KR102377627B1 - Lens Type Flexible LED Strip Lighting, Apparatus Of Fabricating The Same And Method Of Fabricating The Same - Google Patents

Abstract

The present invention, a tray; a printed circuit board disposed inside the tray; an LED light source disposed on the printed circuit board; a support disposed on the printed circuit board around the LED light source; a lens disposed on the LED light source; a reflective cup surrounding the LED light source and the lens; It provides a lens-attached flexible LED strip lighting including a filler disposed on the printed circuit board inside the tray except for the portion surrounded by the support and the reflective cup.

Description

Lens Type Flexible LED Strip Lighting, Apparatus Of Fabricating The Same And Method Of Fabricating The Same}

The present invention relates to a lens-attached flexible LED strip lighting, and in particular, a flexible LED strip lighting having a waterproof function by aligning various types of lenses on the upper part of the LED light source, and injecting a silicone filler to seal and harden it. It relates to a manufacturing process and a mechanical device for performing the process.

Conventional technology is a general flexible LED strip lighting in which the radiation angle of the light source spreads at a certain angle as a product without a lens on the upper part of the LED light source, and a bar-type LED strip with a rigid lens such as polycarbonate (PC) or glass attached to the upper part of the LED There are lights.

1 and 2 are photographs showing conventional flexible LED strip lighting and bar-type LED strip lighting, respectively.

1 and 2, in the flexible LED strip lighting without a lens, the radiation angle of the light source cannot be adjusted and the light efficiency is low, and the rigid lens consistency is destroyed in the rod-type LED strip lighting with a lens. There are disadvantages in that the degree of flexible bending in the normal direction is limited and the volume of the finished product is increased because it is difficult to reduce the size of the component. In addition, a lenticular lens array cover or a diffuser plate cover is placed on top of the LED light source to obtain uniform light. In this case, it has an inflexible mechanism structure. That is, there is a disadvantage in that the high cost, bulky, and rigid rod-shaped configuration is inevitable, so the mobility for manufacturing long products is also poor.

As such, in the case of the conventional flexible LED strip lighting, although there is flexibility, there is a difficulty in changing the radiation angle of the light source or maximizing the light efficiency due to the absence of a lens. And, in the case of the conventional bar-type LED strip lighting, it is possible to adjust the light efficiency and the radiation angle by attaching a lens to the light source. There is a difficulty in that there is no flexibility to bend it or give it a left and right movement. In addition, the structure of the finished product is complicated and there are restrictions on miniaturization due to the complex structure and size of the lens, which is an optical unit, and the light source shape of the LED device in the package type.

In the present invention, as a solution to these problems or limitations, 1) a soft silicone lens is employed, 2) a lens of various structures such as circular, oval, and polygonal structures for adjusting the radiation angle is applied, 3) a product composition with a simple and reduced structure and Adoption of support (base), reflective cup (Boat), liquid silicone injection (silicon filler) to obtain flexibility, 4) Application of aluminum coating/highly reflective silicone material coloring inside the reflective cup to maximize light efficiency, 5) Addition of integrated reflective cup to increase productivity through process simplification and reduce manufacturing cost, 6) The completeness of the product is represented by the alignment and consistency between the LED point light source and the lens center. Adoption of chip-type LED device (Chip Scale Package LED) for applying The final finished product, a lens-integrated linear flexible LED lighting was produced.

The present invention, in order to solve this problem, in a lens-attached flexible LED strip lighting comprising an LED light source with a symmetric/asymmetrical, spherical/aspherical lens, etc., the consistency and alignment between the lens and the LED element is improved An object of the present invention is to provide a lens-attached flexible LED strip lighting optimized for light efficiency and irradiation uniformity, a manufacturing apparatus thereof, and a manufacturing method thereof.

In order to achieve the above object, the present invention, a tray; a printed circuit board disposed inside the tray; an LED light source disposed on the printed circuit board; a support disposed on the printed circuit board around the LED light source; a lens disposed on the LED light source; a reflective cup surrounding the LED light source and the lens; It provides a lens-attached flexible LED strip lighting including a filler disposed on the printed circuit board inside the tray except for the portion surrounded by the support and the reflective cup.

And, the lens may be made of silicon (silicone).

In addition, the lens may have a circular, elliptical or asymmetric polygonal shape.

In addition, a scattering pattern may be formed on the rear surface of the lens to which the light of the LED light source is incident.

In addition, the inner surface of the reflective cup may be coated with aluminum or white color silicon.

In addition, the support and the reflective cup may be integrally formed.

On the other hand, the present invention, the LED light source is mounted on a printed circuit board and a loading unit for placing each of the support in a fixing frame; an alignment attachment unit for aligning the center of the LED light source with the center of the support and attaching the support to the printed circuit board using an adhesive; an adhesive applying unit for applying the adhesive to the upper surface of the printed circuit board; A control unit for transferring the printed circuit board and the fixing frame on which the support is placed, applying the adhesive to the upper surface of the printed circuit board, adsorbing the support, and transferring and aligning the support from the fixing frame to the upper part of the printed circuit board It provides an LED strip assembly device for lens-attached flexible LED strip lighting comprising a.

