JP2009176477A - Illumination control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an illumination control system easy to be installed and capable of dimming. <P>SOLUTION: Each lighting fixture includes a discharge lamp lighting device 100 changing a discharge lamp output into a given output when the on/off-setting of a power source is in a specified pattern. The lighting fixtures 1411, 1412 change the discharge lamp output into a given lighting output when a load control switch A (131) is turned on/off at the specified pattern. An operating switch A (121) corresponds to the load control switch A(131), so that, when either of buttons of a 'high-output' or a 'low output' of the operating switch A(121) is pressed, an illumination control unit 111 generates a switching signal corresponding to an output of the pressed button to transmit the output to a load-side communication control part 133. The load-side communication control part 133 switches on the load control switch A (131) according to the switching signal. By this, the lighting fixtures 1411, 1412 are set at outputs of the pressed button. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a lighting control system for dimming a plurality of lighting fixtures.

In recent years, energy conservation efforts have been carried out in various forms in each industry. The lighting device is always installed in the facility and consumes most of the electric power used in the facility. In order to increase the energy saving effect, it is desirable to set the illuminance of the lighting device appropriately, and until now, by installing an instrument with continuous dimming function, the illuminance has always been set to an appropriate illuminance and the energy saving effect has been increased. . On the other hand, the continuous light control device had to be used integrally with the light control system, and the cost and installation work had to be significantly increased in cost and man-hours compared to the normal device. In other words, when controlling the brightness of the lighting fixture, that is, the output with the lighting control system, it is necessary to use a fixture with a continuous dimming function and to wire a dedicated dimming control line between the lighting fixture and the control device. In addition, the lighting device with a continuous light control function has been forced to significantly increase the cost and the number of man-hours compared to the normal device due to cost and installation work (for example, Patent Document 1).
JP-A-5-13177

  An object of the present invention is to provide a dimmable lighting control system that is easy to install.

The lighting control system of this invention
A lighting fixture group including a plurality of lighting fixtures provided with a discharge lamp lighting device that changes the lighting output of the discharge lamp to a predetermined lighting output when the on / off of the supplied power supply is a prescribed pattern is connected. A load control switch for turning on and off the supply of power to the group of lighting fixtures by switching under control.
A switch unit device that includes a load side communication control unit that receives a switching command signal that commands switching of the specified pattern, and executes control to switch the load control switch according to the received switching command signal;
An operation switch that outputs a request signal that requests a discharge lamp output corresponding to the operated operation unit when any one of the operation units is operated while being provided with a plurality of operation units corresponding to the output of the discharge lamp;
An operation device including an operation side communication control unit that transmits the request signal output by the operation switch;
A switching command signal generator that receives the request signal transmitted from the operating device and generates the switching command signal based on the received request signal;
And a control device including a control side communication control unit that transmits the switching command signal generated by the switching command signal generation unit to the load side communication control unit.

  According to the present invention, it is possible to provide a dimmable lighting control system that is easy to install.

Embodiment 1 FIG.
A lighting control system 1000 according to the first embodiment will be described with reference to FIGS.

  FIG. 1 is a system configuration diagram illustrating a usage mode of the lighting control system 1000 according to the first embodiment. Since a specific system configuration will be described with reference to FIG. 2 described later, an outline of the usage mode will be described with reference to FIG.

  The illumination control system 1000 includes an illumination control device 110 (control device), a load control operation device 120 (operation device), and a plurality (three in FIG. 1) of load control units 130 (switch unit devices). In the lighting control system 1000, by operating the operation switch A (121) or the operation switch B (122) of the load control operator 120, the lighting fixtures of the lighting fixture group connected to any one of the load control units 130 are operated. The discharge lamp output can be set.

(Discharge lamp output setting)
The illumination control device 110 is a computer, and the illumination control unit 111 of the illumination control device 110 can select a load control unit 130 that is an operation target of the load control operation device 120. For example, when the load control unit 130 corresponding to “1F floor” is selected as an operation target, the load control operation unit 120 sets the discharge lamp output of the lighting fixture group on the 1F floor to high output, intermediate output, low output, or the like. be able to. When the load control unit 130 corresponding to “1F floor” is selected as the operation target, the discharge lamp output of the lighting fixture group connected to the load control switch A (131) can be set by the operation switch A (121). The discharge lamp output of the lighting fixture group connected to the load control switch B (132) can be set by the operation switch B (122). The same applies to the load control unit 130 corresponding to the “2F floor” and the load control unit 130 corresponding to the “3F floor”. Therefore, the discharge lamp output can be set finely and easily for each load control unit 130 and for each load control switch of the load control unit.

