KR102517841B1 - Apparatus for controlling LEDs using integrated cable and radio dimming circuit - Google Patents

Abstract

The present invention provides an input power unit, a converter for converting input power into power supplied to the lighting unit, a lighting unit that emits light when the power supplied to the lighting unit is applied, a wired module for inputting a wired dimming signal for controlling the lighting unit, and a wireless dimming signal for controlling the lighting unit. A wireless module and a conversion module that receives the wired dimming signal or the wireless dimming signal, converts it into a preset power, and applies it to the converter, wherein the wired module and the wireless module are connected in parallel to generate the wired dimming signal or the wireless dimming signal. It relates to a lighting control device using a wired/wireless integrated light control circuit characterized in that it selectively receives and applies to a conversion module.

Description

Lighting control device using wired/wireless integrated dimming circuit {Apparatus for controlling LEDs using integrated cable and radio dimming circuit}

The present invention provides an input power unit, a converter for converting input power into power supplied to the lighting unit, a lighting unit that emits light when the power supplied to the lighting unit is applied, a wired module for inputting a wired dimming signal for controlling the lighting unit, and a wireless dimming signal for controlling the lighting unit. A wireless module and a conversion module that receives the wired dimming signal or the wireless dimming signal, converts it into a preset power, and applies it to the converter, wherein the wired module and the wireless module are connected in parallel to generate the wired dimming signal or the wireless dimming signal. It relates to a lighting control device using a wired/wireless integrated light control circuit characterized in that it selectively receives and applies to a conversion module.

LED (Light Emitting Diode) is a type of semiconductor device that converts electrical energy into light. Light emitting diodes have advantages of low power consumption, semi-permanent lifespan, fast response speed, safety, and environmental friendliness compared to conventional light sources such as fluorescent lamps and incandescent lamps. In particular, the LED lighting device can perform various directing by controlling the blinking sequence, light emission color, and brightness of a plurality of arrayed LEDs.

Therefore, many studies are being conducted to replace conventional light sources with light emitting diodes, and light emitting diodes are increasingly used as light sources for lighting devices such as various lamps used indoors and outdoors, liquid crystal display devices, electronic signboards, and street lights. . In particular, it is used for purposes such as general lighting for indoor interiors, stage lighting for creating a specific atmosphere, advertising lighting, and landscape lighting.

The lighting device may be installed on an outer wall of a building, a park, a street light, a bridge railing, or a performance hall as a time-lapse lighting, and its size and application system may vary depending on the purpose, target, or location to which it is applied. In other words, for the outer wall of a building, it is simply used in the form of a band on the outer wall of the building with a flashing function or simply expressed in a single color or combined color, and for parks, street lights, and bridge railings, lights are installed irregularly according to the shape of the object to blink or color is used by changing

On the other hand, LED lighting is rapidly spreading due to its long lifespan and high efficiency compared to conventional lighting, and a dimmer capable of changing the intensity of illumination according to climate change and time is being commercialized. The types of control methods of these dimmers can be divided into wireless communication and wired communication. In particular, when using wireless communication, the brightness is adjusted by adjusting the Dim (+-) line of each driver.

For such a dimmer, a wired dimming circuit that performs 0-10V dimming control through wire and a wireless dimming circuit that performs dimming control using wireless communication such as Zigbee may be used. In particular, wired lighting has been steadily used in LED lighting, but recently interest and demand for wireless lighting have been increasing, and wireless lighting products are being introduced to the market accordingly. In addition, a wired dimming circuit and a wireless dimming circuit

However, referring to FIG. 1 , in order to implement a lighting device using both the wired light control circuit 160 and the wireless light control circuit 170, a board including each circuit must be separately manufactured. In addition, in the case of the conventionally used wired light control circuit 160, since it uses a complicated circuit using an OP-AMP, there is a problem in that it is expensive and bulky due to its configuration.

Therefore, in order to solve the disadvantage of low universality by bringing about a rise in unit price, a circuit that avoids the over-density and enlargement of parts is constructed, and lighting devices using wired and wireless dimming integrated circuits that can supplement mass productivity through simple circuit implementation are various. was being studied.

