JP2018120742A - Illumination system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve disuse of a control signal line of a separate system.SOLUTION: The illumination system includes: an illumination device 11 having an illumination light source 111 lighting up with a DC voltage supplied; a control unit 14 outputting a control signal for executing lighting control of the illumination light source 111; and a control signal superposition circuit 15 disposed on a supply line of a DC voltage from a DC voltage supply source to the illumination device 11 and superposing the control signal from the control unit 14 on the DC voltage to be supplied to the illumination device 11.SELECTED DRAWING: Figure 1A

Description

  Embodiments described herein relate generally to a lighting system.

  In patent document 1, the HEMS system in the house provided with the storage battery is disclosed. This is to supply power from the storage battery to the load when a power failure occurs.

JP, 2006-185004, A

  In Patent Document 1, as a load fed from a storage battery when a power failure occurs, a device that requires power even in an emergency, such as a refrigerator or a lamp, is cited. Since these devices operate by being supplied with AC voltage, the power storage system converts the DC voltage into AC voltage and supplies power to each device.

  On the other hand, in recent years, for example, a light-emitting diode (DC load) such as a light-emitting diode (LED) has been used as an illumination light source in an electric lamp, that is, an illumination device. The power supply to the DC light emitting element requires conversion of an AC voltage into a DC voltage, and thus the lighting device has an AC / DC converter. Further, since general home appliances are DC loads driven by a DC voltage, an AC / DC converter that converts an AC voltage taken from an outlet into a DC voltage is provided. A conversion loss occurs in the AC / DC voltage conversion in the AC / DC converter, and this conversion loss becomes heat. Therefore, each device needs a large heat dissipation structure.

  Therefore, it is conceivable that AC / DC conversion on the DC load side is unnecessary by storing the commercial power supplied from the system power supply to the house in the storage battery and feeding the DC voltage from the storage battery to each DC load. . However, in a configuration in which a DC voltage is supplied, a separate control signal line is required to control each DC load.

  The illumination system of the present embodiment includes an illumination device having an illumination light source that is powered by a DC voltage; a control unit that outputs a control signal for performing lighting control of the illumination light source; and the illumination from a DC voltage supply source And a superimposing unit that is arranged on a supply line of the DC voltage to the apparatus and superimposes the control signal from the control unit on the DC voltage to be supplied to the lighting device.

  According to the present embodiment, since the control signal is superimposed on the DC voltage supply line, it is possible to eliminate the need to provide a separate control signal line.

FIG. 1A is a block diagram illustrating an example of the configuration of the illumination system according to the first embodiment. 1B is a circuit diagram showing an example of the configuration of the rectifier circuit in FIG. 1A. FIG. 2A is a waveform diagram showing an example of a DC voltage output from the storage battery in FIG. 1A. FIG. 2B is a waveform diagram illustrating an example of a control signal superimposed voltage supplied from the control signal superimposed circuit in FIG. 1A to the illumination device. FIG. 2C is a diagram illustrating an example of a control signal output from the control unit in FIG. 1A and an example of a control signal superimposed voltage supplied from the control signal superimposing circuit to the lighting device in response thereto. FIG. 3 is a flowchart for explaining the operation of the control unit. FIG. 4 is a block diagram illustrating an example of a configuration of an illumination system according to the second embodiment. FIG. 5 is a flowchart for explaining the operation of the control unit in the second embodiment. FIG. 6 is a block diagram illustrating an example of a configuration of an illumination system according to the third embodiment. FIG. 7 is a flowchart for explaining the operation of the control signal analysis circuit in FIG.

  An illumination system according to an embodiment includes an illumination device having an illumination light source that is lit by being supplied with a DC voltage; a control unit that outputs a control signal for performing lighting control of the illumination light source; and the illumination device from a DC voltage supply source And a superimposing unit that superimposes the control signal from the control unit on the DC voltage and supplies the control signal to the lighting device.

  Hereinafter, embodiments will be described with reference to the drawings. In FIG. 1A, FIG. 1B, FIG. 4, and FIG. 6, solid lines and dotted lines indicate power wirings, and solid line arrows and dotted line arrows indicate signal transmission directions in the signal wirings. In addition, lighting control of the lighting device includes turning on, turning off, and dimming the illumination light source included in the lighting device.

(First embodiment)
1A and 1B show a configuration of a lighting system 1 as an example of the present embodiment.

  The illumination system 1 includes an illumination device 11 that includes at least one illumination light source 111. Here, when the illumination device 11 includes a plurality of illumination light sources 111, the same lighting control is performed on the plurality of illumination light sources 111. Further, as the illumination light source 111, for example, a DC light emitting element (DC load) such as an LED is used.

  The illuminating device 11 is further connected to a system power source 2 that supplies commercial power, and stores an AC / DC converter 12 that converts an AC voltage into a DC voltage, and receives and supplies power from the AC / DC converter 12. A storage battery 13 that outputs a low DC voltage for supplying power to the battery and a control signal for performing lighting control of the lighting device 11 in response to a user instruction input from an operation panel or a wireless terminal (not shown) operated by the user And a control signal superimposing circuit 15 that generates a control signal superimposed voltage by superimposing a control signal from the control unit 14 on a low DC voltage that feeds power from the storage battery 13 to the lighting device 11.

