KR101226718B1 - Dimming control apparatus of light and method thereof - Google Patents

Abstract

The present invention relates to a brightness control device of a lighting device. The brightness control device of the lighting device detects a movement and outputs a motion detection signal, and receives an AC power supply for driving the lighting device to detect a zero potential level of the AC driving signal to detect a zero potential level detection signal. An output of a zero potential level detection unit and the motion detection signal and the zero potential level detection signal, and output a brightness control signal for gradually decreasing the brightness of the lighting device by a set amount when a motion is not detected for a set time; And a switching unit configured to control the brightness of the lighting device by controlling the supply time of the AC power applied to the lighting device by changing an operation state according to the brightness control signal applied from the controller. As a result, the brightness of the lighting device is automatically controlled according to the surrounding movement state of the lighting device without the user's separate operation, thereby improving user convenience.

Description

Brightness control device of lighting equipment and control method thereof {DIMMING CONTROL APPARATUS OF LIGHT AND METHOD THEREOF}

The present invention relates to a brightness control apparatus and a control method thereof, and more particularly, to a brightness control apparatus and a control method of a lighting device.

A dimmer, which is a brightness control device of a lighting device, generally changes the brightness of the lighting device by using a control switch using a variable resistor. Therefore, when the resistance value of the variable resistor is determined by the user's control switch operation, the state of the drive signal applied to the lighting device such as an incandescent lamp or a halogen lamp is changed according to the determined resistance value, and the brightness corresponding to the predetermined resistance value is changed. The control light emission state of the lighting device is maintained.

As such, when a desired brightness is selected by a user's manual operation, the lighting device maintains the selected brightness unless a separate operation is performed.

The technical problem to be achieved by the present invention is to improve the convenience of the user using the lighting device.

Another technical problem to be achieved by the present invention is to reduce unnecessary power wasted by the lighting device.

According to an aspect of the present invention, a brightness control apparatus for a lighting device detects a motion and outputs a motion detection signal to detect a zero potential level of the AC driving signal by receiving an AC power source for driving the lighting device. A zero potential level detection unit for outputting a zero potential level detection signal, and receiving the motion detection signal and the zero potential level detection signal and gradually reducing the brightness of the lighting device by a set amount when no motion is detected for a set time; A control unit for outputting a brightness control signal to control the switching state, and a switching unit for controlling the brightness of the lighting device by controlling a supply time of AC power applied to the lighting device by changing an operation state according to the brightness control signal applied from the control unit. Include.

The controller may delay the output of the brightness control signal by the set amount from the zero potential level time point of the AC power source determined by the zero potential level detection signal when the motion is not detected during the set time.

The set amount can be determined using the detection time of the zero potential level of the AC power supply.

The controller determines whether the brightness of the lighting device is the minimum setting brightness when the movement is not detected during the setting time, and decreases the brightness of the lighting device when the brightness of the lighting device is the minimum setting brightness. Not good.

When the movement is detected, the controller may output a brightness control signal for controlling the brightness of the lighting device to the maximum brightness.

The zero potential level detector is connected to a full-wave rectifier for full-wave rectification of the AC power, a photo-coupler connected to the full-wave rectifier and whose operating state changes according to the AC-rectified power, and a voltage changing according to the operating state of the photo coupler. And a voltage detector configured to detect a zero potential level of the AC power source according to the magnitude and output the zero potential detection signal to the controller.

The switching unit may include a photo triac whose operating state changes according to the brightness control signal output from the controller, and a triac connected to a gate terminal of the photo triac and connected to the AC power source and the lighting device. Can be.

According to another aspect of the present invention, a method of controlling brightness of a lighting device includes determining whether a motion is detected, determining whether a setting time has elapsed when the movement is detected, and lighting when the setting time has not elapsed. Controlling the brightness of the device to the maximum, determining whether the motion is detected when the set time elapses, and determining whether the brightness of the lighting device is the minimum setting brightness when the determined motion is not detected again. Maintaining the brightness of the lighting device at the minimum setting brightness when the brightness of the lighting device is the minimum setting brightness, and when the brightness of the lighting device is not the minimum setting brightness. Gradually decreasing the brightness by a set amount.

The controlling of the lighting device to the maximum may include determining a time of zero potential level of an AC power supply driving the lighting device according to a zero potential level detection signal applied from the outside, and synchronizing with the determined time of zero potential level. And outputting a brightness control signal for applying the AC power to the lighting device.