  FIG. 2 shows only one load control unit 130 with respect to FIG. The illumination control device 110, the load control operator 120, and the load control unit 130 are connected by a communication control line 103.

  From the commercial power source 1 (commercial AC power source), a power line 102 is connected to the illumination control device 110 and the load control unit 130. In FIG. 2, the power supply line 102 and the communication control line 103 are provided separately, but the power supply line 102 may be used as the communication control line 103. That is, power line communication (PLC: Power Line Communications) may be used as a communication form.

(Lighting control device 110)
The illumination control device 110 includes an illumination control unit 111 (switching command signal generation unit) that controls the entire control, a control-side power supply circuit 112, and other devices (for example, an operation-side communication control unit 123, a load-side communication) through the communication control line 103. A control-side communication control unit 113 that communicates with the control unit 133) according to a predetermined procedure, and a storage unit 114 that stores correspondence information described later. The control side communication control unit 113, the operation side communication control unit 123, and the load side communication control unit 133 can communicate with each other via the communication control line 103. Further, the control side power supply circuit 112 supplies DC power to the communication control line 103. In general, the illumination control device 110 is housed in a power distribution board. As will be described later, the lighting control unit 111 receives the request signal transmitted from the load control operator 120, and generates a switching command signal for a specific load control switch based on the received request signal. Then, the control side communication control unit 113 transmits the generated switching command signal to the load side communication control unit 133.

(Load control operation device 120)
The load control operation device 120 includes two operation switches, that is, an operation switch A (121) and an operation switch B (122), and an operation side communication control unit 123. The operation side communication control unit 123 can communicate with the control side communication control unit 113 and the load side communication control unit 133 via the communication control line 103. The operation side communication control unit 123 transmits the operation state of the operation switch A (121) and the operation switch B (122) to the control side communication control unit 113 of the illumination control device 110 via the communication control line 103. The operation switch A (121) and the operation switch B (122) correspond to a load control switch A (131) and a load control switch B (132) described later. That is, the operation switch A (121) corresponds to the load control switch A (131), and the operation switch B (122) corresponds to the load control switch B (132). More specifically, the load control switch A (131) is switched according to the operation result of the operation switch A (121), and the load control switch B (132) is switched according to the operation result of the operation switch B (122).

  The case of the operation switch A (121) will be described. The operation switch A (121) is a normal lighting state of the lighting fixtures (each lighting fixture of the lighting fixture A group 141) connected to the load control switch A (131). “ON” button for turning on, “OFF” button for turning OFF, and “HIGH OUTPUT”, “INTERMEDIATE OUTPUT” for setting the output state of the lighting fixtures (each lighting fixture in the lighting fixture group A), Each “low output” operation button (operation unit) is provided. As described above, the operation switch A (121) includes a plurality of operation buttons (operation units) such as “high output”, “intermediate output”, and “low output” corresponding to the output of the discharge lamp. When the button is operated, a request signal for requesting a discharge lamp output corresponding to the operated operation button is output. The operation side communication control unit 123 transmits the request signal output by the operation switch A (121) to the illumination control device 110. The operation switch B (122) has the same configuration as the operation switch A (121). Similarly, the operation side communication control unit 123 transmits the request signal output by the operation switch B (122) to the illumination control device 110. As described above, the operation switch A (121) corresponds to the load control switch A (131), and the operation switch B (122) corresponds to the load control switch B (132). As will be described later, it is possible to control the output of the discharge lamp of the lighting fixture A group 141 connected to the load control switch A (131) by operating the operation switch A (121). By operating the switch B (122), it is possible to control the output of the discharge lamp of the luminaire B group 142 connected to the load control switch B (132). In this way, different lighting fixture groups can be controlled to different output states by the operation switch A (121) and the operation switch B (122).

