KR100998662B1 - An economical Lighting device - Google Patents

Abstract

The present invention is responsible for the remote control of the light source, and is provided between the electronic circuit portion having a separate energy storage means and the resistance (R) and commercial power in the RC equivalent circuit connected in series with the electronic circuit portion, the energy storage Auxiliary switching means for selectively opening and closing according to the charging voltage of the means, and the main switch is connected in parallel with the RC equivalent circuit, and opened and closed by a user operation, the electronic circuit portion in accordance with the charging voltage of the energy storage means A microcontroller is provided to operate the auxiliary switching means to allow selective charging of the energy storage means. The auxiliary switching means includes a rectifier circuit for converting commercial power into direct current and a rectifier circuit. A charging capacitor storing one electricity, a zener diode connected in parallel with the charging capacitor, and the first The photocoupler is connected in series with the diode and the auxiliary switch which is selectively opened and closed by the microcontroller receiving the operation signal of the photocoupler is applied to open and close in the low-voltage region Minimizes the shock voltage of the switching voltage. According to the present invention as described above, there is an advantage that the energy waste due to standby power is reduced.

Switch, Commercial Power, Capacitor, Microcontroller, Remote Controller, Equivalent Circuit

Description

Energy saving lighting device {An economical Lighting device}

The present invention relates to a power saving lighting device.

In general, the lighting device is to irradiate light in a dark place by using a light emitting device that emits light when the power is supplied, and the user selectively cuts off the power applied to the light emitting device through a switch operation, thereby lighting Do it.

Recently, various remote control methods such as a remote control or voice recognition have been developed to remotely operate such a lighting device, and such remote control includes an electronic circuit internally. In addition, the electronic circuit maintains standby power in an on state at all times in order to receive a control signal transmitted arbitrarily.

However, the above conventional technologies have the following problems.

The lighting apparatus according to the prior art continuously supplies power to maintain the standby power in the electronic circuit for remote control as described above.

Therefore, energy loss occurs due to the maintenance of standby power, which has a problem of stimulating consumer's emotional dissatisfaction.

It is an object of the present invention to provide a power saving type lighting device having an auxiliary switching means for a power saving function.

Another object of the present invention is to provide a power saving lighting device including a separate energy storage means for supplying standby power to the electronic circuit for remote control.

The present invention provides a lighting device capable of remote control of a light source, the electronic circuit unit responsible for the remote control of the light source and provided with a separate energy storage means, and the resistance (R) in the RC equivalent circuit connected in series with the electronic circuit unit And an auxiliary switching means provided between the commercial power source and selectively opened and closed according to the charging voltage of the energy storage means, connected in parallel with the RC equivalent circuit, and opened and closed by a user operation. It is characterized in that it comprises a microcontroller for enabling the selective charging of the energy storage means by operating the auxiliary switching means in accordance with the charging voltage of the energy storage means.

The auxiliary switching means is connected when the voltage charged in the energy storage means is less than the set voltage for the operation of the electronic circuit portion.

The auxiliary switching means includes a rectifier circuit for converting commercial power into a direct current, a charging capacitor for storing electricity passing through the rectifying circuit, a zener diode connected in parallel with the charging capacitor, and the zener diode. It is characterized in that it is connected in series, the photocoupler is operated when a voltage of more than the breakdown voltage is applied, and an auxiliary switch selectively opened and closed by the microcontroller receiving the operation signal of the photocoupler.

The energy storage means is characterized in that it comprises any one of a supercapacitor or a storage battery.

The auxiliary switch may be disconnected when the photocoupler is turned off.

The energy storage means is charged when the auxiliary switch is turned on, it is characterized in that the discharge is turned off.

The present invention is provided with a separate energy storage means in the electronic circuit unit, to supply the power required during the standby operation in the state in which the commercial power is cut off. In addition, the energy storage means detects the consumption of the charged power and sends a signal to the microcontroller, and when the voltage is lowered below a predetermined voltage, the auxiliary switching means operates to charge the power through commercial power.

Therefore, since the continuous supply of commercial power is not necessary for the standby power of the electronic circuit unit, there is an advantage in that energy waste due to the standby power is reduced.

In addition, the present invention controls the microcontroller so that the operation of the auxiliary switching means operates below the charging voltage of the charging capacitor connected to the rectifier circuit. Therefore, there is an advantage that the electrical shock of the element (Element) that can occur during the operation of the auxiliary switch for the selective blocking of the commercial power source is minimized.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.

However, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention can easily suggest other embodiments within the scope of the same idea.

1 is an equivalent circuit diagram of a power saving type lighting apparatus according to an embodiment of the present invention.

As shown, the energy-saving lighting device according to the present invention has an RC equivalent circuit for turning on the light source 2 connected to the commercial power source 1, and transmits and receives a signal to and from a remote controller such as a remote controller. It is configured to enable remote control.

In addition, an electronic circuit unit 300 connected to the RC equivalent circuit is provided for the remote control as described above, which will be described in more detail with reference to the accompanying drawings.

Auxiliary switching means 200 is selectively provided between the commercial power source 1 and the resistor R to be selectively opened and closed according to the charging voltage of the energy storage means 380. In addition, the main switch 100 for the selective supply of the commercial power source 1 in parallel with the auxiliary switching means 200 is further provided.

The auxiliary switching means 200 is provided between the resistor (R) and the commercial power source in the RC equivalent circuit connected in series with the electronic circuit unit 300. Accordingly, when the main switch 100 is in an off state, by selectively shutting off the power supplied to the electronic circuit unit 300, the standby power consumption of the electronic circuit unit 300 is reduced. Hereinafter, with reference to the accompanying drawings will be described in more detail.

2 is a view for explaining the structure and operation of the auxiliary switching means shown in FIG.

As shown, the auxiliary switching means 200, which is a main component of the present invention, includes a rectifying circuit 260 for converting an alternating current applied from the commercial power source 1 into a direct current.

In one embodiment of the present invention is configured to convert an alternating current to a direct current through a bridge rectifier circuit using a plurality of diodes, it would be possible to use a full-wave rectifier circuit including a transformer with an intermediate tap.

On the other hand, the rectifying circuit 260 is provided with a charging capacitor 240 for storing the converted direct current electricity, the auxiliary switch 220 is further provided between the charging capacitor 240 and the rectifying circuit 260.

Also, a zener diode 270 and a photo coupler 280 are connected in parallel to the charging capacitor 240, and the photo coupler 280 is energized when a voltage equal to or higher than the breakdown voltage of the zener diode 270 is applied. To enable the operation of the photocoupler 280.

That is, the photocoupler 280 is turned on above the breakdown voltage of the zener diode 270 to generate an optical signal, and the optical signal is a microcontroller 320 to be described below. To receive the control command.

In addition, the charging capacitor 240 is connected to the photocoupler 280 and the zener diode 270 in parallel, thereby minimizing the electrical shock that may occur when the electronic switch.

3 is a diagram illustrating a configuration of the electronic circuit unit shown in FIG. 1.

As shown in the drawing, the electronic circuit unit 300 includes an AC power supply unit 350 and a DC power supply unit 360 for power supply, a remote signal receiving unit 340 for receiving a remote signal by user manipulation, and a separate energy. The micro controller 320 receives power by the storage means 380 and processes the control command.

The AC power supply unit 350 is connected to the commercial power supply 1 to supply the main power, and the DC power supply unit 360 is supplied with the electricity supplied from the AC power supply unit 350 converted into DC power through a rectifying circuit. To be possible. The DC power supply 360 is connected to the energy storage means 380 for supplying power to the microcontroller 320.

The energy storage unit 380 continuously supplies power for driving the microcontroller 320 in a state in which the main switch 100 is turned off by using the voltage charged through the DC power supply unit 360. Supply.

That is, the energy storage means 380 is supplied with power to the microcontroller 320 while charging electricity through the DC power supply 360 in a state electrically connected to the DC power supply 360, the DC In the state that is not electrically connected to the power supply unit 360 is to supply the charged power to the microcontroller 320, a supercapacitor or a storage battery is used.

In addition, the energy storage means 380 is further provided with a voltage sensing unit for sensing the amount of voltage charged. The voltage sensing unit detects a voltage charged in the energy storage unit 380 and transmits a sensing state to the microcontroller 320.

On the other hand, the microcontroller 320 receives the voltage state of the energy storage means 380 transmitted through the voltage sensing unit as described above to operate the auxiliary switch 220.

In detail, the auxiliary switch 220 detects and transmits a voltage signal when the state of charge of the energy storage means 380 is completed from the voltage sensing unit provided in the energy storage means 380 to the microcontroller 320. If off, the power supply through the DC power supply unit 360 is cut off.

In addition, since the operation time of the auxiliary switch 220 blocked as described above is made while the photocoupler 280 is turned off under the breakdown voltage of the zener diode 260, the electric shock is minimized.