  In addition to supplying power to the storage battery 13 as described above, the AC / DC converter 12 detects the occurrence of a power failure in which power supply from the system power supply 2 to the AC / DC converter 12 is interrupted due to a local power failure or a fire. Then, a function of notifying the control unit 14 and a function of detecting the return from the power failure state and notifying the control unit 14 may be provided.

  The storage battery 13 is a rechargeable secondary battery such as a lithium ion battery that stores power from the system power supply 2 via the AC / DC converter 12. The storage battery 13 outputs a DC voltage of 45 V or less, for example, about 45 V as shown in FIG. 2A, which is a safety standard from the viewpoint of preventing electric shock in the present embodiment, as a low DC voltage for supplying power to the lighting device 11. This low DC voltage can be continuously output during a dischargeable period corresponding to the amount of stored electric power even if a power failure occurs and power supply by the AC / DC converter 12 is stopped.

  The control unit 14 is connected to an operation panel (not shown) and / or connected to a radio device (not shown) for communicating with a radio terminal (not shown), and a user instruction from the radio terminal or the like via the operation panel or the radio device. A control unit that generates a control signal corresponding to the input content in response to the input is provided. Further, in response to the power failure occurrence notification / return input from the AC / DC converter 12, the control unit also generates a control signal corresponding to the input content. The control unit includes, for example, an integrated circuit such as an application specific integrated circuit (ASIC), a field programmable gate array (FPGA), or a central processing unit (CPU). The operation of the control unit integrated circuit is performed by a recording device provided in the control unit 14 or in accordance with a program recorded in a recording area in the control unit integrated circuit. In the recording area in the recording device or the control unit integrated circuit, a signal pattern corresponding to the input content is also stored as a part of the program or as a table, and the control unit reads out the signal pattern corresponding to the input content. Control signal is generated and output to the control signal superimposing circuit 15. The control signal may be a signal obtained by adding a predetermined synchronization pattern before a signal pattern corresponding to the input content. The control unit 14 operates with power supplied from the storage battery 13.

  The control signal superimposing circuit 15 generates a control signal superimposing voltage based on the control signal from the control unit 14. For example, the control signal superposition circuit 15 generates a control signal superposition voltage as shown in FIG. 2B by switching the time for cutting off the low DC voltage from the storage battery 13 in accordance with the control signal from the control unit 14. That is, the control signal superimposing circuit 15 performs pulse width modulation on the low DC voltage from the storage battery 13 based on the control signal. In this case, since there is a section where the DC voltage is 0 V, a certain amount of capacitance is required on the lighting device 11 side, but the control signal analysis on the lighting device 11 side is caused by a large amplitude difference. Becomes easy.

  Further, as shown in FIG. 2C, for example, the control signal superimposing circuit 15 treats the control signal from the control unit 14 as + 2V when “1” and −2V when “0”. By adding the signal to the low DC voltage from the storage battery 13, it is possible to adopt a configuration for generating a control signal superimposed voltage. That is, the control signal superimposing circuit 15 amplitude-modulates the low DC voltage from the storage battery 13 based on the control signal. In this case, the voltage of the control signal is made smaller than ± 2V or the low DC voltage from the storage battery 13 is made lower than 45V so as not to exceed 45V which is the safety standard in the present embodiment due to the influence of noise or the like. It is desirable to keep it small.

  In addition, since it is feeding with low DC voltage between the storage battery 13 and the control signal superimposing circuit 15 and between the control signal superimposing circuit 15 and the lighting device 11, the wiring between them is F for AC100V feeding. There is no need to use cables.

  In addition to the illumination light source 111, the illuminating device 11 is supplied with a control signal superimposed voltage from the control signal superimposing circuit 15, generates a low DC voltage on which the control signal is not superimposed, and a control signal superimposed voltage. The control signal analysis circuit 113 that analyzes the included control signal and outputs a lighting control instruction signal according to the control signal, and the DC voltage from the rectifier circuit 112 according to the lighting control instruction signal from the control signal analysis circuit 113 A lighting circuit 114 that turns on the illumination light source 111.

  The rectifier circuit 112 includes, for example, a bridge circuit 112B and a resistance element 112R. The bridge circuit 112B rectifies the control signal superimposed voltage, generates a DC voltage on which the control signal is not superimposed, and supplies the DC voltage to the lighting circuit 114. Further, the difference between the input voltage and the output voltage of the bridge circuit 112B corresponding to the control signal superimposed on the control signal superimposed voltage is taken out via the resistance element 112R and supplied to the control signal analysis circuit 113.

  The control signal analysis circuit 113 includes a control unit that analyzes the control signal and generates a lighting control instruction signal corresponding to the input content. The control unit includes, for example, an integrated circuit such as an ASIC, FPGA, or CPU. The operation of the integrated circuit is performed in a recording device provided in the control signal analysis circuit 113 or in accordance with a program recorded in a recording area in the control unit integrated circuit. The recording area in the recording device or the control unit integrated circuit also stores the lighting control content corresponding to the signal pattern of the control signal, and the control unit reads the lighting control content corresponding to the signal pattern and instructs the lighting control. A signal is generated and output to the lighting circuit 114. Further, when the control signal includes a predetermined synchronization pattern, the signal pattern of the control signal can be analyzed based on the synchronization pattern, so that the reliability of the control signal analysis is increased.