In addition, the alignment of the LED light source and the support, the application of the adhesive, and the attachment of the printed circuit board and the support may be automatically and sequentially performed.

In addition, the alignment attachment unit may align the reflective cup with the support, and insert the lens into the upper portion of the LED light source inside the reflective cup.

On the other hand, the present invention, the LED light source is attached to a printed circuit board, a support, a lens, and a loading unit for placing the LED strip assembled with a reflective cup on the support plate; a robot unit for transferring the support plate on which the LED strip is placed; an applicator for applying a filler to an upper portion of the printed circuit board; a lamp unit for supplying light for curing the filler; It provides a lens-attached flexible LED strip lighting filler injection curing device including a control unit for controlling the loading unit, the robot unit, the application unit, and the lamp unit.

In addition, the lamp unit may supply infrared or ultraviolet light.

On the other hand, the step of attaching a support to the LED light source periphery on the upper part of the printed circuit board disposed inside the tray; matching the reflective cup to the support; inserting a lens into the upper portion of the LED light source inside the reflective cup; It provides a method of manufacturing a lens-attached flexible LED strip lighting comprising the step of applying a filler to the upper portion of the printed circuit board inside the tray except for the portion surrounded by the support and the reflective cup.

In addition, the method of manufacturing the lens-attached flexible LED strip lighting may further include curing the filler applied on the printed circuit board using infrared or ultraviolet rays.

The present invention is to manufacture a lens-attached flexible LED strip lighting with a new structure employing a silicone lens and maximize product productivity, improve target light efficiency by focusing light sources for each specific application area, and automate product manufacturing, and integrate product into compact size , improved matching/alignment of the lens and the LED light source, and selectively irradiating light to a specific target area.

1 and 2 are photographs showing a conventional flexible LED strip lighting and a bar-type LED strip lighting, respectively.
3 is an exploded perspective view of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
Figure 4 is a perspective view of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
Fig. 5 is a cross-sectional view taken along line VV of Fig. 4;
Figure 6 is a lens-attached flexible LED strip lighting according to an embodiment of the present invention a) a support, b) a reflective cup (before coating with a reflective material), c) a lens, d) a tray, e) a printed circuit board and an LED light source photo showing .
7 is a photograph showing a) an integrated printed circuit board and a reflective cup, b) a finished product of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
8 is a photograph showing a) a rigid rod-type finished product, b) a lighting state, c) a power supply device, and d) a finished product before cutting of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
9 is a view showing an LED strip assembly apparatus of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
10 is a) a top view, b) a front view, c) a side view, d) a perspective view showing an LED strip assembly apparatus of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
11 and 12 are diagrams and flowcharts showing the LED strip assembly process of the lens-attached flexible LED strip lighting according to an embodiment of the present invention, respectively.
13 is a view showing a filler injection curing device of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
Figure 14 is a view showing an aluminum plate as a support plate of the filler injection curing device of the lens-attached flexible LED strip lighting according to an embodiment of the present invention.
15 is a view showing the application part of the filler injection curing device of the lens-attached flexible LED strip lighting according to an embodiment of the present invention.
16 is a view showing a lamp part of the filler injection curing device of the lens-attached flexible LED strip lighting according to an embodiment of the present invention.
17 is a flowchart illustrating a filler injection curing process of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
18 is a flowchart illustrating a manufacturing process of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
19 is a cross-sectional view of a) a symmetrical tray and b) an asymmetrical tray of a lens-attached flexible LED strip light according to an embodiment of the present invention.
20 is a rear view, top view and perspective view of a) a circular support, b) an oval support, and c) a polygonal support of a lens-attached flexible LED strip light according to an embodiment of the present invention.
21 is a top view, a perspective view, and two side views of a) a circular reflective cup, b) an elliptical reflective cup, and c) an asymmetric polygonal reflective cup of a lens-attached flexible LED strip light according to an embodiment of the present invention.
22 is a top view and a side view of an integrated support and a reflective cup of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
23 is a top view, a perspective view, and two side views of a) a circular lens, b) an elliptical lens, and c) an asymmetric polygonal lens of a lens-attached flexible LED strip light according to an embodiment of the present invention.
24 is a) a plan view, b) a perspective view of a printed circuit board of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
25 is a circuit diagram of a) a standard type constant current method, b) a voltage division constant current method, c) a constant voltage method, and d) a constant current method of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
26 is a view showing a) a lens, b) a scattering pattern of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
27 is a view showing a) intensity according to a directivity angle and b) an intensity according to a radiation angle of a circular lens of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
28 is a diagram illustrating a) intensity according to a directivity angle and b) an intensity according to a radiation angle of the elliptical lens of the LED strip lighting according to an embodiment of the present invention.
29 is a view showing a) intensity according to a directivity angle and b) intensity according to a radiation angle of an asymmetric polygonal lens of LED strip lighting according to an embodiment of the present invention.
30 is a view showing a lens into which a diffusion sheet of a lens-attached flexible LED strip lighting according to an embodiment of the present invention is inserted.
31 is a view showing a) a lens and b) a reflective cup of a lens-attached flexible LED strip lighting according to an embodiment of the present invention.
32 is a view showing a) a lens, a reflective cup, and a support of the first example, b) a lens, a reflective cup, and a support of the second example of the lens-attached flexible LED strip lighting according to an embodiment of the present invention.
33 is a view showing a) circular, b) oval, and c) polygonal reflective cups of lens-attached flexible LED strip lighting according to an embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

