JP2019204746A - Lighting control system - Google Patents

Abstract

To provide a lighting control system that normally starts a lighting controller when power supply from the lighting controller to a terminal is stopped in a case in which a current of a communication line connecting the terminal and the lighting controller exceeds a threshold value.SOLUTION: A lighting control system includes a terminal device that has a smoothing capacitor used for power generation, and performs controls lighting, extinction, and dimming of a light emitting unit of a lighting fixture, and a lighting controller that supplies power to the terminal device via a communication line, and when the lighting controller determines that the current value of the communication line has exceeded a threshold value at a predetermined sampling period, the lighting controller stops the power supply to the terminal device and retries to supply power to the terminal device through the communication line again before the discharge of the smoothing capacitor is completed.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a lighting control system.

  Patent Document 1 discloses a technique in which a response control unit is provided in an interface circuit that receives a communication signal.

Japanese Patent Laying-Open No. 2015-185376

  When power supply is started to the lighting controller, which is a device connected to a higher level in the construction of the lighting control system, it appears to the terminal connected to the lighting controller via the communication line. In addition, an inrush current may flow. This inrush current is generated because a power supply smoothing capacitor mounted on the terminal is charged. The influence of the inrush current may be transmitted to a device connected to the lower level via a communication line.

  When an inrush current is superimposed on a communication line, a device connected to a lower level may perform a protection operation to cut off the communication signal, and may perform an operation of receiving the communication signal after a predetermined time has elapsed. If the inrush current is intermittently superimposed on the communication line, the device connected to the lower level may continue to be unable to communicate.

  Therefore, as described in Patent Document 1, a method of performing response control to blunt the waveform of the signal line is conceivable. However, in this case, since it is not possible to specify when the inrush current is superimposed on the signal line, the waveform of the signal line is always blunted. If the transmitted signal waveform is always dull, the response speed may be dull or recognized as an erroneous signal.

  The lighting controller can stop the output signal for the purpose of protecting circuit components and ensuring safety when the communication line is short-circuited and a short-circuit current flows on the communication line. When the above inrush current exceeds the threshold value for the short circuit current detection determination, the short circuit determination is made and the output is stopped. If the lighting controller stops outputting for a long time, the smoothing capacitor discharge is completed, and when the lighting controller is restarted, an inrush current flows in the same manner, which may prevent the lighting controller from starting normally.

  The present invention has been made to solve the above-described problems. When the current of the communication line connecting the terminal unit and the lighting controller exceeds a threshold value, the power supply from the lighting controller to the terminal unit is stopped. An object of the present invention is to provide a lighting control system that normally starts a lighting controller.

  A lighting control system according to the invention of the present application has a smoothing capacitor used for power generation, a terminal device that performs lighting control, light-off control, and dimming control of a light emitting unit of the lighting fixture, and power supply to the terminal device via a communication line A lighting controller that supplies power to the terminal device when the current value of the communication line exceeds a threshold value in a predetermined sampling period, and the smoothing capacitor Before the discharge is completed, a retry process for supplying power to the terminal through the communication line is performed again.

  Other features of the present invention will become apparent below.

  ADVANTAGE OF THE INVENTION According to this invention, a lighting controller can be started normally by performing the retry process which supplies power to a terminal device via a communication line, before discharge of the smoothing capacitor of a terminal device is completed.

It is a system block diagram of a lighting control system. It is a block diagram of a lighting control system. It is a timing chart which shows the output current when starting retrying after complete discharge of a smoothing capacitor. It is a timing chart which shows the output current when starting retrying before complete discharge of a smoothing capacitor.

  An illumination control system according to an embodiment of the present invention will be described with reference to the drawings. The same or corresponding components are denoted by the same reference numerals, and repeated description may be omitted.

