KR101248490B1 - Board for LED type lighting device having function of electromagnetic interference shielding - Google Patents

Abstract

The present invention relates to a substrate for a light emitting diode type lighting device having an electromagnetic wave shielding function, and more particularly, to a light emitting diode type lighting device substrate having a configuration in which one or more LEDs are installed on an upper surface of a substrate having a positive / negative polarity power supply pattern. To install the transparent dome-type electromagnetic inlet shield in the form of wrapping the LED, the ground pattern is formed around the LED installed on the substrate, the discharge electrode layer is formed on the bottom of the dome-type electromagnetic inlet block to block the induction of electromagnetic wave The discharge electrode layer of the sphere is maintained in electrical contact with the ground pattern of the substrate, the dome type electromagnetic inlet block is formed by forming a transparent polyester film in a dome shape, and coated with a transparent conductive paint on the inner and bottom surfaces of the electromagnetic wave organic With transparent conductive coating layer for transparent and electrode layers for transparent discharge It characterized.
Therefore, it is possible to discharge various kinds of electromagnetic energy generated around the lighting equipment through the dome-type electromagnetic inflow blocking and discharge and bypass it through the ground pattern of the substrate. The internal leads or contacts themselves of LEDs installed on the board can be prevented from being melted and damaged, which can greatly prolong the life of the LED itself, as well as a large transmit / receive antenna that continuously radiates high electromagnetic energy. It is possible to install and use a light emitting diode type lighting device around the lamp, which can prevent unnecessary power waste and economic loss, as well as greatly improving the reliability of the light emitting diode type lighting device.

Description

Board for LED type lighting device having function of electromagnetic interference shielding}

The present invention relates to a substrate for a light emitting diode-type lighting device having an electromagnetic shielding function, and more particularly, to an inner surface of the transparent polyester film in a form of covering a light emitting diode (hereinafter referred to as "LED") installed on the substrate for the lighting device. A dome type electromagnetic inlet blocking device coated with a transparent conductive coating layer for electromagnetic wave organic matter is installed on the inside to prevent the internal lead or the contact point of the LED from being melted and broken by excessive electromagnetic energy generated around the lighting equipment. It is invented to extend the life significantly.

In general, a light-emitting diode (LED) is made of a structure called a PN junction using a semiconductor, and light emission requires macroscopic heat or kinetic energy because the energy of electrons in the PN junction is directly converted into light energy. The electrons and holes injected from the electrode into the semiconductor flow through different energy bands (conducting bands or valence bands) and recombine over the band gap near the PN junction. Emitted as light.

These LEDs also have the same polarity as other diodes in terms of electrical characteristics, and are used by applying a constant voltage from the cathode (cathode) to the anode (anode). I don't even. However, when a voltage is higher than a certain voltage, current flows rapidly in response to a voltage rise, and light is generated in proportion to the amount of current. This voltage is called a forward drop voltage, and a light emitting diode has a higher forward drop voltage as compared with a general diode.

In addition, depending on the emission color, it is about 2.1V in red, orange, yellow, and green, about 1.4V for not emitting red, about 3.5V for white and blue, and about 5V for high-output products. Although the current consumption is about several mA to 50 mA in the light application, a large output light emitting diode with a power consumption of several W units is also sold in the lighting application, and some products have a driving current exceeding 1 A.

When the voltage is applied in the reverse direction, the withstand voltage is lower than that of a general silicon diode, and is usually about -5 V. If it exceeds this, the device is destroyed and cannot be used for rectification.

In addition, unlike most other light sources such as fluorescent and incandescent light, the optical characteristics can be easily obtained light that does not contain unnecessary ultraviolet or infrared light, so it is widely used for lighting sensitive cultural assets, works of art, or objects that are reluctant to be irradiated. Because of the fast response to the input voltage, it is also used for communication, and when used as lighting, the maximum light intensity can be obtained as soon as it is turned on.

In addition, the physical properties are simple, mass production is possible and inexpensive, and because it does not use filament like a bulb, it is small, strong in vibration and has a long life, so it is unlikely to break down. There is a risk of adversely affecting.