3 is an exploded perspective view of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, FIG. 4 is a perspective view of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, and FIG. It is a cross-sectional view along line VV.

3, 4 and 5, the lens-attached flexible LED strip lighting 110 according to an embodiment of the present invention, aligning various types of lenses 124 on top of the LED light source 122 It is an LED strip product that has a waterproof function by injecting a silicone filler 134 between it and sealing and curing it. As a new product, it is a product that responds to the needs of consumers, which has evolved one step from the existing standard type.

The length of the product is continuously connected and designed to be cut to the required length.

To this end, the lens-attached flexible LED strip lighting 110 is a printed circuit board (PCB) 120, an LED light source (LED chip) 122, a lens 124, a filler 134, a base (base) 140 , a tray 142 , and a reflective boat 144 .

Specifically, the printed circuit board 120 is disposed inside the tray 142 made of silicon material, and a plurality of LED light sources 122 spaced apart from each other at regular intervals are disposed on the printed circuit board 120 .

A diode 126 , a driver 128 , and a resistor 130 may be further disposed on the printed circuit board 120 , and a connector 132 may be disposed at an end of the printed circuit board 120 .

A lens 124 made of a soft material such as silicone or a hard material such as polycarbonate (PC) or glass is disposed on each LED light source 122, and each LED light source 122 ) A support 140 made of a silicon material is disposed on the upper part of the printed circuit board 120 of the periphery (perimeter), and the support 140 helps to align the LED light source 122 and the lens 124. plays a role

A reflective cup 144 surrounding the support 140, the LED light source 122, and the lens 124 is disposed on the printed circuit board 120 around each LED light source 122, the reflective cup 144 is It serves to reflect the light of the LED light source 122 in a specific direction in front.

To this end, the reflective cup 144 may be coated with a reflective material on its inner surface or made of white colored silicone.

On the upper portion of the printed circuit board 120 inside the tray 142 excluding the portion (including the LED light source 122) surrounded by the support 140 and the reflective cup 144, a silicone material filler 134 is is disposed, the filler 134 may be cured by infrared or ultraviolet light, and the sidewall of the tray 142 serves as a dam to prevent the filler 134 from overflowing. It may contain two-component or one-component silicone that is resistant to moisture penetration.

Although not shown, a silicon layer may be disposed on the uppermost layer of the lens-attached flexible LED strip lighting 110. By mixing a dye material that enables wavelength shift in the silicon layer, blue wavelength light harmful to human eyes is removed. can do.

Accordingly, for the red LED light source, it is possible to manufacture a light emitting light of a specific wavelength required for plant growth.

The main components of this lens-attached flexible LED strip lighting, its manufacturing apparatus and its manufacturing method are 1) a wall (Dam) that prevents overflow of the silicone filler (134) injected by both sides of the silicone tray (142). Function, 2) a function of injecting and curing a material for fixing the support 140 that is located on the periphery of the LED light source 122 and helps to align the lens 124 in the center of the LED light source 122, 3) A function of matching the lens 124 with the reflection cup 144 that includes a reflective film and allows the lens 124 to be seated, 4) A function of irradiating an infrared heat source or an ultraviolet light source, 5) Measuring electrical characteristics function, and 6) the function of measuring optical properties. In conclusion, it is a technical configuration for an automated manufacturing method and apparatus including the above main functions.

6 shows a) a support, b) a reflective cup (before coating with a reflective material), c) a lens, d) a tray, e) a printed circuit board and an LED light source of a lens-attached flexible LED strip light according to an embodiment of the present invention 7 is a photograph showing a) an integrated printed circuit board and a reflective cup, b) a finished product of the lens-attached flexible LED strip lighting according to an embodiment of the present invention, and FIG. 8 is a photograph of the present invention It is a photograph showing a) a rigid rod-type finished product, b) a lighting state, c) a power supply device, and d) a finished product before cutting of the lens-attached flexible LED strip lighting according to the embodiment.

9 is a view showing an LED strip assembly apparatus of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, and FIG. 10 is an LED strip assembly apparatus of a lens-attached flexible LED strip lighting according to an embodiment of the present invention. a) a top view, b) a front view, c) a side view, and d) a perspective view, which will be described with reference to FIGS. 3 to 5 together.

