KR101326479B1 - LED Lighting System having Common Current Source - Google Patents

Abstract

LED lighting devices having a common current source are disclosed. The LED lighting apparatus of the present invention is an LED light-emitting block including the LED module of the first to nth (where n is an integer of 2 or more) is arranged in series with each other, the light emitting by the rectified voltage, the first to nth The LED module of the LED light emitting block, each tab is formed in the cathode terminal; A switching block including first to nth switches which form an electrical path between the respective taps and the common signal according to first to nth switching control signals corresponding to the respective first to nth switching control signals; A common current source for sourcing the current of the common signal; And a control block for generating the first to nth switching control signals having a logic state corresponding to the level of the rectified voltage. In the LED lighting apparatus of the present invention as described above, the sourcing current amount is controlled by one common current source regardless of the closed circuit formed, that is, the LED module to emit light. Therefore, according to the LED illuminating device of this invention, generation | occurrence | production of the overcurrent in an LED module is prevented and reliability improves as a whole.

Description

LED lighting system having a common current source

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to LED lighting apparatus, and more particularly, to an LED lighting apparatus having a common current source to prevent generation of overcurrent.

BACKGROUND ART A light emitting diode (LED) element is a kind of compound semiconductor and is an element that emits light by a voltage to be applied. Such LED devices have the advantages of small size, long life, and high efficiency of converting electrical energy into light energy. Accordingly, an LED lighting device using an LED element is gradually being developed as an illumination device replacing an incandescent lamp and a fluorescent lamp.

In addition, in recent years, LED lighting apparatuses emit light in response to the size of an alternating voltage provided from the outside in order to easily improve and increase power efficiency and power factor without using complicated circuit structures and capacitors, inductors, and PFC ICs. A light emitting LED number control type LED lighting device in which the number of LED elements is controlled is being developed.

1 is a view for explaining a conventional LED lighting device, it shows a light emitting LED number controlled LED lighting device. In a conventional LED lighting device, the bridge diode (MRC) rectifies the alternating voltage (VAC), and generates the rectified voltage (VREC). The LED elements of the LED light emitting block 10 classified into a plurality of LED modules MD1 to n emit light by the rectified voltage VREC.

On the other hand, the switching control signals VCON1 to n generated by the control block 40 are activated according to the magnitude of the rectified voltage VREC, so that the switches SW1 to n corresponding to the plurality of LED modules MD1 to n. Turn on). The LED module MD1 included in the closed circuit is formed according to whether the switches SW1 to n formed between the taps TP1 to n between the LED modules MD1 to n and the ground voltage VSS are turned on. The number of ˜n) is controlled. At this time, the LED modules MD1 to n included in the closed circuit formed by the turn-on of the switches SW1 to n emit light.

By the way, in the LED illuminating device of FIG. 1, current sources SC1-n for adjusting the electric current of LED module MD1-n of a closed circuit are arrange | positioned for each switch SW1-n. In this case, current can flow simultaneously to two or more current sources SC1 to n. Accordingly, in the LED lighting apparatus of FIG. 1, an overcurrent occurs in the LED modules MD1 to n, thereby causing a problem in that reliability is lowered.

An object of the present invention is to solve the problems of the prior art, to prevent the occurrence of overcurrent in the LED module of the closed circuit is formed, to provide an LED lighting device to improve the overall reliability.

One aspect of the present invention for achieving the above object relates to an LED lighting device. The LED lighting apparatus of the present invention is an LED light-emitting block including the LED module of the first to nth (where n is an integer of 2 or more) is arranged in series with each other, the light emitting by the rectified voltage, the first to nth The LED module of the LED light emitting block, each tab is formed in the cathode terminal; A switching block including first to nth switches which form an electrical path between the taps of the first to nth LED modules corresponding to each other and the common signal according to the first to nth switching control signals corresponding to the respective ones; Each of the first to n-th switches may include: a switching block having one side electrically connected to a tap of the first to nth LED modules corresponding to the respective one, and the other side commonly connected to the common signal; A common current source for sourcing the current of the common signal; And a control block for generating the first to nth switching control signals having a logic state corresponding to the level of the rectified voltage. In this case, the sourcing current amount is controlled by the voltage level of the source control signal, and the voltage level of the source control signal is controlled by the level of the rectified voltage.

In the LED lighting apparatus of the present invention, the sourcing current amount is controlled by one common current source regardless of the LED module to be emitted. Therefore, according to the LED illuminating device of the present invention, generation of overcurrent is prevented in the LED module of the closed circuit to be formed, and the overall reliability is improved.

A brief description of each drawing used in the present invention is provided.
1 is a view for explaining a conventional LED lighting device.
2 is a view showing an LED lighting apparatus according to an embodiment of the present invention.
3 is a diagram illustrating an example of the common current source of FIG. 2.
4 is a block diagram illustrating the control block of FIG. 2 in detail.
5 is a view illustrating in more detail the switching control signal generator of FIG. 4.
FIG. 6 is a diagram specifically illustrating a source control signal generator of FIG. 4.

