JP2006185601A - Lighting control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting control system capable of lowering standby power for each luminaire according to a light control signal. <P>SOLUTION: This lighting control system 1 is provided with monitoring terminal apparatuses 4 and 5 connected to a transmission line 8 for outputting a control signal varying light output from the luminaire 2 and a control terminal device 7 receiving the control signal via the transmission line 8 to compute and generate a light control signal matching the control signal and outputting it to the luminaire 2 and controlling a power supply switching means 3 to interrupt supply of power to the luminaire 2 when the light control signal is equal to or smaller than a light control ratio previously set for lowering the light output of the luminaire 2 to a low level. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a lighting control system including a monitoring terminal and a control terminal.

  In a lighting control system that controls the light output of a lighting fixture and turns on / off the power to the lighting fixture, for example, the illuminance sensor is used to control the illuminance of the lighting area uniformly, and the dimming control device such as a remote control device or a fader Is used to adjust the illuminance of the illumination area. Here, a dimming signal corresponding to a control signal output from the illuminance sensor or the dimming control device is input to the high-frequency lighting device of the lighting fixture. Depending on the light control signal, some lighting fixtures can be controlled from extinguishing (light control rate 0%) to full light (light control rate 100%).

  When the lighting device is turned off by the dimming signal, the power is supplied to a high-frequency lighting device or the like, so that a little power is consumed. That is, standby power is consumed. In recent years, it has been demanded to reduce standby power from the viewpoint of resource saving and power saving, and an illumination control system capable of reducing this standby power has been proposed (for example, see Patent Document 1).

In this prior art lighting control system, the lighting controller and the breaker terminal are each provided with communication means, and the breaker terminal turns off the breaker when all the lighting controllers are turned off the lighting fixtures by detection of the communication means. Is. As a result, the supply of power to each high-frequency lighting device is stopped, and standby power is reduced.
Japanese Unexamined Patent Publication No. 2000-286064 (page 3, FIG. 1)

  The lighting control system of Patent Document 1 has a disadvantage that the remaining standby power is wasted at this time because the breaker is not turned off if even one of the lighting controllers is turned on. . Even if the light output of the luminaire is at a low level that does not change the illuminance of the illumination area, that is, even if the dimming rate of the luminaire is approximately 0% or low, the breaker is off. Therefore, it is considered that power consumption (standby power) in a lighting fixture or the like is useless.

  An object of this invention is to provide the illumination control system which can reduce standby | standby electric power for every lighting fixture according to a light control signal.

  The invention of the lighting control system according to claim 1 is connected between the lighting fixture; the lighting fixture and the power source, and is turned on / off to supply power to the lighting fixture or to cut off power supply to the lighting fixture. A power supply switching means configured as described above; a monitoring terminal connected to the transmission line and outputting a control signal for changing the light output of the luminaire; and a main control means for controlling the control signal to be output to the transmission line And receiving the control signal from the transmission line, calculating and generating a dimming signal according to the control signal, and outputting the dimming signal to the lighting fixture. The dimming signal is set in advance to reduce the light output of the lighting fixture to a low level. And a control terminal for controlling the power supply switching means to cut off the supply of electric power to the luminaire when the dimming rate is less than or equal to the dimming rate.

  In the present invention, each configuration is as follows unless otherwise specified.

  The luminaire includes an illumination lamp and a lighting device for dimming and lighting the illumination lamp. Therefore, “supply or cut-off of electric power to the lighting fixture” means that electric power is supplied to or cut off from the lighting device. Further, “outputting a dimming signal to a lighting fixture” means outputting to a lighting device. Furthermore, “light output of a lighting fixture” means the light output of a lighting lamp. And lighting or extinguishing of a lighting fixture means lighting or extinguishing of the lamp for illumination.

  The monitoring terminal device includes, for example, a sensor device including an illuminance sensor that detects illuminance in an illumination area, a dimming operation device (a dimming control device) such as a fader including a control (knob), and a wireless device transmitted from a remote control device. A wireless transmission / reception apparatus that receives and outputs a signal can be used.