Embodiment 1 FIG.
A configuration example of the illumination control system 80 will be described with reference to FIG. The lighting control system 80 includes a management device 81, a lighting controller 82 that is a control device, a plurality of relay control terminals 83, a plurality of remote control relays 84, and a remote control transformer 85. The management device 81 is composed of, for example, a microcomputer and performs state monitoring and setting of the entire lighting control system 80. The lighting controller 82 communicates with the terminal 83, a wall switch (not shown), various sensors, and the like via the communication line 8. The transmission signal transmitted and received by the lighting controller 82 includes address data and control data.

  The management device 81 and the lighting controller 82 are connected via a LAN (Local Area Network) 7 that is a wired or wireless communication network. Four terminal units 83 for relay control are connected in series to the lighting controller 82 via the communication line 8. Further, various sensors such as an illuminance sensor and a human sensor and an operation panel such as a wall switch are connected to the communication line 8. Four remote control relays 84 are connected to each terminal 83 by a control signal line 9. Four control system terminals 100 are connected to the lighting controller 82.

  A unique address is assigned to each terminal 83 and set. The terminal 83 is identified by the set address. The terminal device 83 includes a receiving unit 831 that receives a transmission signal transmitted from the lighting controller 82 via the communication line 8. In addition, the terminal 83 includes a comparison unit 832 that compares the address data of the transmission signal with the unique address set in the terminal 83. If the comparison unit 832 determines that the address data of the transmission signal matches the unique address set in the terminal 83, the terminal 83 sends a control signal to the remote control relay 84 in order to execute the control data of the transmission signal. Send.

  Each remote control relay 84 is connected to a load such as a lighting fixture (not shown). The remote control relay 84 receives a signal from the terminal unit 83 and intermittently supplies power supplied to a load connected to the remote control relay 84 based on the control data. Remote control transformer 85 is connected to an external power source. The remote control transformer 85 supplies relay drive power for turning on the relay contact to the input side of the remote control relay 84. The relay driving power is, for example, AC 24V.

  Next, a configuration example and operation of the illumination control system will be described with reference to FIGS. FIG. 2 is a diagram illustrating a configuration example of the lighting controller 82 and the terminal device 83. The illumination controller 82 includes a power supply unit 82A, a control unit 82B, an output unit 82C, and a short circuit detection unit 82D. The power supply unit 82A is connected to an external commercial power source and converts an AC voltage supplied from the commercial power source into a DC voltage. The controller 82B controls transmission signals to be transmitted and received. The output unit 82 </ b> C outputs a communication voltage ± 24 V to the communication line 8. The control unit 82B has a function of temporarily stopping output from the output unit 82C to the communication line 8. The short circuit detector 82D monitors the current flowing through the communication line 8, and determines whether or not the current has exceeded the short circuit detection level. If a current at the short-circuit detection level continues to flow through the communication line 8, the short-circuit detection unit 82D needs to send a signal to the control unit 82B to stop the illumination controller 82 because there is a risk of exceeding the rated power of the component.

  The terminal 83 performs lighting, extinction, and dimming control of the light emitting unit of the lighting fixture. The terminal device 83 includes an interface unit 83A, a power generation unit 83B, a communication unit 83D, and a control unit 83E. The interface unit 83A separates the transmission signal from the communication voltage ± 24V. The power generation unit 83B generates a power source for operating the control unit 83E. The power generation unit 83B includes a smoothing capacitor 83C on the input side. The smoothing capacitor 83C is used for power generation. The smoothing capacitor 83C can be an electrolytic capacitor having a large capacity of 220 μF, for example. The communication unit 83D transmits and receives transmission signals. The n terminals 83 having such a configuration are connected to the illumination controller 82 by the communication line 8. n is a positive integer.

  The lighting controller 82 supplies power to the terminal 83 via the communication line 8. More specifically, when the lighting controller 82 is supplied with AC power, it outputs a pulse signal having a communication voltage of ± 24 V including transmission data to the communication line 8. When a pulse signal with a communication voltage of ± 24 V is supplied to the communication line 8, charging of the smoothing capacitor 83 </ b> C included in each terminal device 83 starts, and an inrush current flows through the communication line 8.

