KR100844538B1 - LED lighting which can be used for fluorescent lamp socket with ballast - Google Patents

Abstract

The present invention is configured to supply the LED by converting the power of the ballast provided in the fluorescent lamp socket already installed in the DC power required by the LED can be used without removing the ballast from the fluorescent lamp socket already installed or installing a separate socket The present invention relates to an LED lighting lamp that can be used in a fluorescent lamp socket having a ballast.

The LED lighting lamp which can be used for the fluorescent lamp socket having a ballast of the present invention includes: a light emitting body comprising a plurality of LEDs connected to a substrate made of aluminum PCB in a lamp fitted to a fluorescent lamp socket having a ballast; A converter including a bridge rectifier circuit, which converts the output power of the ballast into a DC power source and supplies the light to the light emitting body; A heat sink for dissipating heat generated from the light emitting body by forming a substrate fixing groove in which the light emitting body is fixed, and a plurality of heat dissipating wings formed on the opposite surface thereof; A terminal cap connected to the converter and protruding from an electrode terminal fixed to both ends of the light emitting body and fitted into a fluorescent lamp socket; A front cover fixedly installed on the front surface of the heat sink to protect the LED and protecting the LED, and having a light diffusion irregularity on one surface to diffuse the light emitted from the LED; It is fixed to the back of the heat sink is characterized in that it comprises a back cover (6) to protect the user's hand from the heat of the heat sink when the user grabs the lamp.

Description

LED lighting for use with fluorescent lamp sockets with ballasts {LED lamp using the fluorescent socket with the ballast}

The present invention relates to a lamp, and in detail, by converting the power supply of the ballast provided in the fluorescent lamp socket already installed into a DC power required by the LED to supply to the LED by separating the ballast from the already installed fluorescent lamp socket or a separate socket The present invention relates to an LED lighting lamp that can be used in a fluorescent lamp socket having a ballast that can be used without installing a lamp.

In particular, the substrate on which the LED is installed is composed of aluminum PCB, and the heat sink is installed to enhance the heat dissipation effect. In addition, the substrate is separated into a plurality of fabricated and assembled and assembled into a fluorescent lamp socket having a ballast which is easy to manufacture. It is about LED lighting which we can use.

In addition, the present invention relates to an LED lighting lamp that can be used in a fluorescent lamp socket having a ballast that can easily adjust brightness by configuring a voltage reducing device such as a zener diode in place of the LED.

Compared to incandescent bulbs, there is less glare, high luminous efficiency, and long life, so one of the lighting fixtures used is fluorescent lamp.

This fluorescent lamp uses light from gas or gas discharge as a light source. A small amount of mercury vapor and argon gas for easy discharge are sealed in a vacuum glass tube, and then electrodes are attached to both ends.

The fluorescent lamp thus constructed has a high efficiency due to less loss due to heat and a long lifespan.

Such a fluorescent lamp is a kind of mercury discharge tube having negative resistance characteristics. When the power supply is only supplied, the fluorescent lamp is provided with a ballast to induce lighting and stably supply power after the lighting.

That is, a ballast was installed to initially apply a high discharge start voltage required for lighting a fluorescent lamp, and then a stable voltage and a current were supplied after lighting.

Fluorescent lamps configured as described above are constructed using a vacuum glass tube as described above, so that the manufacturing of the vacuum glass tube should be sufficiently sealed during manufacture, and there are many difficulties in manufacturing, and there is a case in which the lamp does not suddenly turn on and flickers when the life is near. The street had a problem.

In addition, since the light generated by the conventional fluorescent lamp includes ultraviolet light that fades or deteriorates, there is a problem of deteriorating food when used in a refrigerator or the like.

In addition, if the frequent switching operation is made, the life is drastically shortened, there is a problem that requires a lot of power consumption.

Accordingly, fluorescent lamps using LEDs have been developed and used. However, the circuit board constituting the fluorescent lamps using LEDs uses an insulator instead of a conductive metal. Such conventional LED fluorescent lamps have a very small effect of dissipating heat generated from LEDs. Due to the overheating in the sealed housing part by the heat generated from the LED during use, the deformation of the housing appearance and the efficiency of the LED is sharply lowered, thereby shortening the life of the LED fluorescent lamp.

The present invention has been invented to solve the problems of the prior art as described above, it is easy to manufacture by not requiring a vacuum, can reduce abrupt defects, there is no flicker at the end of life, in particular, conventional fluorescent lamps It is an object of the present invention to provide an LED lighting lamp for a fluorescent lamp socket having a ballast that can be installed in the socket.

