, and / or light color (for example, correlated color temperature) of the luminaire 6.

The notification unit 43 notifies the energization state and / or communication state of the signal conversion unit 4. The notification unit 43 is, for example, a lighting element such as an LED. For example, when the signal conversion unit 4 is energized, the notification unit 43 lights up. Further, for example, when the signal conversion unit 4 is in a state of being able to communicate with the router 2 or the lighting control unit 5, the notification unit 43 is turned on. Here, the notification unit 43 may notify the energization state and / or the communication state of the signal conversion unit 4 by blinking. Further, the notification unit 43 lights the signal conversion unit 4 in different colors according to the energized state and the non-energized state of the signal conversion unit 4 and the communication state of the signal conversion unit 4, so that the energized state and / or the communication state of the signal conversion unit 4 can be changed. It may be notified.

The sensor 44 detects changes in the surrounding environment of the signal conversion unit 4 or infrared rays. The sensor 44 is, for example, a motion sensor, an illuminance sensor, or a biometric authentication sensor. The motion sensor detects infrared rays emitted by humans or animals. The illuminance sensor detects the brightness of the surrounding environment. Biometric sensors detect physical features such as fingerprints or irises. For example, the sensor 44 detects a user who has entered the room in which the lighting control device 3 is installed.

The conversion unit 42a generates a fourth control signal indicating control information of the lighting fixture 6 based on the detection signal of the sensor 44. Specifically, the fourth control signal has a signal format conforming to the second communication protocol. Then, the first communication unit 41 transmits the fourth control signal to the lighting control unit 5. The second communication unit 51 of the lighting control unit 5 receives the fourth control signal. The second control unit 52 controls a plurality of lighting fixtures 6 according to the fourth control signal received by the second communication unit 51.

The input unit 45 is a user interface, for example, a push button. At the time of construction of the signal conversion unit 4, the user presses the input unit 45 to instruct the connection between the router 2 and / or the lighting control unit 5 and the signal conversion unit 4 via the input unit 45. The connection instruction by the user is input to the first communication unit 41 via the input unit 45. The first communication unit 41 connects to the router 2 and / or the lighting control unit 5 according to the connection instruction by the user.

The lighting control unit 5 is, for example, a 4-wire type controller (a form in which two signal lines and two power supply lines are connected). The lighting control unit 5 conforms to, for example, the DALI (DALI) (DALI) Standard. The lighting control unit 5 is connected to a plurality of lighting fixtures 6 via a power line. The second communication unit 51 of the lighting control unit 5 is, for example, a communication interface.

The second control unit 52 of the lighting control unit 5 is, for example, a microcomputer and includes a memory. The second control unit 52 performs various processes such as numerical calculation, information processing, and device control by executing a program stored in the memory. The memory is composed of, for example, ROM, RAM, and / or EEPROM. The second control unit 52 controls the external power (specifically, the waveform of the external power supply voltage) supplied from the distribution board 7 (see FIG. 1) according to the second control signal and / or the fourth control signal. Supply to the lighting fixture 6.

The lighting control unit 5 further includes an operation unit 53. The operation unit 53 is a user interface, for example, a push button. The operation unit 53 may be formed of a touch panel. By operating the operation unit 53, the user can instruct to change at least one of the light amount and the light color of the light generated from the lighting fixture 6. Further, the user can instruct one "scene" from the plurality of "scenes" by operating the operation unit 53. The instruction by the user is input to the second control unit 52 via the operation unit 53. The second control unit 52 controls a plurality of lighting fixtures 6 according to instructions from the user. Further, the second control unit 52 can individually control each of the plurality of lighting fixtures 6.

The lighting fixture 6 may include LEDs having a plurality of colors that emit light having different light colors from each other as a lighting element. For example, as a lighting element, a 5000 Kelvin (cold color) LED and a 2700 Kelvin (warm color) LED can be used. Therefore, dimming and toning control can be realized by using LEDs having different light colors.

As described above with reference to FIG. 2, according to the present embodiment, the notification unit 43 is a lighting element, and by lighting the notification unit 43, the energization state and / or the communication state of the signal conversion unit 4 is notified. .. Therefore, the user can visually determine the energized state and / or the communication state of the signal conversion unit 4.

Further, according to the present embodiment, at the time of construction of the signal conversion unit 4, the user instructs the connection between the router 2 and / or the lighting control unit 5 and the signal conversion unit 4 by pressing the input unit 45. Then, the first communication unit 41 connects to the router 2 and / or the lighting control unit 5 according to the connection instruction. Therefore, at the time of construction of the signal conversion unit 4, the user can connect the router 2 and / or the lighting control unit 5 and the signal conversion unit 4 simply by pressing the input unit 45. That is, the user can easily connect the router 2 and / or the lighting control unit 5 and the signal conversion unit 4.

