KR20160111814A - Fluorescent Lamp Compatible LED Illuminating Device And Electric Shock Protectiong Device Thereof - Google Patents

Abstract

The present invention relates to an LED illuminating device, capable of preventing an electric shock that may occur in a process of separating or coupling the LED illuminating device from or to a fluorescent lamp device and an electric shock protecting device for the same. According to the present invention, the fluorescent lamp-compatible LED illuminating device used in the fluorescent lamp device has a stabilizer. The stabilizer applies a first discharge voltage to the fluorescent lamp device when first and second connection terminals of the fluorescent lamp are fastened to the fluorescent lamp device, and applies a second discharge voltage to the fluorescent lamp device when the first or second connection terminal of the fluorescent lamp is fastened to the fluorescent lamp device. The fluorescent lamp-compatible LED illuminating device comprises; a first connection means and a second connection means electrically connected to both sockets of the fluorescent lamp device; an electric shock preventing device selectively coupled to the first or second connection means; a rectifying means rectifying external AC power inputted through the first connection means and the second connection means; an LED module having a plurality of LEDs; and a driving means driving the LED module based on the driving power provided from the rectifying means. The electric shock preventing device electrically couples the first or second connection means to an internal circuit when a first discharge voltage is applied from the fluorescent lamp device, and disconnects the first or second connection means from the internal circuit as an open state when a second discharge voltage is applied from the fluorescent lamp device.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluorescent lamp compatible LED illumination device and an electric shock protection device for the same.

The present invention relates to a fluorescent lamp-compatible LED lighting device that can be used in place of a conventional fluorescent lamp. More particularly, the present invention relates to an LED lighting device capable of preventing an electric shock accident, Device and an electric shock protection device therefor.

2. Description of the Related Art In recent years, interest in lighting devices using LEDs (Light Emitting Diodes) has been rapidly increasing. The LED lighting device has the advantage of less power consumption and semi-permanent life compared to the fluorescent lamps, incandescent lamps, and halogen lamps that have been used previously. Accordingly, a compatible LED illumination device capable of being used as an alternative to an incandescent lamp or a fluorescent lamp has been developed and widely used.

Fig. 1 is a configuration diagram showing the configuration of a fluorescent lamp apparatus currently in use. The fluorescent lamp apparatus is composed of sockets 2 and 3 for coupling fluorescent lamps, a ballast 4 and a starter tube 5, and the AC power supply 1 is connected to these configurations through a power switch 6.

The fluorescent lamp 10 is provided with first connecting means, that is, first and second terminal pins 11 and 12 on one side and second connecting means, that is, third and fourth terminal pins 13 and 14 ) Is installed. The terminal pins 13 to 14 are inserted into the sockets 2 and 3 and electrically coupled with the fluorescent lamp mechanism. Filaments 15 and 16 for discharge operation of fluorescent lamps are respectively coupled between the first and second terminal pins 11 and 12 and between the third and fourth terminal pins 13 and 14.

When the fluorescent lamp is coupled to the sockets 2 and 3 and the power switch 6 is turned on, the AC power source 1 flows through the ballast 4 and the starter 5. When the fixed electrode and the movable electrode of the starter tube 5 are separated from each other and the starter tube 5 is turned off, a momentary high voltage generated between both ends of the stabilizer 4 is applied to the filaments 15 and 16, A discharge is generated between the fluorescent lamps 15 and 16 so that the fluorescent lamp 10 is turned on. After the fluorescent lamp 10 is turned on, a stable current flow is established between the filaments 15 and 16.

2 is a block diagram showing the configuration of a fluorescent lamp-compatible LED lighting apparatus 20. As shown in Fig. The fluorescent lamp-compatible LED lighting apparatus 20 has first connecting means, namely, first and second terminal pins 21 and 22, which are fastened to the socket 2 of a fluorescent lamp, like conventional fluorescent lamps, Second connecting means, that is, third and fourth terminal pins (23, 24) are provided. The distance between the first connecting means (21, 24) and the second connecting means (23, 24) is set to be the same as that of ordinary fluorescent lamps. The rectifying sections (25, 26) are electrically coupled to the first connecting means (21, 22) and the second connecting means (23, 24), respectively. The rectifying sections 25 and 26 are constituted by, for example, a bridge diode. The rectifying sections 25 and 26 rectify the AC power inputted through the first to fourth terminal pins 21 to 24 and supply the AC power to the driving section 28.