  When the communication line 8 is not short-circuited and the number of terminals 83 connected is small, the current flowing through the communication line 8 has a waveform as shown after “second retry” in FIG. That is, the current that charges the smoothing capacitor 83C at the time of startup becomes the maximum, and the current flowing through the communication line 8 decreases as the charging of the smoothing capacitor 83C proceeds. When charging of the smoothing capacitor 83C is completed, the current flowing through the communication line 8 becomes substantially constant. Here, activation refers to activation of the illumination controller 82. The short-circuit detection unit 82D determines whether the current value of the communication line 8 exceeds the threshold value every predetermined sampling cycle. This threshold is a short circuit detection level. Even if the current value flowing through the communication line 8 when the illumination controller 82 is activated exceeds the short circuit detection level, if the current value is below the short circuit detection level when the short circuit detection unit 82D detects the short circuit, no short circuit is detected. . The short-circuit detection unit 82D detects the current with a delay from the start-up in order to repeat the short-circuit detection operation every sampling cycle.

  On the other hand, when the number of terminals 83 connected to the communication line 8 increases, the combined capacity of the smoothing capacitors 83C connected to the communication line 8 increases, so that the current flowing through the communication line 8 at the time of startup increases. In order to enable the lighting controller to start even in such a situation, the lighting control system according to Embodiment 1 completes the charging of the smoothing capacitor 83C by repeating the retry process.

(Retry processing)
The retry process will be described with reference to FIG. The retry process is a process executed when the short circuit detection unit 82D detects a current value equal to or higher than the short circuit detection level. First, the illumination controller 82 is activated, and power supply to the terminal device 83 via the communication line 8 is started. The short-circuit detection unit 82D detects a short-circuit current that flows through the communication line 8 after the lighting controller 82 is activated. In FIG. 4, the short-circuit detection unit 82 </ b> D detects a short-circuit current flowing through the communication line 8 after the time T <b> 1 has elapsed. The time T1 is a time until the short circuit is detected after the lighting controller 82 is activated. The time T1 can be a sampling time or an interrupt processing time of the control unit 82B. When the current value detected by the short circuit detection unit 82D is equal to or higher than the short circuit detection level (threshold), the short circuit detection unit 82D outputs a short circuit detection signal to the control unit 82B. The short circuit detection signal is, for example, a Hi voltage.

  The control unit 82B to which the short circuit detection signal is input stops outputting the communication voltage to the communication line 8. That is, power supply to the terminal 83 is stopped. For example, the supply of AC 24V to the communication line 8 is stopped by providing a half bridge circuit composed of a transistor in the output unit 82C and stopping the signal from the control unit 82B to the output unit 82C. The configuration of the output unit is an example, and other configurations may be used.

  When the voltage of the communication line 8 becomes 0, the smoothing capacitor 83C provided in each terminal 83 starts discharging. When power is again supplied from the lighting controller 82 to the terminal device 83 after the smoothing capacitor 83C is completely discharged, the current value flowing through the communication line 8 becomes the same current value as when the lighting controller 82 is first activated. Therefore, the short circuit detection unit 82D detects the short circuit again. Resuming power supply by the lighting controller 82 and then restarting it is called retry. In the comparative example of FIG. 3, after the short circuit is detected, the voltage of the communication line 8 becomes 0, and after the time T2 has elapsed and the smoothing capacitor 83C is completely discharged, the “first retry” is performed. . Although depending on the capacity of the smoothing capacitor 83C, for example, when the time T2 is 1 s or longer, the smoothing capacitor 83C is completely discharged. In the comparative example of FIG. 3, since the retry is performed after the smoothing capacitor 83C is completely discharged, even if the retry is repeated once, twice, and three times, a short circuit detection signal is input to the control unit 82B each time, and communication is performed. Output to line 8 stops.