(Load control unit 130)
The load control unit 130 is individually controlled by the load side communication control unit 133 that performs communication control, the load side power supply circuit 134 that generates power for operating the entire load control unit 130, and the load side communication control unit 133. Two systems of load control switch A (131) and load control switch B (132) which are ON-OFF controlled (switching control) are provided. The load side communication control unit 133 communicates with the control side communication control unit 113 and the operation side communication control unit 123. The load-side communication control unit 133 includes a load-side nonvolatile memory 1331 and stores a load control state (set value of discharge lamp output). The load control switch A (131) and the load control switch B (132) turn on and off the power to the lighting fixture. As shown in FIG. 2, the load control switch A (131) is connected to a lighting fixture A group 141 that is a lighting fixture group composed of a plurality of lighting fixtures. The load control switch A (131) switches on and off the power supply to the lighting fixture A group (141) by switching under control. Similarly, the light fixture B group 142 is connected to the load control switch B (132). The load control switch B (132) turns on and off the supply of power to the lighting fixture B group (142) by switching under control. The load-side communication control unit 133 receives a switching command signal designating a load control switch from the control-side communication control unit 113 of the lighting control device 110, and in response to the designated load control switch according to the received switching command signal Perform switching control.

  FIG. 3 is a circuit diagram of the discharge lamp lighting device 100 in the first embodiment. The discharge lamp lighting device 100 is attached to each lighting fixture of the lighting control system 1000. A feature of the discharge lamp lighting device 100 is that when the on / off of the supplied power is in a specified pattern, the discharge lamp is turned on with an output corresponding to the specified pattern, and the set value of the output for lighting the discharge lamp is set. It is to be stored in the nonvolatile memory 81. As a result, the discharge lamp lighting device 100 lights the discharge lamp with a predetermined output in accordance with a prescribed pattern for turning on and off the supplied power, and stores it in the nonvolatile memory 81 when the power is turned off and turned on next time. The discharge lamp can be turned on at the output of the set value.

(Configuration of discharge lamp lighting device 100)
The discharge lamp lighting device 100 of FIG. 3 will be described. The discharge lamp lighting device 100 includes a rectifier circuit 10, an active filter circuit 20, an inverter circuit 30, a load circuit 40, a control power supply circuit 50, a power supply synchronization circuit 60, a drive circuit 70, a microcomputer 80 including a nonvolatile memory 81, a lamp A detection circuit 90 is provided. Hereinafter, the microcomputer may be referred to as a microcomputer.
(1) The rectifier circuit 10 is a diode bridge. The rectifier circuit 10 is a circuit that rectifies the power supply voltage and removes noise.
(2) The active filter circuit 20 includes a choke coil 21, a diode 22, a capacitor 23, and a switching element 24. The active filter circuit 20 is a circuit that boosts the power supply voltage to a predetermined DC voltage and shapes the input current waveform to improve the power factor by switching with the switching element 24 along the power supply voltage waveform.
(3) The inverter circuit 30 generates a high-frequency voltage by alternately switching the switching elements 31 and 32 with the reverse polarity voltage output from the drive circuit 70 from the DC voltage boosted by the active filter circuit 20. Circuit.
(4) The load circuit 40 includes an inductor 41, a discharge lamp 42, capacitors 43 and 45, and a resistor 44. The load circuit 40 is a circuit for lighting a discharge lamp 42 (hereinafter sometimes referred to as a lamp) using the resonance of the inductor 41 and the capacitor 43.
(5) The drive circuit 70 is a circuit that alternately switches the switching elements 31 and 32 of the inverter circuit 30 based on a control signal output from the microcomputer 80.
(6) The power supply synchronization circuit 60 is a circuit that detects ON / OFF of power supply by turning on / off the load control switch.
(7) The lamp detection circuit 90 is a circuit that detects the presence or absence of a lamp from the commercial power source 1 (commercial AC power source) through the resistor 33, the inductor 41, the lamp filament, the resistor 44, and the lamp filament. The lamp detection circuit 90 outputs an H level when the lamp (discharge lamp 42) is mounted, and outputs an L level when the lamp (discharge lamp 42) is not mounted. The microcomputer 80 can determine whether or not the discharge lamp 42 is mounted by inputting an H level signal or an L level signal from the lamp detection circuit 90.
(8) The control power supply circuit 50 is a power supply circuit that drives the microcomputer 80. The control power supply circuit 50 is a circuit that holds electric power that allows the microcomputer 80 to operate for about 5 seconds even after the power supply (load control switch) is turned off.
(9) The microcomputer 80 performs frequency control of the inverter circuit 30 and determination of the power ON / OFF signal sent from the power supply synchronization circuit 60. In the discharge lamp lighting device 100, the microcomputer 80 detects the ON / OFF operation (specified pattern) of the load control switch, sets the output mode of the discharge lamp corresponding to the ON / OFF operation, and releases in the set output mode. Turn on the light. Specifically, when the microcomputer 80 detects an ON / OFF pattern (specified pattern) of a programmed predetermined power supply, the microcomputer 80 sets a predetermined output mode according to a pre-installed program, and sets the set output mode. A corresponding “control signal” is output to the drive circuit 70. When a control signal is input from the microcomputer 80, the drive circuit 70 drives the switching elements 31 and 32 of the inverter circuit 30 according to the control signal. As a result, the inverter circuit 30 oscillates at a predetermined oscillation frequency, and the discharge lamp lights up with an output corresponding to the control signal. Thereby, the light control of the discharge lamp 42 is controlled.

