KR101308894B1 - Lighting control device using power line - Google Patents

Abstract

According to the present invention, by replacing the lamp control switch of the lamp with a semiconductor switching element, accurate signal processing is possible to prevent the malfunction of the lamp control, and at the same time it is possible to generate a variety of control data various individual control of a plurality of lights in one switch The present invention relates to a lighting lamp control apparatus using a power line capable of performing a semiconductor device, the method comprising: setting a predetermined trigger signal according to a semiconductor switching element, a FET, a control diode, a resistor, and a key signal input from a switch unit, And a switch unit configured to output a trigger signal to the semiconductor switching device, and a plurality of switches to input a predetermined key signal to the microcomputer. A control signal generator for transmitting; And a voltage level detector for detecting a voltage level input from the control signal generator and outputting it as a standardized pulse signal, and a pulse signal input from the voltage level detector, detecting an ID signal, and detecting an ID signal. And a control unit for analyzing a light switch signal or a dimming signal inputted through the control signal generator and outputting a control signal corresponding to the control lamp to a lamp, when the ID signal matches. Or it is characterized by consisting of a lighting device including a dimming light.

Description

Lighting control device using power line {LIGHTING CONTROL DEVICE USING POWER LINE}

The present invention relates to a lamp control device for controlling the lighting and dimming (Dimming) of the lamp using a power line, more specifically, by replacing the lamp control switch with a semiconductor switching element, accurate signal processing is possible to control the lamp The present invention relates to a lamp control apparatus using a power line capable of preventing a malfunction and simultaneously generating various control data to perform various individual control of a plurality of lamps from a single switch.

The lighting and dimming control apparatus of the lighting lamp using the power line as described above is a device capable of performing the rollon dimming control only by the power line applied to the lighting lamp without a separate control line for dimming control.

Such a lamp control apparatus has already been disclosed in the applicant's patent number 1046476. This will be described with reference to the accompanying drawings, FIGS. 1 to 3.

Conventional lamp control apparatus using a power line is, as shown in Figure 1, the main power switch (SW) connected to one end of the power source (AC), the control signal generator 10 connected in series with the main power switch (SW) and And a plurality of lighting devices 20 connected to both ends of the power source AC.

The main power switch SW is a switch that supplies or cuts power to the control signal generator 10 and the lighting device 20, and the control signal generator 10 is turned on and off by the lighting device 20. A control signal (hereinafter referred to as 'light off signal') or a control signal for dimming (hereinafter referred to as 'dimming signal') is a switch for generating and transmitting.

The turn-off signal and the dimming signal of the control signal generator 10 are signals generated according to the time or the number of times that the control switch S1 is pressed for a predetermined time, and the lamp is controlled using this signal.

The lighting device 20 is configured such that one end is supplied with power through the control signal generator 10, a voltage level sensing unit 21 for sensing a voltage level of the applied power, and the voltage level sensing unit ( 22 is a control unit 22 receiving a voltage level signal input through the control signal generation unit 10 through the control signal generation unit 10 and analyzes the lighting signal and the dimming signal and outputs a control signal corresponding to the lighting lamp 23; And an illuminator 23 that is turned on or dimmed by the output of the controller 22.

In addition, a relay switch RY is further interposed on one end of a power line applied to the lamp 23, and when the lamp 23 off command is output from the controller 22, the relay switch RY is turned off to illuminate the lamp 23. ) Is turned off.

2, the control signal generator 10 includes a control switch S1 connected in series to a main power switch SW, and a FET Q1 connected in parallel to the control switch S1. And a control diode ZD1 connected to the drain and gate terminals of the FET Q1, and a resistor R1 connected to the source and gate terminals of the FET Q1.

Here, the control switch S1 is a normal close type switch.

The control signal generating unit 10 configured as described above has a current when the main power switch SW is turned on, and the current is controlled when the control switch S1 is kept on. Flow through the switch (S1) is a normal AC power (AC) is applied to the lighting device (20). At this time, the sine wave AC power is applied to the lighting device 20 as shown in the waveform (A) of the section t3 or t5 of FIG. 3.

However, when the control switch (S1) is pressed off (OFF), the current supplied to the lighting device 20 through the main power switch (SW) and the control switch (S1) flows through the FET (Q1).