For a better understanding of the present invention and its operational advantages, and the objects attained by the practice of the present invention, reference should be made to the accompanying drawings, which illustrate preferred embodiments of the invention, and the accompanying drawings. In understanding each of the figures, it should be noted that like parts are denoted by the same reference numerals whenever possible. Further, detailed descriptions of known functions and configurations that may be unnecessarily obscured by the gist of the present invention are omitted.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a structure of a leg-folding work table according to an embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a view showing an LED lighting apparatus according to an embodiment of the present invention. Referring to FIG. 2, the LED lighting apparatus of the present invention includes an LED light emitting block 100, a switching block 200, a common current source 300, and a control block 400.

The LED light emitting block 100 is connected to a rectified voltage VREC generated from a rectifying generation block GPW. Preferably, the rectification generation block (GPW) comprises an alternating current supply (MSAC) and a rectifier (MRC). The AC supply MSAC supplies an AC voltage VAC. The rectifier MRC rectifies the AC voltage VAC to provide the rectified voltage VREC. In this case, the rectified voltage VREC has a voltage in one direction with respect to the ground voltage VSS and changes with time.

Preferably, the rectifier MRC is a full-wave rectifier for rectifying the entire region of the AC voltage VAC with the voltage in the same direction to provide the rectified voltage VREC.

That is, by the rectifier MRC, a negative voltage at the AC voltage VAC is rectified to a positive voltage of the rectified voltage VREC.

More preferably, the rectifier MRC is a bridge diode.

2, the LED light emitting block 100 includes first to nth LED modules MD1 to n connected in series with each other. The first to nth LED modules MD1 to n are controlled to emit light by the rectified voltage VREC. At this time, each of the taps TP1 to n is formed between the LED modules MD1 to n and at the cathode terminals of the last LED module MD3.

The switching block 200 is connected to each tap TP1 to n of the LED light emitting block 100 to form a closed circuit of the LED modules MD1 to n to each tap TP1 to n. Driven.

The switching block 200 includes first to n th switches SW1 to SWn. The first to n-th switches SW1 to SWn correspond to the taps TP1 to n corresponding to the self and the common signal VCOM in response to the corresponding first to nth switching control signals VCON1 to n. To form an electrical path. That is, each of the first to n th switches SW1 to SWn has one side electrically connected to the taps TP1 to n corresponding to the respective ones, and the other side has the common signal VCOM. Are commonly connected).

The common current source 300 adjusts the sourcing current amount of the common signal VCOM. That is, the common current source 300 is formed between the common signal VCOM and the ground voltage VSS to adjust the amount of current flowing in the formed closed circuit.

Preferably, the sourcing current amount of the common current source 300 is controlled by the voltage level of the source control signal VCSC. And more preferably, the voltage level of the source control signal VCSC is controlled by the level of the rectified voltage VREC.

3 is a diagram illustrating an example of the common current source 300 of FIG. 2, and illustrates a voltage controlled common current source. Referring to FIG. 3, the common current source 300 includes a source comparator 310, a source transistor 320, and a source resistor 330.

The source comparator 310 compares the voltage level of the source control signal VCSC and the feedback signal VFB. In the present embodiment, the source control signal VCSC is applied to the non-inverting input terminal (+) of the source comparator 310, and the feedback signal VFB is applied to the inverting input terminal (−) of the source comparator 310. Is approved.

The source transistor 320 is gated to an output signal of the source comparator 310 to electrically connect the common signal VCOM and the feedback signal VFB. In the present embodiment, the source transistor 320 is applied to the output signal of the source comparator 310 to the gate terminal, the NMOS transistor is connected to the common signal (VCOM) and the feedback signal (VFB) two junctions to be.

The source resistor 330 is formed between the feedback signal VFB and the ground voltage VSS.

By the above configuration, the source current amount ISC of the common current source 300 is controlled according to the voltage level of the source control signal VCSC.

Referring back to FIG. 2, the control block 400 detects the level of the rectified voltage VREC and generates the first to nth switching control signals VCON1 to n. In this case, the first to nth switching control signals VCON1 to n have a logic state according to the voltage level of the rectified voltage VREC.

4 is a block diagram illustrating in detail the control block 400 of FIG. 2. Referring to FIG. 4, the control block 400 includes a switching control signal generator 410 and a source control signal generator 430.

The switching control signal generator 410 generates the first to nth switching control signals VCON1 to n. In this case, the first to nth switching control signals VCON1 to n have a logic state according to the rectified voltage VREC.

FIG. 5 is a diagram illustrating the switching control signal generator 410 of FIG. 4 in more detail. Referring to FIG. 5, the switching control signal generator 410 includes a resistor string 411 and a comparator group 413.