Next, the relationship between the load control switch A (131) and the discharge lamp lighting device 100 will be described with reference to FIG. As an operation procedure, the load control switch A (131) is ON / OFF controlled based on the operation of the operation switch A (121), and the relationship between the load control switch A (131) and the discharge lamp lighting device 100 is obtained. First, the relationship between the load control switch A (131) of FIG. 4 and the discharge lamp lighting device 100 will be described first, and then the relationship between the operation switch A (121) and the load control switch A (131) will be described. To do.
FIG. 4A shows the switching state of the load control switch A (131).
FIG. 4B is a diagram showing a supply state of commercial power based on switching of the load control switch A (131).
FIG. 4C is a diagram illustrating the output of the power supply synchronization circuit 60.
FIG. 4D is a diagram illustrating an output state of the discharge lamp lighting device 100.

(Dimming control method by microcomputer 80)
A dimming control method by the microcomputer 80 will be described. As shown in FIG. 4, in the operating state of the discharge lamp lighting device 100, the load control switch A (131) is controlled so that the load control switch A (131) has a predetermined ON / OFF pattern (specified pattern). . In the first embodiment, the predetermined ON / OFF pattern (hereinafter sometimes referred to as a prescribed pattern) of the load control switch A (131) that supplies power to the discharge lamp lighting device 100 is the following:
(1) After “OFF between 0.1 second and 3 seconds”
(2) “ON between 0.1 seconds and 3 seconds”,
After that, (3) “OFF between 0.1 seconds and 3 seconds”
Say.
With this ON / OFF pattern, the microcomputer 80 is a program that lowers the output setting by one stage (intermediate output) 3 seconds after the power is turned on thereafter (initial setting is high output). Further, when the power operation as described above is performed in a state where the first stage output is lowered (intermediate output), the second stage output state (low output) is set. Further, when the power operation is performed in this state, the high output which is the initial state is set. When a predetermined lighting time elapses in a state where the output is newly set, the set state is stored in the nonvolatile memory 81 of the microcomputer 80. When the power is turned off and turned on again, the light is turned on with the output setting stored in the nonvolatile memory 81. Since the set value is stored in the non-volatile memory 81 even when the power is turned off, the discharge lamp is turned on with the set value stored in the non-volatile memory 81 from the next time the power is turned on until the setting is changed. Let The order of the loops may be low output, intermediate output, and high output.

  The operation of the microcomputer 80 will be described as follows. The power supply synchronization circuit 60 detects ON / OFF of the operation switch A (121) and outputs a signal corresponding to ON / OFF to the microcomputer 80. The microcomputer 80 determines whether or not the “specified pattern ((1) to (3))” shown in FIG. 4 is based on the signal input from the power supply synchronization circuit 60. If the microcomputer 80 determines that the “specified pattern ((1) to (3))” is satisfied, it corresponds to a preset dimming rate when 3 seconds have elapsed after the completion of the “operation (3)”. A control signal to be generated is generated and output to the drive circuit 70, and the drive circuit 70 drives the inverter circuit 30.

(Relationship between operation switch A (121) and load control switch A (131))
FIG. 5 is a sequence diagram showing the operation of the illumination control system 1000.
Next, the relationship between the operation of the operation switch A (121) and the ON / OFF operation of the load control switch A (131) will be described with reference to FIGS.