At this time, when the voltage applied to the source terminal of the FET Q1 is + polarity, current flows through the FET Q1, but when the voltage applied to the drain terminal of the FET Q1 is -polar, a zener diode Only when the voltage applied to the ZD1 becomes equal to or greater than the breakdown voltage, the FET Q1 is turned on so that a current flows, and the lighting device 20 has the same waveform as the (A) waveform in the section t4 of FIG. 5. Power will be provided.

Next, the voltage level detecting unit 21 of the lighting device 20 will be described.

The voltage level detecting unit 21 includes a resistor R2 (R3), a photocoupler PC, a transistor Q2, a resistor R4, and a capacitor C1.

In the state where the main power switch SW is turned on and the control switch S1 of the control signal generator 10 is kept in an ON state where the control switch S1 is not pressed, the normal AC power source is provided with a resistor R2. ) Is applied to the light emitting portion of the photocoupler (PC). At this time, the photocoupler PC is turned on except for a short section near the zero cross of the AC waveform applied to the light emitting unit, and an output is generated at the collector end of the light receiving unit.

That is, when the photocoupler PC is applied as a normal power source, the photocoupler PC maintains the off state (t0 section in FIG. 5) only in a short section of the zero cross point of the applied AC waveform.

In addition, the signal output to the light-receiving part collector stage of the photocoupler PC turns on the transistor Q2 when the output signal is at the high level, turns off the transistor Q2 at the low level, and outputs the capacitor. The pulse signal of a predetermined form is inputted to the control unit 22 through the C1.

At this time, the waveform input to the control unit 22 is the same as the waveform (B) of the t3 or t5 section in FIG.

On the other hand, in such a drive, the case in which the control switch (S1) of the control signal generating unit 10 is pressed, that is, the state (OFF) will be described.

When the control switch S1 is turned off, a power source such as the waveform (A) in the section t4 of FIG. 5 is applied to the lighting apparatus 20 as described above.

At this time, in the period t2 in which the FET Q1 of the control signal generator 10 is turned off for a predetermined time, the photocoupler PC of the voltage level sensing unit 21 is turned off so that its output is maintained at a low level. The signal is not input to the controller 22.

That is, the control unit 22 detects the pulse section t2 in which the low level signal of the input pulse signal becomes longer through the pulse signal input from the voltage level detecting unit 21, whereby the control switch S1 is turned off. It is recognized that the state, and by detecting the number of the low level signal t2 (hereinafter referred to as 'low time'), it is possible to recognize the time when the control switch (S1) is off.

For example, it is possible to detect whether the control switch S1 is shortly pressed, long pressed or shortly pressed several times.

The control unit 22 detects the number of low-times input from the voltage level detecting unit 21 according to the time when the control switch S1 is turned off by a built-in program, and turns off the flashing light signal of the lamp 23 and the dimming signal. Will be determined.

For example, if it is detected that the control switch S1 is briefly pressed, it is determined to repeat the lighting or extinguishing command (light off signal), and if it is detected for a long pressing, the dimming level is swinged from the highest brightness to the lowest brightness. The lighting 23 is determined to correspond to the command (dimming signal) to correspond thereto.

For example, when the control switch S1 is turned off for less than 1 second, the lamp 23 is turned on. When the control switch S1 is turned off for less than 1 second, the lamp is turned off, and the control switch S1 is turned off for at least 1 second. If it is maintained as a dimming signal and the lamp is turned on at the highest brightness, and as the off time elapses, the lamp brightness is gradually reduced to light at the lowest brightness.

Therefore, the user can release the pressing (OFF) of the control switch (S1) at an appropriate time to select the brightness of the lamp.

As such, the generation of the mute light signal and the dimming signal according to the operation time and the number of times of the control switch S1 can be modified in any number of forms.

Accordingly, the control unit 22 detects the number of low-time signals input from the voltage level detecting unit 21 to discriminate the lighting signal and the dimming signal, and controls the lighting lamp 23. In the case of the lighting signal, the relay switch Output the OFF command with (RY).

At this time, the controller 22 outputs a high level signal to the transistor Q3. Accordingly, the transistor Q3 is turned on and the relay switch RY is operated, the relay switch RY is turned off, the power supplied to the lamp 23 is cut off, and the lamp 23 is turned off.