Furthermore, the present invention not only prevents the deformation of the housing by efficiently dissipating heat generated from the LED, but also reduces the efficiency of the LED and reduces the efficiency of the LED. The purpose is to provide LED lighting that can be used.

In addition, it is possible to operate with less power to reduce the power consumption, and to provide an LED lighting lamp that can be used in the fluorescent lamp socket having a ballast that does not shorten the life even in frequent switching operations.

LED lighting can be used for a fluorescent lamp socket having a ballast for achieving the object of the present invention is a lighting lamp fitted in a fluorescent lamp socket having a ballast, comprising: a light emitting body configured by connecting a plurality of LEDs to a substrate made of aluminum PCB; A converter including a bridge rectifier circuit, which converts the output power of the ballast into a DC power source and supplies the light to the light emitting body; A heat sink for dissipating heat generated from the light emitting body by forming a substrate fixing groove in which the light emitting body is fixed, and a plurality of heat dissipating wings formed on the opposite surface thereof; A terminal cap connected to the converter and protruding from an electrode terminal fixed to both ends of the light emitting body and fitted into a fluorescent lamp socket; A front cover fixedly installed on the front surface of the heat sink to protect the LED and protecting the LED, and having a light diffusion irregularity on one surface to diffuse the light emitted from the LED; It is fixed to the back of the heat sink is characterized in that it comprises a rear cover to protect the user's hand from the heat of the heat sink when the user grabs the lamp.

The present invention is configured by arranging a plurality of LEDs do not require a vacuum, it is easy to manufacture, can reduce abrupt defects, there is an effect that can provide a lamp without flicker at the end of life.

In particular, since it can be installed in the existing fluorescent lamp socket can be used without replacing the socket has the effect of reducing the socket installation cost.

In addition, by configuring a plurality of LEDs constituting the lamp of the present invention as a pair and can be connected in parallel, as well as by configuring some LEDs can be replaced by a diode without a light emitting function such as zener diode light The brightness can be adjusted freely.

In addition, the power consumption can be reduced because it can be operated with less power, there is also an effect that can be used for a long time because the life is not shortened even in the frequent switching operation.

Hereinafter, with reference to the accompanying drawings, the LED lighting lamp according to the present invention will be described in detail.

1 is an exploded perspective view showing an example of the LED lighting lamp according to the invention, Figure 2 is a perspective view of the LED lighting lamp according to the invention, Figure 3 is a cross-sectional view of Figure 2, Figure 4 LED lighting according to the present invention 5 is a plan view showing one example of a substrate constituting the LED lighting lamp according to the present invention, Figure 6 is a plan view showing another example of the substrate constituting the LED lighting lamp according to the present invention; 7 is a circuit diagram of an LED lighting lamp according to the present invention.

As shown in the figure, an LED lighting lamp which can be used for a fluorescent lamp socket having a ballast according to the present invention includes a light emitting body 1 composed of a substrate on which an LED 12 is installed, and the light emitting body 1 includes a ballast 100. It is configured to include a means for supplying power to the bladder body (1) while being able to fit in one socket.

That is, the LED lighting lamp according to the present invention includes a light emitting body 1 configured by connecting a plurality of LEDs 12 to a substrate 11 made of aluminum PCB having excellent thermal conductivity; A converter (2) comprising a bridge rectifier circuit (2a) for converting the output power of the ballast (100) to DC power and supplying it to the light emitting body (1); On the surface facing the light emitting body 1 is formed a substrate fixing groove 31 to which the light emitting body 1 is fixed, and a plurality of heat dissipation wings 33 are formed on the opposite surface to emit heat generated from the light emitting body. A heat sink 3; A terminal cap 4 connected to a conversion circuit of the converter 2 and having protruding electrode terminals 41 fixed to both ends of the light emitting body 1 and fitted into a fluorescent lamp socket; The front cover is fixed to the front surface of the heat sink (3) to cover the front surface of the light emitting body (1) to protect the LED 12, the front cover is formed on one surface of the light diffusion irregularities 52 to diffuse the light emitted from the LED (5) and; It is fixed to the back of the heat sink 3 is configured to include a back cover (6) to protect the user's hand from the heat of the heat sink when the user is holding the lamp.

The light emitting body 1 is configured by installing a plurality of LEDs 12 on the bottom surface of the substrate 11, as shown in Figure 1, such a substrate 11 is separated into a plurality of Can be configured.