  First, the case of FIG. 5A will be described. FIG. 5A shows that a setting value of “high output” is stored as an initial setting value in the nonvolatile memory 81 of each discharge lamp lighting device 100 and each load-side nonvolatile memory 1331. To do. In the initial setting, the same set value is set in the non-volatile memory 81 and the load-side non-volatile memory 1331 of the discharge lamp lighting device 100 (high output is an initial value is an example). Thereafter, when a button such as “intermediate output” or “low output” of the operation switch A (121) or the operation switch B (122) is pressed, the nonvolatile memory 81 of the discharge lamp lighting device 100 and the discharge lamp lighting device 100 are displayed. The same discharge lamp output set value is updated and stored in the load-side nonvolatile memory 1331 of the load-side communication control unit corresponding to.

(Load side control actuator)
It is assumed that the operator presses the “light” button of the operation switch A (121) in order to turn on the discharge lamps of the lighting fixtures 1411 and 1412 of the lighting fixture A group 141 (S11). When the “lighting” button is pressed, the operation switch A (121) outputs a lighting signal requesting “lighting”. When the lighting signal is output from the operation switch A (121), the operation-side communication control unit 123 adds operation switch identification information indicating that the lighting signal is output from the operation switch A (121) to the lighting signal. Then, the data is transmitted to the control side communication control unit 113.

(Lighting control device)
The control side communication control unit 113 receives the lighting signal to which the operation switch identification information indicating the operation switch A (121) is added (S12). The illumination control device 110 includes a storage unit 114 that stores correspondence information indicating the correspondence between operation switches and load control switches. When the lighting control unit 111 receives the lighting signal from the operation-side communication control unit 123, the operation control identification information is obtained from the operation switch identification information added to the lighting signal and the correspondence information stored in the storage unit 114. The load control switch corresponding to the operation switch indicated by is identified. In this example, the illumination control unit 111 specifies the load control switch A (131). Then, the lighting control unit 111 includes the load control switch identification information indicating the specified load control switch A (131) in the lighting command signal, and transmits it to the load side communication control unit 133 via the control side communication control unit 113. (S13).

(Load side control unit)
When receiving the lighting command signal, the load-side communication control unit 133 refers to the load control switch identification information included in the lighting command signal, and turns on the load control switch indicated by the load control switch identification information according to the lighting command signal (S14). . In this example, the load control switch identification information included in the lighting command signal indicates the load control switch A (131). Therefore, the load side communication control unit 133 turns on the load control switch A (131). In this case, since the non-volatile memory 81 of each discharge lamp lighting device 100 of the lighting fixtures 1411 and 1412 connected to the load control switch A (131) stores the set value of “high output”, the lighting fixtures 1411, 1412 lights at high output. Further, as described above, the setting value “high output” is also stored in the load-side nonvolatile memory 1331.

(Change of discharge lamp output: load control actuator)
Next, the case of FIG. 5B will be described. FIG. 5B shows the lighting control system 1000 when the operator changes the discharge lamp output of the lighting fixtures 1411 and 1412 of the lighting fixture A group 141 from “high output” of the initial setting value to “intermediate output”. Is the action.

  When the operator wants to change the lighting output of the lighting fixtures 1411 and 1412 of the lighting fixture A group 141, he presses the button of the operation switch A (121). In this case, the operator presses the “intermediate output” button of the operation switch A (121) (S21). When the “intermediate output” button is pressed, the operation switch A (121) outputs a request signal for requesting the discharge lamp output corresponding to the “intermediate output” button. Then, when the request signal is output from the operation switch A (121), the operation-side communication control unit 123 adds operation switch identification information indicating that the request signal is output from the operation switch A (121) to the request signal. Then, the data is transmitted to the control side communication control unit 113.

(Lighting control device)
The control side communication control unit 113 receives the request signal to which the operation switch identification information indicating the operation switch A (121) is added (S22). When the illumination control unit 111 receives the request signal from the operation-side communication control unit 123, the operation switch identification information is obtained from the operation switch identification information added to the request signal and the correspondence information stored in the storage unit 114. The load control switch corresponding to the operation switch indicated by is identified. In this example, the illumination control unit 111 specifies the load control switch A (131).