  The lighting circuit 114 turns on the illumination light source 111 using the DC voltage from the rectifier circuit 112 or turns off the lit illumination light source 111 according to the lighting control instruction signal from the control signal analysis circuit 113.

  In addition, when the lighting circuit 114 is configured to be capable of dimming to adjust the light amount of the illumination light source 111, the lighting circuit 114 performs dimming of the illumination light source 111 according to the lighting control instruction signal. In this case, the control unit of the control unit 14 generates a control signal indicating the light amount of the illumination light source 111, and the lighting control instruction signal from the control signal analysis circuit 113 is a signal that specifies the light amount. Dimming by the lighting circuit 114 can be performed by pulse width control for adjusting the lighting time of the illumination light source 111 and / or current control for adjusting the drive current of the illumination light source 111. Note that the light amount of the illumination light source 111 when turning on the illumination light source 111 may be a prescribed light amount, but it is desirable to turn on the light by the light control set before turning off. This can be realized by storing the light amount before turning off in the control signal analyzing circuit 113 or the lighting circuit 114.

  Moreover, as the storage battery 13, it can also be set as the intelligence storage battery provided with the function to detect generation | occurrence | production of a power failure by detecting interruption | blocking of the electric power feeding from the AC / DC converter 12. FIG. In this case, the lighting system 1 is configured to give a power failure occurrence notification / recovery input to the control unit 14 from the storage battery 13 as shown by a dotted arrow in FIG. 1A instead of from the AC / DC converter 12. May be.

  Further, as shown by a dotted line in FIG. 1A, the lighting system 1 further includes a renewable energy source 16, and the storage battery 13 can be charged by a DC voltage supplied from the renewable energy source 16. good. Examples of the renewable energy source 16 include a solar power generation system and a wind power generation system.

  An example of the operation flow of the illumination system according to the present embodiment will be described with reference to FIG. In the flow of FIG. 3, power supply from the storage battery 13 to the control unit 14 is started, and the control unit included in the control unit 14 is placed in a recording device provided in the control unit 14 or in a recording area in the control unit integrated circuit. Start by starting the recorded program.

  First, the control unit of the control unit 14 determines whether or not a power failure notification is input from the AC / DC converter 12 (or the storage battery 13) (Act 11). When it is determined that there is no power failure occurrence notification input, the control unit determines whether or not a power failure recovery notification is input from the AC / DC converter 12 (or the storage battery 13) (Act 12). When it is determined that there is no power failure recovery notification input, the control unit determines whether there is a user instruction input from an operation panel, a wireless terminal, or the like (Act 13). If it is determined that there is no user instruction input, the control unit returns to the operation of Act11. In this way, the control unit waits for a power failure occurrence notification, a power failure recovery notification, or a user instruction to be input.

  If it is determined in Act 13 that there is a user instruction input, the control unit determines whether or not the input user instruction is a lighting instruction for the illumination light source 111 of the illumination device 11 (Act 14). . Here, when it is determined that the input user instruction is a lighting instruction, the control unit reads a signal pattern corresponding to the lighting instruction from the recording area in the recording device or the control unit integrated circuit to generate a lighting instruction signal. This is output to the control signal superimposing circuit 15 as a control signal (Act 15). Thereafter, the control unit returns to the operation of Act11. By the operation of Act 15, the control signal superimposing circuit 15 supplies the lighting device 11 with a control signal superimposed voltage obtained by superimposing a lighting instruction signal as a control signal on the low DC voltage from the storage battery 13. Therefore, in the lighting device 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage to determine that the lighting instruction has been given, and the lighting circuit 114 causes the illumination light source 111 to be turned on. It will be lit.

  In Act 14, if the input user instruction is not an instruction to turn on the illumination light source 111 of the illumination device 11, the control unit determines that the input user instruction is an instruction to turn off the illumination light source 111 of the illumination device 11. It is determined whether or not there is (Act 16). Here, when it is determined that the input user instruction is a turn-off instruction, the control unit reads a signal pattern corresponding to the turn-off instruction from the recording area in the recording apparatus or the control unit integrated circuit, and generates a turn-off instruction signal. This is output to the control signal superimposing circuit 15 as a control signal (Act 17). Thereafter, the control unit returns to the operation of Act11. By the operation of Act 17, the control signal superimposing circuit 15 supplies the lighting device 11 with a control signal superimposed voltage obtained by superimposing a turn-off instruction signal as a control signal on the low DC voltage from the storage battery 13. Accordingly, in the lighting device 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage to determine that the turn-off instruction has been given, and the lighting circuit 114 causes the illumination light source 111 to be turned on. It will be turned off.

  In Act 16, if the input user instruction is not an instruction to turn off the illumination light source 111 of the illumination device 11, the control unit determines that the input user instruction is a dimming instruction for the illumination light source 111 of the illumination device 11. It is determined whether or not (Act 18). Here, when it is determined that the input user instruction is a dimming instruction, the control unit reads a signal pattern corresponding to the dimming instruction from the recording area in the recording apparatus or the control unit integrated circuit, and controls the dimming instruction signal. Is output to the control signal superimposing circuit 15 as a control signal (Act 19). Thereafter, the control unit returns to the operation of Act11. By the operation of Act 19, the control signal superimposing circuit 15 supplies the lighting device 11 with a control signal superimposed voltage obtained by superimposing a dimming instruction signal as a control signal on the low DC voltage from the storage battery 13. Therefore, in the lighting device 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage to determine that the dimming instruction has been given, and the lighting circuit 114 causes the illumination light source 111 to be determined. Will be dimmed.