As described above, the present invention provides a lighting control device using a wired/wireless integrated dimming circuit that connects and integrates wired dimming (0-10V dimming) and wireless dimming (Zigbee dimming) in parallel in one circuit for miniaturization and integration of parts. intended to provide

The technical problem to be achieved by the present invention is not limited to the above-mentioned technical problem, and may include various technical problems within the scope apparent to those skilled in the art from the contents to be described below.

A lighting control device using a wired/wireless integrated dimming circuit of the present invention for solving the above problems is an input power unit, a converter that converts input power into power supplied to the lighting unit, a lighting unit that emits light when the power supplied to the lighting unit is applied, and the lighting unit A wired module for inputting a wired dimming signal for controlling, a wireless module for inputting a wireless dimming signal for controlling the lighting unit, a conversion for receiving the wired dimming signal or the wireless dimming signal, converting it into a preset power, and applying it to the converter module, wherein the wired module and the wireless module are connected in parallel to selectively receive the wired dimming signal or the wireless dimming signal and apply it to the conversion module.

In addition, the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention may further include an EMI filter for removing noise from the input power and applying it to the converter.

In addition, in the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention, the converter includes a PFC converter and a fly-back converter.

In addition, in the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention, the converter receives the wired dimming signal or the wireless dimming signal and controls the dimming of the lighting unit when a necessary driving condition is met. characterized by

In addition, in the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention, the wired module includes a wired signal input unit for receiving a wired dimming signal. At this time, the wired dimming signal is characterized in that the 0-10V dimming signal.

In addition, in the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention, the wired module includes a first power supply unit and a power distribution module for distributing supply power of the first supply power unit. do.

At this time, in the lighting control device using the wired/wireless integrated dimming circuit according to an embodiment of the present invention, the power distribution module has a first wired resistor connected in series with the wired dimming signal input unit and a second wired dimming signal input unit connected in parallel. The method may further include a wire resistance, a third wire resistance connected in series with the first wire resistance, and a fourth wire resistance connected in parallel with the third wire resistance.

At this time, in the lighting control device using the wired/wireless integrated dimming circuit according to an embodiment of the present invention, the wired module has an input filter module that removes noise from the wired dimming signal input and an output filter that removes noise from the wired dimming signal output. Characterized in that it further includes a module.

In addition, in the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention, the wired module may further include a first diode for preventing a reverse bias voltage.

Further, in the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention, the wireless module receives a PWM dimming signal.

In addition, in the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention, the wireless module includes a second supply power supply unit, a wireless signal input unit for receiving a wireless dimming signal, and the wireless dimming signal is applied. )/off operation, and a second switch element performing an opposite operation to the first switch element and generating a dimming signal by an on/off operation.

At this time, in the lighting control device using the wired/wireless integrated dimming circuit according to an embodiment of the present invention, the wireless module has a first wireless resistor connected in series with the wireless signal input unit, and a first wireless resistor connected in parallel with the first resistor. 1 wireless capacitor and a second wireless resistor, a third wireless resistor and a second wireless capacitor connected in parallel with the output terminal of the first switch element, a fourth wireless resistor connected between the output terminal of the first switch element and the power supply unit, It is characterized in that it comprises a fifth wireless resistor connected between the output terminal of the second switch element and the power supply unit.

At this time, in the lighting control device using the integrated wired/wireless dimming circuit according to an embodiment of the present invention, the wireless module has a sixth wireless resistor connected in series to the output terminal of the second switch element, and series with the sixth wireless resistor. A seventh wireless resistor connected to , a third capacitor connected in parallel with the seventh wireless resistor, an eighth wireless resistor connected in parallel between the sixth wireless resistor and the seventh wireless resistor, and the eighth wireless resistor It is characterized in that it includes a ninth wireless resistor connected in series.

In addition, in the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention, the wireless module further includes a second diode for preventing a reverse bias voltage.

In addition, in the lighting control device using a wired/wireless integrated dimming circuit according to an embodiment of the present invention, the conversion module receives the wired dimming signal or the wireless dimming signal to convert first-level power to second-block power characterized by

In addition, the lighting control device using the wired and wireless integrated dimming circuit according to an embodiment of the present invention is characterized in that it further comprises a standby module for generating a voltage to drive the converter.