(Communication between the control side communication control unit 113 and the load side communication control unit 133)
When specifying the load control switch A (131), the lighting control unit 111 communicates with the load side communication control unit 133 via the control side communication control unit 113 (S23). Through this communication, the illumination control unit 111 refers to the setting value stored in the load-side nonvolatile memory 1331 and confirms that the current setting value is “high output”. The illumination control unit 111 generates a switching command signal for the received request signal based on the reference value reference result (high output) and the received request signal (intermediate output). In this case, to change from high output to intermediate output, as shown in FIG.
(1) After “OFF between 0.1 second and 3 seconds”
(2) “ON between 0.1 seconds and 3 seconds”,
After that, (3) “OFF between 0.1 seconds and 3 seconds”
It is only necessary to turn the power of the specified pattern on and off. Therefore, the illumination control unit 111 generates a switching command signal that commands switching of the specified pattern and includes load control switch identification information indicating the specified load control switch A (131) in the generated switching command signal. It transmits to the load side communication control part 133 via the side communication control part 113 (S24).

(Load control unit)
When the load side communication control unit 133 receives the switching command signal instructing the change to the intermediate output, the load side communication control unit 133 refers to the load control switch identification information included in the switching command signal and sets the load control switch indicated by the load control switch identification information to the switching command. Switch according to the signal. In this example, the load control switch identification information included in the switching command signal indicates the load control switch A (131). Therefore, the load side communication control unit 133 switches the load control switch A (131) with the specified pattern (S25). FIG. 4A shows this state. In the discharge lamp lighting device of the lighting fixtures 1411 and 1412, when the load control switch A (131) is switched according to the specified pattern, the current “high output” is changed to “intermediate output”, and the nonvolatile memory 81. Rewrite the “high output” setting value to the “intermediate output” setting value. Further, the load side communication control unit 133 determines the current state of the load side nonvolatile memory 1331 from the content of the received switching command (specified pattern) and the content (high output) of the load side nonvolatile memory 1331 currently stored. Rewrite the setting value from “High output” to “Intermediate output”. Thereby, the contents of the nonvolatile memory 81 and the load-side nonvolatile memory 1331 always match.

  FIG. 5C shows the lighting control system 1000 when the operator changes the discharge lamp output of the lighting fixtures 1411 and 1412 of the lighting fixture A group 141 from “intermediate output” of the initial setting value to “low output”. Is the action. The case of FIG. 5C is the same as the case of FIG.

(Load control actuator)
That is, the worker presses the “low output” button of the operation switch A (121) (S31). The operation switch A (121) outputs a low output request signal when the “low output” button is pressed. When the request signal is output, the operation-side communication control unit 123 adds operation switch identification information indicating the operation switch A (121) to the request signal and transmits it to the control-side communication control unit 113.

(Lighting control device)
The control side communication control unit 113 of the illumination control device 110 receives the request signal to which the operation switch identification information is added (S32). The illumination control unit 111 identifies the load control switch A (131) as in the case of FIG.

(Communication between the control side communication control unit 113 and the load side communication control unit 133)
As in the case of FIG. 5B, the control side communication control unit 113 and the load side communication control unit 133 communicate (S33). Through this communication, the illumination control unit 111 confirms that the current setting value is “intermediate output” with reference to the setting value stored in the load-side nonvolatile memory 1331, and the setting value reference result (intermediate output) Output) and the received request signal (low output), a switching command signal for the received request signal is generated. In this case, in order to change from the intermediate output to the low output, it is only necessary to turn on / off the power of the same specified pattern as in FIG. 5B. A switching command signal for instructing switching of the specified pattern is generated, and load control switch identification information indicating the load control switch A (131) is included in the switching command signal, and the load side communication control unit 133 is connected via the control side communication control unit 113. (S34).

(Load control unit)
When the load-side communication control unit 133 receives a switching command signal that instructs low output, the load-side communication control unit 133 refers to the load control switch identification information included in the switching command signal and switches the load control switch A (131) indicated by the load control switch identification information. Switching is performed according to the command signal (S35). In the discharge lamp lighting device of the lighting fixtures 1411 and 1412, when the load control switch A (131) is switched according to the specified pattern, the current “intermediate output” is changed to “low output” and the non-volatile memory 81. Rewrite the “intermediate output” setting value to the “low output” setting value. Further, the load side communication control unit 133 determines the current state of the load side nonvolatile memory 1331 from the content of the received switching command (specified pattern) and the currently stored content of the load side nonvolatile memory 1331 (intermediate output). Rewrite the set value from “Intermediate output” to “Low output”. Thereby, the contents of the nonvolatile memory 81 and the load-side nonvolatile memory 1331 always match.