  If it is determined in Act 18 that the input user instruction is not a dimming instruction for the illumination light source 111 of the illumination device 11, the control unit performs another operation in accordance with the input user instruction ( Act20), and then the operation returns to Act11. Other operations in response to the user instruction include, for example, a detection operation of the storage amount of the storage battery 13, an inspection operation of the lighting device 11, and the like, but are not directly related to the present embodiment. Is omitted.

  If it is determined in Act 11 that there has been an input of a power failure notification from the AC / DC converter 12 (or the storage battery 13), the control unit turns on the current state of the illumination light source 111 of the illumination device 11, that is, turns on. Whether the light is turned on or off, or if it is turned on, the dimming state is stored in a recording area in the recording device or the control unit integrated circuit (Act 21). Then, from the recording area in the recording device or the control unit integrated circuit, a signal pattern for turning on the illumination light source 111 with a light amount stipulated as an emergency light by a law of each country is read to generate a dimming instruction signal, This is output to the control signal superimposing circuit 15 as a control signal (Act 22). Thereafter, the control unit returns to the operation of Act11. By the operation of Act 22, the control signal superimposing circuit 15 supplies the lighting device 11 with a control signal superimposed voltage obtained by superimposing a dimming instruction signal as a control signal on the low DC voltage from the storage battery 13. Accordingly, in the lighting device 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage, thereby determining that the dimming instruction according to the occurrence of the power failure has been made, and turning on the light. The circuit 114 turns on the illumination light source 111 with a light quantity that defines the illumination light source 111 as an emergency light. That is, if the illumination light source 111 is already turned on, the light amount is adjusted to the light amount specified as an emergency light, and if the illumination light source 111 is turned off, the illumination light source 111 is adjusted with the light amount specified as an emergency light. Light up.

  When the storage battery 13 is also used as a power source for home appliances or air conditioning equipment other than the lighting device 11, the control unit 14 or other control device supplies power to devices other than those expected to be used in an emergency. It is desirable to provide a configuration for stopping the operation. In addition, the control unit 14 or other control device operates at least the lighting device 11, the control unit 14, and the control signal superimposing circuit 15 during the lighting time of the emergency light in the event of a power failure specified by the laws of each country. It is also necessary to be able to control the amount of electricity stored in the storage battery 13 so that the amount of stored electricity is always left in the storage battery 13.

  In Act 12, when the AC / DC converter 12 (or the storage battery 13) determines that a power failure recovery notification has been input, the control unit stores it in a recording area in the recording device or the control unit integrated circuit. The state of the illumination light source 111 of the illumination device 11 before the power failure is read, a return instruction signal for setting the illumination light source 111 to that state is generated, and this is output as a control signal to the control signal superimposing circuit 15 (Act 23). Thereafter, the control unit returns to the operation of Act11. By the operation of Act 23, the control signal superimposing circuit 15 supplies the lighting device 11 with a control signal superimposed voltage obtained by superimposing a return instruction signal as a control signal on the low DC voltage from the storage battery 13. Therefore, in the illumination device 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage to determine the state of the illumination light source 111 before the power failure, and the lighting circuit 114 performs illumination. The light source 111 is returned to that state. That is, if the illumination light source 111 was turned on before the power failure, the amount of light when the illumination light source 111 was turned on is adjusted. If the illumination light source 111 is turned off, the illumination light is turned on as an emergency light. The light source 111 is turned off.

When a power failure occurs, an operation as indicated by a dotted line in FIG. 3 may be performed.
That is, after storing the current state of the illumination light source 111 of the lighting device 11 in Act 21, the control unit determines whether or not the current state is lit (Act 24). If the illumination light source 111 is turned off, the process proceeds to Act 22, and the dimming instruction signal is output as a control signal to the control signal superimposing circuit 15, thereby turning on the illumination light source 111 as an emergency light.

  On the other hand, when it is determined that the illumination light source 111 is turned on, the control unit further stores the storage amount of the storage battery 13 in the recording device of the control unit 14 or the recording area in the control unit integrated circuit. It is determined whether or not there is a remaining battery level equal to or greater than the threshold charge amount by comparing with the threshold charge amount based on the light quantity and lighting time of the emergency light specified by the law of each country. Act 25). Here, when it is determined that there is still a battery remaining amount equal to or greater than the threshold power storage amount, the control unit returns to the operation of Act11. That is, when there is a remaining battery level, the illumination light source 111 is kept on with the same amount of light. However, in this case, it is necessary to notify that a power failure has occurred by some method. When the remaining battery level becomes less than the threshold storage amount, the control unit proceeds to the operation of Act 22, and outputs the dimming instruction signal as a control signal to the control signal superimposing circuit 15, thereby making the illumination light source 111 emergency. Reduce the light intensity of the lamp.