  “Low level of light output of lighting equipment” means that the ratio of the illuminance by the lighting equipment to the illuminance of the lighting area is low. The illuminance of the lighting area illuminated at the low level and the lighting equipment are turned off. This means that the illuminance difference with the illuminance of the illumination area is small.

  “Below the preset dimming rate” includes a dimming rate of 0%. At least at a dimming rate of 0%, the lighting fixture is turned off. The said light control rate can be arbitrarily set, for example in 0 to 24%.

  According to the present invention, the control signal output from the monitoring terminal is received by the control terminal corresponding to the monitoring terminal from the transmission line. When the dimming signal corresponding to the control signal exceeds a preset dimming rate, the lighting fixture is dimmed at the dimming rate and is equal to or less than the preset dimming rate. The power supply to is cut off, the lighting fixture is turned off, and power is not consumed by the lighting fixture. Moreover, since a control signal is received by the control terminal corresponding to the monitoring terminal, the lighting fixture is turned off for each lighting fixture controlled by the control terminal, and power consumption in the lighting fixture is stopped.

  According to the first aspect of the present invention, the control terminal that receives the control signal output from the monitoring terminal is connected to the control terminal when the dimming signal corresponding to the control signal is equal to or less than a preset dimming rate. Since the supply of electric power to the lighting fixture controlled by the fixture is cut off, standby power of the lighting fixture can be reduced. In addition, since standby power can be reduced for each lighting fixture controlled by the control terminal, it is possible to efficiently reduce power consumption of the lighting control system.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. First, a first embodiment of the present invention will be described.

  1 to 5 show a first embodiment of the present invention, FIG. 1 is a block diagram of a lighting control system, FIG. 2 is a perspective view of a sensor device, FIG. 3 is a block diagram of a lighting control device, and FIG. FIG. 5 is a block diagram of the control terminal.

  In FIG. 1, a lighting control system 1 includes a lighting fixture 2, a relay 3 as a power switching means, a sensor device 4 and a dimming operation device 5 as a monitoring terminal, a main control device 6 and a control terminal as main control means. 7. The lighting fixture 2, the sensor device 4, the dimming operation device 5, the main control device 6, and the control terminal device 7 are connected to the transmission line 8. The lighting fixture 2 and the sensor device 4 are disposed on the ceiling surface 9. Here, the control terminal 7 and the relay 3 may be integrated and configured as one control terminal 7A, or may be configured separately.

  The lighting fixture 2 is directly attached to the ceiling surface 9 and is provided with a dimmable fluorescent lamp 10 and a lighting device 11 for dimming and lighting the fluorescent lamp 10 therein. In general, a plurality of lighting fixtures 2 are connected to one control terminal 7 and controlled. The plurality of lighting fixtures 2 are arranged on the ceiling surface 9 for each lighting area 12. A predetermined illumination area 12 is formed by illumination by the plurality of lighting fixtures 2.

  The lighting device 11 is a high-frequency lighting device, and lights the fluorescent lamp 10 at a dimming rate of 0 to 100% in accordance with a dimming control signal output from the control terminal 7 such as a PWM dimming signal. Here, the fluorescent lamp 10 is turned off at least when the light control rate is 0%, and is turned on at all times when the light control rate is 100%. That is, the light output of the fluorescent lamp 10 is controlled according to the dimming signal. The illumination intensity of the illumination area 12 changes according to this light output.

  The relay 3 is connected between the lighting device 11 of the lighting fixture 2 and the commercial AC power source Vs. When a drive voltage is output from the control terminal 7, a relay coil (not shown) is energized and turned on, and the lighting device 11 is supplied with power (power) from the commercial AC power supply Vs. Further, when the drive voltage is not output from the control terminal 7, the relay coil is deenergized and turned off, and the supply of power (power) from the commercial AC power supply Vs to the lighting device 11 is cut off.