In addition, the light intensity of LED is determined according to the amount of current, and if it exceeds the maximum rated current, the life is shortened and the device is damaged and cannot be used.When driving at constant voltage, the forward drop voltage due to the device gap or device temperature is fluctuated. As the current also changes, it is recommended to use a method of controlling the amount of current, and the method of limiting the direct current by connecting a resistor or a constant current diode in series using a DC power supply that generates a voltage higher than the forward drop voltage of the light emitting diode is well practiced. Because of its polarity, it does not emit light when the anode and the cathode are applied in reverse, and the reverse withstand voltage is low and easy to be destroyed.

On the other hand, as mentioned above, various lighting apparatuses using light emitting diodes (LEDs) with low power consumption and long lifespan as light sources have been developed and released.

Such a light emitting diode (LED) has a junction structure of a P-type and an N-type semiconductor as described above, and when a voltage is applied, the light emitting diode (LED) emits light of energy corresponding to a bandgap of the semiconductor by coupling electrons and holes. It is an optoelectronic device, the reaction time is faster than the general bulb, the power consumption is low to 20% level has been utilized in various fields including high efficiency lighting means in recent years.

Such light emitting diodes are used as a light source in a light fixture using a module assembled with a plurality of high-brightness light emitting diodes or power light emitting diodes on a substrate, and is used for lighting or lighting of street lamps, signs, structures, bridges, etc. It is used as a means of lighting such as a fountain.

In addition, the lighting device using the light emitting diode as described above, and the band and the shape of the band to be used as a general lighting lamp by placing one or more light emitting diodes on a printed circuit board formed in a variety of shapes including a disk shape. Various types of light emitting diodes, such as a line bar type in which a plurality of light emitting diodes are arranged at a predetermined interval, are used in a solid or flexible printed circuit board.

In the former case, the former is widely used for general lighting, traffic lights, street lights, security lights, etc., and the latter case is widely used for lighting of high-rise buildings, bridges, overpasses, and advertisements.

By the way, such LED has a disadvantage in absorbing electromagnetic energy, and usually protects against electromagnetic energy by connecting a protection resistor or current limiter, but excessive electromagnetic energy (GHz band) energy in a range that cannot be protected by such resistance or current limiter. When exposed to, the lead or contact itself inside the LED melts and breaks regardless of whether a load resistor or current limiter is installed and whether current is supplied.

For example, a test that puts several LEDs in a microwave oven and starts the microwave shows that the LED itself bursts with a spark within 3-5 seconds, or the internal lead or contact itself melts, resulting in a loss of time. there was.

In particular, when the lighting device using the light emitting diode is installed near a large transmitting / receiving antenna installed in a broadcasting station or a large ship or military base antenna base where a large amount of electromagnetic radiation is generated, high electromagnetic energy continuously radiated from a large transmitting / receiving antenna, etc. As a result, the lifespan of the light emitting diode type lighting device itself becomes very short, and thus, it is impossible to install and use a lighting device composed of light emitting diodes in such a place.

The present invention has been made in order to solve such a conventional problem, a domed electromagnetic wave formed by forming a ground pattern around the LED installed on the substrate for lighting equipment, and coated with a transparent conductive coating layer for electromagnetic waves on the inner surface of the transparent polyester film The inlet shield is installed in the form of wrapping the LED, but the discharge electrode layer coated on the periphery of the bottom surface of the dome type electromagnetic inlet shield is installed in the form of contact with the ground pattern formed on the substrate for the lighting device, thereby generating around the lighting device. Internal leads of LEDs installed on LED boards can be discharged and bypassed through the ground of the substrate by inducing the electromagnetic energy through the dome-type electromagnetic inlet block. Or the contacts themselves melt It is possible to prevent it from happening in advance, which can greatly extend the life of the LED itself, and it is also possible to install a light emitting diode-type lighting device around a large transmitting / receiving antenna that emits high electromagnetic wave energy. It is an object of the present invention to provide a substrate for a light emitting diode-type lighting device having an electromagnetic shielding function that can prevent power waste and economical loss.

The present invention for achieving the above object, in the substrate for a light emitting diode type lighting device having a configuration in which one or more LED is installed on the upper surface of the substrate provided with a positive / negative power supply pattern, transparent in the form surrounding the LEDs A dome type electromagnetic wave inlet is installed, but the ground pattern is extended around the LED installed on the substrate, and a discharge electrode layer is formed on the bottom of the dome type electromagnetic inlet. It is characterized in that to maintain the electrical contact with the pattern.