  FIG. 4 is a diagram illustrating control employed in the illumination control system according to Embodiment 1. When a short circuit is detected after the time T1 has elapsed and power supply to the terminal device 83 is stopped, power is supplied again to the terminal device 83 via the communication line 8 before the discharge of the smoothing capacitor 83C is completed. Restarting the power supply to the terminal 83 before the smoothing capacitor 83C is completely discharged leads to a reduction in the short-circuit current at the time of retry. That is, by restarting the power supply to the terminal 83 before the smoothing capacitor 83C is completely discharged, the current value flowing through the communication line 8 in the “first retry” rather than the current value at the first activation of the lighting controller 82. Can be reduced. FIG. 4 shows that the current value flowing through the communication line 8 in the “first retry” is smaller than the current value at the first activation of the lighting controller 82. The time T2 in FIG. 4 is 30 ms, for example.

  If the current value of the communication line 8 is equal to or less than the threshold value after the sampling time T1 has elapsed after the “first retry”, the power supply to the terminal 83 is continued. On the other hand, as shown in FIG. 4, when the short-circuit detection unit 82D determines that the current value of the communication line 8 exceeds the threshold value when the sampling time T1 has elapsed after the “first retry”, the control unit 82B stops the output to the communication line 8 again. When the power supply to the terminal device 83 is stopped, the smoothing capacitor 83C again supplies power to the terminal device 83 via the communication line 8 before the discharge is completed. This operation is shown in “second retry” of FIG. FIG. 4 shows that the current flowing through the communication line 8 in the “second retry” is smaller than the current flowing through the communication line 8 in the “first retry”. In the example of FIG. 4, it is illustrated that the current value of the communication line 8 is equal to or lower than the threshold value and the power supply to the terminal 83 is continued when the sampling time T <b> 1 elapses after the “second retry”.

  In this way, the retry process is repeated, and the current value of the communication line 8 in the sampling period becomes equal to or less than the threshold value. In other words, by repeating the retry process, the charge is charged in the smoothing capacitor 83C of the terminal device 83, and the inrush current at the time of retry decreases. Therefore, the illumination controller 82 can be activated without the short circuit detection unit 82D detecting a short circuit. As the number of terminals 83 increases, the number of retry processes increases, and the time until normal startup increases.

(Restriction of retry processing count)
As shown in FIG. 3, when the communication line is short-circuited or when the lighting controller 82 does not start normally after repeated retries, the circuit components of the device connected to the communication line 8 may be overheated. . In order to suppress this, the lighting controller 82 may stop supplying power to the terminal device 83 during a predetermined pause period when the retry process is repeated for a predetermined “upper limit number”. For example, the upper limit number can be about 25 times. For example, FIG. 3 shows a pause period T3. By providing the suspension period, it is possible to suppress the temperature rise of the circuit components of the equipment connected to the communication line 8. If the retry process for supplying power to the terminal 83 again is repeated a certain number of times before the discharge of the smoothing capacitor 83C is completed, the inrush current is sufficiently reduced, so it is difficult to assume that the retry process reaches the upper limit. However, for example, assuming that there are a large number of terminals to be connected or a case where the communication line is short-circuited, it is meaningful to provide such a pause period.

(Communication line short circuit)
As described above, when the number of retries reaches a predetermined upper limit, there is a high possibility that the communication line 8 is short-circuited. In this case, it is necessary to notify the possibility of a short circuit. Therefore, when the retry process is repeated a predetermined upper limit number of times, the lighting controller 82 may notify the installer or the manager by turning on the short-circuit display LED. Specifically, when the number of retries exceeds the upper limit number, the control unit 82B stops the power supply to the communication line 8 and simultaneously turns on the short-circuit display LED provided in the illumination controller 82, for example, in yellow. The short-circuit display LED continues to light until the short-circuit detection state is canceled. By turning on the short-circuit display LED, the installer or the manager can confirm that the communication line 8 is short-circuited or that the number of devices connected to the communication line 8 is exceeded.