The LED module 27 is provided with a plurality of LEDs, and these LEDs are arranged along the longitudinal direction of the LED lighting device, though not shown in the drawings. The driving unit 28 drives the LED module 27 with operating power applied from the rectifying units 25 and 26.

However, the above-described conventional LED lighting device 20 has the following problems.

In general, fluorescent lamps have a long lifetime, so it is necessary to replace them at regular intervals. The replacement work of the fluorescent lamp is usually performed in a state in which the power switch 6 is set to the ON state. This is because the lighting condition can be visually confirmed at the same time as the fluorescent lamp is replaced.

1, when a worker newly mounts the fluorescent lamp 10 or the fluorescent lamp-compatible LED lighting apparatus 20 in the fluorescent lamp apparatus, the operator firstly fastens one terminal pin of the fluorescent lamp to one socket, The terminal pin is fastened.

However, most of the stabilizers 4 employed in the fluorescent lamp apparatus are arranged such that when the power switch 6 is in the ON state, the terminal pins of the fluorescent lamps are not fastened to both the sockets 2 and 3, Or 3) of the fluorescent lamp is fastened to the fluorescent lamp, it is recognized that the fluorescent lamp is fastened to the fluorescent lamp so that the discharge operation for the fluorescent lamp is performed. That is, when the terminal pin is not fastened to the other socket (2 or 3), it is recognized that the starter tube (5) is in the off state and the high voltage is continuously applied to the fluorescent lamp (10 or 20).

In the conventional fluorescent lamp 10, current flows between the filaments 15 and 16 only after the discharge is performed and the fluorescent lamp 10 is turned on. Therefore, even if a high voltage is applied to one terminal pin of the fluorescent lamp 10, The voltage is not changed.

However, in the fluorescent-lamp-compatible LED lighting apparatus 20, the internal circuit is mostly composed of semiconductor elements or electronic elements. Since these components usually have parasitic capacitance, leakage current flows when power is applied from outside even in the non-operating state. Therefore, when a high voltage is applied to one terminal pin of the fluorescent lamp-compatible LED lighting apparatus 20, the high voltage is transmitted to the other terminal pin, thereby causing an accident that the operator is electrocuted.

Accordingly, it is a technical object of the present invention to provide a fluorescent lamp-compatible LED lighting device which is originally created in view of the above circumstances, and which can prevent an electric shock accident of a worker.

In addition, the present invention provides a method of electrically connecting a terminal pin and an internal circuit of a fluorescent lamp-compatible LED lighting apparatus in a state where both the terminal pins, i.e., the first and second connecting means are not connected to the socket of the fluorescent lamp apparatus, The present invention has another technical object in providing an electric shock protection device for a fluorescent lamp-compatible LED lighting device which makes it possible to prevent an electric shock.

In order to achieve the above-mentioned object, a fluorescent-lamp-compatible LED lighting device according to a first aspect of the present invention comprises a ballast, wherein when the first and second connection terminals of the fluorescent lamp are fastened to the fluorescent lamp, And a second discharge voltage is applied when the first or second connection terminal of the fluorescent lamp is fastened to the fluorescent lamp apparatus, wherein the fluorescent lamp is provided on both sides of the fluorescent lamp apparatus An electric shock protection device selectively connected to the first or second connection means, and an external AC power source which is inputted through the first and second connection means A rectifying unit, an LED module having a plurality of LEDs, and driving means for driving the LED module based on driving power supplied from the rectifying unit And the electric shock protection device electrically couples the first or second connection means with the internal circuit when the first discharge voltage is applied from the fluorescent lamp apparatus and when the second discharge voltage is applied from the fluorescent lamp apparatus, Or the second connecting means is set to an open state with the internal circuit.