At this time, the dome-shaped electromagnetic wave inlet is formed by forming a transparent polyester film in a dome shape, and coated with a transparent conductive paint on the inner and bottom surfaces to form a transparent conductive coating layer for electromagnetic waves and an electrode layer for transparent discharge.

In addition, a disk-shaped discharge electrode layer molded plate is further formed on the periphery of the dome-shaped electromagnetic wave inflow blocking port.

In addition, the dome type electromagnetic inlet block is characterized in that installed to individually wrap each of the LEDs installed on the substrate.

In addition, the dome type electromagnetic wave inlet is molded using a transparent polyester film having an area and a shape corresponding to the area and the planar shape of the substrate, and the dome type electromagnetic waves are respectively located at positions corresponding to the positions of the LEDs installed on the substrate. It is characterized in that the inlet blocks are integrally formed and integrally installed on the upper surface of the substrate on which several LEDs are installed.

In this case, the transparent conductive paint is characterized in that the indium tin oxide (ITO).

In addition, the dome type electromagnetic wave inlet is fixed to the upper surface of the substrate through the conductive adhesive so that the electromagnetic wave organic transparent conductive coating layer and the discharge electrode layer of the dome type electromagnetic wave inlet is electrically connected to the ground pattern of the substrate through the conductive adhesive. It is characterized by.

In addition, an insulating paint layer is coated on the upper surface of the positive / negative polarity power supply pattern except for the ground pattern which extends around the LED of the substrate and contacts the electrode layer for discharge of the dome type electromagnetic inlet blocking device.

As described above, according to the present invention, the LED is formed by extending a ground pattern around the LED installed on the substrate for lighting equipment, and applying a dome type electromagnetic inlet blocking device coated with a transparent conductive coating layer for electromagnetic wave on the inner surface of the transparent polyester film. It is installed in the form of enclosing, by installing a discharge electrode layer coated in the peripheral portion of the bottom surface of the dome-type electromagnetic inlet shield in contact with the ground pattern formed on the substrate for the lighting device, dome-shaped various electromagnetic energy generated around the lighting device It can be discharged and bypassed through the ground pattern of the substrate by inducing through the electromagnetic inflow blocking, so that the internal leads or the contacts of the LEDs installed on the light emitting diode-type lighting equipment by the excessive electromagnetic energy radiated from around the lighting equipment To melt and break As it prevents, the lifespan of LED itself can be greatly extended, and light emitting diode-type lighting equipment can be installed and used around large transmitting / receiving antennas where high electromagnetic wave energy is continuously emitted. Phosphorus loss can be prevented and of course, the reliability of the light emitting diode type lighting device can be greatly improved.

1 is an exploded perspective view according to an embodiment of the present invention.
Figure 2 is an exploded perspective view according to another embodiment of the present invention.
Figure 3 is an exploded perspective view according to another embodiment of the present invention.
Figure 4 (a)-(c) is an enlarged cross-sectional view of the main portion of the coupling state of each embodiment of the present invention.
5 is a perspective view showing an embodiment of a lighting device to which the substrate of the present invention is applied.

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

1 is an exploded perspective view according to an embodiment of the present invention, Figure 2 is an exploded perspective view according to another embodiment of the present invention, Figure 3 is an exploded perspective view according to another embodiment of the present invention 4 (a)-(c) show enlarged cross-sectional views of main parts of the coupling state of each embodiment of the present invention, and FIG. 5 shows a perspective view showing an embodiment of a lighting device to which the substrate of the present invention is applied.

According to the present invention,

In the substrate for light-emitting diode type lighting equipment having a configuration in which one or more LEDs 2 are provided on the upper surface of the substrate 1 with the positive / negative polarity power supply patterns 11 and 12,

A transparent dome type electromagnetic wave inlet 3 is installed to surround the LEDs 2, but a ground pattern 12a is formed around the LED 2 installed on the substrate 1 to extend the dome type electromagnetic wave inlet. A discharge electrode layer 32 is formed on the bottom of the block 3 so that the discharge electrode layer 32 of the dome type electromagnetic inlet block 3 is in electrical contact with the ground pattern 12a of the substrate 1. It is characterized by maintaining.

At this time, the dome type electromagnetic inlet block 3,

The transparent polyester film 30 is molded into a dome shape, and a transparent conductive paint is coated on the inner surface and the bottom thereof to form an electromagnetic wave organic transparent conductive coating layer 31 and a transparent discharge electrode layer 32.