In the case of the dimming signal, the control unit 22 outputs the set dimming signal to the lamp 23. The dimming signal may be a PWM signal or a variable DC voltage (OV ~ 10V) signal. The control signal is output.

Therefore, the lighting control device using such a power line can be installed without changing the existing wiring by controlling the lighting, turning off or dimming of the lighting using the power line to provide cost saving and convenience in use, Even when the power supply is temporarily cut off in a predetermined form to generate a control signal for dimming, the lighting device is supplied with a predetermined level or more, thereby preventing the power supply from being completely cut off, thereby providing the maximum protection of the lamp.

However, such a lighting control device has been derived the following problems.

That is, the lamp control apparatus detects the number of low times t2 generated when the control switch S1 is turned off to determine whether the lamp is turned on or off, or the dimming signal and level.

By the way, the control switch (S1) is a switch that is turned on, off by pressing or releasing the user directly, and generates a light, a light, a dimming control signal by the user's pressing operation. At this time, when the operation of returning to the on state after the control switch S1 is turned off includes the low time t2 section, the low time t2 period is shortened so that the phenomenon that the control switch S1 is not recognized as the low time t2 occurs. do.

This phenomenon means that an error occurs in the number of detected low times t2. Such an error may not recognize the ON or OFF signal to which the set number of low times t2 should be input for a short time (e.g., less than 1 second), or failure to recognize the dimming signal and the level signal, that is, a malfunction may occur. As a result, a problem arises in the precise control of the lamp 23.

In addition, the conventional control switch (S1) is a general mechanical switch has a relatively large volume has also been derived a problem that takes up unnecessary space when manufacturing the product.

In addition, the conventional lighting control device is also pointed out the problem of simple control that can not only turn on or off the dimming control a plurality of lighting devices (20).

Therefore, the present invention was devised to solve the above problems, and an object of the present invention is to replace the lamp control switch with a semiconductor switching element, the lamp control by using a power line to eliminate the malfunction of the lamp control by accurate signal processing It is in providing a device.

In addition, another object of the present invention is to provide a lamp control apparatus using a power line capable of generating a variety of control data to perform a variety of individual control for a plurality of lights in one switch.

In addition, another object of the present invention is to provide a lamp control apparatus using a power line that can be compactly manufactured by replacing the lamp control switch with a small semiconductor switching element.

A semiconductor switching device connected between a plurality of lighting devices and a power supply line, a FET connected in parallel to the semiconductor switching device, a control diode connected to a drain and a gate end of the FET, and the A resistor connected to the source and gate terminals of the FET, a predetermined trigger signal according to a key signal input from the switch unit, a microcomputer for outputting the set trigger signal to the semiconductor switching element, and a plurality of switches; A control signal generator for generating and transmitting a unique ID signal, a flashing light or a dimming signal to a lighting device, the switch unit configured to input a predetermined key signal to the microcomputer; And a voltage level detector for detecting a voltage level input from the control signal generator and outputting it as a standardized pulse signal, and a pulse signal input from the voltage level detector, detecting an ID signal, and detecting an ID signal. And a control unit for analyzing a light switch signal or a dimming signal inputted through the control signal generator and outputting a control signal corresponding to the control lamp to a lamp, when the ID signal matches. Or it is characterized by consisting of a lighting device including a dimming light.

In addition, the switch unit according to the invention is characterized in that it comprises at least a lamp set switch, a light switch, a light switch, a dimming level selection switch.

In addition, the microcomputer according to the present invention detects a key signal input from each switch of the switch unit 130 and generates a corresponding trigger signal, the trigger signal is characterized in that the off time of the semiconductor switching device is set differently It is done.

In addition, one end of the power line is applied to the lamp according to the invention is characterized in that the relay switch is further interposed.

In addition, the control signal generator according to the present invention is a semiconductor switching device connected between a plurality of lighting devices and power lines, a FET connected in parallel to the semiconductor switching device, a control diode connected to the drain and the gate terminal of the FET And a microcomputer for setting a predetermined trigger signal according to a key signal input from a switch unit, a resistor connected to the source and gate terminals of the FET, and outputting the set trigger signal to the semiconductor switching device, and at least a lamp set. And a receiver configured to receive a key signal remotely transmitted from a remote controller having a switch, a light switch, a light switch, a dimming level selection switch, and input the received key signal to the microcomputer.