  FIG. 6 shows an operation sequence for initializing the setting of the output state of the discharge lamp lighting device. The predetermined power ON / OFF operation is performed, for example, four times. To initialize the output state setting, the operation switch A (121) and the operation switch B (122) may be operated by “lighting” and “OFF”, or the operation switch A (121) and the operation switch B (122). ) Is provided with a reset button, and the lighting control unit 111 generates a switching command signal for commanding ON / OFF switching of the reset pattern and transmits it to the load side communication control unit 133 in the same manner as when changing the discharge lamp output. Then, the load side communication control unit 133 may turn the load side control switch on and off with a reset pattern.

(Variation of load control switch)
FIG. 7 is a diagram showing an example in which application of power to the discharge lamp lighting device and transmission of a setting signal are performed by a semiconductor switch connected in series to the power. FIG. 8 shows an example in which a mechanical contact is used.

  In the first embodiment described above, only the transition of output setting from high output → intermediate output → low output is shown. However, as in the case shown in FIG. The same operation is performed, such as saving, turning on the output in the stored state when the power is turned on, and resetting the setting.

Embodiment 2. FIG.
FIG. 9 is a diagram illustrating a lighting control system 1000 according to the second embodiment. In the lighting control system 1000 of the second embodiment, the load control operator 120 includes a common operation switch 124 and a designation switch 125 that designates the load control switch. In the illumination control system 1000 of Embodiment 1 shown in FIG. 2, two operation switches, the operation switch A (121) and the operation switch B (122), are required. On the other hand, in the second embodiment, the designation switch 125 for designating the load control switch is provided, so that only one operation switch is possible. The processing operation is the same as in the first embodiment, but will be described briefly.

  The operator designates a load control switch with the designation switch 125. When a request signal is output from the common operation switch 124 when any one of the load control switches is designated by the designation switch 125, the operation side communication control unit 123 indicates the load control switch designated by the designation switch. The load control switch identification information is added to the request signal and transmitted to the control side communication control unit 113. When the illumination control unit 111 receives the request signal from the operation side communication control unit, the illumination control unit 111 includes the load control switch identification information added to the request signal in the switching command signal and transmits it to the load side communication control unit 133. When the load-side communication control unit 133 receives the switching command signal, the load-side communication control unit 133 refers to the load control switch identification information included in the switching command signal and executes control for switching the load control switch indicated by the load control switch identification information according to the switching command signal. To do.

  Since the load control operation device 120 according to the second embodiment includes the designation switch 125 that designates the load control switch, the number of operation switches can be reduced, so that the configuration is simplified.

1 is a diagram showing a system configuration assumed in Embodiment 1. FIG. 1 is a configuration diagram of a lighting control system 1000 according to Embodiment 1. FIG. 1 is a circuit diagram of a discharge lamp lighting device 100 according to Embodiment 1. FIG. The figure explaining the relationship between the load control switch A (131) and the discharge lamp lighting device 100 in the first embodiment. FIG. 3 is a sequence diagram showing an operation of lighting control system 1000 in the first embodiment. The figure which shows the operation | movement sequence which initializes the setting of the output state of the discharge lamp lighting device in Embodiment 1. FIG. FIG. 3 shows a semiconductor switch in Embodiment 1; The figure which shows the case where the mechanical contact in Embodiment 1 is used. FIG. 6 is a configuration diagram of a lighting control system 1000 according to Embodiment 2.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Commercial power supply, 10 Rectifier circuit, 20 Active filter circuit, 21 Choke coil, 22 Diode, 23 Capacitor, 24 Switching element, 30 Inverter circuit, 31, 32 Switching element, 33 Resistance, 40 Load circuit, 41 Inductor, 42 Discharge lamp , 43 capacitor, 44 resistor, 45 capacitor, 50 control power supply circuit, 60 power supply synchronization circuit, 70 drive circuit, 80 microcomputer, 81 non-volatile memory, 90 lamp detection circuit, 100 discharge lamp lighting device, 102 power supply line, 103 communication control 110, lighting control unit, 111 lighting control unit, 112 control side power supply circuit, 113 control side communication control unit, 120 load control operation unit, 121 operation switch A, 122 operation switch B, 123 operation side communication control unit, 124 Operation switch, 125 Designated switch, 130 Load control unit, 131 Load control switch A, 132 Load control switch B, 133 Load side communication control unit, 1331 Load side nonvolatile memory, 134 Load side power supply circuit, 135 Semiconductor switch, 136 Semiconductor Switch drive circuit, 141 lighting fixture A group, 142 lighting fixture B group, 1000 lighting control system, 1411, 1412 lighting fixture, 1421, 1422 lighting fixture.