The step of decreasing the brightness of the lighting device by a set amount step may include determining a zero potential level timing of an AC power source driving the lighting device according to a zero potential level detection signal applied from the outside, and And outputting a brightness control signal for applying the AC power to the lighting device from the zero potential level time period by a corresponding delay time.

According to a feature of the present invention, since the brightness of the lighting device is automatically controlled according to the surrounding movement state of the lighting device without the user's separate operation, the user's convenience is improved.

In addition, if a human motion is not detected without a separate user's operation, the brightness of the lighting device is automatically reduced, thereby preventing unnecessary power consumption.

1 is a schematic block diagram of an apparatus for controlling brightness of a lighting apparatus according to an embodiment of the present invention.
2 is a flowchart illustrating a method of controlling brightness of a lighting device according to an embodiment of the present disclosure.
3 (a) to (i) is an operation waveform diagram of the brightness control device of the lighting device according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

In the drawings, the thickness is enlarged to clearly represent the layers and regions. When a layer, film, region, plate, or the like is referred to as being "on" another portion, it includes not only the case directly above another portion but also the case where there is another portion in between. Conversely, when a part is "directly over" another part, it means that there is no other part in the middle. In addition, when a part is formed “overall” on another part, it means that it is not only formed on the entire surface (or front) of the other part but also on the edge part.

Next, a brightness control apparatus and method thereof for a lighting device according to an embodiment of the present invention will be described with reference to the accompanying drawings.

First, a structure of a brightness control apparatus of a lighting apparatus according to an embodiment of the present invention will be described with reference to FIG. 1.

1 is a schematic block diagram of an apparatus for controlling brightness of a lighting apparatus according to an embodiment of the present invention.

Referring to FIG. 1, an apparatus for controlling brightness of a lighting apparatus according to an exemplary embodiment of the present invention may include a motion detector 10, a controller 20 connected to the motion detector 10, and an alternating current supply. (AC), an incandescent lamp 40 connected to an AC input power source (AC), a resistor (R1) connected to a power source (Vcc), a photo triac connected to a resistor (R1) and the control unit 20 (triode AC switch) (30), the gate terminal (G) is connected to the photo triac (30), the triac (TC) is connected to the AC input power (AC) and the incandescent lamp (40), respectively (TRIAC) (TC) ), A resistor (R2) connected between the photo triac (30) and the incandescent lamp (40), a resistor (R3) connected between the photo triac (30) and the triac (TC), and one terminal of an AC input power source (AC). A switching unit 60 including a resistor R3 connected thereto, a resistor R5 connected to the other terminal of the AC input power source AC, and a zero potential level connected between the resistors R4 and R5 and the control unit 20. And a 50.

The motion detector 10 detects the movement of the surroundings and outputs a motion detection signal (eg, a voltage) of a corresponding size according to the detected motion state.

The controller 20 outputs a brightness control signal DC for controlling the operation of the incandescent lamp 40 by using the motion detection signal from the motion detector 10 and the signal from the zero potential level detector 50.

The control unit 20 has a timer 21 that counts time.

The AC input power source AC outputs an AC power source for driving the incandescent lamp 40.

The incandescent lamp 40 is a lighting device that operates by receiving AC input power AC in a corresponding state according to the brightness control signal DC from the control unit 20. In this example, although an incandescent lamp is used as an example of the lighting device, other types of lighting devices may be used without being limited thereto.

The photo triac 30 includes a light emitting diode 31 and a triac 32, and an operating state of the photo triac 30 is changed according to the brightness control signal DC output from the controller 20. The photo triac 30 separates a DC signal and an AC signal and acts as a switching element.

The triac TC is an AC power control element, and the signal state applied to the gate terminal G varies according to the operation state of the photo triac 30, and the conduction is performed by the signal state applied to the gate terminal G. FIG. The state is controlled. Therefore, the triac TC converts the input state of the AC power source AC applied to the incandescent lamp 40 according to its operating state.

The zero potential level detecting unit 50 includes a full-wave rectifying unit 51 for full-wave rectifying AC power applied through the resistors R4 and R5, a photo coupler 52 whose operating state changes according to the full-wave rectified signal, A resistor R51 located between the power supply Vcc and the photo coupler 52 and a voltage detector 53 for outputting a voltage of the corresponding state to the controller 20 according to an operating state of the photo coupler 52.

The photo coupler 52 includes a light emitting diode 521 and a photo transistor 522. The photo triac 30 separates a DC signal from an AC signal and functions as a switching element.