In addition, a disk-shaped discharge electrode layer shaping plate 33 is further formed in the peripheral portion of the dome type electromagnetic wave inlet 3.

In addition, the dome type electromagnetic inlet block 3,

It is characterized in that it is installed so as to individually wrap each of the LED (2) installed on the substrate (1).

In addition, the dome type electromagnetic wave inlet block 3,

Molded using a transparent polyester film 30 having an area and a shape corresponding to the area and planar shape of the substrate 1, but at a position corresponding to the position of the LEDs 2 installed on the substrate 1 Each of the dome-shaped electromagnetic wave inlet shield 3 is integrally formed and integrally installed on the upper surface of the substrate 1 on which several LEDs 2 are installed.

In this case, the transparent conductive paint is characterized in that the indium tin oxide (ITO).

In addition, the dome type electromagnetic wave inlet 3 is fixed to the upper surface of the substrate 1 through a conductive adhesive 4 to the transparent conductive coating layer 31 for electromagnetic wave organic radiation of the dome type electromagnetic wave inlet 3. The exclusive electrode layer 32 is characterized in that it is electrically connected to the ground pattern 12a of the substrate 1 through the conductive adhesive (4).

In addition, the positive / negative power supply pattern is formed except the ground pattern 12a which extends around the LED 2 of the substrate 1 and is in contact with the discharge electrode layer 32 of the dome type electromagnetic wave inlet 3. 11) An insulating paint layer 13 is applied to the upper surface of the film.

Referring to the effects of the light emitting diode-type lighting device substrate having an electromagnetic shielding function of the present invention configured as described above are as follows.

First, an embodiment of a substrate for a light emitting diode type lighting device having an electromagnetic shielding function of the present invention is one on the upper surface of the substrate 1 having the positive / negative polarity power supply patterns 11 and 12 as shown in FIG. 1. In the substrate for a light emitting diode-type lighting equipment having a configuration in which the above-described LED (2) is provided, the transparent dome-shaped electromagnetic wave inlet shield (3) in the form of surrounding the LED (2) installed on the substrate (1) is installed in the vicinity of the lighting equipment Various electromagnetic energy generated through the dome-type electromagnetic wave inlet block (3) described above is discharged around the lighting device in such a way that it can be discharged and bypassed through the ground pattern (12a) of the substrate (1) Note that it is possible to prevent the internal leads or the contacts themselves of the LEDs 2 installed on the light emitting diode type lighting equipment substrate 1 from being melted and damaged by excessive electromagnetic wave energy. The technology component.

At this time, the ground pattern 12a connected to the negative power supply pattern 12 is further formed around the LED 2 installed on the substrate 1, and the bottom surface of the dome type electromagnetic wave inlet 3 The dome-type electromagnetic wave is formed by forming a discharge electrode layer 32 so that the discharge-electrode layer 32 of the dome-shaped electromagnetic wave inlet 3 is in electrical contact with the ground pattern 12a of the substrate 1. Various electromagnetic wave energy induced through the inlet block 3 may be discharged and bypassed through the ground pattern 12a of the substrate 1.

On the other hand, the domed electromagnetic wave inlet 3 is formed in a dome shape of the transparent polyester film 30 having a predetermined thickness, as shown in Figure 1, indium tin oxide (Indium) which is a transparent conductive paint on the inner and bottom surfaces Tin Oxide (ITO) is coated to a predetermined thickness to form a transparent conductive coating layer 31 for electromagnetic wave organic and an electrode layer 32 for transparent discharge.

In this case, the dome type electromagnetic wave inlet 3 itself is an electromagnetic wave organic coating coated using indium tin oxide (ITO), which is a transparent conductive paint, inside the transparent polyester film 30 molded to have a dome shape as described above. Irrespective of the transparent conductive coating layer 31 and the transparent electrode layer 32 for transparent discharge, the light is irradiated from the LED 2 installed on the substrate 1 for the lighting device. Since it passes through as it is irradiated to the outside through a lens (not shown) does not affect the illuminance of the light emitting diode-type lighting equipment.

On the other hand, since the transparent polyester film that is the main body of the dome-shaped electromagnetic wave inlet 3 has a relatively thin thickness, the transparent discharge electrode layer 32 is the bottom surface of the dome-shaped electromagnetic wave inlet 3, that is, transparent When coating on the end face of the polyester film as it is, the contact area with the ground pattern 12a extended to the substrate 1 is very small, there is a possibility that the electromagnetic energy can not be bypassed smoothly.