9 and 10, in the manufacturing step by the LED strip assembly device 310, the center of the LED light source 122 and the center of the light incident part of the lens 124 must coincide with the loss of the LED light source 122 There is no such thing, and the light efficiency of the product can be maximized. Therefore, it serves to attach the support 140 to hold the reflective cup 144 surrounding the lens 124 on the printed circuit board 120 on which the LED light source 122 is mounted in an accurate position.

Specifically, the LED strip assembly device 310 includes a support loading unit 320, first and second PCB loading units 322 and 324, an adhesive application unit 326, an alignment attachment unit 328, and an application control unit ( 330 ), a display unit 332 , first and second switches 334 and 336 , a control unit 338 , and an air supply unit 340 .

The support loading unit 320 places the support 140 in the fixing frame, and the first and second PCB loading units 322 and 324 place the printed circuit board 120 in the fixing frame, and the support loading unit 320 ) and the first and second PCB loading units 322 and 324 may be arranged side by side in parallel.

The alignment attachment part 328 aligns the center of the LED light source 122 mounted on the printed circuit board 120 and the center of the support 140 so that the center of the support 140 is aligned, and the support 140 is adsorbed and transported using an adhesive. ) is attached to the printed circuit board 120 .

The adhesive applying unit 326 applies an adhesive such as epoxy, silicone, or instant adhesive to a designated portion on the printed circuit board 120 .

The control unit 338 transfers the fixing frame on which the support 140 is placed and the fixing frame on which the printed circuit board 120 is placed, applies an adhesive on the printed circuit board 120 upper portion, and adsorbs the support 140 . to carry out the overall control function of conveying and aligning.

The LED strip assembly device 310 automatically sequentially performs the alignment of the printed circuit board 120 and the support 140, the application of adhesive, and the attachment of the printed circuit board 120 and the support 140 in sequence to increase productivity. can be improved

11 and 12 are diagrams and flowcharts illustrating an LED strip assembly process of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, respectively, which will be described with reference to FIGS. 3 to 5 together.

11 and 12, the printed circuit board 120 on which the LED light source 122 is electrically mounted (SMT) is loaded on the tray 142 (st112), and the support 140 is placed on the fixing plate. Loading (st114), applying an adhesive (epoxy, instant adhesive, silicone, etc.) to the outer display part of the LED light source 122 in order to align and attach the support 140 (st116), and the support 140 on the fixing plate ) is adsorbed with an adsorber, moved to the printed circuit board 120, aligned and attached (st118), and the adhesive is cured with heat or light (st120).

After that, it is possible to align the lens 24 by inserting the support 140 and the reflective cup 144 in the matching state.

13 is a view showing a filler injection curing apparatus for a lens-attached flexible LED strip lighting according to an embodiment of the present invention, and FIG. 14 is a filler injection curing apparatus for a lens-attached flexible LED strip lighting according to an embodiment of the present invention. It is a view showing an aluminum plate, which is a support plate of It is a view showing the lamp part of the filler injection curing device of the lens-attached flexible LED strip lighting according to the present invention, and FIG. 17 is a flowchart showing the filler injection curing process of the lens-attached flexible LED strip lighting according to an embodiment of the present invention It will be described with reference to 3 to 5 together.

13 to 17, the filler injection and curing device 510, the lens 124 inserted on the printed circuit board 120 inside the tray 142, and the reflective cup 144 to the LED strip after bonding The printed circuit board 120 , the LED light source 122 , the support 140 , the reflective cup 144 , and the lens 124 are injected and covered with a liquid transparent silicone filler 134 to form an integrated structure. It can be cured to complete lens-attached flexible LED strip lighting.

Specifically, the filler injection and curing device 510 includes a loading unit 520 , a robot unit 524 , an application unit 526 , a lamp unit 528 , an unloading unit 530 , a control unit 532 , and a display unit ( 534).

Although not shown, the filler injection and curing device 510 may further include a distribution unit equipped with a vacuum pump for supplying a filler 134 such as silicone and suppressing the generation of bubbles inside the supplied filler 134 . When two-component silicone is used as the filler 134 , the filler injection and curing device 510 may further include a mixing unit for supplying a predetermined ratio using a gear.

The loading unit 520, the assembled tray 142, the printed circuit board 120, the LED light source 122, the support 140, the lens 124, the LED strip of the reflective cup 144, the support plate 522 ) is placed in

The application unit 526 may include a mixer unit that helps to mix the supplied filler 134 and a nozzle for discharging the filler 134 , and applies a predetermined amount of the filler 134 to a predetermined position for a predetermined time. do.

The support plate 522, the integrated tray 142, the printed circuit board 120, the LED light source 122, the support 140, the lens 124, the LED strip of the reflective cup 144 is seated, applied It serves to improve the flatness and uniformity of the filled filler 134, and can be used as a loading and unloading auxiliary device that improves workability and facilitates position control when applying the filler 134 for various products, and can be used as an anode It may be made of oxidized aluminum.