The lighting control device using the integrated wired/wireless dimming circuit of the present invention has a 0-10V dimming circuit (wired) as well as a wireless dimming circuit simultaneously implemented, so that customers or consumers can selectively select and drive the dimming circuit. can be designed to

In addition, the lighting control device using the wired/wireless integrated dimming circuit of the present invention can be applied and used in various ways according to the diversity of direct circuits for controlling dimming.

In addition, the lighting control device using the wired/wireless integrated dimming circuit of the present invention can quantitatively reduce the unit cost compared to the conventional 0-10V dimming circuit, and can reduce the size of the PCB due to the simplification of the circuit.

In addition, the lighting control device using the integrated wired and wireless dimming circuit of the present invention can select and use a wired or wireless dimming circuit according to customer needs, and can appeal to customers as a technical and differentiated product due to a concept not used in the past. there is.

1 is a configuration diagram showing a lighting control device of the prior art.
Figure 2 is a configuration diagram showing a lighting control device according to an embodiment of the present invention.
3 is a configuration diagram showing a wired/wireless integrated light control circuit of a lighting control device according to an embodiment of the present invention.
4 is a circuit diagram showing a wired module of a wired/wireless integrated dimming circuit of a lighting control device according to an embodiment of the present invention.
5 is a circuit diagram showing a wireless module of a wired/wireless integrated lighting circuit of a lighting control device according to an embodiment of the present invention.
6 is a circuit diagram showing a wired/wireless integrated light control circuit conversion module of a lighting control device according to an embodiment of the present invention.

Hereinafter, a 'lighting control device using a wired/wireless integrated light control circuit' according to the present invention will be described in detail with reference to the accompanying drawings. The described embodiments are provided so that a person skilled in the art can easily understand the technical spirit of the present invention, and the present invention is not limited thereto. In addition, matters represented in the accompanying drawings may be different from those actually implemented in the drawings schematically illustrated to easily explain the embodiments of the present invention.

On the other hand, each component expressed below is only an example for implementing the present invention. Accordingly, other components may be used in other implementations of the present invention without departing from the spirit and scope of the present invention.

In addition, the expression 'including' certain components simply refers to the existence of the corresponding components as an expression of 'open type', and should not be understood as excluding additional components.

In addition, expressions such as 'first and second' are expressions used only for distinguishing a plurality of components, and do not limit the order or other characteristics between the components.

In the description of the embodiments, each layer (film), region, pattern or structure is "on" or "under/under" the substrate, each layer (film), region, pad or pattern. The description of being formed in "" includes all those formed directly or through another layer. The criteria for upper/upper or lower/lower of each layer will be described based on drawings.

When a part is said to be "connected" to another part, this includes not only the case of being "directly connected" but also the case of being "indirectly connected" with another member interposed therebetween. In addition, when a part "includes" a certain component, it means that it may further include other components without excluding other components unless otherwise stated.

1 is a configuration diagram showing a lighting control device of the prior art.

Referring to FIG. 1 , in order to implement a lighting device using both the wired light control circuit 160 and the wireless light control circuit 170, a board including each circuit must be separately manufactured. In addition, in the case of the conventionally used wired light control circuit 160, since it uses a complicated circuit using an OP-AMP, there is a problem in that it is expensive and bulky due to its configuration.

Therefore, in order to solve the disadvantage of low universality by bringing about a rise in unit price, a circuit that avoids the over-density and enlargement of parts is constructed, and lighting devices using wired and wireless dimming integrated circuits that can supplement mass productivity through simple circuit implementation are various. was being studied.

In order to improve the problems of conventional lighting control devices, the present invention provides wired dimming (0-10V, 1-10V dimming, etc...) and wireless dimming (Zigbee, BLE, Bluetooth dimming, etc.), and can implement a wired/wireless integrated dimming circuit that selectively receives a wired dimming signal and a wireless dimming signal. For a detailed description thereof, reference will be made to FIGS. 2 to 5 .