As described above, the present invention replaces the lamp control switch with a semiconductor switching element, thereby enabling accurate signal processing to eliminate malfunction of the lamp control, thereby improving product reliability, and at the same time manufacturing the product compactly.

In addition, the present invention is capable of generating a variety of control data provides an advantage that can perform a variety of individual control for a plurality of lights in one switch.

1 is a configuration diagram of a lamp control apparatus using a conventional power line,
2 is a detailed circuit diagram of FIG. 1;
3 is an output waveform diagram of a main part of FIG. 1;
4 is a circuit diagram of a lamp control apparatus using a power line according to an embodiment of the present invention;
5 is a circuit diagram of a lamp control apparatus using a power line according to another embodiment of the present invention;
6 is an example of data generation according to the output waveform diagram of the main part of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on different drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

4 is a circuit diagram of a lamp control apparatus using a power line according to an embodiment of the present invention.

As shown, the lighting control device using a power line according to an embodiment of the present invention, the main power switch (SW) connected to one end of the power source (AC), and the control signal connected in series to the main power switch (SW) It includes a generator 100 and a plurality of lighting devices 200 connected to both ends of the power (AC).

The main power switch SW is a switch for supplying or cutting off power to the control signal generator 100 and the lighting device 200, and the control signal generator 100 is turned on and off by the lighting device 200. And a control signal (illumination signal) or a control signal (dimming signal) for dimming.

The turn-off signal and the dimming signal of the control signal generator 100 are signals generated according to the time (low time) and the number of times the power is turned off for a predetermined time, and the lamp is controlled using this signal.

Here, the configuration of the control signal generator 100 will be described in detail.

The control signal generator 100 includes a semiconductor switching device 110 connected in series to a main power switch SW, a FET Q1 connected in parallel to the semiconductor switching device 110, and the FET Q1. Outputs a trigger signal to the control diode (ZD1) connected to the drain and the gate terminal of the < RTI ID = 0.0 >), a resistor (R1) < / RTI > It consists of a microcomputer 120 and a switch unit 130 is composed of a plurality of switches to input a predetermined key signal to the microcomputer 120.

The semiconductor switching device 110 maintains an on state and is switched off only while a trigger signal is input. The semiconductor switching device 110 includes a triac, a silicon controlled rectifier (SCR), and the like. It can be various kinds of semiconductor switches.

The switch unit 130 is composed of a plurality of switches, the switches include at least a set lamp (light), (light) switch, lights off switch, dimming level selection switch.

Here, the lamp set switch is a switch for setting the lighting device 200 including the lighting 23 to control the lighting and dimming, it is possible to set at least one lighting device 200.

As will be described later, each lighting device 200 is stored with a unique ID that is identified with other lighting devices.

In addition, the on and off switch is a switch for performing the on or off command for the selected lamp 23, the dimming level selection switch is a switch for selecting the dimming level of the selected lamp (23).

The microcomputer 120 detects a key signal input from each switch of the switch unit 130, generates a corresponding trigger signal, and outputs the trigger signal to the semiconductor switching device 110. Intermittent control of on and off.

On the other hand, the lighting device 200 is configured so that one end is supplied with power through the control signal generator 100, a voltage level detecting unit 21 for detecting the voltage level of the power applied, and the voltage level detecting unit Receives a voltage level signal input through the 22, and detects the ID signal to determine whether it matches the ID, and if the ID signal is matched with the control signal generation unit 100 and the light off signal and And a control unit 22A for analyzing the dimming signal and outputting a control signal corresponding thereto to the lamp 23, and a lamp 23 for turning on or off the output by the output of the controller 22A.

The relay switch RY may be further interposed at one end of the power line applied to the lamp 23. The relay switch RY is operated by the control of the control unit 22A. When the command to turn off the lamp 23 is output from the controller 22A, the relay switch RY is turned off and the lamp 23 is turned off. .

 In the lighting apparatus of the present invention configured as described above, when any switch of the switch unit 130 of the control signal generator 100 has no key input while the main power switch SW is turned on, Since the trigger signal is not output from the semiconductor switch 120, the semiconductor switching device 110 maintains an initial ON state.

At this time, the power (AC) current flows through the semiconductor switching device 110, the normal sine wave AC power such as the t3 section of FIG. 6A is applied to the lighting device 200.