(Effects of the first embodiment)
According to the illumination system 1 according to the present embodiment, the illumination device 11 having the illumination light source 111 that is lit by being supplied with a DC voltage; and control as a control unit that outputs a control signal for performing lighting control of the illumination light source 111 A control signal as a superimposing unit which is arranged on a DC voltage supply line from the DC voltage supply source to the lighting device 11 and superimposes a control signal from the control unit 14 on the DC voltage and supplies it to the lighting device 11; Therefore, the lighting control of the illumination light source 111 can be performed without providing a separate control line.

  Therefore, since there is no loss due to AC / DC voltage conversion in the illuminating device 11, the amount of heat generated by the illuminating device 11 can be suppressed, and the size can be reduced by reducing the heat dissipation structure.

  In addition, since a separate control signal line is not required, only the DC voltage supply line needs to be implemented, and the enforcement operation can be simplified. Furthermore, since it operates in a low voltage band (45 V or less), it is safe, and it is not necessary to use a wiring F cable as a supply line for this DC voltage, thereby reducing costs.

  The DC voltage supply source uses a storage battery charged with commercial power, so that stable operation is possible even in places where the commercial power source is unstable (voltage fluctuation, high frequency noise). Furthermore, since the illumination light source 111 is turned on as an emergency light in the event of a power failure when charging of the storage battery with commercial power is stopped, it is not necessary to install an emergency light separately.

(Second Embodiment)
In this embodiment, the case where the illumination system 1 includes a plurality of illumination devices 11 will be described. The overall system diagram of the second embodiment will be described with reference to FIG. 4, and the same components as those in the first embodiment will be denoted by the same reference numerals and detailed description thereof will be omitted.

  As shown in FIG. 4, the illumination system 1 according to the present embodiment is configured such that each of the plurality of illumination devices 11 is fed from one storage battery 13 via one control signal superimposing circuit 15. . Here, each illumination device 11 has the same configuration. However, the number of illumination light sources 111 included in each may be different. Further, different addresses are allocated to the respective lighting devices 11, and the address information is stored in a recording device provided in the control signal analysis circuit 113 included in each lighting device 11 or the control unit integrated circuit of the control signal analysis circuit 113. Is recorded in the recording area.

  Further, the control unit 14 records address information of each lighting device 11 and a signal pattern corresponding to the address information in a recording area in the control unit integrated circuit included in the control unit 14 or in a recording device provided in the control unit 14. At the same time, specific machine information indicating a plurality of lighting apparatuses 11 (specific machines) that should function as emergency lights when a power failure occurs is recorded among the plurality of lighting apparatuses 11 included in the lighting system 1.

  An example of the operation flow of the illumination system according to the present embodiment will be described with reference to FIG. Here, the same components as those of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  Also in this embodiment, the control unit 14 has a control unit 14 that waits for a power failure occurrence notification, a power failure recovery notification, or a user instruction to be input by the loop of Act 11 to Act 13. In the present embodiment, user instructions such as a lighting instruction, a light-off instruction, and a dimming instruction are input together with designated machine information indicating which of the plurality of lighting devices 11 is an instruction. That is, if a user instruction is issued from the operation panel, the operation panel is normally provided with a lighting / extinguishing switch and a dimming switch for each lighting device 11, so which switch is operated by the user. It becomes machine information. Further, if the user instruction is issued from the wireless terminal, for example, when each lighting device 11 is installed in the same room or the like, the wireless terminal is turned on / off / adjusted for each lighting device 11 like the operation panel. An operation mechanism for instructing light is provided, and a distinguishable operation signal is wirelessly transmitted for each operated operation mechanism. Therefore, this distinguishable operation signal is designated machine information. For example, when each lighting device 11 is arranged in a different room, a communication device is arranged for each room, and therefore, from which communication device the user instruction is input to the control unit is designated machine information.

  If it is determined in Act 13 that there is a user instruction input, the control unit determines whether or not the input user instruction is an instruction to turn on the illumination light source 111 of the designated machine (Act 31). . Here, when it is determined that the input user instruction is a lighting instruction for the designated machine, the control unit, from the recording area in the recording device or the control unit integrated circuit, the signal pattern corresponding to the address of the designated machine and the lighting instruction. The designated device lighting control signal is generated by reading out the signal pattern corresponding to, and is output to the control signal superimposing circuit 15 as a control signal (Act 32). Thereafter, the control unit returns to the operation of Act11. By the operation of Act 32, the control signal superimposing circuit 15 supplies the control signal superimposed voltage obtained by superimposing the designated machine lighting control signal as the control signal to the low DC voltage from the storage battery 13 to all of the plurality of lighting devices 11. . In each of the plurality of lighting devices 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage to determine whether or not a lighting instruction has been given to the own device. If a lighting instruction is issued, the lighting circuit 114 turns on the illumination light source 111.

  In Act 31, if it is determined that the input user instruction is not an instruction to turn on the illumination light source 111 of the designated machine, the control unit determines whether the input user instruction is an instruction to turn off the illumination light source 111 of the designated machine. It is determined whether or not (Act 33). Here, when it is determined that the input user instruction is an instruction to turn off the designated machine, the control unit reads the signal pattern corresponding to the address of the designated machine and the turn-off instruction from the recording area in the recording device or the control unit integrated circuit. The designated machine extinguishing control signal is generated by reading the signal pattern corresponding to, and is output to the control signal superimposing circuit 15 as a control signal (Act 34). Thereafter, the control unit returns to the operation of Act11. By the operation of Act 34, the control signal superimposing circuit 15 supplies the control signal superimposing voltage obtained by superimposing the designated machine extinction control signal as the control signal to the low DC voltage from the storage battery 13 to all of the plurality of lighting devices 11. . In each of the plurality of lighting devices 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage, thereby determining whether or not a turn-off instruction is given to the own device. If an instruction to turn off is given, the illumination light source 111 is turned off by the lighting circuit 114.