The switching control signal generator 410 includes distribution resistors RS1 to n corresponding to the first to nth switching control signals VCON1 to n. In this case, the distribution resistors RS1 to n are connected in series. In addition, corresponding division voltages VDV1 to n are generated at connection nodes of the distribution resistors RS1 to n.

The comparator group 413 includes control comparators COM1 to n corresponding to the first to nth switching control signals VCON1 to n. In this case, a threshold voltage VTH is commonly applied to the non-inverting input terminals (+) of the control comparators COM1 to n, and corresponding distribution voltages are applied to the inverting input terminals of the control comparators COM1 to n. VDV1 to n are commonly applied.

As described above, the first to n th switching control signals VCON1 to n which are output signals of the switching control signal generator 410 have a logic state corresponding to the rectified voltage VREC. That is, when the rectified voltage VREC rises, the first to nth switching control signals VCON1 to n sequentially change from "H" to "L". When the rectified voltage VREC falls, the first to nth switching control signals VCON1 to n sequentially change from "L" to "H".

Accordingly, in the LED light emitting block 100, the number of the LED modules MD1 to n included in the closed circuit, that is, the number of the LED modules MD1 to n to emit light sequentially increases as the rectified voltage VREC increases. And decrease sequentially as the rectified voltage VREC falls (see FIG. 2).

Referring back to FIG. 4, the source control signal generator 430 detects a logic state of the first to nth switching control signals VCON1 to n to generate the source control signal VCSC. In this case, the source control signal VCSC is controlled corresponding to the logic state of the first to nth switching control signals VCON1 to n.

6 is a diagram illustrating in detail the source control signal generator 430 of FIG. 4. Referring to FIG. 6, the source control signal generator 430 includes a reference voltage generator 431 and a switching unit 433.

The reference voltage generating unit 431 generates first to nth reference voltages VR1 to VRn corresponding to the first to nth switching control signals VCON1 to n. The switching unit 433 may control any one of the first to nth reference voltages VR1 to VRn according to a logic state of the first to nth switching control signals VCON1 to n. Driven to provide a signal VCSC.

For example, the logic states of the first to second switching control signals VCON1 and VCON2 are “L” according to the rectified voltage VREC, and the third to nth switching control signals VCON1 and VCON2 may be disposed. Assume the logic state is "H".

In this case, only the switch 433_3 corresponding to the third reference voltage VR3 of the reference voltage generating unit 431 is "turned on", and all the other switches 433_1 to 2 and 433_3 to n are "turned off". do. Therefore, the voltage level of the source control signal VCSC is controlled by the third reference voltage VR3.

The source control signal VCSC provided by the source control signal generator 430 is a logic state of the first to nth switching control signals VCON1 to n, and consequently, the rectified voltage VREC. Is controlled according to Accordingly, the source current amount ISC of the common current source 300 may be controlled to an appropriate value corresponding to the rectified voltage VREC.

In the LED lighting apparatus of the present invention as described above, the sourcing current amount is controlled by one common current source regardless of the closed circuit formed, that is, the LED module to emit light. Therefore, according to the LED illuminating device of this invention, generation | occurrence | production of the overcurrent in an LED module is prevented and reliability improves as a whole.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

For example, in this specification, a source control signal generator for generating a voltage control type common current source and a source control signal whose voltage level is adjusted is shown and described. However, it will be apparent to those skilled in the art that the technical idea of the present invention may be implemented by a source control signal generator for generating a current control type common current source and a current control source control signal.

Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (5)

In an LED lighting device,
An LED light-emitting block comprising LED modules of first to nth (where n is an integer of 2 or more), which are emitted by a rectified voltage and arranged in series with each other, wherein each of the first to nth LED modules has a cathode terminal. The LED light emitting block having respective tabs formed thereon;
A switching block including first to nth switches which form an electrical path between the taps of the first to nth LED modules corresponding to each other and the common signal according to the first to nth switching control signals corresponding to the respective ones; Each of the first to n-th switches may include: a switching block having one side electrically connected to a tap of the first to nth LED modules corresponding to the respective one, and the other side commonly connected to the common signal;
A common current source for sourcing the current of the common signal; And
A control block for generating the first to nth switching control signals having a logic state according to the level of the rectified voltage;
The common current source is
The amount of sourcing current is controlled by the voltage level of the source control signal,
The voltage level of the source control signal is
LED lighting device, characterized in that controlled by the level of the rectified voltage.
delete delete The method of claim 1, wherein the common current source is
A source comparator for comparing a voltage level of the source control signal and a feedback signal;
A source transistor gated to an output signal of the source comparator and electrically connecting the common signal and the feedback signal; And
And a source resistor formed between the feedback signal and the ground voltage.
The method of claim 1, wherein the control block
A switching control signal generator for generating the first to nth switching control signals, the first to nth switching control signals having a logic state corresponding to the rectified voltage; And
A source control signal generator for generating the source control signal, wherein the source control signal includes the source control signal generator controlled according to a logic state of the first to nth switching control signals; Device.

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