The electric shock protection device may further include a first switch for interrupting electrical coupling between the first or second connection terminal and the internal circuit, and a second switch connected to the first or second connection terminal according to the first and second discharge voltages applied from the first or second connection terminal. A first detection unit coupled to an output side of the first switch and configured to maintain the ON state of the first switch when a current is supplied to the internal circuit through the first switch, 1 switching driving means.

And the first switch is formed of a triac.

The first detecting means may include two or more neon lamps connected in series.

The first switching drive means includes a first bridge circuit coupled in parallel with the detection means, a first photocoupler provided in a current path of the first bridge circuit, and a second photocoupler electrically connected between the first switch and the internal circuit And a second bridge circuit for on / off driving the first photocoupler together with the second photocoupler.

The electric shock protection device may further include second and third switches provided in series in a current path between the first or second connection terminal and the internal circuit and a second switch connected in series with the first or second connection terminal, Second and third detecting means for on / off-driving the second switch and the third switch respectively in accordance with first and second discharge voltages applied from the second connection terminal, and second and third detection means coupled to the output side of the second switch And a switching driving means for maintaining the on state of the second and third switches when a current is supplied to the internal circuit through the second switch.

And the second and third switches are triacs.

And the second and third detection means include two or more neon lamps connected in series.

The second switching driving means includes third and fourth bridge circuits respectively connected in parallel to the second and third detecting means, second and fourth bridge circuits respectively provided in the current paths of the third and fourth bridge circuits, A third photocoupler and a fifth bridge circuit electrically coupled between the second switch and the internal circuit and driving the second and third photocouplers on and off.

An electric shock protection device for a fluorescent lamp-compatible LED power supply device according to a second aspect of the present invention includes first and second connection means fastened to a fluorescent lamp device, and an external power source input through the first and second connection means An LED module having a plurality of LEDs, and driving means for driving the LED module using the operation power of the power source means, Wherein the electric shock protection device includes a switch provided between the first or second connection means and the power supply means for interrupting electrical coupling between the first or second connection terminal and the power supply means, Detecting means for detecting a voltage value of a discharge voltage applied from the first connection terminal or the second connection terminal to drive the switch on and off, When a current is supplied to the stage it is characterized by being configured to include a switching driving means for holding the ON state of the switch.

And the switch is formed of triac.

Further, the detecting means comprises two or more neon lamps connected in series.

The switching drive means includes a first bridge circuit coupled in parallel with the detection means, an optocoupler provided in a current path of the first bridge circuit, and a photocoupler electrically coupled between the switch and the internal circuit, And a second bridge circuit for on / off-driving the first bridge circuit.

An electric shock protection device for a fluorescent lamp-compatible LED lighting device according to a third aspect of the present invention includes first and second connection means fastened to a fluorescent lamp device, and an external power source input through the first and second connection means An LED module having a plurality of LEDs, and driving means for driving the LED module using the operation power of the power source means, Wherein the electric shock protection device is provided between the first or second connection means and the power source means and is provided between the first or second connection terminal and the power source means in series, And a second switch connected to the first or second connection terminal in series, and the first switch and the second switch are turned on / off according to first and second discharge voltages applied from the first or second connection terminal, respectively, The first and second detection means being connected to the output side of the second switch and supplying a current to the power supply means through the second switch, And means for controlling the operation of the apparatus.

The first and second switches may be triacs.

Further, the first and second detecting means include two or more neon lamps connected in series.

According to the present invention configured as described above, it is judged whether or not the fluorescent lamp-compatible LED lighting apparatus is normally mounted on the fluorescent lamp apparatus based on the discharge voltage applied from the ballast of the fluorescent lamp apparatus. In addition, in a work state in which the LED lighting apparatus is fastened to the fluorescent lamp apparatus, high voltage from the ballast is prevented from being applied to the LED lighting apparatus, thereby preventing an electric shock of the worker.