In addition, when a voltage less than the minimum voltage required to operate the microcontroller 320 is sensed from the voltage sensing unit of the energy storage means 380 and transferred to the microcontroller 320, the auxiliary switch 220. It is turned on so that the energy storage means 380 can be charged through the DC power supply 360.

Hereinafter, the operation of the present invention having the configuration as described above will be described.

In the lighting apparatus according to the present invention, the main switch 100 is directly operated by a user so that the light source 2 is turned on or off, or the light source 2 can be turned on or off by a separate remote controller.

In the former case, the user can directly operate the main switch 100 in an on or off position. In the latter case, the electronic circuit unit 300 is provided in accordance with a remote control signal of the user. ) Is activated to turn on or turn off the light source 2.

In addition, standby power for operating the microcontroller 320 must be continuously supplied to the electronic circuit unit 300 to control the light source 2 through the remote control as described above. Provided by 380.

The energy storage unit 380 is charged by receiving power from the DC power supply unit 360 provided in the electronic circuit unit 300, and the voltage charged in the energy storage unit 380 is charged by the microcontroller 320. Provided with an available power source.

In this case, when the main switch 100 is turned off and the light source 2 is turned off, the energy storage means 380 uses a RC equivalent circuit, that is, a charging capacity of the energy storage means 380. When the charging capacity is satisfied by checking the level of charge in the voltage sensing unit and the charging capacity is satisfied, the auxiliary switch 220 is turned off by transmitting a charging completion signal to the microcontroller 320. do.

Since the auxiliary switch 220 is turned off, the photocoupler 280 is turned off under the breakdown voltage of the zener diode 260 to reduce the electric shock of the device.

On the other hand, when the auxiliary switch 220 is off as described above, while the voltage charged to the energy storage means 380 is supplied to the microcontroller 320, the amount of charge of the energy storage means 380 is reduced. do.

When the amount of charge of the energy storage means 380 reduced as described above reaches a minimum voltage for operating the microcontroller 320, the microcontroller 320 checks this through the voltage sensing unit, and the auxiliary switch ( 220 to operate the power supply from the DC power supply 360 so that the energy storage means 380 can be charged.

Thus, as described above, the energy storage means 380 maintains charging and discharging continuously and provides the operating voltage required by the microcontroller 320, thereby reducing the power supply through the DC power supply 360. As a result, power consumption due to standby power is reduced.

1 is an equivalent circuit diagram of a power saving type lighting apparatus according to an embodiment of the present invention.

2 is a view for explaining the structure and operation of the auxiliary switching means shown in FIG.

FIG. 3 is a diagram showing the configuration of the electronic circuit portion shown in FIG. 1; FIG.

Explanation of symbols on the main parts of the drawings

100 ..... Main switch 200 ..... Auxiliary switching means

220 ..... Auxiliary switch 240 ..... Charging capacitor

260 ..... rectifier circuit 270 ..... zener diode

280 ..... Photo coupler 300 ..... Electronic circuit part

320 ..... microcontroller 340 ..... remote signal receiver

350 ..... AC power supply 360 ..... DC power supply

380 ..... Energy Storage

Claims (6)

delete delete In the lighting device capable of remote control of the light source, An electronic circuit unit that is responsible for remote control of the light source, and provided with a separate energy storage means; An auxiliary switching means provided between the resistor R and a commercial power source in an RC equivalent circuit connected in series with the electronic circuit unit, the auxiliary switching means being selectively opened and closed according to the charging voltage of the energy storage means; It is connected in parallel with the RC equivalent circuit, the main switch opened and closed by a user operation; includes, The electronic circuit portion, A microcontroller for operating the auxiliary switching means in accordance with the charging voltage of the energy storage means to enable selective charging of the energy storage means; The auxiliary switching means, A rectifier circuit for converting commercial power into a direct current, a charging capacitor for storing electricity passing through the rectifying circuit, a zener diode connected in parallel with the charging capacitor, and a breakdown connected in series with the zener diode A photocoupler operated when a voltage above the voltage is applied and an auxiliary switch selectively opened and closed by the microcontroller receiving the operation signal of the photocoupler are included to open and close in a low voltage region, thereby minimizing switching voltage shock of a small device. Lighting equipment. delete The method of claim 3, wherein the auxiliary switch, Power saving lighting device is disconnected when the photocoupler is turned off. The method of claim 3, wherein the energy storage means, Power saving lighting device that is charged when the auxiliary switch is turned on, and is discharged when turned off.

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