That is, the substrate 11 constituting the LED lighting lamp according to the present invention is composed of an aluminum PCB, as described above, by constituting the substrate from the aluminum PCB in this way, the heat generated during the light emission of the LED 12 faster heat dissipation By preventing the LED 12 from overheating, it is possible to prevent deformation of other components constituting the lamp.

In other words, in the case of the conventional LED lighting lamps, the substrate is used as an insulator, but insulators have a very small effect of dissipating heat generated from the LED. Therefore, when the LED lamp is continuously lit for a long time, the heat generated from the LED As the housing is overheated, the appearance of the housing is not only deformed, but the efficiency of the LED is sharply lowered, which shortens the life of the LED lights. However, when the aluminum PCB having high thermal conductivity is used as in the present invention, heat can be quickly released to the outside. Therefore, deformation of the housing and deterioration of the efficiency of the LED can be prevented by heat.

As illustrated in FIGS. 6 and 7, the substrate 11 has a circuit pattern 13 for supplying power to the LED 12.

In particular, the circuit pattern 13 constituting the LED lighting of the present invention, as shown, a plurality of LED blocks 10 are formed between the GND pattern and the Vcc pattern formed in the longitudinal direction along the edge of the substrate 11 It is composed.

The LED block 10 is a conductive pattern formed to connect a plurality of LEDs 12 (indicated by a thick dotted line in the drawing) in series with each other, and the number of LEDs may be connected in series with one or more than tens. The number of LEDs that can be connected in series can vary depending on the type or capacity of the fluorescent lamp socket, but can not be limited.

The reason why the substrate 11 is separated into a plurality of components as described above is that the lengths of the normal fluorescence are various and have a length of 1.2 m.

When manufacturing the LED lights that can be installed in the socket used for such a long fluorescent lamp, if the substrate 11 is manufactured in one, the overall length is too large and can be easily deformed, and there is a problem that the production itself is not easy. As shown in the drawing, a plurality of substrates 11 are separated and manufactured, and the parts to be connected are preferably integrated by soldering.

In order to electrically connect a plurality of separated substrates 11, a film cable or a general sheathed cable may be used, and the distance between the substrates may be narrowed, and then directly soldered only with lead so that the substrates may be electrically connected. have.

In addition, the substrate 11 made of aluminum PCB may enhance the efficiency by painting or coating the front part where the LED 12 is installed in a white or easily reflective color to reflect light to the outside.

In addition, between the LED blocks 10 of the circuit pattern 13 formed on the substrate 11, between the LED block 10 and the GND pattern, and between the LED block 10 and the Vcc pattern, the short circuit portion 13b is shorted. Was formed.

By forming the short circuit 13b and selectively energizing the short circuit 13b, the LED blocks 10 can be connected to each other in series or in parallel. The method of energizing the short circuit 13b is a film cable or a general method. A method such as connecting a shielded cable or spreading and spreading lead can be used. An electrical resistance of 0 ohm can be used.

The short circuit 13b is configured to selectively energize as described above to prevent the current and voltage output from the ballast from overriding the characteristics of the LED to reduce the life of the LED or to damage the LED. That is, it is to be able to selectively adjust the number of connections of the LED 12 in accordance with various kinds of ballasts.

In addition, the LED 12 installed in the light emitting body 1 configured as described above may adjust the light emission amount by installing a non-luminous zener diode 12a in place of the LED 12 as shown in FIG. 7.

That is, even when the place where the lighting is desired is not desired to be too bright, the power supplied from the ballast 100 is constant and should be consumed. In order to consume this, the zener diode 12a may be installed instead of the LED 12. Configure.

In this case, the necessary LEDs are placed first, and the zener diodes 12a corresponding to the number of insufficient LEDs or electronic components for reducing the voltage are replaced with the LED mounting positions so that the LEDs are turned on.

At this time, the zener diode and electronic parts used should be the same size or mountable size as SMD type LED. If there is no suitable part, other types of parts can be selected and used.

In addition, as shown in FIG. 7, the light emitting body 1 includes a first light emitting unit 1a and a second light emitting unit 1b connected in parallel to each other, and the light emitting units 1a and 1b and the ballasts respectively. The converters 2 may be connected to each other between the parts 100.

In this way, the first light emitting unit 1a and the second light emitting unit 1b are connected in parallel to form a single light emitting body 1 so that any one of the light emitting units may be broken by other light emitting units. .