1 is a block diagram showing a configuration of a general fluorescent lamp mechanism.
Fig. 2 is a block diagram showing a configuration of a general fluorescent lamp-compatible LED lighting apparatus. Fig.
3 is a configuration diagram showing the configuration of a fluorescent lamp-compatible LED lighting apparatus according to the present invention.
Fig. 4 is a block diagram showing a first configuration example of the electric shock protection device 100 in Fig. 3; Fig.
5 is a circuit diagram showing a practical circuit configuration of the electric shock protection device 100 shown in Fig.
FIG. 6 is a block diagram showing a second configuration example of the electric shock protection device 100 in FIG.
7 is a circuit diagram showing a practical circuit configuration of the electric shock protection device 100 shown in Fig.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings. However, the embodiments described below represent one preferred embodiment of the present invention, and examples of such embodiments are not intended to limit the scope of the present invention. It will be readily understood by those skilled in the art that the present invention can be variously modified and practiced based on the embodiments described below.

First, the basic concept of the present invention will be described.

A very large number of ballasts are currently used in fluorescent lamp appliances that are commercially available. These ballasts differ in structure and operating characteristics. As a result of studying very many types of ballast characteristics, the inventor of the present invention confirmed that the ballasts generate and output different discharge voltages according to the state of the fluorescent lamp to the fluorescent lamp apparatus. For example, in the case of a ballast used for a power supply voltage of 220 V, the first and second connection means, that is, the first to fourth terminal pins 11 to 14 are connected to both side sockets 2, The first sockets 2 and 3 are connected to the sockets 2 and 3 while the first sockets 2 and 3 are connected to the first sockets 2 and 3. In contrast, A second voltage, that is, a voltage of about 500 V is applied.

In the present invention, the voltage between the first voltage and the second voltage is set as a reference voltage, and when the external voltage input through the terminal pin of the fluorescent lamp-compatible LED lighting apparatus is lower than the reference voltage, The current path between the means (21, 22) and the second connecting means (23, 24) is cut off to prevent an electric shock of the worker.

3 is a block diagram showing a configuration of a fluorescent lamp-compatible LED lighting apparatus 30 according to the present invention. In FIG. 3, substantially the same parts as those of FIG. 2 described above are denoted by the same reference numerals, and a detailed description thereof will be omitted.

In FIG. 3, the electric shock protection device 100 is provided on one terminal pin of the fluorescent lamp-compatible LED illumination device 30. FIG. Although the first connecting means 21 and 22 are shown as being coupled to the electric shock protection device 100 in the figure, the electric shock protection device 100 may be coupled to the second connection means 23 and 24 in the same manner . The electric shock protection apparatus 100 detects an initial external power source applied from the outside through the first connecting means 21 or 22 or the second connecting means 23 and 24. When the external power source is lower than the reference voltage The power supply path between the first connecting means (21, 22) and the internal circuit is cut off. That is, only one terminal pin of the LED lighting apparatus 30 is coupled to the socket 2 or 3 of the fluorescent lamp apparatus by the replacement operation of the LED lighting apparatus 30, It is possible to reliably prevent an accident that the worker is electrocuted by the improper high voltage by cutting off the current path between one terminal pin and the other terminal pin of the LED lighting device when an improper high voltage is applied from the ballast.

4 is a block diagram showing a first configuration example of the electric shock protection device 100 according to the present invention.

4, a switch 110 is provided between one terminal pin of the LED lighting apparatus 30, that is, the first connecting means 21, 22 and the rectifying unit 25 in this embodiment. The switch 110 is for interrupting the current flow between the first connecting means 21, 22 and the rectifying unit 25. [ Resistors R1 and R2 are coupled to the first and second terminal pins 21 and 22, respectively. These resistors R1 and R2 are set to have a resistance value corresponding to the filament 15 in Fig. The resistors R1 and R2 are provided to enable the ballast 4 to recognize that the fluorescent lamp 10 is coupled to the socket 2 or 3.

The switch 110 is turned on / off by the detecting unit 120 and the switching driver 130. The detection unit 120 controls on / off the switch 110 based on the initial external power. As described above with reference to FIG. 1, when the user turns on the power switch 6 of the fluorescent lamp apparatus, a high voltage for discharging the fluorescent lamp is initially applied from the ballast 4. Also, the high voltage applied at this time has a first or second voltage value according to the state of engagement of the LED illumination device 30 with respect to the fluorescent lamp apparatus, as described above. The detecting unit 120 turns on the switch 110 when the initial external voltage applied through the first connecting means 21 and 22 is higher than the reference voltage.