Next, the processing of the signal conversion unit 4 and the lighting control unit 5 will be described with reference to FIGS. 2 and 3. FIG. 3 is a flowchart showing the processing of the signal conversion unit 4 and the lighting control unit 5. As shown in FIGS. 2 and 3, the processing of the signal conversion unit 4 includes steps S1 to S3. The process of the lighting control unit 5 includes steps S11 and S12.

In step S1, the first communication unit 41 of the signal conversion unit 4 receives the first control signal from the system control device 1, the communication terminal 9, or the communication terminal 10.
In step S2, the conversion unit 42a converts the first control signal into a second control signal that can be recognized by the lighting control unit 5.
In step S3, the first control unit 42b controls the first communication unit 41 so as to transmit the second control signal to the lighting control unit 5. As a result, the first communication unit 41 transmits the second control signal to the lighting control unit 5.

Then, in step S11, the second communication unit 51 of the lighting control unit 5 receives the second control signal.
In step S12, the second control unit 52 controls the luminaire 6 according to the second control signal.

Next, with reference to FIG. 2, the first storage unit 47, the clock unit 46, and the first control unit 42b will be described. As shown in FIG. 2, the first storage unit 47 stores a plurality of schedule information SCs in advance. For example, the auxiliary storage device of the first storage unit 47 stores the schedule information SC. "Remembering in advance" means "remembering before controlling the lighting fixture 6." The first storage unit 47 may store one schedule information SC in advance.

The schedule information SC indicates a schedule for controlling the lighting fixture 6. Specifically, the schedule information SC includes a control schedule and control contents of the lighting fixture 6. The control content includes information for controlling the state of the lighting fixture 6. The information for controlling the state of the luminaire 6 is, for example, information instructing the state of the luminaire 6 to be switched from the lit state to the off state, and information instructing the state of the luminaire 6 to be switched from the off state to the lit state. , At least one of the dimming setting value of the lighting fixture 6 and the toning setting value of the lighting fixture 6. For example, the schedules indicated by the plurality of schedule information SCs are different from each other.

The conversion unit 42a generates a third control signal recognizable by the lighting control unit 5 based on the schedule information SC stored in the first storage unit 47. The third control signal has a signal format conforming to the second communication protocol. The clock unit 46 measures the time and indicates the time. Then, the first control unit 42b controls the first communication unit 41 so as to transmit the third control signal to the lighting control unit 5 based on the time and schedule information SC indicated by the clock unit 46. Therefore, the first communication unit 41 transmits the third control signal to the lighting control unit 5. As a result, the lighting control unit 5 controls the lighting fixture 6 according to the third control signal. Since the third control signal is based on the schedule information SC, the lighting fixture 6 is controlled according to the schedule indicated by the schedule information SC. That is, the third control signal includes the control information of the lighting fixture 6 according to the schedule information SC.

According to the present embodiment, since the third control signal is generated based on the schedule information SC, the lighting fixture 6 can be controlled according to the schedule indicated by the schedule information SC. As a result, the convenience of the user can be improved. That is, in the present embodiment, the cost is reduced by providing the conversion unit 42a that converts the first control signal into the second control signal while improving the convenience of the user by the schedule information SC stored in the first storage unit 47. can.

Further, in the present embodiment, since the signal conversion unit 4 includes the clock unit 46, it is possible to accurately control the lighting fixture 6 according to the schedule indicated by the schedule information SC based on the time indicated by the clock unit 46. Further, it is not necessary for each of the lighting control units 5 to be equipped with a clock, and it is not necessary for each of the lighting fixtures 6 to be equipped with a clock. As a result, the cost of the lighting control unit 5 and the lighting fixture 6 can be reduced.

Further, according to the present embodiment, as long as the first storage unit 47 stores the schedule information SC, the communication terminal 9 and the communication terminal 10 transmit the first control signal having the same contents as the schedule information SC. Can be omitted. Therefore, the operation load of the communication terminal 9 or the communication terminal 10 by the user can be reduced. As a result, the convenience of the user can be further improved. Further, as long as the first storage unit 47 stores the schedule information SC, it is possible to reduce the processing load for the communication terminal 9 and the communication terminal 10 for generating the first control signal having the same contents as the schedule information SC. ..