Figure 2 is a configuration diagram showing a lighting control device according to an embodiment of the present invention, Figure 3 is a configuration diagram showing a wired and wireless integrated dimming circuit of the lighting control device according to an embodiment of the present invention.

2 and 3, the lighting control device of the present invention includes an input power supply unit 210, converters 230 and 240, a lighting unit 251, a wired module 310, a wireless module 330, and a conversion module 350. ) may be included.

The input power unit 210 supplies overall input power to the lighting device. At this time, the input power input to the input power supply unit 210 is preferably 220V commercial power, and in the case of 220V commercial power, it may have a sine wave form that periodically alternates between -311V and +311V. More specifically, the input power unit may serve as a supply power source for various elements used in the power supply device.

In addition, by further including an EMI filter 220 in the input power unit, noise of the input power may be removed and applied to the converter. When input power is supplied from the input power supply unit, electrical noise is changed into a magnetic field, which may cause electromagnetic interference (EMI) that interferes with other elements of the lighting control device. Such noise can be removed using an EMI filter.

The converters 230 and 240 convert input power into power supplied to the lighting unit. These converters receive the main power and convert it into stable and efficient power required by the system and perform a power conditioning role. In particular, the converter of the present invention can be implemented as an AC/DC converter that converts AC power to DC power, and a diode rectifier, a phase control rectifier, and a bridge rectifier are used to achieve desired power conversion while minimizing power loss. AC/DC conversion can be performed using various rectifier circuits, such as multiple switches and transformers.

In addition, the converter of the present invention may include a PFC converter 230 and a fly-back converter 240. In particular, the flyback converter is an isolated SMPS circuit method and is electrically insulated from the power supply line, so that power can be stably supplied to the output stage.

In addition, the converter of the present invention may receive the wireless dimming signal or the wired dimming signal and control dimming of the lighting unit when a necessary driving condition is met. More specifically, the flyback converter is a main block of the driving power supply of the LED lighting unit, and can control dimming of the driving power supply of the LED lighting unit when the Vcc voltage and required driving conditions are met.

In addition, although a general DC power supply may be used as the voltage for driving the converter of the present invention, a standby module 271 generating a voltage for driving the converter may be implemented separately.

The lighting unit 251 emits light when power supplied to the lighting unit is applied. The converter converts the input power into power supplied to the lighting unit and applies it. In particular, the lighting unit 251 of the present invention may be composed of a light emitting diode (LED). A light emitting diode (LED) is a semiconductor-based light source and has various advantages such as low price, long life, miniaturization, eco-friendly waste treatment, low energy consumption, high efficiency, and linearity, and is a generally widely used light source.

The dimmer inputs a dimming signal to control the lighting unit. Such a dimmer is a device for continuously increasing or decreasing the brightness, illuminance, or color of a lamp, and both wired and wireless operations (remote operation) are possible.

In particular, the dimmer of the present invention is characterized by inputting at least one of a 0-10V dimming signal, a 1-10V dimming signal, and a PWM dimming signal. The 0-10V dimming signal is controlled by varying the voltage of the control line from 0V to 10V, and the 1-10V dimming signal is controlled by varying the voltage from 1V to 10V. In addition, the PWM dimming signal is a method of adjusting the amount of current by modulating the width of the frequency controlling the power supply. In addition to this, the dimmer of the present invention can be used by inputting various dimming signals that can be generally used.

More specifically, the dimmer of the present invention may include a wired module 310 for inputting a wired dimming signal and a wireless module 330 for inputting a wireless dimming signal. In addition, the dimmer of the present invention can selectively receive a wireless dimming signal or a wired dimming signal because the wired module and the wireless module are connected in parallel. Accordingly, the user or manager may control the dimming of the lighting device by selecting wireless dimming or wired dimming as needed.

More specifically, the wireless module does not operate when the 0-10V dimming signal is input by the wired module, and the wired module does not operate when the PWM dimming signal is input by the wireless module. This is because the wired module and the wireless module are connected in parallel. Therefore, it is possible to prevent an error that may occur when the wired module and the wireless module are input at the same time.