A resistor R3 is provided between the switch 110 and the rectifier 25 and a switching driver 130 is provided at both ends of the resistor R3. When the switch 110 is turned on and the external power is supplied to the rectifying unit 25 through the resistor R3, the switching driving unit 130 outputs a switching driving signal so that the switch 110 can be maintained in the on state do.

The electric shock protection apparatus 100 shown in FIG. 4 is configured such that when a normal discharge voltage, that is, a high voltage higher than the reference voltage, is applied from the ballast 4 through the first connection means 21, 22, Is turned on. When the switch 110 is turned on and the external power is supplied to the rectifying unit 25 through the resistor R3, the switching driving unit 130 keeps the switch 110 in the ON state, so that the driving power from the fluorescent lamp is normally supplied to the rectifying unit 25, respectively.

On the other hand, the first connecting means 21, 22 are connected to the socket 2 or 3 by the process of replacing the LED lighting apparatus 30 with respect to the fluorescent lamp apparatus and the second connecting means 23, The initial external power input through the first connecting means 21 and 22 is set to be lower than the reference voltage so that the detecting unit 120 keeps the switch 110 in the off state. Since the current flow through the resistor R3 is also cut off by turning off the switch 110, the switching driver 130 is also set to the non-driven state. Therefore, in this case, since the first connecting means 21 and 22 and the internal circuit are set in the open state by keeping the switch 110 in the OFF state continuously, even if the operator contacts the second connecting means 21 and 22, Is prevented.

When the operator connects the second connecting means 23 and 24 to the socket 2 or 3 of the fluorescent lamp apparatus in the operation of replacing the LED lighting apparatus 30, the first connecting means 21 and 22 Since no external voltage is applied, the detection unit 120 is set to the non-driving state and the switch 110 is turned off. When the switch 110 is set to the OFF state, the current flow through the resistor R3 is cut off, so that the switching driver 130 is also set to the non-driven state. Therefore, even in this case, the first connecting means 21, 22 and the internal circuit are set to the open state, so that the occurrence of an electric shock accident is prevented even if the operator touches the first connecting means 21, 22.

5 is a circuit diagram showing a specific circuit configuration of the electric shock protection device 100 shown in Fig.

In this embodiment, triac is employed as the switch 110 for interrupting the current flow between the first and second terminal pins 21 and 22 and the rectifying part 25 in Fig. The triac is preferably employed as the switch 110 because the parasitic capacitance is relatively low among the semiconductor switches for interrupting the current flow.

4, the detecting unit 120 includes a plurality of neon lamps 121-1, 121-2, ..., and 121-n connected in series. As described above, an electronic component such as a semiconductor device has a parasitic capacitance, which causes leakage current. In Fig. 1, the conventional fluorescent lamp was free from an electric shock accident because the fluorescent lamp is a discharge tube. That is, current flows only when the discharge tube is turned on by discharge. The discharge tube has a parasitic capacitance close to "0 " when the discharge tube is not lighted. In the present embodiment, the neon lamp 121 constituting the detection unit 120 is a discharge tube like a fluorescent lamp. Therefore, the detection unit 120 has an advantage that the influence of the leakage current can be excluded.

As described above, the discharge voltage supplied from the ballast 4 is set to a first voltage of about 600 V or more and a second voltage of about 500 V or more, depending on the state of the fluorescent lamp. Rated voltage 220V The neon lamp is set to approximately 90V threshold voltage. 5, when six neon lamps 121 are connected in series to constitute the detector 120, the overall threshold voltage of the detector 120 is set to approximately 540V. This is a value that can be appropriately adopted as a reference voltage for the first or second voltage supplied from the fluorescent lamp apparatus.

The output terminal of the detector 120 is coupled to the gate electrode of the triac 110 through a bias resistor R4. In the figure, when the external voltage applied through the first and second terminal pins 21 and 22 is the first voltage, for example, 600 V, the neon lamp 121 constituting the detecting unit 120 is turned on, (Not shown). Therefore, in this case, the triac 110 is turned on, so that the first and second terminal pins 21 and 22 are electrically coupled to the rectifying part 25.