Further, in the present embodiment, the communication terminal 9 or the communication terminal 10 (FIG. 1) transmits a storage instruction signal for storing the schedule information SC in the first storage unit 47 to the signal conversion unit 4. Then, the first communication unit 41 receives the storage instruction signal. Further, the first control unit 42b controls the first storage unit 47 so as to store the schedule information SC according to the storage instruction signal. Therefore, the user can operate the communication terminal 9 or the communication terminal 10 to store the desired schedule information SC in the first storage unit 47. As a result, the convenience of the user can be further improved.

Specifically, the storage instruction signal has a signal format conforming to the first communication protocol. Further, the storage instruction signal includes information instructing to store the schedule information SC and the schedule information SC.

Further, in the present embodiment, it is preferable that the first control signal and the storage instruction signal have a signal format conforming to the communication standard of ECHONET Lite. In this embodiment, since the conversion unit 42a is provided, the lighting fixture 6 that does not correspond to the communication standard of ECHONET Lite can be easily controlled by using the relatively widely used communication standard ECHONET Lite. be. Further, it is preferable that the second control signal and the third control signal have a signal format conforming to the communication standard of the serial signal. This is because the lighting control unit 5 is an example of a recognizable signal format. The communication standard for serial signals is, for example, "RS485".

Next, the schedule information SC will be described with reference to FIG. 4 by giving a specific example. FIG. 4 is a diagram showing an example of the schedule information SC. As shown in FIG. 4, each of the plurality of schedule information SCs includes the start time information SC1 and the scene information SC2. The schedule information SC may include the fade period information SC3. The fade period information SC3 indicates a fade period for executing the fade control. The fade control indicates a control that continuously or stepwise changes the state of the lighting fixture 6 (specifically, the setting value of dimming and / or toning). Therefore, the lighting fixture 6 under fade control is not in a constant lighting state.

The start time information SC1 indicates the time when the lighting fixture 6 starts lighting in a constant lighting state. The scene information SC2 determines the state of the lighting fixture 6 according to the scene. The state of the luminaire 6 is represented by, for example, a dimming and / or toning setting value of the luminaire 6. A scene is a scene. The scene indicates, for example, "wake up", "reading", or "sleeping".

If the schedule information SC does not include the fade period information SC3, or if the fade period indicated by the fade period information SC3 is zero, the first control unit 42b is the state of the luminaire 6 at the start time indicated by the start time information SC1. Refers to the time indicated by the clock unit 46 and transmits the third control signal to the lighting control unit 5 via the first communication unit 41 so that is in the state defined by the scene information SC2. As a result, the lighting control unit 5 controls the state of the lighting fixture 6 so that the state is determined by the scene information SC2 at the start time indicated by the start time information SC1. Therefore, according to the present embodiment, the state of the lighting fixture 6 can be set according to the scene at the start time indicated by the start time information SC1. Then, after the start time indicated by the start time information SC1, the lighting fixture 6 lights up in a constant lighting state corresponding to the scene.

Further, when the fade period indicated by the fade period information SC3 is a value other than zero (for example, 5 minutes), the fade control is executed. In the present embodiment, the end point of the fade period indicates the start time indicated by the start time information SC1. Therefore, the start time of the fade control is a time before the start time indicated by the start time information SC1 by the fade period (hereinafter, referred to as “time tf”). Therefore, the first control unit 42b transmits the third control signal via the first communication unit 41 with reference to the time indicated by the clock unit 46 so as to execute the fade control for the lighting fixture 6 at the time tf. It is transmitted to the lighting control unit 5. As a result, the lighting control unit 5 starts fade control for the lighting fixture 6 at time tf. In other words, fade control is started according to the schedule indicated by the schedule information SC. As a result, the effect of the lighting fixture 6 can be improved.

Then, the lighting control unit 5 controls the lighting fixture 6 so as to end the fade control for the lighting fixture 6 when the fade period indicated by the fade period information SC3 elapses from the time tf. Then, the lighting control unit 5 controls the state of the lighting fixture 6 so as to be in the state defined by the scene information SC2 at the end of the fade control, that is, at the start time indicated by the start time information SC1. In other words, according to the schedule indicated by the schedule information SC, the state of the lighting fixture 6 can be set to the state defined by the scene information SC2 following the fade control. As a result, the effect of the lighting fixture 6 can be further improved.

Here, in the present embodiment, the communication terminal 9 or the communication terminal 10 (FIG. 1) selects one schedule information SC from the plurality of schedule information SCs stored in the first storage unit 47. Then, the signal conversion unit 4 generates a third control signal based on the selected schedule information SC. Therefore, the user can operate the communication terminal 9 or the communication terminal 10 to select a desired schedule information SC. As a result, the user can set the state of the lighting fixture 6 corresponding to the desired scene indicated by the desired schedule information SC.