The conversion module 350 receives the wireless dimming signal or the wired dimming signal, converts it into a preset power, and applies it to the converter. More specifically, the conversion module may receive the wireless dimming signal or the wired dimming signal and convert first-level power into second-level power. When the dimming signal is input and converted into an analog voltage (approximately 0~2.5V, 2.5V~5.0V), power of this value cannot be applied to the power control device as it is, so it must be converted into power of an appropriate value. Therefore, it can be converted into secondary power through the conversion module and used in the converter and power control device.

4 is a circuit diagram showing a wired module of a wired/wireless integrated dimming circuit of a lighting control device according to an embodiment of the present invention.

Referring to FIG. 4 , when the dimming signal is wired, it is possible to check the configuration of the wired module that is selected and received. The wired module 310 of the present invention includes a wired signal input unit 311, a first power supply unit (+10V), power distribution modules 312, 317, 319, and 320, input filter modules 313 and 316, and an output filter module. 321, and a first diode 322 may be included.

The wired module 310 inputs a wired dimming signal for controlling the lighting unit. At this time, the wired module may receive and apply a wired dimming signal through the wired signal input unit 311 . In addition, the wired dimming signal may receive an analog voltage between 0V and 10V by receiving a 0-10V dimming signal.

The power distribution modules 312, 317, 319, and 320 distribute power of the first supply power (+10V). At this time, the power distribution module is preferably composed of a plurality of resistors, and the sizes of the first wire resistance 317, the second wire resistance 312, the third wire resistance 319, and the fourth wire resistance 320 are set. It is possible to adjust the size of the power applied to the node by adjusting, and the value of the output dimming signal of the wired module can be adjusted according to the difference in the level of the dimming signal applied to the node and the wired signal input unit.

The first wire resistor 317 is connected in series with the wired dimming signal input unit, and the second wired resistor 312 is connected in parallel with the wired dimming signal input unit. In addition, the third wired resistor 319 is connected in series with the first wired resistor, and the fourth wired resistor 320 is connected in parallel with the third wired resistor. At this time, the positions of the first, second, third, and fourth wired resistors may be appropriately changed according to the size of power distribution.

In addition, the wired module of the present invention may further include an input filter module and an output filter module for removing noise from input and output. The input filter modules 313 and 316 may remove noise from the wired dimming signal input, and the output filter module 321 may remove noise from the wired dimming signal output. In particular, the input filter module and the output filter module may be implemented as an RC noise filter of a plurality of capacitors or resistance-capacitors, or may be implemented as a general noise filter module.

The first diode 322 prevents the reverse bias voltage of the voltage application module. When a voltage is applied to the output, a reverse bias is generated and the circuit itself may be destroyed. This can be prevented by including a diode in the wired signal input unit. In addition, the first diode may prevent a short circuit of the wired module.

5 is a circuit diagram showing a wireless module of a wired/wireless integrated lighting circuit of a lighting control device according to an embodiment of the present invention.

Referring to FIG. 5 , a configuration of a wireless module received by selecting a case in which a dimming signal is wireless can be confirmed.

The wireless module 330 inputs a wireless dimming signal for controlling the lighting unit. The wireless module of the present invention may include a second power supply unit (+10V), a wireless signal input unit 331, a first switch element 335 (Q1), and a second switch element (338, Q2). In addition, the first wireless resistor 332, the first wireless capacitor 334, the second wireless resistor 333 and the second wireless capacitor 337, the third wireless resistor 336, the fourth wireless resistor 339, A fifth wireless resistor 341 may be further included. At this time, it is preferable that the wireless module 330 receives a PWM dimming signal.

The second supply power unit inputs 10V supply power. This supply power may operate as driving power for the first switch element and the second switch element, and may be applied to the voltage application module to generate an analog voltage level according to the duty cycle of the PWM signal. More specifically, the larger the PWM signal period, the larger the analog voltage, and the smaller the PWM signal period, the smaller the analog voltage.

The wireless signal input unit 331 receives a PWM dimming signal. When the PWM dimming signal is input with a period of high-low-high-low, etc., the signal may be converted by the first switch element and the second switch element.

The first switch element (Q1, 335) receives a PWM dimming signal to perform an on/off operation, and the second switch element (Q2, 338) performs an opposite operation to that of the first switch element. will perform In this case, the first switch element and the second switch element may be made of at least one of FET, BJT, and SCR. In addition, the square wave dimming signal generated by the second switch element is converted into analog power.