On the other hand, when the external voltage applied through the first and second terminal pins 21 and 22 is the second voltage, for example, 500 V, the neon lamp 121 constituting the detection unit 120 is maintained in the off state, Thus, the triac 110 is set to the OFF state. Therefore, in this case, the first and second terminal pins 21 and 22 and the rectifying part 25 are set to the open state.

The switching driver 130 includes a first bridge circuit 131 coupled between both ends of the resistor R3 and a second bridge circuit 132 and a second bridge circuit 132 coupled in parallel with the detection unit 120. [ And a photocoupler 133 for interrupting the current path of the photodiode. A charge-up capacitor C1 is coupled between the photodiode PD of the photocoupler 133.

The first bridge circuit 131 includes diodes D1 to D4 and the second bridge circuit 132 includes diodes D5 to D8. The phototransistor PT of the photocoupler 133 is coupled to the current path of the second bridge circuit 132 and the photodiode PD of the photocoupler 133 is coupled to the first bridge circuit 131 And the cathode is coupled to the first bridge circuit 131 via the resistor R5.

When the triac 110 is turned on and the current flows through the resistor R3 in the switching driver 130, the voltage of the resistor R3 is applied to the photodiode 133 through the first bridge circuit 131 The phototransistor PT is turned on while current is supplied. When the phototransistor PT is turned on, the gate voltage is continuously supplied to the triac 110 through the diodes D5 and D8 of the second bridge circuit 132 from the first and second terminal pins 21 and 22 So that the triac 110 can stably stay on.

1, when the power switch 6 is turned on, a discharge voltage of a high voltage is supplied to the fluorescent lamp 10 by the ballast 4 at the beginning of operation, and when the fluorescent lamp 10 is turned on, The driving power source is supplied to the fluorescent lamp 10 through the sockets 2 and 3.

5, when the power switch 6 of the fluorescent lamp is turned on and a discharge voltage of a high voltage is applied from the fluorescent lamp mechanism, the triac 110 is turned on by the detecting unit 120 and the first and second terminal pins 21 The external power is supplied to the rectifying unit 25 from the photodiode 22 and the photocoupler 133 of the switching driver 130 is driven so that the triac 110 stably remains on. When a stable driving power source, that is, an AC power source is supplied from the fluorescent lamp apparatus through the first connection terminals 21 and 22 and the second connection terminals 23 and 24 by the power supply flow, the driving power is supplied to the triac 110, So that it is supplied to the rectifying part 25 in a stable manner.

In FIG. 5, the capacitor C1 is for driving the photo coupler 133 stably. The LED illumination device is driven by an AC power source. The power supply current supplied from the fluorescent lamp apparatus in the normal operation state alternately flows between the first connection terminals 21 and 22 and the second connection terminals 23 and 24 with a constant period. When the driving current is supplied from the first bridge circuit 131 to the photodiode PD, the capacitor C1 is charged by the driving current. During a time period during which the drive current is not supplied from the first bridge circuit 131 to the photodiode PD due to the zero crossing section of the AC power source, the capacitor C1 is discharged and the charge current is applied to the photodiode PD And is supplied as a current. Accordingly, the photocoupler 133 is driven irrespective of the zero crossing point of the AC power source, so that the first bridge circuit 132 is always stably set to the operating state.

5, when the external power source flows from the first connection terminals 21 and 22 to the second connection terminals 23 and 24, the driving power inputted through the first connection terminals 21 and 22 is supplied to the second bridge circuit The triac 110 is turned on by being supplied to the gate of the triac 110 through the diode D5 of the photodiode 132 and the phototransistor PT and the diode D8, (110) to the rectifying part (25) through the main electrode. When the external power source flows from the second connection terminals 23 and 24 to the first connection terminals 21 and 22 side, the current flows from the rectifying unit 25 and the resistor R3 to the main electrode-gate electrode of the triac 110, The triac 110 is set in an ON state by forming a current path to the first connection terminals 21 and 22 through the diode R4, the diode D6, the phototransistor PT and the diode D7, The driving power source flows from the rectifying section 25 to the first connection terminals 21 and 22 through the main electrode of the triac 110. [

The above operation is continued until the power supply switch 6 of the fluorescent lamp is turned off and the driving power supplied through the first and second terminal pins 21 and 22 is cut off.