The operation of the brightness control device of the lighting apparatus having such a structure will be described with reference to FIGS. 2 to 3 (a) to (i) as well as FIG. 1.

2 is a flowchart illustrating a method of controlling brightness of a lighting device according to an embodiment of the present invention. 3A to 3I are operational waveform diagrams of a brightness control apparatus of a lighting apparatus according to an embodiment of the present invention.

First, when an AC power source that is a sine wave is output from the AC input power source AC, the zero potential level detection unit 50 detects a zero potential level by using an applied AC power source. The zero potential level detection signal of the state is output to the control unit 20.

That is, after the level is adjusted through the resistors R4 and R5, the AC input power source AC as shown in FIG. 3A is applied to the full wave rectifying unit 51, and the full wave rectifying unit 71 is shown in FIG. Outputs a full-wave rectified signal as Then, the light emitting diode 521 of the photo coupler 52 is operated by the full wave rectified signal, and the light emitted by the operation of the light emitting diode 521 is applied to the base terminal of the photo transistor 522. In this case, the photo transistor 522 in the turn-off state is turned to the turn-on state. When the photo transistor 522 is turned from the turn-off state, since the power supply Vcc flows through the turned-on photo transistor 522, the voltage level applied to the voltage detector 53 is a ground level at a high level. It will change to low level.

Therefore, the voltage detector 53 outputs the zero potential level detection signal as shown in FIG. 3C according to the turn on / off state of the photo transistor 522 and outputs it to the controller 20. That is, the voltage detector 53 outputs a high level signal to the controller 20 when the AC input power source AC reaches the zero level level.

As described above, when the zero potential level of the AC input power source AC is detected and applied to the control unit 20 by the operation of the zero potential level detection unit 50, and the power required for the operation is applied to the control unit 20, the incandescent lamp ( Operation of the control unit 20 for controlling the operation state of 40 is started (S11).

As shown in (d) of FIG. 3, the control unit 20 generates a control signal DC corresponding to steps (i) (i = 1, 2, 3... N) to generate a light emitting diode of the phototriac 30. Output to 31 to control the brightness of the incandescent lamp 40 to the maximum brightness (S17).

That is, the control unit 20 detects the zero potential level timing using the zero potential level detection signal output from the zero potential level detection unit 50, and adjusts the brightness control signal of the low level signal L in accordance with the detected zero potential level timing. Outputs (DC) for the set time. In this example, the application time of the low level signal L is important for the brightness control signal DC, but the retention time of the low level signal L is not important. Therefore, the holding time of the low level signal L is already determined, and can be changed as needed. However, the holding time of the low level signal L does not exceed the time until the next zero potential level is detected.

Accordingly, the light emitting diode 31 of the phototriac 30 operates to emit light while the low level signal L is applied, and the triac 32 is light-emitting by the light emitting diode 31. In the conduction state, the AC power applied through the resistor R3 is output to the gate terminal G of the triac TC, and the triac TC is turned on.

As described above, since the operation timing of the light emitting diode 31 of the photo triac 30 coincides with the zero potential level time point, the application time of the AC power output through the triac 32 also matches the zero potential level time point. do. Therefore, in this step (step i), the AC power outputted to the incandescent lamp 40 through the Fort Liac TC is applied in accordance with the zero potential level detection time, so that the AC shown in FIG. It is the same signal as the input power source AC (Fig. 3 (e)).

As a result, the driving signal applied to the incandescent lamp 40 becomes a driving signal of 100% brightness, that is, a driving signal of maximum brightness, which does not cause energy loss due to the driving signal output from the control unit 20. The incandescent lamp 40 is turned on at a brightness of 100% by the maximum driving signal.

As such, after the operation of the control unit 20 is started, the brightness of the light output from the incandescent lamp 40 reaches a maximum regardless of the operation state of the motion detection unit 10.

Next, the control unit 20 reads the motion detection signal from the motion detection unit 10 (S19), and determines whether there is a motion around the installation of the motion detection unit 10 (S21).

When it is determined that the motion exists by the motion detection signal, the controller 20 resets the set time and immediately sends the brightness control signal DC in the state as shown in FIG. ), The incandescent lamp 40 is turned on at maximum brightness.

However, when it is determined that the motion does not exist by the read motion detection signal, the controller 20 determines whether the elapsed time after the incandescent lamp 40 is turned on by using the timer 21 exceeds the set time. (S23).