More specifically, when the PWM dimming signal is high (H), a 3V signal is applied to connect the first switch elements Q1 and 335. When the first switch element is turned on, the gate voltage of the second switch element becomes 0, and the drain-source of the second switch element is in an open state. Therefore, the 10V supply power of the supply power unit is applied as it is to the voltage application module, and becomes 10V.

In addition, when the PWM dimming signal is low (L), a 0V signal is applied so that the first switch element Q1 or 335 is not connected. When the first switch element is turned off, the gate voltage of the second switch element is applied, and the drain-source of the second switch element is in a short circuit state. Accordingly, since the 10V supply power of the supply power supply unit escapes through the short-circuited line, the magnitude of the power applied to the voltage application module becomes 0V.

The first wireless resistor (R1, 332) is connected in series with the wireless signal input unit and serves to control current according to the PWM dimming signal. The first wireless capacitor 334 and the second wireless resistor 333 are connected in parallel with the first resistor and serve as an RC filter to remove noise of the input PWM dimming signal. The third wireless resistor 336 is connected in parallel with the output terminal of the first switch element and controls the magnitude of the voltage applied to the second switch element. The second wireless capacitor 337 is connected in parallel with the output terminal of the first switch element, and removes noise from a signal generated by the first switch element.

The fourth wireless resistor 339 is connected between the output terminal of the first switch element and the power supply unit, and applies the power supply unit (+10V) to the first switch element. The fifth wireless resistor 341 is connected between the output terminal of the second switch element and the power supply unit, and serves to divide the supply power of the supply power unit according to the size setting of the resistor present in the output terminal of the second switch element. do.

The sixth wireless resistor 342, the seventh wireless resistor 345, the eighth wireless resistor 343, and the ninth wireless resistor 344 distribute power of the second supply power (+10V). The size of the power applied to the node can be adjusted by adjusting the size of the sixth wireless resistor 342, the seventh wireless resistor 345, the eighth wireless resistor 343, and the ninth wireless resistor 344, and the node and The value of the output dimming signal of the wireless module may be adjusted according to the difference in magnitude of the dimming signal applied to the wireless signal input unit.

In addition, the sixth wireless resistor 342 is connected in series with the output terminal of the second switch element 338, and the seventh wireless resistor 345 is connected in series with the sixth wireless resistor. The eighth wireless resistor 343 is connected in parallel between the sixth wireless resistor and the seventh wireless resistor, and the ninth wireless resistor 344 is connected in series with the eighth wireless resistor. At this time, the position of the wireless resistor may be changed to an appropriate arrangement according to the size of power distribution.

The third capacitor 346 is connected in parallel with the seventh wireless resistor and implements a noise removal and smoothing circuit of the output signal. Compared to the input PWM dimming signal, the generated signal passing through the first switch and the second switch element may include a ripple voltage in DC, so a smoothing circuit should be implemented to reduce this pulsation.

The second diode 347 prevents the reverse bias voltage of the voltage application module like the first diode. When a voltage is applied to the output, a reverse bias is generated and the circuit itself may be destroyed. This can be prevented by including a diode in the wireless signal input unit. Also, the second diode may prevent a short circuit of the wireless module.

The embodiments of the present invention described above are disclosed for illustrative purposes, and the present invention is not limited thereto. In addition, those skilled in the art will be able to make various modifications and changes within the spirit and scope of the present invention, and these modifications and changes will be considered to fall within the scope of the present invention.