FIG. 6 is a configuration diagram showing a second configuration example of the electric shock protection device 100 in FIG.

In this embodiment, first and second switches 210 and 220 are provided in series between the first and second terminal pins 21 and 22 and the rectifying part 25, and the first and second switches 210 and 210, 220 are turned on / off by the first detection unit 230 and the second detection unit 240, respectively. When the switches 210 and 220 are turned on and the external power is supplied to the rectifying unit 25 through the resistor R3, the switching driver 250 outputs a switching driving signal to maintain the switch 110 in an on state .

As described above, electronic components such as semiconductor devices have a parasitic capacitance. As is well known, the capacitance value of a capacitor or the like is significantly lowered when a plurality of capacitors are coupled in series. The triac constituting the switch 110 in FIGS. 4 and 5 has a constant value although the parasitic capacitance value is relatively low. In this configuration example, for example, a switch composed of a triac is connected in series to a plurality of stages so that the overall parasitic capacitance value by the switches 210 and 220 can be further lowered.

7 is a circuit diagram showing a specific circuit configuration of the discharge protection device 100 shown in Fig. In FIG. 7, substantially the same parts as those in FIG. 5 described above are denoted by the same reference numerals, and a detailed description thereof will be omitted. 7, the first and second triacs 210 and 220 are provided between the first and second terminal pins 21 and 22 and the rectifying part 25, respectively. The first and second triacs 210 and 220 are on / off driven by the first and second detectors 230 and 240, respectively. The first detecting unit 230 includes first through third neon lamps 231 through 233 coupled in series and the second detecting unit 240 includes fourth through sixth neon lamps 241 through 243 coupled in series . The first detection unit 230 and the second detection unit 240 are coupled in series through the gate-to-main electrode current path of the first triac 210. Therefore, also in this configuration, the overall reference voltage set by the first and second detection units 230 and 240 is substantially the same as the configuration of FIG. 4 and FIG.

That is, in this configuration example, the parasitic capacitance value set by the triacs 210 and 220 is obtained by connecting the triacs 210 and 220 in series in multiple stages while maintaining the reference voltage with respect to the discharge voltage applied from the fluorescent lamp, .

A third bridge circuit 252 is coupled in parallel with the first detection unit 230 and a fourth bridge circuit 253 is coupled in parallel with the second detection unit 240. A second photocoupler 254 is provided in the current path of the third bridge circuit 252 and a third photocoupler 255 is provided in the current path of the fourth bridge circuit 253. These second and third photocouplers 254 and 255 are driven by the first bridge circuit 131. Since the configuration and operation of the switching driver 250 are substantially the same as those in FIG. 5, the detailed description of the operation will be omitted.

The embodiments according to the present invention have been described above. However, the present invention is not limited to the above embodiments. The present invention can be variously modified without departing from the technical idea thereof.

For example, in the above-described embodiment, triac is employed as the switches 110, 210, and 220 in FIGS. 4 and 6 as an example. However, the switch may be any other switch Can also be applied by the same method.

21 to 24: terminal pin, 25, 26: rectifying part,
27: LED module, 28: driving part,
30: fluorescent lamp compatible LED lighting device, 100: electric shock protection device.

Claims (16)