  As shown in FIG. 2, the sensor device 4 includes a sensor device body 13, a cover 14, attachment springs 15 and 15, and the like. The cover 14 is provided with an illuminance sensor 16, a human body detection sensor 17, a receiving element 18, a transmission LED 19, a display LED 20, and the like so as to be exposed to the outer surface 14a. The sensor device body 13 houses therein an illumination control device 21 (not shown) as main control means, and a terminal group 22 is disposed on the side surface 13a. The terminal group 22 is formed by output terminals that connect the illumination control device 21 to the transmission line 8.

  The illuminance sensor 16 is configured to indirectly detect the illuminance of the illumination area 12 mainly by reflected light from the illumination area 12 and send it to the illumination control device 21. The human body detection sensor 17 detects a human body that approaches the illumination area 12. When the human body is detected, the fluorescent lamp 10 is turned on.

  The receiving element 18 is formed of, for example, CdS, and is configured to receive various control signals such as target illuminance transmitted from the remote control device 23 (shown in FIG. 1) and send the signals to the illumination control device 21. The transmission LED 19 transmits a reply signal or the like sent from the illumination control device 21 to the remote control device 23. The display LED 20 is lit when the sensor device 4 such as the illumination control device 21 or the illuminance sensor 16 is operating normally.

  As shown in FIG. 3, the illumination control device 21 includes an illuminance input unit 24, a human body detection unit 25, a wireless reception unit 26, a wireless transmission unit 27, a display unit 28, a storage unit 29, a transmission unit 30, and a power supply unit 31. And a control unit 32.

  The illuminance input unit 24 is electrically connected to the illuminance sensor 16, and is configured to input an output voltage of the illuminance sensor 16 and send it to the control unit 32. Here, the output voltage of the illuminance sensor 16 correlates with the illuminance of the illumination area 12. That is, the illuminance input unit 24 receives the illuminance of the illumination area 12 detected by the illuminance sensor 16.

  The human body detection unit 25 is connected to the human body detection sensor 17 and is configured to send a human body detection signal detected by the human body detection sensor 17 to the control unit 32. When a human body detection signal is input from the human body detection unit 25, the control unit 32 transmits an illumination control signal for lighting the fluorescent lamp 12 from the transmission unit 30 to the transmission line 8.

  The wireless receiving unit 26 is connected to the receiving element 18 and is an illumination control signal such as an on / off control signal and a dimming control signal transmitted from the remote control device 23, an external signal such as a target illuminance setting signal and a release signal, an address signal, and the like. Are sent to the control unit 32.

  The wireless transmission unit 28 is connected to the transmission LED 19 and is configured to transmit a reply signal transmitted from the control unit 32 from the transmission LED 19 to the remote control device 23.

  The display unit 28 is connected to the display LED 20 and is configured to light the display LED 20 in accordance with the control of the control unit 32 when the sensor device 4 is operating normally.

  The storage unit 29 stores various data such as addresses of the sensor device 4, the main control device 6, the lighting fixture 2, the control terminal 7, and the like, and target illuminance of the lighting area 12. The target illuminance is set from the remote control device 23, for example.

  The transmission unit 30 is configured to output the dimming control signal calculated and generated by the control unit 32 to the transmission line 8 in addition to the illumination control signal transmitted from the remote control device 23 and input to the wireless reception unit 26. Yes.

  The power supply unit 31 is connected to a commercial AC power supply Vs, and is configured to convert an AC voltage into a DC voltage, adjust the voltage to a predetermined voltage value, and supply drive power to the control unit 32 and other circuit units. ing.

  The control unit 32 includes a CPU and a ROM that stores programs. Then, the control unit 32 inputs the illuminance of the illumination area 12 detected by the illuminance sensor 16 from the illuminance input unit 24. And the light control signal which changes the light output (light control rate) of the lighting fixture 2 so that the illumination intensity of the illumination area 12 may substantially correspond to the target illumination intensity memorize | stored in the memory | storage part 29 is calculated and produced, and a transmission part 30 to the main controller 6 via the transmission line 8.