  If it is determined in Act 33 that the input user instruction is not an instruction to turn off the illumination light source 111 of the designated machine, the control unit determines that the input user instruction is a dimming instruction of the illumination light source 111 of the designated machine. Is determined (Act 35). Here, when it is determined that the input user instruction is a dimming instruction for the designated machine, the control unit adjusts the signal pattern and the light pattern corresponding to the address of the designated machine from the recording area in the recording device or the control unit integrated circuit. A signal pattern corresponding to the light instruction is read to generate a designated machine dimming control signal, which is output as a control signal to the control signal superimposing circuit 15 (Act 36). Thereafter, the control unit returns to the operation of Act11. By the operation of Act 36, the control signal superimposing circuit 15 supplies the control signal superimposing voltage obtained by superimposing the designated dimming control signal as the control signal to the low DC voltage from the storage battery 13 to all of the plurality of lighting devices 11. To do. In each of the plurality of lighting devices 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage to determine whether or not a dimming instruction has been given to the own device. If the dimming instruction is given to the machine, the lighting light source 111 is dimmed by the lighting circuit 114.

  On the other hand, when it is determined in Act 11 that there has been an input of a power failure occurrence notification from the AC / DC converter 12 (or the storage battery 13), the control unit presents the current state of the illumination light sources 111 of all the lighting devices 11 Is stored in a recording area in the recording device or the control unit integrated circuit (Act 37). And the specific machine information which shows the some illuminating device 11 (specific machine) made to function as an emergency light at the time of a power failure from the recording area in a recording device or a control part integrated circuit is read, and the signal pattern corresponding to the address of these specific machines And a signal pattern for lighting with an amount of light stipulated as an emergency light by the law of each country, etc., to generate a dimming control signal for the specific machine, and output this to the control signal superimposing circuit 15 as a control signal (Act 38). By the operation of Act 38, the control signal superimposing circuit 15 causes the control signal superimposing voltage obtained by superimposing the dimming control signal for the specific machine as the control signal to the low DC voltage from the storage battery 13 for all of the plurality of lighting devices 11. Is supplied to the lighting device 11. In each of the plurality of lighting devices 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage, so that a dimming instruction corresponding to the occurrence of a power failure is given to the own device. If it is determined whether or not a dimming instruction has been made, the lighting circuit 114 turns on the illumination light source 111 with a light amount defined as an emergency light by the lighting circuit 114. That is, when the own device is specified as an emergency light, if the illumination light source 111 is already turned on, the light amount is adjusted to the light amount specified as the emergency light, and the illumination light source 111 is turned off. Illuminates the illumination light source 111 with a light quantity defined as an emergency light.

  In addition, the control unit reads out the signal pattern corresponding to the address of each lighting device 11 other than the specific unit and the signal pattern corresponding to the turn-off instruction from the recording area in the recording unit or the control unit integrated circuit. A light extinction control signal is generated for other than the above and is output to the control signal superimposing circuit 15 as a control signal (Act 39). Thereafter, the control unit returns to the operation of Act11. By the operation of Act 39, the control signal superimposing circuit 15 applies the control signal superimposing voltage obtained by superimposing the extinction control signal for other than the specific machine as the control signal to the low DC voltage from the storage battery 13 for all of the plurality of lighting devices 11. It is supplied to the lighting device 11. In each of the plurality of lighting devices 11, the control signal analysis circuit 113 analyzes the control signal superimposed on the control signal superimposed voltage, thereby determining whether or not a turn-off instruction is given to the own device. If an instruction to turn off is given, the illumination light source 111 is turned off by the lighting circuit 114. Therefore, the illumination light source 111 is turned off in the illumination devices 11 other than the specific machine that functions as an emergency light when a power failure occurs.

  In addition, when it is determined in Act 12 that there has been an input of a power failure recovery notification, in Act 23, a return control signal is generated for returning all the lighting devices 11 to their original states. Will do.

  In addition, since it is desirable to turn on the emergency light promptly when a power failure occurs, only one dimming control signal is generated without performing identification of a specific machine, and the plurality of illuminations are generated via the control signal superimposing circuit 15. You may make it send to all the apparatuses 11 simultaneously. In this case, in each of the plurality of lighting devices 11, information on whether or not the own device is a specific device that should function as an emergency light is recorded in the recording device of the control signal analysis circuit 113 or in the recording area in the control unit integrated circuit. In addition, when analyzing that it is a dimming control signal, it is determined whether or not the own device is a specific device, and dimming or extinguishing as an emergency light is performed.

Further, when a power failure occurs, an operation as indicated by a dotted line in FIG. 5 may be performed.
That is, after storing the current state of the illumination light source 111 of the illuminating device 11 in Act 37, the control unit causes the recording device or the recording unit in the control unit integrated circuit to function as an emergency light when a power failure occurs. The specific machine information indicating 11 (specific machine) is read, and it is determined whether or not the current state of the specific machine is all extinguished (Act 40). If all the specified machines are turned off, the process proceeds to Act 38, and all the specified machines that are turned off are turned on as emergency lights.