  When the lighting controller 82 is started, the output is temporarily stopped, and a retry process is performed to restart the smoothing capacitor 83C before discharging it beyond a certain voltage value, whereby the smoothing capacitor 83C is charged and the inrush current is suppressed. The lighting controller 82 can be normally activated. Since it is necessary to shorten the retry interval so that the smoothing capacitor 83C is not completely discharged, a short-circuit current flows continuously. Therefore, for example, in order to suppress the heat rise of the switching circuit component of the output unit 82C, it is effective to set the above-described upper limit number of times or execute the notification process.

  Since the illumination control system according to the following embodiment has many similarities to the first embodiment, the differences from the first embodiment will be mainly described.

Embodiment 2. FIG.
Parameters such as the sampling period of the short-circuit detection unit 82D described in the first embodiment, the time T2 until the start retry is executed after the power supply output from the illumination controller 82 to the terminal device 83 is stopped, the suspension period T3, and the upper limit number of times are as follows. It is conceivable that the margin is determined in consideration of a margin when the equipment connected to the lighting control system 80 is the maximum. Therefore, there is a possibility that a large margin is expected from the configuration of the actual lighting control system 80. If setting parameters that allow for margins are used as they are, the operation of a specific lighting control system may be wasted. For example, it is conceivable that a sampling period longer than necessary is set, the time T2 is not optimized, the upper limit number is too small, or the pause period is too long.

  Therefore, the management device 81 in the lighting control system according to the second embodiment outputs a signal to the lighting controller 82 to change the sampling period, change the time T2 from the power supply stop to the power supply restart in the retry process, and the upper limit number of times. Change or change the suspension period. As a result, the operator can change the above-described parameters in order to eliminate the deviation between the setting parameters that allow for margins and the actual configuration. The management device 81 can set parameters of the illumination controller 82 or the terminal device 83 by infrared or wireless communication. Thus, by enabling parameter setting from the management device 81, the time until the lighting controller 82 is normally started can be tuned.

  80 Lighting Control System, 81 Management Device, 82 Lighting Controller, 82A Power Supply Unit, 82B Control Unit, 82C Output Unit, 82D Short Circuit Detection Unit, 83 Terminal Unit, 83A Interface Unit, 83B Power Supply Generation Unit, 83C Smoothing Capacitor, 83D Communication Unit , 83E control unit

Claims (7)

A terminal device that has a smoothing capacitor used for power generation, and performs lighting control, lighting control, and dimming control of a light emitting unit of a lighting fixture;
A lighting controller for supplying power to the terminal unit via a communication line,
When the lighting controller determines that the current value of the communication line has exceeded a threshold value at a predetermined sampling period, the lighting controller stops the power supply to the terminal and again before the discharge of the smoothing capacitor is completed. A lighting control system for performing a retry process for supplying power to the terminal through a communication line.   The lighting control system according to claim 1, wherein the retry process is repeated so that a current value of the communication line in the sampling period becomes equal to or less than the threshold value.   3. The lighting control according to claim 1, wherein the lighting controller stops power supply to the terminal during a predetermined pause period when the retry process is repeated a predetermined upper limit number of times. system.   The lighting control system according to claim 1, wherein the lighting controller turns on the short-circuit display LED when the retry process is repeated a predetermined upper limit number of times.   5. The management device according to claim 1, further comprising a management device that outputs a signal to the illumination controller and changes the sampling period or changes a period from power supply stop to power supply restart in the retry process. The lighting control system according to claim 1.   The lighting control system according to claim 3, further comprising a management device that outputs a signal to the lighting controller and changes the upper limit number of times.   The lighting control system according to claim 3, further comprising a management device that outputs a signal to the lighting controller and changes the suspension period.

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