If the elapsed time does not exceed the set time, the incandescent lamp 40 is turned on at the maximum brightness. For this reason, since the incandescent lamp 40 maintains the lighting state at the maximum brightness for a set time even when there is no movement, the user's inconvenience caused by the sudden brightness change and the frequent brightness change is prevented.

However, if the motion is not detected during the elapsed time, the control unit 20 reads the signal applied from the motion detecting unit 10 again (S25), and determines once again whether there is a motion (S27).

If there is motion, the set time is reset and the control unit 20 goes to step S17. The controller 20 outputs a brightness control signal DC as shown in FIG. 3D to drive the incandescent lamp 40 at maximum brightness. For this reason, when the motion is detected, the controller 20 controls the brightness of the incandescent lamp 40 to the maximum brightness.

However, if the motion is not detected even after the set time has elapsed, the controller 20 controls the brightness state of the incandescent lamp 40 of the previous state (eg, (i) state) to be set to the minimum brightness (that is, the minimum set brightness). It is determined whether it has reached (S29).

In the previous state [state (i)], when the light emission brightness of the incandescent lamp 40 reaches the minimum set brightness, the control unit 20 does not change the brightness control signal DC, that is, the application of the low level signal L. The brightness control signal DC of the previous state is output without delaying the timing any longer (S31). Thus, the incandescent lamp 40 maintains the lighting state of the minimum set brightness. In this case, the minimum set brightness may correspond to about 10% of the maximum brightness or may be turned off, and the set brightness may be changed according to a user.

However, if the brightness of the incandescent lamp 40 does not reach the minimum set brightness, the control unit 20 performs a control to decrease the brightness of the incandescent lamp 40 in steps by the set amount (S33).

That is, the control unit 20 reads the zero potential level detection time T detected by the timer 21, and also reads the zero potential level detection signal to determine the zero potential level timing of the AC input power source AC. .

The corresponding delay time T1 for the set amount is calculated using the zero potential level detection time T, and the low level signal of the brightness control signal DC is detected from the zero potential level timing detected by the calculated delay time T1. The application timing is delayed (FIG. 3F).

At this time, the delay time T1 is determined according to the set amount and the zero potential level detection time T, and the set amount also varies as necessary. For example, when the set amount is 10%, the delay time T1 is a time corresponding to 1 / 10T of the zero potential level detection time T. The zero potential level detection time T is detected every time by the timer 21 using the zero potential level detection signal output from the zero potential level detection unit 50, or is set using the timer 21 and the zero potential level detection signal. After detecting the zero potential level detection time T by the number of times, the average value thereof may be used.

As described above, when the time corresponding to the set amount is delayed from the detected zero potential level time, the low level signal L is applied, and thus the operation time of the phototriac 30 is also delayed by the delay time of the low level signal L. The turn-on timing of the triac TC is also delayed by the operation delay of the photo triac 30. Accordingly, as shown in FIG. 3G, the driving time of the AC power source AC applied to the incandescent lamp 40 is also shortened by the delay time T1, and the driving time is applied to the incandescent lamp 40 during the shorter driving time. The brightness of the incandescent lamp 40 decreases as much as the reduced driving signal.

After applying the brightness control signal (DC) whose application time is reduced by the set amount as described above,

The control unit 20 proceeds to step S25 and determines whether there is a motion using the motion detection signal (S27).

If no motion is continuously detected, the controller 20 outputs a brightness control signal DC for reducing the brightness of the incandescent lamp 40 by a set amount (eg, 10%). Therefore, when the brightness control signal DC of the low level signal L is applied after the set time (e.g., 1 / 10T) corresponding to the set amount in the previous state (e.g., (i + 1) state). The delay time of the current brightness control signal DC is further delayed by a 10% delayed time (eg, 1 / 10T), so that the controller 20 is zero in the current state (eg, (i + 2) state). The low level signal L is output as the brightness control signal DC after a delay of 2 / 10T from the level level detection time. For this reason, the brightness control signal DC as shown in Fig. 3H is output to the phototriac 30, and the phototriac 30 by 2 / 10T in accordance with the brightness control signal DC. The timing of the operation of the and triacs is also delayed. Therefore, the supply timing of the AC power source AC supplied to the incandescent lamp 40 is shortened by (2/10) T (Fig. 3 (i)), and the brightness of the incandescent lamp 40 is reduced by the shortened supply time. For example, the brightness of the lit incandescent lamp 40 is emitted at a brightness reduced by 20% from the maximum brightness.