  In addition, when the target illuminance setting signal is input from the receiving element 18 to the wireless reception unit 26, the control unit 32 stores the target illuminance in the storage unit 29. In addition, when a human body detection signal is input from the human body detection sensor 17 to the human body detection unit 25, the control unit 32 calculates and generates a lighting control signal for lighting the lighting fixture 2, and transmits the transmission line 8 from the transmission unit 30. To the main control device 6 via In addition, it is configured to perform various controls.

  In FIG. 1, the dimming operation device 5 outputs a control signal for changing the dimming rate of the fluorescent lamp 10 between 0 and 100% to the transmission line 8 by moving the knob 5a up and down. It is configured to transmit to the control device 6.

  The main control device 6 performs overall management of the entire lighting system. As shown in FIG. 1, the main control device 6 is connected to the sensor device 4 and the control terminal 7 disposed in each illumination area 12 via the transmission line 8. It is connected. The main controller 6 has a main controller main body 6a installed inside the wall such that the surface on which the display unit, the operation unit, and the like are provided is exposed to the wall surface 33.

  As shown in FIG. 4, the main control device 6 includes a main control unit 34, a power supply unit 35, a nonvolatile storage unit 36, a transmission interface (I / F) unit 37, and an external input interface (I / F) unit. 38, a setting operation unit 32, a display unit 33, and the like.

  The power supply unit 35 converts the AC voltage input from the commercial AC power supply Vs into a DC voltage and adjusts the voltage to a predetermined voltage value, and supplies power to the main control unit 34 and the like to operate. The non-volatile storage unit 36 stores various data such as addresses of the sensor device 4 and the lighting fixture 2 and the target illuminance of the lighting fixture 2.

  The transmission I / F unit 37 is connected to the transmission line 8 and configured to transmit and receive control signals and the like between the sensor device 4, the dimming operation device 5, and the control terminal device 7.

  The external input I / F unit 38 is connected to, for example, an external switch (not shown) provided on the surface of the main controller 6. The lighting fixture 2 can be turned on or off by operating the external switch. The setting operation unit 32 is used to input address settings, target illuminance, and the like. Moreover, the display part 33 is comprised so that the lighting state of the lighting fixture 2 of the illumination area 12 may be displayed, for example.

  The main control unit 34 includes a CPU and a ROM in which programs are stored. Then, the main control unit 34 performs arithmetic processing on the control signal output from the illumination control device 21 of the sensor device 4, and outputs the control signal from the transmission I / F unit 37 to the transmission line 8 to output the control terminal 7. Send to. That is, when a lighting control signal for turning on the lighting fixture 2 when the human body detection sensor 17 detects a human body is input, the control terminal 7 is caused to transmit a control signal to which an address is assigned. When an illumination control signal that changes the light output of the lighting fixture 2 (the dimming rate of the fluorescent lamp 10) according to the illuminance detected by the illuminance sensor 16 is input, the control signal to which the address is assigned is sent to the control terminal 7 To send to.

  Further, when the knob 5a of the dimming operation device 5 is operated and the lighting control signal for changing the light output of the lighting fixture 2 (the dimming rate of the fluorescent lamp 10) is input, the main control unit 34 sets the address. The given control signal is transmitted to the control terminal 7 corresponding to the dimming controller 5.

  The main control unit 34 processes the control signal output from the dimming operation device 5 by operating the knob 5a in preference to the control signal output from the sensor device 4 (illumination control device 21). Then, the illuminance of the illumination area 12 detected by the illuminance sensor 16 at this time is stored as a temporary target illuminance in the nonvolatile storage unit 36 and the storage unit 29 of the illumination control device 21, respectively. Then, until the lighting control signal for turning off the lighting fixture 2 is transmitted from the main control device 6 to the lighting fixture 2, the sensor device 4 is controlled so that the illuminance of the illumination area 12 becomes the temporary target illuminance. Once the lighting fixture 2 is turned off, the temporary target illuminance is erased from the nonvolatile storage unit 36 and the storage unit 29 of the lighting control device 21 and output from the sensor device 4 (lighting control device 21). The control signal to be processed is prioritized over the control signal output from the dimming operation device 5 until the knob 5a of the dimming operation device 5 is operated.