Claims (4)

A lighting fixture group including a plurality of lighting fixtures provided with a discharge lamp lighting device that changes the lighting output of the discharge lamp to a predetermined lighting output when the on / off of the supplied power supply is a prescribed pattern is connected. A load control switch for turning on and off the supply of power to the group of lighting fixtures by switching under control.
A switch unit device that includes a load side communication control unit that receives a switching command signal that commands switching of the specified pattern, and executes control to switch the load control switch according to the received switching command signal;
An operation switch that outputs a request signal that requests a discharge lamp output corresponding to the operated operation unit when any one of the operation units is operated while being provided with a plurality of operation units corresponding to the output of the discharge lamp;
An operation device including an operation side communication control unit that transmits the request signal output by the operation switch;
A switching command signal generator that receives the request signal transmitted from the operating device and generates the switching command signal based on the received request signal;
A lighting control system comprising: a control device including a control side communication control unit that transmits the switching command signal generated by the switching command signal generation unit to the load side communication control unit. The switch unit device is
A plurality of load control switches;
The operating device is:
A plurality of the operation switches corresponding to each of the plurality of load control switches;
The operation side communication control unit
When the request signal is output by any of the operation switches, operation switch identification information indicating which of the operation switches is output by the operation switch is added to the request signal and transmitted.
The control device further includes:
A storage unit storing correspondence information indicating the correspondence between the operation switch and the load control switch;
The switching command signal generator is
When the request signal is received from the operation device, the load control switch corresponding to the operation switch indicated by the operation switch identification information is specified from the operation switch identification information and the correspondence information added to the request signal. Including the load control switch identification information indicating the specified load control switch in the switching command signal,
The load side communication control unit
When the switching command signal is received, the load control switch identification information included in the switching command signal is referred to, and control is performed to switch the load control switch indicated by the load control switch identification information according to the switching command signal. The lighting control system according to claim 1. The switch unit device is
A plurality of load control switches;
The operating device further includes:
A designation switch for designating any one of the plurality of load control switches;
The operation side communication control unit
When the request signal is output from the operation switch when any one of the load control switches is designated by the designation switch, load control switch identification information indicating the load control switch designated by the designation switch Is added to the request signal and transmitted,
The switching command signal generator is
When the request signal is received from the operating device, the load control switch identification information added to the request signal is included in the switching command signal,
The load side communication control unit
When the switching command signal is received, the load control switch identification information included in the switching command signal is referred to, and control is performed to switch the load control switch indicated by the load control switch identification information according to the switching command signal. The lighting control system according to claim 1. Each of the discharge lamp lighting devices,
When the discharge lamp is turned on with the lighting output changed in response to the prescribed pattern, the nonvolatile memory includes a non-volatile memory that stores a setting value corresponding to the lighting output, and when the power is supplied next time, the non-volatile memory The discharge lamp is lit with the lighting output of the set value stored in
The load side communication control unit
The discharge lamp lighting device includes a load-side nonvolatile storage unit that stores information in a nonvolatile manner and interprets the specified pattern indicated by the switching command signal when the switching command signal is received. The load control switch indicated by the load control switch identification information is specified by specifying the set value to be stored in the nonvolatile memory and referring to the load control switch identification information included in the received switching command signal. Identify and store the identified load control switch and the identified set value in the load-side nonvolatile storage unit in association with each other,
The control side communication control unit and the load side communication control unit are:
Can communicate with each other,
The switching command signal generator is
When the request signal is received from the controller device, the setting value stored in the load-side nonvolatile storage unit is referred to by communicating with the load-side communication control unit via the control-side communication control unit. 4. The illumination according to claim 2, wherein the switching command signal for the received request signal is generated based on a reference result of the set value and the received request signal. Control system.

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