Although not shown, the filler injection and curing device 510 may further include an electric part having an automatic control function to set and operate the supply amount, location, and application time when the filler 134 is injected.

The robot unit 524 transfers the support plate 522 on which the LED strip is seated before and after the filling material 134 is applied, and may include a roller.

The lamp unit 528 supplies infrared rays for curing the filler 134 , and may include infrared heating rays disposed in parallel on the upper portion of the support plate 522 , and the controller 532 controls the filler 134 through temperature setting. ) It can transmit uniform temperature to the entire surface.

In another embodiment, the lamp unit 528 may supply ultraviolet rays to cure the heat/light curable filler (liquid silicone/urethane) 134, while the filler 134 may be fixed or move while the ultraviolet rays are supplied. , it is possible to harden the filler 528 within a relatively short time. In addition, the size or volume of the lamp unit 528 can be reduced by using the ultraviolet LED array and the movable conveyor.

Although not shown, the filler injection and curing device 510 is disposed adjacent to the unloading unit 530 and measures the electrical and optical properties of the lens-attached flexible LED strip lighting 110 after the filler 134 is cured. It may further include a measurement evaluation unit. The tray 142 integrated through the loading unit 520, the printed circuit board 120, the LED light source 122, the support 140, the lens 124, the reflective cup ( After loading the support plate 522 on which the LED strip of 144 is placed (st210), and waiting for the buffer area (st212), it is surrounded by the support 140 and the reflective cup 144 through the applicator 526 and the LED light source The filler 134 is applied (st214) on the upper part of the printed circuit board 120 inside the tray 142 outside the portion including the 122 and the lens 124, and infrared rays are emitted through the lamp unit 528. 134) to dry the filler 134 (st216), wait for the buffer area (st218), and then integrate and apply the filler 134 to the tray 142, the printed circuit board 120, and the LED light source 122. , the support 140, the lens 124, and the support plate 522 on which the reflective cup 144 is disposed (st220).

The manufacturing process of such a lens-attached flexible LED strip lighting will be described with reference to the drawings.

18 is a flowchart illustrating a manufacturing process of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together.

18, the lens attachable flexible LED strip lighting 110 according to the embodiment of the present invention is largely a lens module assembly step (st314), a strip assembly step (st324), a filler application and curing step (st330) manufactured through

First, an inspection is performed on the printed circuit board 120 to which the LED light source 122 is attached (st310), and if a defect occurs, rework is performed (st312).

Thereafter, a support 140 having both side walls is formed (st316), an inspection is performed on the formed support 140 (st320), and if a defect occurs, rework is performed (st322).

Then, the lens 124 is placed on top of each LED light source 122 to assemble the lens module (st314), inspect the assembled lens module (st318), and if a defect occurs, rework is performed ( st322).

Specifically, an LED light source 122, a diode 126, a driver 128, and an electrical device such as a resistor 130 are mounted on the printed circuit board 120. In order to secure flexible characteristics, the printed circuit board 120 ) may have a thickness of 0.3 mm or less or a flexible substrate may be employed.

In the case of manufacturing a bar-type (rigid) strip lighting having durability against high heat, a substrate having a thickness of 1 mm to 1.6 mm made of aluminum metal or FR4 may be used as a printed circuit board.

After the printed circuit board 120 is prepared, the center of the support 140 is positioned around the LED light source 122 to help the lens 124 to be aligned with the center of the LED light source 122. Align it with the center of (122) and fix it using an instant adhesive.

The reflective cup 144 may be fastened to the upper portion of the support 140 to be fixed. In order to increase the light efficiency, the inner surface of the reflective cup 144 may be coated with aluminum or white color silicon, and the reflective cup 144 may be coated with white silicone. It may be made of silicon having a white color.

The reflective cup 144 made of white silicon may have a reflectance that is 3% to 5% higher than that of the aluminum-coated reflective cup 144 .

The lens 124 is seated inside the reflective cup 144, and a material such as silicone is coated on the lower outer surface of the lens 124 and the lower inner surface of the reflective cup 144 to fix the lens 124 to the reflective cup 144, , the lower part of the assembly of the lens 124 and the reflective cup 144 may be fixed to the upper part of the support 140 .

This lens module assembly step (st314) is the first process of matching the center of the LED light source 122 with the lower center of the lens 124 and electrically and mechanically completing the unit corresponding to the minimum unit of the finished lighting product. , may be performed in the support assembly device 310 .

Thereafter, a plurality of printed circuit boards 120 of a minimum unit on which the LED light source 122 and the lens 124 are mounted are connected to each other using the male and female connectors 132 at both ends, and are fixed by pressing with a fixing means such as a clip. , arranged inside the tray 142 to assemble the LED strip (st324), the assembled tray 142, the printed circuit board 120, the LED light source 122, the lens 124, and the LED of the support 140 Inspection is performed on the strip (st326), and if a defect occurs, rework is performed (st328).