  The main control unit 34 is configured to perform various other controls.

  As shown in FIG. 1, the control terminal 7 is connected to the transmission line 8 and receives various control signals from the transmission line 8. As shown in FIG. 5, the control terminal 7 includes a transmission interface (I / F) unit 39, a control unit 40, a dimming signal output unit 41, an ON / OFF signal output unit 42, a nonvolatile storage unit 43, and a power source. A portion 44 is provided.

  The transmission I / F unit 39 is connected to the transmission line 8, receives a control signal from the transmission line 8, and sends a monitoring signal such as a lighting state of the fluorescent lamp 10 to the transmission line 8.

  When the control unit 40 determines that the control signal received by the transmission I / F unit 39 is a control signal for turning on or off the lighting fixture 2, the control unit 40 turns on a relay on signal for turning on the relay 3 or a relay off signal for turning off the relay 3. / OFF signal output unit 42. When the relay-on signal is transmitted from the state in which the relay-off signal is transmitted, a dimming signal having an initial dimming rate, for example, 70%, for example, a PWM dimming signal is transmitted to the dimming signal output unit 41. .

  When the control unit 40 determines that the control signal received by the transmission I / F unit 39 is a control signal that changes the light output of the lighting fixture 2, the control unit 40 calculates and generates a dimming signal corresponding to the control signal. Then, when the dimming signal exceeds a preset dimming rate, for example, 24%, the dimming signal is sent to the dimming signal output unit 41. Further, when the dimming signal is equal to or less than a preset dimming rate, a relay off signal for turning off the relay 3 is sent to the ON / OFF signal output unit 42.

  Then, the control unit 40 uses the dimming signal output to the dimming signal output unit 41 and the ON / OFF signal output unit 42, the lighting state of the fluorescent lamp 10 according to the relay on signal and the relay off signal as a monitoring signal, and transmits the transmission I / O. Output from the F unit 39 to the transmission line 8. The monitoring signal is transmitted to the main control device 6.

  The dimming signal output unit 41 is connected to the lighting device 11 of the lighting fixture 2 and is configured to output the dimming signal sent from the control unit 40 to the lighting device 11. The lighting device 11 lights the fluorescent lamp 10 at a dimming rate according to the dimming signal. In addition, when the lighting device 11 turns on the fluorescent lamp 10 from turning off without using a dimming signal, that is, turning off the power (power supply) from the commercial AC power supply Vs, the lighting device 11 initially has an initial dimming rate (for example, (70%).

  The ON / OFF signal output unit 42 is connected to the relay coil of the relay 3. When a relay-on signal is sent from the control unit 40, a drive voltage is output to the relay coil of the relay 3. With this drive voltage, the relay coil is energized and the relay 3 is turned on. And electric power (power supply) is supplied to the lighting device 11 of the lighting fixture 2 from the commercial alternating current power supply Vs, and the fluorescent lamp 10 lights up. The fluorescent lamp 10 is initially lit at an initial dimming rate (for example, 70%).

  Further, when a relay-off signal is sent from the control unit 40, no drive voltage is output to the relay coil of the relay 3. Thereby, the relay coil is de-energized and the relay 3 is turned off. And supply of the electric power (power supply) to the lighting device 11 of the lighting fixture 2 from the commercial AC power supply Vs is interrupted, and the fluorescent lamp 10 is turned off.

  The non-volatile storage unit 43 stores various data such as an arithmetic expression of a dimming signal with respect to the control signal, a preset dimming rate, an initial dimming rate, and addresses of the control terminal 7 and the lighting fixture 2. .