The converter 2, which is a means for supplying power exclusively to the light emitting body 1 configured as described above, is installed inside the terminal cap 4 as shown in FIGS. 1 and 4, as shown in FIG. It is composed together.

In this way, the inside of the terminal cap (4) with the converter (2) is molded to protect the circuit by molding the coating material 42, as shown, the outer diameter of the exposed portion of the electrode terminal 41 is the light emitting body (1) ), The outer diameter of the part connected to the small is formed so that it can be easily plugged into the existing fluorescent lamp socket.

An end portion of the electrode terminal 41 extending inwardly of the terminal cap 4 is soldered 41a to be in an electrically connected state with the circuit configured in the converter 2.

As shown in FIG. 7, the converter 2 connects a resistor 2b in parallel to an input terminal of a bridge rectifying circuit 2a for converting alternating current supplied from the discharger 100 into a direct current, and a capacitor ( 2c) was configured in parallel.

The diode constituting the bridge rectifier circuit 2a is constructed using a high frequency diode.

In the case of electronic ballasts, 60Hz commercial power is output at high frequency (tens of KHz). After installing a fuse for overvoltage protection, the high-frequency current and voltage are passed through the fuse and converted to DC through the diode. When the general-purpose diode is used for a part of the diode used, heat is generated in the part. May occur and eventually break, and it is desirable to configure the diode for high frequency.

In order to stabilize the output of the converter 2, the capacitor 2c was further installed in parallel at the final stage of the DC conversion, that is, at the output of the bridge rectifying circuit 2a to stabilize the voltage.

In the above, the configuration of the light emitting main body 1, which is a main component of the LED lighting lamp of the present invention, and the converter 2, which is a power supply means, has been described below. The heat dissipation plate 3, which is a component for dissipating heat, and the two covers 5 and 6, which are protection means, will be described in detail.

The heat sink 3 serves to release heat from the light emitting body 1 to the outside and at the same time serves as a skeleton to maintain the shape of the light emitting body 1.

As shown in FIG. 1, the heat dissipation plate 3 is provided with a substrate fixing groove 31 on which the light emitting main body 1 rests, and a plurality of heat dissipating blades ( 33) is formed.

The surface of the heat dissipation wing 33 formed on the heat dissipation plate 3 may further form an unevenness 33a to increase the heat dissipation effect. That is, in order for the heat of the substrate 11 transferred to the heat sink 3 to be quickly transmitted to the outside beam, the heat dissipation area should be wide. Accordingly, a plurality of unevennesses 33a are formed on the outer surface of the heat dissipation wing 33. The heat dissipation area is widened.

In addition, the heat sink 3 is fixed to the front cover 5 and the rear cover 6 as described above, and the structure for fixing the two covers (5, 6), both edges of the heat sink (3) The engaging portion 35 is formed in the heat sink insertion grooves 53 formed at both edges of the front cover 5 are fitted and coupled.

In addition, the end of the heat dissipation blade formed in a perpendicular to the body portion of the heat dissipation blade 33 formed on the rear surface of the heat dissipation plate 3 as a means for fixing the back cover 6 is formed in the center of the back cover 6 A locking blade 36 fitted into the heat sink insertion groove 63 is formed.

After the end of the heat sink insert groove 53 formed in the front cover 5 is opposite to the end of the catch portion 35 formed in the heat sink 3, the front cover is pushed so that the catch portion 35 is the heat sink insert groove ( 53) to be fixed, and the end of the locking blade 36 is opposed to the end of the heat sink insertion groove 63 formed in the rear cover 6, and then the rear cover is pushed so that the locking blade 36 is the heat sink insertion groove 63. The heat sink 3 and the two covers 5 and 6 are coupled to each other.

Although the light diffusion concave-convex 52 formed on the front cover 5 is formed on the inner surface of the front cover 5 as shown in one example, it may be formed on the outer surface, the light diffusion concave-convex 52 is an LED There is an effect to diffuse the light irradiated at (12) to make it look brighter.

The light diffusion concave-convex 52 may be formed long in the longitudinal direction of the cover 5 in an arc shape as shown, but may be formed by densely forming hemispherical protrusions.

The rear cover 6 covers the outer surface of the heat sink 3 to prevent the heated heat sink 3 from coming into contact with the human body, and when the entire heat sink 3 is covered, the heat dissipation effect of the heat sink 3 is prevented. Since it can be lowered as shown in Figures 1 and 3 was installed so as to cover only a part of the heat sink (3).