Here, in order to improve durability, a transparent film (PC, PET) or a metal strip (stainless steel) of a predetermined length may be inserted between the tray 142 and the printed circuit board 120 as a back wrap film. .

And, the tray 142, the printed circuit board 120, the LED light source 122, the lens 124, the LED strip of the base 140, a power supply wire is connected to one end, and a dummy connector to the other end It is connected to prevent the inlet and application of the filler 134 .

In other embodiments, multiple LED strips may be connected by soldering.

On the other hand, a barrier wall for preventing the flow of the filler 134 may be formed at both ends of the LED strip, and the barrier wall may employ silicone, thermal resin, or a solid flow prevention kit.

Thereafter, the tray 142 is surrounded by the support 140 and the reflective cup 144 on the printed circuit board 120 on the inside and the filler 134 on the outside of the part including the LED light source 122 and the lens 124. is applied and cured (st330), and the tray 142 to which the filler 134 is applied, the printed circuit board 120, the LED light source 122, the lens 124, and the support 140 are inspected. (st332), if a defect occurs, rework is performed (st334).

Specifically, the tray 142 having both side walls is arranged in a predetermined arrangement on the support plate 522 , and the filler 134 can be applied while skipping each lens 124 . The application and curing step of the filler 134 . (st330) may be performed in the filler coating and curing device 510 .

For example, the applicator 526 of the filler application and curing device 510 that mixes lyotropic silicone and minimizes air bubbles may apply a fixed amount of the filler 134 at regular time intervals. In this case, the tray 142 ) and the structure of the lens 124 may determine the discharge amount and discharge time of the filler 134 .

And, after one or multiple application operations, the entire support plate 522 is moved to the region where the infrared heat source is arranged, and the liquid filler 134 is cured using the heat source.

This curing may be repeated two or three times in some cases to effectively remove air bubbles inside the filler 134 .

In addition, the filler 134 may be the Silguard 184 elastomer two-component silicone and its substitute, and may have characteristics of not discoloring or denaturing even when exposed to ultraviolet rays for a long time. In addition, when a waterproof and dustproof primer (eg OS1200) is added to the filler 134 or applied to the outer surface of the reflective cup 144 , the inner surface of the tray 142 , and the upper surface of the printed circuit board 120 , a metal thin film or plastic The interfacial adhesion between the injection-molded material and the filler 134 may be strengthened.

Thereafter, the completed lens-attached flexible LED strip lighting is packaged (st336) and shipped (st338).

A detailed configuration of such a lens-attached flexible LED strip lighting will be described with reference to the drawings.

19 is a cross-sectional view of a) a symmetrical tray and b) an asymmetrical tray of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together.

As shown in FIG. 19 , the side walls of the tray 142 of the lens-attached flexible LED strip lighting 110 have the same shape and the same height symmetrical or different depending on the role of the wall to prevent overflow of the filler 134 . It can be formed into asymmetrical shapes and different heights.

20 is a rear view, top view, and perspective view of a) a circular support, b) an oval support, and c) a polygonal support of a lens-attached flexible LED strip lighting according to an embodiment of the present invention. It will be described with reference to each other.

20, the support 140 of the lens-attached flexible LED strip light 110 has a circular, oval, or polygonal shape depending on the shape and arrangement of the LED light source 122 and the lens 124. can

21 is a top view, a perspective view, and two side views of a) a circular reflective cup, b) an elliptical reflective cup, and c) an asymmetric polygonal reflective cup of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, FIGS. 3 to 5 will be referred to together.

As shown in FIG. 21 , the reflective cup 144 of the lens-attached flexible LED strip lighting 110 may have a circular, oval, or asymmetric polygonal shape depending on the shape or lighting direction of the LED light source 122 .

22 is a top view and a side view of an integrated support and a reflective cup of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together.

22, the support 140 and the reflective cup 144 of the lens-attached flexible LED strip lighting 110 may be integrally formed to simplify the manufacturing process.

If the support 140 and the reflective cup 144 are separately formed, the manufacturing process becomes complicated, manufacturing time and manufacturing cost may increase, and if the reflective cup 144 is coated with a reflective film of a metallic material, defects may increase. can

On the other hand, when the support 140 and the reflective cup 144 are integrally formed with white silicone, the manufacturing process is simplified, the manufacturing time and manufacturing cost are reduced, and the reflective efficiency can be improved by 3% or more.

23 is a top view, a perspective view, and a second side view of a) a circular lens, b) an elliptical lens, and c) an asymmetric polygonal lens of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, and FIGS. 3 to 5 together Refer to and explain.

As shown in FIG. 23 , the lens 124 of the lens-attached flexible LED strip lighting 110 may have a circular, oval, or asymmetric polygonal shape depending on the shape or lighting direction of the LED light source 122 .