  The power supply unit 44 converts the AC voltage input from the commercial AC power supply Vs into a DC voltage and adjusts the voltage to a predetermined voltage value, and supplies the power to the control unit 40 and the like to operate.

  The control terminal 7 may be configured as a dimming control terminal having a dimming signal output unit 41 and an ON / OFF control terminal having an ON / OFF signal output unit 42.

  Next, the operation of the first embodiment of the present invention will be described.

  When a person approaches the illumination area 12, a human body is detected by the human sensor 17 of the sensor device 4, and a control signal for lighting the luminaire 2 is transmitted from the illumination control device 21 to the main control device 6. The main control device 6 sends a control signal to which an address is given to the transmission line 8 so that the control signal is transmitted to the control terminal 7 corresponding to the sensor device 4. The control signal is received by the control terminal 7 corresponding to the sensor device 4.

  The control unit 40 of the control terminal 7 outputs a relay ON signal to the ON / OFF signal output unit 42 and outputs a dimming signal with an initial dimming rate of 70% to the dimming signal output unit 41.

  The ON / OFF signal output unit 42 outputs a drive voltage based on the relay on signal to turn on the relay 3. Thereby, the AC voltage of the commercial AC power supply Vs is input to the lighting device 11 of the lighting fixture 2. Then, the lighting device 11 lights the fluorescent lamp 10 with an initial dimming rate of 70% output from the dimming signal output unit 41. The illumination area 12 is illuminated by the radiated light from the fluorescent lamp 10.

  The illuminance of the illumination area 12 is detected by the illuminance sensor 16 of the sensor device 4. Then, the control unit 32 of the illumination control device 21 calculates and generates a control signal for changing the light output of the luminaire 2 so that the illuminance detected by the illuminance sensor 16 becomes the target illuminance stored in the storage unit 29. Then, the signal is output from the transmission unit 30 to the transmission line 8. The control signal is transmitted from the main control device 6 to the control terminal 7 corresponding to the sensor device 4.

  The control unit 40 of the control terminal 7 calculates and generates a dimming signal corresponding to the control signal. When the dimming signal exceeds a preset dimming rate (for example, 24%) stored in the nonvolatile storage unit 43, the dimming signal is sent to the dimming signal output unit 41. The dimming signal output unit 41 outputs the dimming signal to the lighting device 11. The lighting device 11 lights the fluorescent lamp 10 with the dimming rate of the dimming signal. Thereby, the illumination area 12 is illuminated with the target illuminance.

  Then, the control unit 40 of the control terminal 7 sends a relay off signal for turning off the relay 3 to the ON / OFF signal output unit 42 when the calculated dimming signal is equal to or less than a preset dimming rate (for example, 24%). To send. The ON / OFF signal output unit 42 does not output a drive voltage to the relay coil of the relay 3 based on the relay off signal. As a result, the relay 3 is turned off, the supply of power (power) from the commercial AC power supply Vs to the lighting device 11 of the lighting fixture 2 is interrupted, and the fluorescent lamp 10 is turned off. And power consumption is no longer performed by the lighting fixture 2.

  In the illumination area 12, since the light output from the luminaire 2 decreases because the fluorescent lamp 10 is not lit at a dimming rate equal to or lower than a preset dimming rate (for example, 24%), the illuminance is lower than the target illuminance. Become. However, if the outside light incident on the illumination area 12 is large, for example, even if the light output from the lighting fixture 2 that is turned on at a dimming rate of 24% is lost, the work environment in the illumination area 12 is greatly affected. It is thought that there is nothing.

  Here, if the illuminance of the illumination area 12 is lower than the target illuminance and the work in the illumination area 12 is disturbed, the preset dimming rate is reduced to, for example, 10% or 5%. You only have to set it. Thereby, even if the fluorescent lamp 12 is forcibly turned off, the difference in illuminance between the illuminance of the illumination area 12 and the target illuminance is reduced, and a sense of discomfort or discomfort is suppressed.