Accordingly, in the present invention, as in the other embodiment shown in FIG. 2, the disk-shaped discharge electrode layer forming plate 33 is further formed at the periphery of the dome-shaped electromagnetic wave inlet 3 and the transparent surface is formed on the bottom thereof. By coating the discharge electrode layer 32, the area where the ground pattern 12a extended to the substrate 1 and the transparent discharge electrode layer 32 of the dome type electromagnetic wave inlet 3 is very wide. Various electromagnetic wave energy induced through the electromagnetic wave organic transparent conductive coating layer 31 of the dome type electromagnetic wave inlet block 3 smoothly into the ground through the transparent discharge electrode layer 32 and the ground pattern 12a of the substrate 1. It can be discharged and bypassed.

In addition, in the present invention, the dome type electromagnetic wave inlet blocking device as shown in FIGS. 1, 2, and 4 (a) (b) corresponds to the number of LEDs 2 installed on the substrate 1 of the lighting device, or the installation form thereof. 3) It is also possible to manufacture itself to be installed so as to surround each LED (2) installed on the substrate 1, and also the area and planar shape of the substrate 1 as shown in Figs. 3 and 4 (a) Molded using a transparent polyester film 30 having an area and a shape corresponding to the dome-shaped electromagnetic wave inlet shield (3) at positions corresponding to the positions of the LEDs (2) installed on the substrate (1), respectively ) May be integrally molded and integrally installed on the upper surface of the substrate 1 on which several LEDs 2 are installed.

At this time, when the dome type electromagnetic wave inlet 3 is simply installed on the upper surface of the substrate 1 in the form of wrapping the LEDs 2, the dome type electromagnetic wave inlet 3 itself is not fixed to the upper surface of the substrate is flowed There is a fear that the electrode layer 32 for discharge of the dome type electromagnetic wave inlet 3 is not in electrical contact with the ground pattern 12a of the substrate 1.

Therefore, in the present invention, when the dome-shaped electromagnetic wave inlet 3 is installed on the upper surface of the substrate 1 in a form to surround each of the LEDs 2, the room is coated on the periphery of the bottom surface of the dome-shaped electromagnetic wave inlet 3 A conductive adhesive 4 is applied between the dedicated electrode layer 32 and the ground pattern 12a of the substrate 1 so that the transparent conductive coating layer 31 for electromagnetic waves and the electrode layer 32 for discharge are ground patterns of the substrate 1. The dome type electromagnetic wave inlet 3 itself was fixed to the substrate 1 while being electrically connected to the substrate 12 by the conductive adhesive 4.

Therefore, it is possible to prevent the flow of the domed electromagnetic wave inlet 3 itself, as well as the transparent conductive coating layer 31 and the transparent discharge electrode layer 32 for the electromagnetic wave of the dome-shaped electromagnetic wave inlet 3 is a conductive adhesive (4) maintains a state of being electrically connected to the ground pattern (12a) of the substrate (1) through a variety of electromagnetic energy induced through the transparent conductive coating layer 31 for electromagnetic wave organic electromagnetic inlet of the dome-type electromagnetic inlet (3) Through the transparent discharge electrode layer 32, the conductive adhesive 4 and the ground pattern 12a of the substrate 1 can be smoothly discharged and bypassed to the ground.

On the other hand, the positive / negative power supply pattern (except the ground pattern 12a which is formed to extend around the LED 2 of the substrate 1 and is in contact with the discharge electrode layer 32 of the dome type electromagnetic inlet shield 3) 11) The positive / negative polarity formed on the substrate 1 by the discharge electrode layer 32 of the dome-shaped electromagnetic wave inlet 3 which is conductive by applying an insulating paint layer 13 to the upper surface of the 12. It is possible to prevent closed ends such that the power supply patterns 11 and 12 are mutually shorted.