The symmetrical tray 142 of FIG. 19 may be applied to a) a circular reflective cup or b) an elliptical reflective cup of FIG. 21, and a) a circular lens or b) an elliptical lens of FIG. 23, and the asymmetric tray 142 of FIG. 21 c) may be applied to the asymmetric polygonal reflective cup and FIG. 23 c) asymmetric polygonal lens.

24 is a) a plan view and b) a perspective view of a printed circuit board of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together.

As shown in FIG. 24 , a plurality of LED light sources 122 spaced apart from each other at regular intervals are disposed on the printed circuit board 120 of the lens-attached flexible LED strip lighting 110 .

25 is a circuit diagram of a) standard constant current method, b) voltage division constant current method, c) constant voltage method, d) constant current method of the lens-attached flexible LED strip lighting according to an embodiment of the present invention, FIGS. 3 to 5 together Refer to and explain.

As shown in FIG. 25, the lens-attached flexible LED strip lighting 110 has seven LED light sources 122 to which a constant current is applied to a power supply voltage of 24V are connected in series, or a constant current is applied to a distributed power voltage of 24V. Seven LED light sources 122 to be applied are connected in series, or seven LED light sources 122 to which a constant voltage is applied to a power supply voltage of 140V are connected in series, or 14 LED light sources to which a constant current is applied to a power supply voltage of 48V. (122) may have a circuit configuration connected in series.

Specifically, a) the standard type constant current type circuit is designed to have a product protection function against external voltage and current influences for each printed circuit board 120 of the basic unit, and a voltage of DC 24V and a constant current of 250 mA are applied in the regulator. Having the configuration to supply, it can be basically composed of a series arrangement of 6 to 8 3V starting LED light source 122, the change in the constant current value can be adjusted by the resistance value (R1).

b) Voltage division constant current type circuit has a configuration to protect the product in case of overvoltage from the power supply, and a method of lowering the maximum voltage by dividing the voltage in two can be used. Two resistors (R2, R3) It can be configured by adding.

c) The constant voltage circuit may have a configuration in which the voltage applied to the product is constant and the flowing current is changed, and it can be used when a single power supply wants to drive a large amount of the LED light source 122, 140V ~ When a DC voltage of 170V is applied, it is possible to drive 300 LED light sources 122 of 4.5A.

d) The constant current circuit may have a structure in which the supply voltage is increased and the number of connected LED light sources 122 is increased, and 14 LED light sources 122 can be driven with a DC voltage of 48V.

This lens-attached flexible LED strip lighting 110 has a unit length of 1.5m to 3m, and can be used by connecting or cutting the unit length.

And, the plurality of LED light sources 122 of the lens-attached flexible LED strip lighting 110 may have a uniformity of 1.5 steps or less.

26 is a view showing a) a lens and b) a scattering pattern of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together.

As shown in FIG. 26, in the lens-attached flexible LED strip lighting 110, the light from the LED light source 122 is scattered on the rear surface of the lens 124 to which the light of the LED light source 122 is incident to ensure uniformity. In order to improve, a scattering pattern (random pattern, sandblasting, microlens structuring, etc.) composed of a plurality of protrusions may be formed.

27 is a view showing the intensity according to a) the directional angle and b) the intensity according to the radiation angle of the circular lens of the lens-attached flexible LED strip lighting according to an embodiment of the present invention, see FIGS. 3 to 5 together. to explain

27, the light of the LED light source 122 incident to the circular lens of the lens-attached flexible LED strip lighting 110 according to the embodiment of the present invention may have an radiation angle of 15 degrees, and the circular lens The light passing through may have a relatively narrow and symmetrical intensity according to the beam angle and the radiation angle.

28 is a view showing a) intensity according to a directivity angle and b) an intensity according to a radiation angle of the elliptical lens of the LED strip lighting according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together.

28, the light of the LED light source 122 incident to the elliptical lens of the lens-attached flexible LED strip lighting 110 according to the embodiment of the present invention may have a radiation angle of 20 degrees to 45 degrees, , the light passing through the elliptical lens may have a relatively wide and symmetrical intensity according to the beam angle and the radiation angle.

29 is a view showing the intensity according to a) the directional angle and b) the intensity according to the radiation angle of the asymmetric polygonal lens of the LED strip lighting according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together. .

29, the light from the LED light source 122 incident to the asymmetric polygonal lens of the lens-attached flexible LED strip lighting 110 according to the embodiment of the present invention may have an emission angle of 0 degrees to 60 degrees. In addition, the light passing through the asymmetric polygonal lens may have a relatively wide and asymmetrical intensity according to the beam angle and the radiation angle.

30 is a view showing a lens into which a diffusion sheet of a lens-attached flexible LED strip lighting is inserted according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together.

30, in the lens-attached flexible LED strip lighting 110 according to the embodiment of the present invention, a diffusion sheet 146 is disposed between the LED light source 122 and the lens 124, It is possible to effectively scatter light emitted from the LED light source 122 to improve uniformity.