1 is an exploded perspective view showing an example of an LED lighting lamp according to the present invention,

2 is a perspective view of an LED lighting lamp according to the present invention,

3 is a cross-sectional view taken along line A-A of FIG.

4 is a cross-sectional view of a socket constituting the LED lighting according to the present invention,

5 is a plan view showing an example of a substrate constituting the LED lighting lamp according to the present invention,

6 is a plan view showing another example of the substrate constituting the LED lighting lamp according to the present invention,

7 is a circuit diagram of an LED lighting lamp according to the present invention.

<Description of the symbols for the main parts of the drawings>

1: light emitting body

  10: LED block

  1a: first light emitting unit 1b: second light emitting unit

  11: substrate

  12: LED

  13 Circuit Pattern 13a LED Connection 13b Short Circuit

2: converter

  2a: bridge rectifier circuit 2b: resistor 2c: capacitor

3: heat sink

  31: substrate fixing groove

  33: heat dissipation wing 33a: irregularities

  35: hanging part

  36: hanging wing

4: Terminal cap

  4a: main body insertion part 4b: narrow part

  41: electrode terminal 41a: soldering

  42: coating material

5: Front cover

  52: uneven diffused light 53: heat sink insertion groove

6: back cover

  63: heat sink insertion groove

Claims (6)

In a lamp fitted to a fluorescent lamp socket having a ballast 100, A light emitting body 1 configured by connecting a plurality of LEDs 12 to a substrate 11 made of aluminum PCB having excellent thermal conductivity; A converter (2a) comprising a bridge rectifier circuit (2a) composed of a high frequency diode and converting the output power of the ballast (100) into a DC power supply to the light emitting main body (1); On the surface facing the light emitting body 1 is formed a substrate fixing groove 31 to which the light emitting body 1 is fixed, and a plurality of heat dissipation wings 33 are formed on the opposite surface to emit heat generated from the light emitting body. A heat sink 3; A terminal cap 4 connected to a conversion circuit of the converter 2 and having protruding electrode terminals 41 fixed to both ends of the light emitting body 1 and fitted into a fluorescent lamp socket; The front cover is fixed to the front surface of the heat sink (3) to cover the front surface of the light emitting body (1) to protect the LED 12, the front cover is formed on one surface of the light diffusion irregularities 52 to diffuse the light emitted from the LED (5) and; LED fixedly installed on the back of the heat sink (3) includes a back cover (6) to protect the user's hand from the heat of the heat sink when the user grabbed the lamp, can be used in the fluorescent lamp socket having a ballast Lighting. The method of claim 1, The surface of the heat dissipation wing (33) formed in the heat dissipation plate (3) is LED lighting lamp that can be used in a fluorescent lamp socket having a ballast characterized in that the concave-convex (33a) is further formed to increase the heat dissipation effect. The method according to claim 1 or 2, Engaging portions 35 are formed at both edges of the heat sink 3 so as to be fitted into the heat sink insertion grooves 53 formed at both edges of the front cover 5. A locking blade 36 fitted to the heat sink insertion groove 63 formed at the center of the rear cover 6 at an end of the heat radiation wing formed perpendicular to the body part of the heat radiation wing 33 formed on the rear surface of the heat sink 3. LED lighting lamp that can be used in the fluorescent lamp socket having a ballast characterized in that it is further formed. The method of claim 3, wherein The light emitting body 1 has a first light emitting unit 1a and a second light emitting unit 1b connected in parallel with each other, and each converter 2 between the light emitting unit 1a and 1b and the ballast 100 respectively. Is connected, The substrate 11 is composed of a plurality of separated, the circuit pattern 13 formed on each separated substrate is formed by forming a plurality of LED block 10 pattern between the GND pattern and Vcc pattern formed in the longitudinal direction of the substrate However, a short circuit portion 13b is formed between the LED block 10 pattern, the GND pattern, and the Vcc pattern, so that the short circuit portion 13b can be selectively energized. LED lighting that can be used. The method of claim 4, wherein The LED block 10 can be used in a fluorescent lamp socket having a ballast, characterized in that the non-emitting zener diode (12a) is further installed. The method of claim 5, wherein Resistor 2b is connected in parallel to the input terminal of the bridge rectifier circuit 2a of the converter 2 including the bridge rectifier circuit 2a, and the output terminal is further connected in parallel with the capacitor 2c. LED lighting lamp which we can use for fluorescent lamp socket having ballast.

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