  On the other hand, when it is determined that any one of the specific machines is lit, the control unit further determines the amount of power stored in the storage battery 13 in the recording device of the control unit 14 or in the control unit integrated circuit. Whether or not there is a remaining battery level equal to or greater than the threshold charge amount by comparing it with the threshold charge amount based on the light quantity and lighting time of the emergency light that is stored in the recording area and stipulated by the laws of each country Is determined (Act 25). Here, when it is determined that there is still a remaining battery level equal to or greater than the threshold storage amount, the control unit generates a dimming control signal for the specific machine that is turned off, and outputs this to the control signal superimposing circuit 15 as a control signal. (Act 41). That is, when the remaining battery level is present, the specific device that is lit is continuously lit with the same amount of light, and the specific device that is unlit is lit as an emergency light. However, in this case, it is necessary to notify that a power outage has occurred by some method at a location corresponding to the specific machine that is kept on. Thereafter, the control unit proceeds to the operation of Act39.

  Then, in Act 25, when it is determined that the remaining battery level is less than the threshold power storage amount, the control unit proceeds to the operation of Act 38 and turns on the specific machine that has been lit as an emergency light.

(Effect of 2nd Embodiment)
According to the present embodiment, in addition to the effects of the first embodiment, the lighting devices 11 can be controlled to be lighted independently.

  Moreover, at the time of a power failure, only the illumination light source 111 to be turned on as an emergency light is turned on, and the others are turned off, so that the lighting continuation time required as an emergency light can be ensured.

(Third embodiment)
In the present embodiment, a case will be described in which the illumination system 1 includes a plurality of illumination devices, as in the second embodiment. The overall system diagram of the third embodiment will be described with reference to FIG. 6, and the same components as those of the second embodiment will be denoted by the same reference numerals and detailed description thereof will be omitted.

  As shown in FIG. 6, the illumination system 1 according to the present embodiment also includes a plurality of illumination devices. In the present embodiment, the illumination device 11 having the control signal analysis circuit 113 and the illumination device 11A that does not have the control signal analysis circuit 113 are provided. Two types of lighting devices are mixed. That is, the illumination system 1 according to the present embodiment includes at least one illumination device 11 and at least one illumination device 11A.

  In this case, each lighting device 11 and each lighting device 11A are assigned different addresses, and the address information is stored in the recording device provided in the control signal analysis circuit 113 included in each lighting device 11 or the control signal analysis circuit. 113 is recorded in a recording area in the control unit integrated circuit. The control signal analysis circuit 113 of the illumination device 11 records address information of the illumination device 11A connected to the control signal analysis circuit 113 in addition to the own device. That is, when the control unit of the control signal analysis circuit 113 of the lighting device 11 analyzes the control signal superimposed on the control signal superimposed voltage, an instruction to turn on, turn off, dimm, or dimm is given to the own device. In addition to turning on, turning off, dimming, or dimming the illumination light source 111 of the own device by the lighting circuit 114 of the own device, the lighting circuit 11A controls the lighting device 11A having the address that it manages. When a light or dimming instruction is given, the lighting circuit 114 of the lighting device 11A turns on, turns off, dimmes, or dimmes the illumination light source 111 of the lighting device 11A.

  The example of the operation | movement flow of the illumination system which concerns on this embodiment is demonstrated using FIG. Here, since the operation of the control unit 14 is the same as that of the second embodiment, the description thereof is omitted. In the flow of FIG. 7, the control unit of the control signal analysis circuit 113 of the illumination device 11 starts the program recorded in the recording device provided in the control signal analysis circuit 113 or in the recording area in the control unit integrated circuit. Start by.

  First, the control unit of the control signal analysis circuit 113 of the illumination device 11 analyzes the control signal superimposed on the control signal superimposed voltage (Act 51). Then, the control unit determines whether or not the dimming control signal for the specific plurality of devices having the lighting device 11 or 11A managed by itself as the specific device is superimposed as a control signal (Act 52). That is, the control unit corresponds to the address of the lighting device 11 or 11A managed by itself, in which the address indicating the specific plurality of devices in the control signal is recorded in the recording area in the recording device or the control unit integrated circuit. Judge whether or not.

  Here, if it is determined that the dimming control signal for the specific plurality of devices whose specific device is the lighting device 11 or 11A managed by itself is not superimposed, the control unit selects the lighting device 11 or 11A managed by itself. It is determined whether or not the designated machine lighting control signal as the designated machine is superimposed as a control signal (Act 53). That is, the control unit corresponds to the address of the lighting device 11 or 11A managed by itself, in which the address indicating the designated machine in the designated machine lighting control signal is recorded in the recording area in the recording device or the control unit integrated circuit. Judge whether to do. Here, if it is determined that the designated device lighting control signal having the designated illumination device 11 or 11A managed by the designated device as the designated device is superimposed, the control unit determines the illumination light source 111 of the designated illumination device 11 or 11A. A designated machine lighting control instruction signal for lighting is output to the lighting circuit 114 of the designated lighting device 11 or 11A (Act 54). Thereafter, the control unit returns to the operation of Act 51.