However, when a key input is generated from a switch of the switch unit 130 and a trigger signal is output from the microcomputer 120, the semiconductor switching device 110 is triggered to maintain an OFF state.

At this time, the current of the power source AC flows through the FET Q1 when the semiconductor switching element 110 is turned off, and the current flowing to the FET Q1 has a + polarity voltage applied to the source terminal of the FET Q1. In the case where the voltage flows through the FET Q1 and the voltage applied to the drain terminal of the FET Q1 is -polar, the FET Q1 is applied only when the voltage applied to the zener diode ZD1 becomes greater than the breakdown voltage. In FIG. 6, the lighting device 200 is provided with a power including a low time t2 as shown in a waveform of the t4 section in FIG. 6A.

Look at the lighting device 200 is provided with such a power.

First, when a normal sine wave power source such as the t3 section of FIG. 6A is provided, the voltage level detecting unit 21 of the lighting apparatus 200 is only shown in the short section of the zero cross point of the applied AC waveform. After maintaining the off state as in the t0 section in (B), the pulse signal in the on state is generated and output.

In addition, when a power source including a low time t2 is provided as in the t4 section of FIG. 6A, the voltage level detector 21 may also have a low time section of the AC waveform to which the applied voltage is applied. Generates and outputs a pulse signal that maintains the off state as in the t2 section of.

That is, the voltage level detecting unit 21 detects the voltage level input from the control signal generating unit 100 and outputs a standardized pulse signal, but shapes the detected low time t2 to control the controller 22A. To print.

The control unit 22A of the lighting device 200 detects a value input from the voltage level detecting unit 21 to determine predetermined information.

For example, if a pulse waveform such as (B) in section t3 of FIG. 6 is input, the waveform of one cycle is recognized as 0 bits, and if a pulse waveform including low time (t2) is input, such as section t4, the waveform of one cycle is input. Is recognized as 1 bit. Accordingly, the pulse waveform of (B) in the sections t3 and t4 of FIG. 6 is recognized as binary '0011' information.

This means that it is possible to extract a variety of information by detecting the voltage level input through the control signal generation unit 100, address information, command information, data information that is a unique ID Can be recognized respectively.

Accordingly, the control unit 22A detects a pulse signal according to the voltage level from the voltage level detecting unit 21 to determine the ID. If the IDs match, the control unit 22A discriminates the next light and the dimming signal and the command and data of the dimming signal. To control the lamp 23.

It looks at the overall operation of the present invention configured as described above.

First, the power switch (SW) is turned on and selects the illuminating and dimming control target lighting apparatuses 200 by using the lamp set switch of the switch unit 130 of the control signal generator 100. This selection method, after the key input the lamp set switch, and then performs a key input for the selection of the control target lighting device 200 from the other switches of the switch unit 130 in one of various forms. .

When the setting of the control target lighting device 200 is completed as described above, the microcomputer 120 sets a unique ID of the selected control target lighting device 200.

In this state, when the user presses the light switch of the switch unit 130, the light switch is a switch that generates only a short switching signal and does not continue to operate while pressing the control switch S1 (see FIG. 2). Is not a switch.

Accordingly, when the key signal of the lighting switch is input, the microcomputer 120 generates information corresponding to the ID signal of the set lighting device 200 and the lighting signal of the lighting lamp 23 to be transmitted to the lighting device 200. After setting the trigger signal output, the set trigger signal is output to the semiconductor switching element 110.

The semiconductor switching device 110 is triggered by the output of the microcomputer 120 to input a power supply current to each lighting device 200 in a predetermined form.

The power applied through the control signal generator 100 is input to the voltage level detector 21 of each lighting device 200, and the voltage level detector 21 forms a control signal by shaping an input voltage level signal. 22A).

The controller 22A detects predetermined information by detecting a value input from the voltage level detector 21, that is, the number of low times t2.

If the ID information does not match, the controller 22A ignores the command signal input thereafter and does not perform the control of the lamp 23 through the read information.

However, if the ID information is matched, a command signal (here, a lighting signal) inputted thereafter is read to generate a lamp 23 lighting signal, and outputs a control signal accordingly.

Therefore, the control unit 22A turns on the relay switch RY so that the power is applied to the lamp 23 so as to light the lamp 23.