110: Conventional input power supply unit 120: Conventional EMI filter;
130: conventional converter; 140: conventional transformer
150: Conventional lighting unit 160: Conventional wired lighting circuit
170: conventional wireless dimming circuit
210: input power unit 220: EMI filter
230: PFC converter 240: flyback converter
241: transformer 250: output diode
251: lighting unit 271: standby module
272: transformer 273: output diode
300: dimming control unit 310: wired module
311: wired signal input unit 313, 316: input filter module
317: first wire resistance 312: second wire resistance
319: third wire resistance 320: fourth wire resistance
321: output filter module 322: first diode
330: wireless module 331: wireless signal input unit
332: first wireless resistor 333: second wireless resistor
334: first wireless capacitor 335: first switch element
336: third wireless resistor 337: second wireless capacitor
338: second switch element 339: fourth wireless resistor
341: fifth wireless resistor 342: sixth wireless resistor
343: 8th wireless resistor 344: 9th wireless resistor
345: 7th radio resistor 346: 3rd capacitor
347: second diode 350: conversion module

Claims (17)

input power unit;
A converter that converts input power into power supplied to the lighting unit;
a lighting unit that emits light when power supplied to the lighting unit is applied;
a wired module inputting a wired dimming signal for controlling the lighting unit;
a wireless module for inputting a wireless dimming signal for controlling the lighting unit;
a conversion module for receiving the wired dimming signal or the wireless dimming signal, converting it into a preset power source, and applying the converted power to the converter;
including,
The wired module and the wireless module,
Connected in parallel to selectively receive the wired dimming signal or the wireless dimming signal and apply it to the conversion module;
The wired module,
A first power supply unit;
A power distribution module for distributing the power supplied by the first power supply unit,
The power distribution module,
A first wire resistance connected in series with the wired dimming signal input unit;
A second wire resistance connected in parallel with the wired dimming signal input unit;
A third wire resistance connected in series with the first wire resistance;
A lighting control device using a wired/wireless integrated dimming circuit comprising a fourth wired resistor connected in parallel with the third wired resistor.
delete delete delete delete delete delete delete input power unit;
A converter that converts input power into power supplied to the lighting unit;
a lighting unit that emits light when power supplied to the lighting unit is applied;
a wired module inputting a wired dimming signal for controlling the lighting unit;
a wireless module for inputting a wireless dimming signal for controlling the lighting unit;
a conversion module for receiving the wired dimming signal or the wireless dimming signal, converting it into a preset power source, and applying the converted power to the converter;
including,
The wired module and the wireless module,
Connected in parallel to selectively receive the wired dimming signal or the wireless dimming signal and apply it to the conversion module;
The wired module,
An input filter module that removes noise of wired dimming signal input;
A lighting control device using a wired/wireless integrated dimming circuit including an output filter module that removes noise from a wired dimming signal output.
delete delete input power unit;
A converter that converts input power into power supplied to the lighting unit;
a lighting unit that emits light when power supplied to the lighting unit is applied;
a wired module inputting a wired dimming signal for controlling the lighting unit;
a wireless module for inputting a wireless dimming signal for controlling the lighting unit;
a conversion module for receiving the wired dimming signal or the wireless dimming signal, converting it into a preset power source, and applying the converted power to the converter;
including,
The wired module and the wireless module,
connected in parallel to selectively receive and apply the wired dimming signal or the wireless dimming signal to the conversion module;
The wireless module,
A second power supply unit;
A wireless signal input unit for receiving a wireless dimming signal;
A first switch element to which the wireless dimming signal is applied to perform an on/off operation;
A lighting control device using a wired/wireless integrated dimming circuit, characterized in that it includes a second switch element that performs an opposite operation to the first switch element and generates a dimming signal by an on/off operation.
According to claim 12,
The wireless module,
A first wireless resistor connected in series with the wireless signal input unit;
A first wireless capacitor and a second wireless resistor connected in parallel with the first wireless resistor;
A third wireless resistor and a second wireless capacitor connected in parallel with the output terminal of the first switch element;
A fourth wireless resistor connected between the output terminal of the first switch element and the second supply power supply;
A lighting control device using a wired/wireless integrated dimming circuit comprising a fifth wireless resistor connected between the output terminal of the second switch element and the second supply power supply.
According to claim 12,
The wireless module,
A sixth wireless resistor connected in series with the output terminal of the second switch element;
A seventh wireless resistor connected in series with the sixth wireless resistor;
A third capacitor connected in parallel with the seventh wireless resistor;
An eighth wireless resistor connected in parallel between the sixth wireless resistor and the seventh wireless resistor;
A lighting control device using a wired/wireless integrated lighting circuit including a ninth wireless resistor connected in series with the eighth wireless resistor.
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