31 is a view showing a) a lens and b) a reflective cup of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together.

31, in the lens-attached flexible LED strip lighting 110 according to the embodiment of the present invention, a protrusion (undercut) is formed on the lower outer surface of the lens 124, the lower portion of the reflective cup 144 An undercut is formed on the inner surface.

Accordingly, when the lens 124 is inserted into the place where the support 140 and the reflective cup 144 are fastened, the protrusion of the lens 124 is fixed to the bump of the reflective cup 144, so that the lens 124 is It can be prevented from being easily separated from the reflective cup 144 .

The distance between the outer diameter of the lens 124 and the inner diameter of the reflective cup 144 may be 1 mm or less.

32 is a view showing a) a lens of a first example, a reflective cup, a support, b) a lens, a reflective cup, and a support of a second example of the lens-attached flexible LED strip lighting according to an embodiment of the present invention, FIG. It will be described with reference to 3 to 5 together.

32, in the lens-attached flexible LED strip lighting 110 according to the embodiment of the present invention, the first example of the lens 124, the reflective cup 144, the outer or inner surface of the support 140 On the other hand, a protrusion of a protrusion is formed on the lower outer surface of the lens 124 of the second example, and a protrusion of a bump is formed on the lower inner surface of the reflective cup 144 of the second example, and a support of the second example is formed. A hole may be formed in the water 140, and the lens 124, reflection on the printed circuit board 120 by aligning the projection of the lens 124, the projection of the reflective cup 144, and the hole of the support 140 The cup 144 and the support 140 can be aligned.

The lower outer surface of the reflective cup 144 and the upper inner surface of the support 140 may have a rectangular shape to prevent rotation, and the corners of the rectangular shape may have a round shape.

Although not shown, a projection (boss) is formed on the lower surface of the support 140, a hole is formed on the upper surface of the printed circuit board 120, and the projection of the support 140 is inserted into the hole of the printed circuit board 120. The support 140 and the printed circuit board 120 may be aligned.

33 is a view showing a) circular, b) oval, and c) polygonal reflective cups of a lens-attached flexible LED strip lighting according to an embodiment of the present invention, which will be described with reference to FIGS. 3 to 5 together.

33, in the lens-attached flexible LED strip lighting 110 according to the embodiment of the present invention, the inner surface of the reflective cup 144, which is an injection-molded product, may be coated with aluminum to increase the reflectance, and the reflectance Sputtering-type metal coating can be additionally adopted for deposition method to have high adhesion and strong adhesion.

The reflective cup 144 may have a mechanism structure in consideration of rotation prevention during fastening and fixing with the support 140 and alignment. Can have a wing structure to increase and enhance durability

In this way, when bending or twisting the lens-attached flexible LED strip lighting 110, the reflective cup ( It is possible to prevent a separation between the 144 and the filler 134 or tearing of the filler 134 .

Such a lens-attached flexible LED strip lighting 110 can be applied to lighting for architectural interiors, light sources for liquid crystal display devices, light sources for medical instruments and measuring devices, light sources for plant growth, etc. It has possible features and can be used as indirect lighting for architectural interiors by utilizing various auxiliary equipment.

In addition, the lens-attached flexible LED strip lighting 110 has an air layer on top of the lens 124 and forms a silicone layer, a film layer, or a sheet layer containing a material that shifts wavelengths for medical, mechanical, It can be applied to light sources of devices and measuring instruments, bio-friendly, plant growth and image display devices.

In addition, the lens-attached flexible LED strip lighting 110 can be used as a light source for external exposure by applying a silicone material with excellent waterproof and dustproof effects.

110: lens-attached flexible LED strip lighting
120: printed circuit board 122: LED light source
124: lens 140: pedestal
142: tray 144: reflective cup

Claims (14)

delete delete delete delete delete delete a loading unit for placing each of the printed circuit board and the support on which the LED light source is mounted on a fixing frame;
an alignment attachment unit for aligning the center of the LED light source with the center of the support and attaching the support to the printed circuit board using an adhesive;
an adhesive applying unit for applying the adhesive to the upper surface of the printed circuit board;
A control unit for transferring the printed circuit board and the fixing frame on which the support is placed, applying the adhesive to the upper surface of the printed circuit board, adsorbing the support, and transferring and aligning the support from the fixing frame to the upper part of the printed circuit board
An LED strip assembly device for lens-attached flexible LED strip lighting comprising a.
8. The method of claim 7,
An LED strip assembly device for lens-attached flexible LED strip lighting in which the alignment of the LED light source and the support, the application of the adhesive, and the attachment of the printed circuit board and the support are automatically and sequentially performed.
8. The method of claim 7,
The alignment attachment unit, a lens-attached flexible LED strip assembling device for aligning the reflective cup to the support, and inserting a lens into the upper portion of the LED light source inside the reflective cup.
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