Lighting device for the light emitting diode-type lighting equipment of the present invention having an electromagnetic shielding function as described above is installed in the vicinity of a large transmitting / receiving antenna in places such as broadcasting stations or large vessels and military base antenna bases that generate a lot of electromagnetic radiation energy (e.g., For example, when applied to a lighting device of the type shown in Figure 5, the high electromagnetic wave energy continuously radiated from a large transmit / receive antenna, etc. through the dome-type electromagnetic wave inlet block 3 as described above to the substrate (1) It can be discharged and bypassed to the ground through the ground pattern 12a of the LED, so that the internal leads or the contacts themselves of the LEDs installed on the LED-type lighting equipment substrate are melted and broken by excessive electromagnetic energy radiated from around the lighting equipment. Can be prevented beforehand, greatly extending the life of the LED itself. Rather, the reliability of driving the light emitting diode-type lighting device is greatly improved.

It should be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

1: substrate
11, 12: Positive / Negative Power Supply Pattern
12a: grounding pattern 13: insulating paint layer
2: LED
3: dome type electromagnetic inlet
30: transparent polyester film
31: transparent conductive coating layer for electromagnetic wave organic
32: electrode layer for discharge 33: electrode layer molded plate for discharge
4: conductive adhesive

Claims (8)

A light emitting diode type lighting device substrate having a configuration in which one or more LEDs are provided on an upper surface of a substrate provided with a positive / negative polarity power supply pattern.
A transparent dome type electromagnetic inlet blocking device is installed to surround the LEDs, but a ground pattern is extended around the LED installed on the substrate, and a discharge electrode layer is formed on a bottom of the dome type electromagnetic inlet blocking device. The electrode layer for discharging is kept in electrical contact with the ground pattern of the substrate,
The dome type electromagnetic inlet block,
For a light emitting diode type lighting device having an electromagnetic shielding function, the transparent polyester film is formed into a dome shape, and a transparent conductive paint is coated on the inner surface and the bottom surface to form a transparent conductive coating layer for electromagnetic wave induction and an electrode layer for transparent discharge. Board.
delete The method according to claim 1,
A substrate for a light emitting diode-type lighting device having an electromagnetic shielding function, characterized in that a disk-shaped discharge electrode layer forming plate is further formed on the periphery of the dome type electromagnetic wave inlet blocking port.
A light emitting diode type lighting device substrate having a configuration in which one or more LEDs are provided on an upper surface of a substrate provided with a positive / negative polarity power supply pattern.
The dome-type electromagnetic inlet shield is formed to surround the LEDs, but the ground pattern is extended around the LED installed on the substrate, and a discharge electrode layer is formed on the bottom of the dome-type electromagnetic inlet shield. The electrode layer for discharging is kept in electrical contact with the ground pattern of the substrate,
The dome type electromagnetic inlet block,
A substrate for a light emitting diode type lighting device having an electromagnetic shielding function, characterized in that it is installed to individually wrap each of the LEDs installed on the substrate.
A light emitting diode type lighting device substrate having a configuration in which one or more LEDs are provided on an upper surface of a substrate provided with a positive / negative polarity power supply pattern.
The dome-type electromagnetic inlet shield is formed to surround the LEDs, but the ground pattern is extended around the LED installed on the substrate, and a discharge electrode layer is formed on the bottom of the dome-type electromagnetic inlet shield. The electrode layer for discharging is kept in electrical contact with the ground pattern of the substrate,
The dome type electromagnetic inlet block,
Molded by using a transparent polyester film having an area and a shape corresponding to the area and the planar shape of the substrate, by integrally molding the dome-shaped electromagnetic inlet shields respectively at a position corresponding to the position of the LEDs installed on the substrate A substrate for light emitting diode type lighting equipment having an electromagnetic shielding function, which is integrally provided on an upper surface of a substrate on which several LEDs are installed.
The method according to claim 1,
The transparent conductive paint is an indium tin oxide (ITO) substrate for light emitting diode type lighting equipment having an electromagnetic shielding function.
The method according to claim 1,
The dome type electromagnetic inlet block,
It is fixed to the upper surface of the substrate through a conductive adhesive, the electromagnetic shielding function characterized in that the transparent conductive coating layer for electromagnetic wave organic discharge and the electrode layer for discharge of the dome type electromagnetic inlet shield is electrically connected to the ground pattern of the substrate through the conductive adhesive. A light emitting diode type lighting device substrate.
The method according to claim 1,
Light emission having an electromagnetic shielding function, which is formed around the LED of the substrate and is coated with an insulating paint layer on the upper surface of the positive / negative polarity power supply pattern except for the ground pattern which is in contact with the discharge electrode layer of the dome type electromagnetic inlet blocking device. Substrate for diode type lighting equipment.

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