  And if the illumination intensity of the illumination area 12 is only the external light and becomes the target illumination intensity, the control signal output from the illumination control device 21 of the sensor device 4 and received by the control terminal device 7 has a dimming rate of 0%. It becomes a dimming signal. Even when the dimming rate is 0%, the supply of electric power (power supply) to the lighting fixture 2 is cut off, and the fluorescent lamp 10 is forcibly turned off.

  Further, a control for changing the light output of the lighting fixture 2 by operating the knob 5a of the dimming operation device 5 or transmitting a wireless signal (illumination control signal) from the remote control device 23 to the receiving element 18 of the sensor device 4. When the signal is received by the control terminal 7, the control terminal 7 performs the same control as that of the sensor device 4 described above.

  When no person is present in the illumination area 12 and the human sensor 17 of the sensor device 4 no longer detects a human body, a control signal for turning off the luminaire 2 is output from the illumination control device 21 after a predetermined time. A control signal for turning off the lighting fixture 2 is received by the control terminal 7 corresponding to the sensor device 4.

  The control unit 40 of the control terminal 7 outputs the relay off signal to the ON / OFF signal output unit 42, and the ON / OFF signal output unit 42 stops outputting the driving voltage based on the relay off signal. Thereby, the relay 3 is turned off, the supply of power (power) from the commercial AC power source Vs to the lighting device 11 of the lighting fixture 2 is interrupted, and the fluorescent lamp 10 is turned off.

  As described above, when the dimming signal by the control signal output from the sensor device 4 or the dimming operation device 5 and transmitted to the control terminal device 7 is equal to or less than the preset dimming rate, the sensor device 4 or dimming Since the supply of power (power) to the lighting fixture 2 in the lighting area 12 corresponding to the light operating device 5 is cut off, the standby power (power consumption) of the lighting fixture 2 for each lighting area 12 (for each lighting fixture 2) Is reduced. Therefore, the power consumption of the lighting control system 1 is efficiently reduced.

  Next, a second embodiment of the present invention will be described.

  FIG. 6 is a block diagram of a lighting control system showing a second embodiment of the present invention. The same parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof is omitted.

  The illumination control system 45 shown in FIG. 6 transmits the control signal output from the sensor device 4 directly to the control terminal 7 corresponding to the sensor device 4 via the transmission line 8 in the illumination system 1 shown in FIG. It is configured as described above. The illumination control device 21 (control unit 32) disposed in the sensor device 4 constitutes a main control unit that controls to output a control signal to the transmission line 8.

  In the illumination control system 45, the same operation and effect as the illumination control system 1 shown in FIG. 1 can be obtained.

The block diagram of the illumination control system which shows the 1st Embodiment of this invention. Similarly, the perspective view of a sensor apparatus. Similarly, the block diagram of a lighting control apparatus. Similarly, the block diagram of a main controller. Similarly, the block diagram of a control terminal. The block diagram of the illumination control system which shows the 2nd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,45 ... Lighting control system 2 ... Lighting fixture 3 ... Relay 4 as power supply switching means ... Sensor device 5 as monitoring terminal device ... Dimming operation device 6 as monitoring terminal device ... Main control device 7 as main control device ... Control terminal 21 ... Lighting control device as main control means

Claims (1)

Lighting equipment;
Power supply switching means connected between the luminaire and the power source and configured to be turned on / off to supply power to the luminaire or to cut off supply of power to the luminaire;
A monitoring terminal connected to the transmission line and outputting a control signal for changing the light output of the luminaire;
Main control means for controlling to output the control signal to a transmission line;
The control signal is received from the transmission line, and a dimming signal corresponding to the control signal is calculated and generated and output to the lighting fixture, and the dimming signal is set in advance to lower the light output of the lighting fixture. A control terminal for controlling the power supply switching means to cut off the supply of power to the lighting fixture when the dimming rate is less than or equal to the dimming rate;
A lighting control system comprising:

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