In this state, if the set time has elapsed after the motion is not detected, the incandescent lamp may be shortened step by step by shortening the supply time of the AC power AC, which is a driving signal applied to the incandescent lamp 40 by the corresponding time, until the motion is detected again. The brightness of 40 is gradually reduced to the minimum set brightness.

When the motion is not detected by the brightness control device, the brightness of the incandescent lamp 40 is automatically reduced step by step without a separate control operation by the user. Therefore, since it is not necessary to manually control the brightness of the incandescent lamp 40, the user's convenience is improved, and when there is no movement, the driving signal applied to the incandescent lamp 40 is reduced to prevent unnecessary power consumption. .

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

10: motion detection unit 20: control unit
30: Photo Triac 40: Incandescent
50: zero potential level detector 51: full-wave rectifier
52: photo coupler 53: voltage detector
AC: AC input power R1-R5, R51: resistor
SW: Drive Switch TC: Triac

Claims (11)

A motion detector for detecting a motion and outputting a motion detection signal;
A zero potential level detector for detecting a zero potential level of an AC drive signal obtained by full-wave rectification of an AC power source for driving a lighting device, and outputting a zero potential level detection signal;
Receiving the motion detection signal and the zero potential level detection signal, and when the zero potential level timing is detected by the zero potential level detection signal, controlling the brightness of the lighting device to a maximum value for a set time in accordance with the zero potential level timing. After outputting the brightness control signal, it is determined whether the motion is detected by the motion detection signal, and when the motion is detected, the setting time is reset, the brightness of the lighting device is controlled to the maximum value, and the motion is during the setting time. If not detected, it is determined whether the brightness of the lighting device is the minimum setting brightness, and if the brightness of the lighting device is the minimum setting brightness, the motion is detected by reading the motion detection signal without reducing the brightness of the lighting device. The illumination when the brightness of the lighting device is not the minimum set brightness. A controller for outputting a brightness control signal for gradually decreasing the brightness of the device by a set amount; and
A switching unit for controlling the brightness of the lighting device by changing the operation state in accordance with the brightness control signal applied from the control unit, controlling the supply time of the AC power applied to the lighting device
Brightness control device of the lighting device comprising a. In claim 1,
And the control unit is configured to delay the output of the brightness control signal by the set amount from the zero potential level timing of the AC power source determined by the zero potential level detection signal when the movement is not detected during the set time. Brightness control device. 3. The method according to claim 1 or 2,
And the set amount is determined using a detection time of a zero potential level of the AC power supply. delete delete In claim 1,
The zero potential level detection unit is a full-wave rectifying unit for full-wave rectifying the AC power source,
A photo coupler connected to the full wave rectifier and whose operating state changes according to the AC power rectified;
And a voltage detector configured to detect a zero potential level of the AC power source and output the zero potential detection signal to the controller according to a voltage level that changes according to an operation state of the photo coupler. In claim 1,
The switching unit has a gate terminal connected to the photo triac and the photo triac whose operating state changes according to the brightness control signal output from the controller, and an anode terminal and a cathode terminal are connected to the AC power source and the lighting device. Brightness control device for lighting equipment including a triac. In claim 1,
The lighting device is a brightness control device of the lighting device is an incandescent lamp. Determining the zero potential level timing of the AC power supply driving the lighting device according to the zero potential level detection signal applied from the outside;
If the zero potential level timing is detected, controlling the brightness of the lighting device to the maximum for a set time in accordance with the detected zero potential level timing,
Determining whether motion is detected,
Determining whether the set time has elapsed when the motion is detected;
If the set time has not elapsed, controlling the brightness of the lighting device to the maximum;
If the set time elapses, determining again whether motion is detected;
Determining whether the brightness of the lighting device is a minimum setting brightness when the determined motion is not detected again;
Maintaining the brightness of the lighting device at the minimum setting brightness when the brightness of the lighting device is the minimum setting brightness, and
If the brightness of the lighting device is not the minimum set brightness, gradually decreasing the brightness of the lighting device by a set amount.
Brightness control method of a lighting device comprising a. delete The method of claim 9,
Step by step of decreasing the brightness of the lighting device by a set amount,
Determining a zero potential level timing of an AC power supply for driving the lighting device according to the zero potential level detection signal, and
Outputting a brightness control signal for applying the AC power to the lighting device from the zero potential level time period by a delay time corresponding to the set amount;
Brightness control method of a lighting device comprising a.

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