The start time information SC1 may indicate the start time of the control of the lighting fixture 6. In this case, the control start time of the lighting fixture 6 may be the start time of the fade control or the start time of the control based on the scene information SC2. Further, the start time information SC1 may indicate the lighting start time of the lighting fixture 6.

Next, the processing of the signal conversion unit 4 and the lighting control unit 5 will be described with reference to FIGS. 2 and 5. FIG. 5 is a flowchart showing the processing of the signal conversion unit 4 and the lighting control unit 5. As shown in FIGS. 2 and 5, the processing of the signal conversion unit 4 includes steps S21 to S23. The process of the lighting control unit 5 includes steps S31 and S32. Note that FIG. 5 shows control when the fade period indicated by the fade period information SC3 included in the schedule information SC indicates zero.

In step S21, the first control unit 42b of the signal conversion unit 4 refers to the time indicated by the clock unit 46 and determines whether or not the start time indicated by the start time information SC1 has arrived. The first control unit 42b refers to the time indicated by the clock unit 46 and determines whether or not a predetermined time (for example, 0.5 seconds) before the start time indicated by the start time information SC1 has arrived. May be determined.
If a negative determination (No) is made in step S21, the process repeats step S21.
If a positive determination (Yes) is made in step S21, the process proceeds to step S22.
In step S22, the conversion unit 42a generates a third control signal based on the schedule information SC. Therefore, the third control signal includes the control information of the lighting fixture 6 according to the scene information SC2 included in the schedule information SC.
In step S23, the first control unit 42b controls the first communication unit 41 so as to transmit the third control signal to the lighting control unit 5. As a result, the first communication unit 41 transmits the third control signal to the lighting control unit 5.

Then, in step S31, the second communication unit 51 of the lighting control unit 5 receives the third control signal.
In step S32, the second control unit 52 controls the luminaire 6 according to the third control signal.

As described above with reference to FIG. 5, according to the present embodiment, the third control signal is transmitted to the lighting control unit 5 at the start time indicated by the start time information SC1 according to the time indicated by the clock unit 46. .. Therefore, the lighting control unit 5 can set the state of the lighting fixture 6 according to the scene according to the third control signal.

The embodiments (including modifications) of the present invention have been described above with reference to the drawings. However, the present invention is not limited to the above embodiment, and can be implemented in various embodiments without departing from the gist of the present invention (for example, (1) to (8) shown below). In addition, various inventions can be formed by appropriately combining the plurality of components disclosed in the above embodiments. For example, some components may be removed from all the components shown in the embodiments. In addition, components across different embodiments may be combined as appropriate. In order to make it easier to understand, the drawings are schematically shown with each component as the main component, and the thickness, length, number, spacing, etc. of each of the illustrated components are actual for the convenience of drawing creation. May be different. Further, the material, shape, dimensions, etc. of each component shown in the above embodiment are merely examples, and are not particularly limited, and various changes can be made without substantially deviating from the effects of the present invention. be.

(1) As described with reference to FIG. 2, in the present embodiment, the lighting control unit 5 is a 4-wire type, but the lighting control unit 5 is not limited to the 4-wire type, and the lighting control unit 5 is a plurality of lighting fixtures. As long as 6 can be controlled, the lighting control unit 5 may be, for example, a two-wire system (a form in which only two signal lines are connected).

(2) As described with reference to FIG. 1, in the present embodiment, the distribution board 7 supplies external power to the signal conversion unit 4, the lighting control unit 5, and the plurality of home appliances 8. However, a photovoltaic power generation system may be connected to the distribution board 7, and the distribution board 7 transfers the electric power generated by the photovoltaic power generation system to the signal conversion unit 4, the lighting control unit 5, and a plurality of home appliances. It may be supplied to 8.

(3) As described with reference to FIG. 2, in the present embodiment, the luminaire 6 has, as a luminaire, two-color LEDs that emit light having different light colors from each other, but the luminaire 6 has. As long as it lights up, the luminaire 6 may have only one color LED. In this case, only dimming control is performed.

(4) As described with reference to FIG. 2, in the present embodiment, the notification unit 43 is an LED, but as long as the notification unit 43 is lit, the notification unit 43 is, for example, an organic EL element or an incandescent light bulb. There may be.

(5) The plurality of lighting fixtures 6 described with reference to FIGS. 1 and 2 may have a unique address (destination) set for each lighting fixture 6. In this case, the system control device 1 generates the first control signal including the address. Therefore, the second control unit 52 can individually control each luminaire 6.

