KR100953224B1 - The led lighting - Google Patents

Abstract

The present invention relates to an LED fluorescent lamp through a magnetic auxiliary ballast module for driving a light emitting diode (LED) using a magnetic ballast output to be interchangeable with an existing fluorescent lamp,

More specifically, a plurality of LEDs are arranged in a plurality of rows along the periphery of the rod shape, and a flexible board (FPCB) connected and aligned with each other, and a plurality of LEDs connected to the flexible board are inserted in the upright shape to be combined with the same rod shape as the flexible board. An aluminum reflector having a plurality of LED reflecting grooves formed around the rod-shaped main body, and inserted into a circular shape between an end of the aluminum reflector and a fluorescent lamp electrode pin to generate an initial discharge of the magnetic fluorescent lamp. As it consists of a magnetic auxiliary ballast module that blocks the start and protects a plurality of LEDs formed on the flexible board,

It is an object of the present invention to provide an LED fluorescent lamp through a magnetic auxiliary ballast module that can be easily replaced with an LED fluorescent lamp without an additional configuration, and is environmentally friendly, long-lived, and has good light efficiency.

LED fluorescent lamp, magnetic auxiliary ballast module, flexible board

Description

LED fluorescent lamps with magnetic auxiliary ballast module {THE LED LIGHTING}

The present invention relates to an LED fluorescent lamp through a magnetic auxiliary ballast module for driving a light emitting diode (LED) using a magnetic ballast output to be interchangeable with an existing fluorescent lamp.

Fluorescent lighting, which is currently used most frequently in homes and offices, has better light efficiency, longer life, and various colors than incandescent lamps.

However, the demand for the quality of lighting is increasing, and lighting is also attempting to change in accordance with the trend of becoming more environmentally friendly in all fields. One of them is lighting using LED.

LED has many advantages in comparison with existing lamps in many ways, and lighting fixtures using this are being released.

However, the LED lighting fixtures currently on the market must be driven by using a separate control device while using commercial power (AC110 ~ 220V). Therefore, there is a problem in that all existing fluorescent lamp fixtures must be removed or the internal circuits must be substantially modified. there was.

In order to solve this problem, Korean Utility Model Publication No. 20-0385056 has a circuit board 10 is arranged in a plurality of LEDs 11 are arranged inside the bottom surface; A connection terminal 20 connected to both sides of the circuit board 10 and connected to a conventional fluorescent lamp outlet 1;

A control unit 30 for converting AC power to DC power, the control unit 30 being mounted on one side of the circuit board 10 to adjust LED color; LED lamps are provided that surround the components and are mounted on a fluorescent lamp outlet formed of a cylindrical diffusion cover 40 for diffusing light emitted from the LEDs 11 by forming various patterns 41.

When the LED lamp is used to replace the fluorescent lamp driven by the magnetic ballast, there is a problem that the LED is burned out or a malfunction occurs in other electronic devices due to the starter start causing the initial discharge of the magnetic fluorescent lamp.

In order to solve this problem, the present invention can easily replace the existing magnetic fluorescent lamp with an LED fluorescent lamp without a separate configuration, to provide an LED fluorescent lamp through an environmentally friendly, long life and light efficiency magnetic auxiliary ballast module. The purpose is.

In order to achieve the above object, the LED fluorescent lamp through the magnetic auxiliary ballast module according to the present invention,

It consists of the same size and the same shape as the fluorescent lamp is made of LED fluorescent lamp which is connected to the fluorescent lamp socket and driven,

The LED fluorescent lamp is a flexible substrate (FPCB) connected to the plurality of LEDs arranged in a plurality of rows along the periphery of the rod-shaped,

An aluminum reflecting plate formed in the same rod shape as the flexible substrate so that a plurality of LEDs connected to the flexible substrate are inserted into and coupled to the flexible substrate, and a plurality of LED reflecting grooves are formed along the rod-shaped main body;

It consists of a magnetic auxiliary ballast module which is formed so as to be inserted in a circular shape between the end of the aluminum reflector and the fluorescent electrode electrode pin to block the start of the starter causing the initial discharge of the magnetic fluorescent lamp to protect the plurality of LEDs formed on the flexible substrate. Is achieved.

As described above, in the present invention, the existing magnetic fluorescent lamp can be easily replaced with the LED fluorescent lamp without any configuration, and it is environmentally friendly, has a long life and has good light efficiency.

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

1 is a perspective view showing the components of the LED fluorescent lamp through the magnetic auxiliary ballast module according to the present invention, which is a flexible substrate (FPCB) 100, aluminum reflector 200, magnetic auxiliary ballast module 300 It is composed of

The flexible board (FPCB) 100 is a place where a plurality of LEDs are arranged in a row in a plurality of rows along the circumference of the rod-shaped, and this is a flexible board (FPCB) with an insertion hole so that the chip LED is inserted along the circumference of the rod-shaped body. (100a) is formed, and the insulating pad portion (100b) of the rubber material to support the rod-shaped flexible substrate at the bottom of the flexible substrate (FPCB) (100a) and to insulate firstly, the insulating pad portion The lower flexible board 100a and the aluminum heat dissipation plate 100c for supporting the rod-shaped insulating pad portion and insulated secondarily are formed at the lower end of the upper portion 100b.