In addition, when the user presses the light-off switch of the switch unit 130 and the key signal of the light-off switch is input to the microcomputer 120, the microcomputer 120 generates an ID signal of the set lighting device 200 and the lighting device ( After the trigger signal output is set to generate information corresponding to the lamp 23 off signal to be transmitted to the 200, the set trigger signal is output to the semiconductor switching device 110.

The semiconductor switching device 110 is triggered in a predetermined form by the output of the microcomputer 120, and the power applied through the control signal generator 100 is a voltage level detection unit of each lighting device 200 ( 21, the control unit 22A turns off the relay switch RY when the ID information is matched through the value input from the voltage level detecting unit 21 and the extinguishing signal is detected. Turning off the power applied to 23, the lamp 23 is turned off.

In addition, when the user presses the dimming level selection switch of the switch unit 130 and the key signal of the dimming level selection switch is input to the microcomputer 120, the microcomputer 120 is connected to the ID signal of the set lighting device 200. The trigger signal output is set to generate information corresponding to the dimming level of the lamp 23 to be delivered to the lighting device 200, and then outputs the set trigger signal to the semiconductor switching device 110.

The semiconductor switching device 110 is triggered in a predetermined form by the output of the microcomputer 120, and the power applied through the control signal generator 100 is a voltage level detection unit of each lighting device 200 ( 21, the control unit 22A detects a dimming command and a selected dimming level signal when ID information is matched by a value input from the voltage level detecting unit 21, so that the illuminator 23 selects a dimming level. The control signal is output so as to dim with.

The dimming control signal may be a PWM signal or a variable DC voltage (OV to 10V) signal. The signal may be applied to the lamp 23 to adjust the brightness of the lamp 23.

According to the present invention configured as described above, the effect that can prevent the error by accurate signal processing by the microcomputer 120, except for the method of directly pressing the control switch (S1) as in the prior art, and various information By the generation of provides the effect of individually controlling a plurality of lighting devices 200 at the same time.

5 is a circuit diagram of a lamp control apparatus using a power line according to another embodiment of the present invention.

As shown, according to another embodiment of the present invention,

In the present invention, the lighting control device, in the control signal generation unit, the configuration of the switch unit 130 consisting of a plurality of switches, eliminates the wireless signal reception unit 140 is connected to the microcomputer 120, a plurality of By further forming a remote control 300 consisting of a key button, it is possible to control the lighting and dimming of the control target lighting device 200 remotely by the operation of the remote control 300.

Accordingly, the key button of the remote controller 300 includes at least a lamp set switch, a light switch, a light switch, a dimming level selection switch, and the operation thereof is the same as the above-described embodiment of the present invention.

100: control signal generator 110: semiconductor switching element
120: microcomputer 130: switch unit
200: lighting device 21: voltage level detection unit
22A: control unit 23: lighting
140: receiver 300: remote control

Claims (5)

A semiconductor switching element 110 connected between the plurality of lighting devices 200 and a power line, a FET Q1 connected in parallel to the semiconductor switching element 110, and a drain and a gate end of the FET Q1. A predetermined trigger signal is set according to a control diode ZD1 connected to the control diode, a resistor R1 connected to a source and a gate terminal of the FET Q1, and a key signal input from the switch 130; The microcomputer 120 for outputting the trigger signal to the semiconductor switching device 110 and the switch unit 130 is composed of a plurality of switches to input a predetermined key signal to the microcomputer 120, the lighting device A control signal generator 100 for generating and transmitting a unique ID signal and a flashing light or a dimming signal to the 200; And
The voltage level detecting unit 21 detects the voltage level input from the control signal generating unit 100 and outputs it as a standardized pulse signal, and receives the pulse signal input from the voltage level detecting unit 21. Detects an ID signal and determines whether it matches its ID, and if the ID signal is matched, analyzes a control signal generation unit 100 through the control signal generating unit 100 and illuminates a control signal corresponding thereto. A lighting device (200) including a control unit (22A) for outputting to the control panel; and an illuminating lamp (23) outputting a mute or dimming output by the output of the control unit (22A);
The microcomputer 120 detects key signals input from the switches of the switch unit 130 and generates a corresponding trigger signal, which sets the off time of the semiconductor switching element 110 differently. Control device such as a lamp using a power line characterized in that. delete delete delete delete

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