(6) As described with reference to FIG. 2, in the present embodiment, the notification unit 43 is, for example, a lighting element such as an LED. However, as long as the notification unit 43 notifies the energization state and / or the communication state of the signal conversion unit 4, the notification unit 43 may be a voice output element such as a buzzer. Even if the signal conversion unit 4 notifies the change of the energization state and / or the communication state of the signal conversion unit 4 by outputting voice when the energization state and / or the communication state of the signal conversion unit 4 changes. good.

(7) As described with reference to FIG. 1, in the present embodiment, the signal conversion unit 4 and the lighting control unit 5 are connected by wire. However, as long as the signal conversion unit 4 and the lighting control unit 5 can communicate with each other, the signal conversion unit 4 and the lighting control unit 5 may be wirelessly connected. In this case, the first communication unit 41 of the signal conversion unit 4 may transmit the second control signal to the second communication unit 51 of the lighting control unit 5 via the router 2, or Bluetooth (Bluetooth®). ) May be transmitted to the second communication unit 51 of the lighting control unit 5 via wireless communication such as).

(8) As described with reference to FIG. 1, in the present embodiment, the lighting system 200 includes a plurality of lighting fixtures 6. However, the lighting system 200 may include a single lighting fixture 6. Therefore, the lighting control device 3 controls one or more lighting fixtures 6.

The present invention relates to a signal conversion unit, a lighting control device, and a lighting system, and has industrial applicability.

3 Signal conversion device 4 Signal conversion unit 41 1st communication unit (communication unit)
42a Conversion unit 42b First control unit (control unit)
43 Notification unit 44 Sensor 46 Clock unit 47 First storage unit (storage unit)
5 Lighting control unit 51 Second communication unit 52 Second control unit 6 Lighting equipment

Claims (6)

A signal conversion unit that can connect multiple lighting fixtures to a controllable lighting control unit.
Control unit and
A communication unit that receives a first control signal indicating control information of the lighting fixture, and
A conversion unit that converts the first control signal into a second control signal that can be recognized by the lighting control unit.
It is equipped with a clock unit that indicates the time and a storage unit that stores schedule information indicating the control schedule of the lighting fixture in advance.
The conversion unit generates a third control signal recognizable by the lighting control unit based on the schedule information.
The control unit is a signal conversion unit that controls the communication unit so as to transmit the third control signal to the lighting control unit based on the time and the schedule information indicated by the clock unit. The communication unit receives a storage instruction signal for storing the schedule information in the storage unit, and receives the storage instruction signal.
The signal conversion unit according to claim 1, wherein the control unit controls the storage unit so as to store the schedule information according to the storage instruction signal. The signal conversion unit according to claim 1 or 2, wherein the schedule information includes scene information that determines the state of the lighting fixture according to the scene. The schedule information is
Start time information indicating the start time when the lighting fixture starts lighting in a constant lighting state, and
Contains fade period information indicating the fade period for which fade control is performed.
The fade control indicates a control that continuously or stepwise changes the state of the luminaire.
The signal conversion unit according to any one of claims 1 to 3, wherein the end point of the fade period indicates the start time. With the signal conversion unit,
Equipped with a lighting control unit,
The signal conversion unit is
The first control unit and
The first communication unit that receives the first control signal indicating the control information of the lighting equipment,
A conversion unit that converts the first control signal into a second control signal that can be recognized by the lighting control unit.
It includes a clock unit that indicates the time and a storage unit that stores schedule information indicating the control schedule of the lighting fixture in advance.
The conversion unit generates a third control signal recognizable by the lighting control unit based on the schedule information.
The first control unit controls the first communication unit so as to transmit the third control signal to the lighting control unit based on the time and the schedule information indicated by the clock unit.
The lighting control unit is
A second communication unit that receives the second control signal or the third control signal, and
A lighting control device including a second control unit that controls the luminaire according to the second control signal or the third control signal. With the signal conversion unit,
Lighting control unit and
Equipped with lighting equipment,
The signal conversion unit is
The first control unit and
A first communication unit that receives a first control signal indicating control information of the lighting fixture, and
A conversion unit that converts the first control signal into a second control signal that can be recognized by the lighting control unit.
It includes a clock unit that indicates the time and a storage unit that stores schedule information indicating the control schedule of the lighting fixture in advance.
The conversion unit generates a third control signal recognizable by the lighting control unit based on the schedule information.
The first control unit controls the first communication unit so as to transmit the third control signal to the lighting control unit based on the time and the schedule information indicated by the clock unit.
The lighting control unit is
A second communication unit that receives the second control signal or the third control signal, and
A lighting system including a second control unit that controls the luminaire according to the second control signal or the third control signal.

Images