In the present invention, the flexible substrate (FPCB) 100a, which is easy to bend, is configured to be 0.6 to 0.9 times smaller than the diameter of the aluminum reflector to be manufactured in the same size (size) as a fluorescent lamp, and is formed in the same rod shape as the fluorescent lamp.

That is, insertion holes (not shown) are formed to insert the plurality of chip LEDs 110 along the circumference of the flexible substrate.

Subsequently, the chip LED 110 is inserted into the insertion hole and then mounted, and a rubber insulating pad portion 100b is formed at the lower end of the flexible substrate. Here, the insulating pad part 100b serves to insulate the rod-shaped flexible substrate and to insulate it first.

Subsequently, an aluminum heat sink 100c is formed at the lower end of the insulating pad part 100b. Here, the aluminum heat dissipation plate 100c serves to insulate the rod-shaped flexible substrate and the rod-shaped insulating pad part and to insulate it secondarily.

Subsequently, when a plurality of LEDs (FPCB) (100a), the insulating pad portion (100b), the aluminum heat dissipation plate (100c) is stacked in order, the flexible substrate (FPCB) (100a) is arranged in a rod shape of the same size and the same shape as the fluorescent lamp do.

As described above, in the present invention, an insulating pad portion 100b made of a rubber material to insulate the primary portion and an aluminum heat sink 100c to insulate secondly are formed in the lower end portion of the flexible substrate (FPCB) 100a. In addition to prolonging its service life, it is possible to prevent malfunction of the equipment due to heat.

The aluminum reflector 200 is formed in the same rod shape as the flexible substrate so that a plurality of LEDs 110 connected to the flexible substrate 100a are inserted and coupled in an upright shape, and reflects the plurality of LEDs along the circumference of the rod-shaped main body. Groove 210 is formed.

As shown in Figs. 1 and 2, it is composed of the same size (size) as the fluorescent lamp, and is formed in the same rod shape as the fluorescent lamp.

A plurality of LED reflecting grooves 210 are formed along the circumference of the rod-shaped body surface.

Here, as shown in Figure 1, the LED reflecting groove 210 is formed in a shape that gradually decreases in diameter from the top surface to the bottom surface, and the light is inserted into the internal reflection surface reflecting the light emitted by the LED is inserted. A plurality of bent lines to be reflected are formed.

As such, in the present invention, when the LED 110 of the flexible substrate 100a is inserted into the LED reflecting groove 210 in an upright position, the light emitted from the LED 110 forms the reflecting surface of the LED reflecting groove 210. Therefore, it can be reflected back to provide LED fluorescence having high efficiency.

In addition, the aluminum reflecting plate 200 according to the present invention, as shown in Figure 4, the PCB guide rail groove 250 is configured so that the plate-shaped PCB substrate module 400 is inserted into the semi-circular shape, both ends The fluorescent lamp electrode pin 10 is configured.

In addition, the plate-shaped PCB substrate module 400 is formed by arranging a plurality of LEDs 410 at the lower end, and a heat sink 420 is formed at the upper end to dissipate heat generated from the LEDs.

This is in order to be compatible with the plate-shaped PCB substrate module generally used in addition to the rod-like flexible substrate described above.

In addition, the aluminum reflector 200 used herein may be made of a transparent plastic material in addition to the aluminum material.

The magnetic auxiliary ballast module 300 is formed to be inserted in a circular shape between the end of the aluminum reflector 200 and the fluorescent electrode pin to block the start of the starter causing the initial discharge of the magnetic fluorescent lamp to form a plurality of flexible substrates It protects the LED.

It is composed of a high voltage organic prevention unit 310, rectifier 320, constant current control unit 330.

The high voltage organic prevention unit 310 is to block the operation of the start bulb when the fluorescent electrode pin is inserted into the fluorescent lamp socket, which is composed of a high voltage diode D1 and a high voltage diode D2, as shown in FIG. do.

The high voltage diode D1 blocks the clockwise current flowing through the input power supply, the magnetic ballast, and the fluorescent lamp electrode 1 toward the start light bulb, thereby blocking the operation of the start light bulb.

In addition, the high voltage diode D2 cuts off the counterclockwise current flowing toward the start light bulb through the input power supply and the fluorescent lamp electrode 2 on the right side to block operation of the start light bulb.

The rectifier 320 rectifies the input AC power into a DC power source capable of operating an LED, which is configured as a capacitor C1 as shown in FIG. 3.

Through this capacitor C1, AC power is converted into DC.

The constant current controller 330 controls the constant current to flow through the LED. As shown in FIG. 3, the constant current controller 330 includes a variable voltage regulator IC and a resistor R. Referring to FIG.