Wherein the first and second connection terminals of the fluorescent lamp are fastened to each other by applying a first discharge voltage when the first and second connection terminals of the fluorescent lamp are both fastened to the fluorescent lamp mechanism, A second discharge voltage is applied to the fluorescent lamp,
First and second connecting means electrically coupled to both sockets of the fluorescent lamp mechanism,
An electric shock protection device selectively coupled to the first or second connection means,
Rectifying means for rectifying external AC power inputted through the first and second connecting means,
An LED module having a plurality of LEDs,
And driving means for driving the LED module based on driving power supplied from the rectifying means,
The electric shock protection device electrically couples the first or second connection means with the internal circuit when the first discharge voltage is applied from the fluorescent lamp apparatus and the first or second connection means when the second discharge voltage is applied from the fluorescent lamp apparatus. And the connection means is set to an open state with an internal circuit. The method according to claim 1,
The electric shock protection device includes a first switch for interrupting electrical coupling between the first or second connection terminal and the internal circuit,
First detection means for on / off-driving the first switch in accordance with first and second discharge voltages applied from the first or second connection terminal,
And a first switching driving means coupled to an output side of the first switch for maintaining the ON state of the first switch when current is supplied to the internal circuit through the first switch. LED lighting device. 3. The method of claim 2,
Wherein the first switch is composed of a triac. 3. The method of claim 2,
Wherein the first detecting means comprises two or more neon lamps connected in series. 3. The method of claim 2,
The first switching driving means includes a first bridge circuit coupled in parallel with the detection means, a first photocoupler provided in a current path of the first bridge circuit, and a second photocoupler electrically connected between the first switch and the internal circuit. And a second bridge circuit for driving the first photocoupler on / off, and a second bridge circuit for driving the first photocoupler on / off. The method according to claim 1,
The electric shock protection device includes second and third switches provided in series in a current path between the first or second connection terminal and the internal circuit,
A first switch connected in series to the first or second connection terminal and a second switch connected between the first or second connection terminal and the second switch for turning on and off the second switch and the third switch in accordance with the first and second discharge voltages applied from the first or second connection terminal, And third detecting means,
And a switching driving unit coupled to the output side of the second switch and maintaining the on state of the second and third switches when current is supplied to the internal circuit through the second switch. Type LED lighting device. The method according to claim 6,
And the second and third switches are triacs. The method according to claim 6,
Wherein the second and third detection means comprise two or more neon lamps connected in series. The method according to claim 6,
The second switching driving means includes third and fourth bridge circuits respectively connected in parallel with the second and third detecting means, second and third bridge circuits respectively provided in the current paths of the third and fourth bridge circuits, And a fifth bridge circuit that is electrically coupled between the second switch and the internal circuit and drives the second and third photocouplers on and off. Device. Power source means for generating operating power using an external power source input through the first and second connecting means, an LED module having a plurality of LEDs, An electric shock protection device for use in a fluorescent-lamp-compatible LED lighting device including driving means for driving an LED module using an operation power source of a power source means,
Wherein the electric shock protection device is provided between the first or second connection means and the power supply means,
A switch for interrupting electrical coupling between the first or second connection terminal and the power supply means,
Detection means for detecting a voltage value of a discharge voltage applied from the first or second connection terminal and driving the switch on / off,
And a switching driving means coupled to an output side of the switch for maintaining the ON state of the switch when a current is supplied to the power source means through a switch. . 11. The method of claim 10,
Wherein the switch is formed of a triac. 11. The method of claim 10,
Wherein the detecting means comprises at least two neon lamps connected in series. ≪ RTI ID = 0.0 > 8. < / RTI > 11. The method of claim 10,
The switching drive means includes a first bridge circuit coupled in parallel with the detection means, an optocoupler provided in a current path of the first bridge circuit, and a photocoupler electrically coupled between the switch and the internal circuit, And a second bridge circuit for on / off driving the LED lighting device. Power source means for generating operating power using an external power source input through the first and second connecting means, an LED module having a plurality of LEDs, An electric shock protection device for use in a fluorescent-lamp-compatible LED lighting device including driving means for driving an LED module using an operation power source of a power source means,
Wherein the electric shock protection device is provided between the first or second connection means and the power supply means,
First and second switches provided in series in a current path between the first or second connection terminal and the power supply means,
A first switch connected in series to the first or second connection terminal and a first switch connected to the first connection terminal and a second switch connected between the first connection terminal and the second connection terminal, And second detecting means,
And a switching driving means coupled to an output side of the second switch for maintaining the ON state of the first and second switches when current is supplied to the power source means through the second switch. Shielding protection device for LED lighting devices. 15. The method of claim 14,
Wherein the first and second switches are triacs. 2. The apparatus of claim 1, wherein the first and second switches are triacs. 15. The method of claim 14,
Wherein the first and second detection means comprise two or more neon lamps connected in series.

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