  Further, in Act 53, when it is determined that the designated device lighting control signal using the designated lighting device 11 or 11A as the designated device is not superimposed, the control unit designates the lighting device 11 or 11A managed by itself. It is determined whether or not the designated machine extinguishing control signal is superimposed as a control signal (Act 55). That is, the control unit corresponds to the address of the lighting device 11 or 11A managed by itself, in which the address indicating the designated device in the designated device turn-off control signal is recorded in the recording area in the recording device or the control unit integrated circuit. Judge whether to do. Here, if it is determined that the designated device turn-off control signal with the designated illumination device 11 or 11A managed by itself is superimposed, the control unit determines the illumination light source 111 of the designated illumination device 11 or 11A. A designated machine turn-off control instruction signal for turning off the light is output to the lighting circuit 114 of the designated lighting device 11 or 11A (Act 56). Thereafter, the control unit returns to the operation of Act 51.

  In Act 55, if it is determined that the designated device turn-off control signal using the lighting device 11 or 11A managed by the designated device is not superimposed, the control unit designates the lighting device 11 or 11A managed by itself. It is determined whether or not the designated machine dimming control signal is superimposed as a control signal (Act 57). That is, the control unit has the address indicating the designated machine in the designated machine dimming control signal recorded in the recording area of the recording device or the control unit integrated circuit, and the address of the lighting device 11 or 11A managed by itself. It is determined whether or not it corresponds. Here, if it is determined that the designated device dimming control signal having the designated lighting device 11 or 11A managed by the designated device as a designated machine is superimposed, the control unit illuminates the designated lighting device 11 or 11A. The designated machine dimming control instruction signal for dimming is output to the lighting circuit 114 of the designated lighting device 11 or 11A (Act 58). Thereafter, the control unit returns to the operation of Act 51.

  On the other hand, in Act 51, when it is determined that the specific multi-device dimming control signal having the specific lighting device 11 or 11A managed by itself is superimposed, the control unit determines that the specified lighting device 11 and A specific multi-device dimming control instruction signal for lighting the illumination light source 111 of 11A as an emergency light is output to the specified lighting device 11 and / or the lighting circuit 114 of 11A (Act 59). Thereafter, the control unit returns to the operation of Act 51.

(Effect of the third embodiment)
According to the present embodiment, similarly to the second embodiment, the lighting devices 11 can be controlled to be lit independently. Further, since the lighting control of the lighting device 11A that does not have the control signal analysis circuit 113 can be performed with the single control signal analysis circuit 113 in addition to the lighting device 11 provided with the control signal analysis circuit 113, the cost can be reduced.

  Although some embodiments have been described above, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1 ... Lighting system, 2 ... System power supply, 11 ... Lighting apparatus, 11A ... Lighting apparatus, 12 ... AC / DC converter, 13 ... Storage battery, 14 ... Control unit, 15 ... Control signal superimposition circuit, 16 ... Renewable energy source, DESCRIPTION OF SYMBOLS 111 ... Illumination light source, 112 ... Rectification circuit, 112B ... Bridge circuit, 112R ... Resistance element, 113 ... Control signal analysis circuit, 114 ... Lighting circuit

Claims (8)

An illuminating device having an illuminating light source that is lit by being supplied with a DC voltage;
A control unit for outputting a control signal for performing lighting control of the illumination light source;
A superimposing unit disposed on a DC voltage supply line from a DC voltage supply source to the lighting device, and superimposing the control signal from the control unit on the DC voltage to supply the lighting device;
Lighting system. The illumination system according to claim 1, wherein the illumination device includes an analysis unit that analyzes the control signal superimposed on the DC voltage and performs lighting control of the illumination light source. The illumination system according to claim 1, wherein the superimposing unit superimposes the control signal on the DC voltage by passing or blocking the DC voltage according to the control signal. The illumination system according to claim 1, wherein the superimposing unit superimposes the control signal on the DC voltage by adding the control signal to the DC voltage. The DC voltage source comprises a storage battery charged with commercial power;
The said control part outputs the control signal for making the said illumination light source of the said illuminating device light as an emergency light, when charge to the said storage battery by the said commercial power is stopped. The lighting system described in. The lighting system includes a plurality of the lighting devices;
The control unit includes address information of a lighting device to be controlled in the control signal;
The illumination system according to claim 2, wherein the analysis unit of the illumination device analyzes the address information included in the control signal and performs lighting control of the illumination light source of the illumination device including the analysis unit. The illumination system has a plurality of illumination devices including the illumination device having the analysis unit and the illumination device not having the analysis unit;
The control unit includes address information of a lighting device to be controlled in the control signal;
The analysis unit of the lighting device analyzes the address information included in the control signal, and the lighting device that does not include the lighting control of the illumination light source and the analysis unit of the lighting device having the analysis unit has The lighting system according to claim 2, wherein lighting control of the illumination light source is performed. The DC voltage source comprises a storage battery charged with commercial power;
The control unit turns on the illumination light source of a predetermined illumination device as an emergency light among the plurality of illumination devices when charging to the storage battery by the commercial power is stopped, and the predetermined The illumination system according to claim 6 or 7, wherein a control signal for turning off the illumination light source of an illumination device other than the illumination device is output.