At this time, the current I flowing in the constant current controller is controlled to 1.25V ÷ R (resistance value). The user can determine the R value according to the rated current value of the LED.

Hereinafter, a specific operation process of the LED fluorescent lamp through the magnetic auxiliary ballast module according to the present invention will be described.

3 is a circuit diagram of a magnetic auxiliary ballast module according to the present invention.

First, the operation of the start bulb is blocked by blocking a clockwise current flowing through the input power source, the magnetic ballast and the fluorescent lamp electrode 1 from the high voltage diode D1.

Subsequently, in the high voltage diode D2, the counterclockwise current flowing through the input power supply and the fluorescent lamp electrode 2 on the right side is cut off to block the operation of the start bulb.

Subsequently, the capacitor C1 changes the AC power supply to the DC power supply.

Subsequently, in the constant current control circuit (Regulator), the current I flowing through the variable voltage regulator IC and the resistor R to the LED is controlled to 1.25V ÷ R (resistance value).

In the present invention, as shown in Fig. 3, when the LED fluorescent lamp is mounted on the fluorescent lamp socket in the configuration of D1, D2 symmetrical arrangement of the fluorescent lamp electrode 1 and short-circuit of the fluorescent lamp electrode 2, the left and right and up and down are reversed. It is configured to operate normally even if it is installed.

1 is a perspective view showing the components of the LED fluorescent lamp through the magnetic auxiliary ballast module according to the present invention,

2 is a front view showing the components of the LED fluorescent lamp through the magnetic auxiliary ballast module according to the present invention,

Figure 3 is an embodiment showing a circuit configuration of the magnetic auxiliary ballast module of the components of the LED fluorescent lamp through the magnetic auxiliary ballast module according to the present invention,

4 is a PCB guide rail groove 250 is configured to guide and insert the plate-shaped PCB substrate module 400 inside the aluminum reflector 200 according to the present invention, both ends of the fluorescent lamp electrode pin 10 is configured One embodiment also shows that.

※ Brief description of drawing code ※

100: flexible substrate (FPCB) 200: aluminum reflecting plate

300: magnetic auxiliary ballast module 310: high voltage organic prevention unit

320: rectifier 330: constant current controller

Claims (5)

In the LED fluorescent lamp (1) made of the same size and the same shape as the fluorescent lamp and connected to the fluorescent lamp socket and driven, The LED fluorescent lamp 1 includes a flexible substrate (FPCB) 100 in which a plurality of LEDs are arranged in a row in a plurality of LEDs along a rod-shaped periphery; An aluminum reflecting plate 200 formed in the same rod shape as the flexible board so that a plurality of LEDs connected to the flexible board are inserted and coupled in an upright shape, and a plurality of LED reflecting grooves are formed along the rod-shaped main body; Magnetic auxiliary ballast module 300 is formed so as to be inserted between the end of the aluminum reflector and the fluorescent electrode pin in a circular shape to block the start of the starter causing the initial discharge of the magnetic fluorescent lamp to protect the plurality of LED formed on the flexible substrate 300 LED fluorescent lamp through the magnetic auxiliary ballast module, characterized in that consisting of. The method of claim 1, Magnetic auxiliary ballast module 300 is When the fluorescent electrode pin is inserted into the fluorescent lamp socket high-voltage organic prevention unit 310 to block the operation of the start bulb,  Rectifier 320 for rectifying the input AC power to a DC power source that LED can operate; LED fluorescent lamp through the magnetic auxiliary ballast module, characterized in that consisting of a constant current control unit 330 to control the constant current flows through the LED. The method of claim 2, wherein the high-voltage organic prevention unit 310 A voltage diode D1 for blocking the operation of the start bulb by cutting off the current flowing through the input power supply and the electrode of one side of the magnetic ballast and the fluorescent lamp toward the start bulb; LED fluorescent lamp through the magnetic auxiliary ballast module, characterized in that the high voltage diode D2 for blocking the operation of the start bulb by blocking the current flowing to the start bulb through the other side of the input power and the fluorescent lamp. The flexible substrate (FPCB) 100 of claim 1, A flexible substrate (FPCB) 100a is formed with an insertion hole so that the chip LED is inserted along the circumference of the rod-shaped main body, and at the same time as supporting the rod-shaped flexible substrate at the bottom of the flexible substrate (FPCB) 100a An insulating pad portion 100b made of a rubber material to insulate is formed, and an aluminum heat dissipation plate for supporting the rod-shaped flexible substrate 100a and the rod-shaped insulating pad portion at the lower end of the insulating pad portion 100b and simultaneously insulating the second heat sink ( LED fluorescent lamp through the magnetic auxiliary ballast module, characterized in that formed 100c). According to claim 1, The aluminum reflector 200 is a PCB guide rail groove 250 is configured to guide the insertion of the plate-shaped PCB substrate module 400 therein, both ends of the fluorescent electrode pin 10 is configured LED fluorescent lamp through the magnetic auxiliary ballast module, characterized in that.

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