KR20140100811A - Apparatus for detecting surface lens of led package - Google Patents

Abstract

The present invention relates to an apparatus for inspecting the surface of a lens of an LED package. The apparatus comprises: a first lighting unit which radiates R, G, B, W, and UV direct light to the upper part of an lens of an LED package; and a second lighting unit which radiates R, G, B, W, and UV oblique light to the upper part of the first lighting unit. The apparatus can inspect a wide range of the surface of the lens of the LED package by radiating the R, G, B, W, and UV oblique light from the second lighting unit to an inspection area which is not radiated with the R, G, B, W, and UV direct light from the first lighting unit, and can significantly improve inspection performance to the extent to inspect even small and various defects on the surface of the lens of the LED package by consecutively radiating the R, G, B, W, and UV direct light and the R, G, B, W, and UV oblique light from the first lighting unit and the second lighting unit respectively.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a lens appearance inspection apparatus for an LED package,

[0001] The present invention relates to a lens appearance inspection apparatus for an LED package, and more particularly to a lens appearance inspection apparatus for an LED package which is capable of inspecting various defects such as contamination, foreign matter, scratches, To an inspection apparatus.

In general, an LED package is a unit for lighting an LED. The LED package includes a LED chip, a circuit board for driving and controlling the LED chip, a protection circuit for protecting the LED chip and the circuit board, .

In the LED package thus constructed, the LED chip and the circuit board are combined in a state of being embedded in one mold, and the lens for covering and protecting the LED chip and the circuit board is separately provided on the upper surface of the circuit board with epoxy or silicone resin The same adhesive is applied in a state of being applied.

Therefore, since the epoxy or silicone resin applied on the circuit board is not uniformly applied, the non-uniformly coated epoxy or silicone resin is applied to the inner surface or the surface of the lens in the process of adhering the lens to the circuit board The surface of the lens, that is, the surface, or foreign matter is generated.

In addition, bubbles are generated inside the lens during the manufacturing process of the lens, and defects such as scratches are generated on the surface of the lens during the transfer.

As a result, after the assembly of the LED package, the light source is not uniformly diffused and irradiated from the LED chip, thereby reducing the reliability of the LED package. Thus, the appearance inspection of the lens is indispensable have.

As shown in FIG. 1, the lens appearance inspection apparatus of the conventional LED package includes an oblique illumination unit 3 which is formed at an upper portion of the lens 2 of the LED package 1 and whose lower portion is inclined toward the center and emits white light, An image capturing unit 4 that is installed on the upper part of the oblique illumination unit 3 and acquires contrast image information of light irradiated and reflected by the oblique illumination unit 3; (Front surface) of the lens 2 of the LED package 1, as shown in FIG.

However, when the light is irradiated to the oblique illumination unit 3 on the outer surface of the lens 2 of the LED package 1, the inspection apparatus is configured such that the light irradiated from the oblique illumination unit 3, due to the hemispherical shape characteristic of the lens 2, (Circular) as shown in Fig. 2A, and is incident on the photographing section 4 as shown in Fig. 2A.

Therefore, in the case where the outer surface of the lens 2 of the LED package 1 has a defect such as foreign matter, dirt, or air bubbles, the light irradiated from the oblique illumination portion 3 does not affect the defect, When defects such as foreign matter, dirt, or bubbles appear very small in the vicinity of the reflected and reflected circular light, or when the size of the defective portion is small, all of the reflected light is not reflected.

In addition, even when relatively large defects such as scratches are generated on the outer surface of the lens 2 of the LED package 1, small defects appear in the state excluding the portions irradiated by the oblique illumination portion 3 and reflected, It appears as a small defect.

Therefore, the inspection apparatus is inspecting that the appearance of the defect of the lens 2 of the LED package 1 is small or does not show any defects, so that the defects can not be accurately inspected.

In addition, since the inspection apparatus is adapted to irradiate only the white light to the light irradiated from the oblique illumination unit 3, it is difficult to perform inspection such as cracking and crushing in addition to the defect, The phosphor of various colors formed in the phosphor can not react with each other, resulting in a problem that reliability can not be precisely inspected.

The inspection apparatus is adapted to irradiate light to the outer surface of the lens 2 of the LED package 1 within a range of an inclination angle defined at the upper portion of the LED package 1, However, the range of light irradiation is limited, and the reflected and incident light is limited, and defects in the appearance of the lens 2 can not be inspected over a wide range.

An object of the present invention to solve the above problems is to improve defect inspection performance by inspecting a lens appearance of an LED package in a wide range.

Another object of the present invention is to provide a method and apparatus for accurately examining various types of large and small defects generated in the lens outer surface of an LED package.

According to an aspect of the present invention, there is provided a light emitting diode package comprising: a first illumination unit located on an LED package to be inspected and irradiating a light source on the lens of the LED package; A second illuminating unit located above the first illuminating unit and irradiating a light source to a lens area of the LED package that is not illuminated by the first illuminating unit; A camera for acquiring image information of a light source irradiated from the first illumination unit and the second illumination unit and reflected from a lens of the LED package; A controller for storing the image information acquired by the camera, ORing the stored image information according to a preset algorithm, and outputting the calculated OR image information; And a display unit for displaying image information output from the control unit.

The first illuminating unit may be formed as a cylindrical body having a first through-hole in which reflected light is incident on a center of an inner side at a center of the first illuminating unit, and a first illuminating unit And a light source unit.

In the means of the present invention, the first light source unit may include a red, green, blue, white, and ultraviolet lamps circularly extending from the inner side to the outer side along the circumference.

The second illuminating unit may have a diameter smaller than that of the first illuminating unit and may include a second through-hole through which the reflected light is incident on the inner center at a predetermined aperture communicated with the first through- The inclined portion being inclined outwardly toward the lower end of the central inward side surface of the second through-hole middle portion; And a second light source unit for irradiating at least one oblique light to the inside of the inclined portion.

In the means of the present invention, the second light source unit may include a red, a green, a blue, a white, and an ultraviolet lamp while being rounded from the top to the bottom along the circumference in the inclined portion.

In the means of the present invention, the camera includes a 10-frame image including R, G, B, W, UV direct ray 5 frame images of the first illumination unit and R, G, B, W, Is acquired.

In the means of the present invention, the control unit may include an illumination driving unit for separately driving the R, G, B, W, and UV direct rays of the first illumination unit and the R, G, B, W, and UV oblique lights of the second illumination unit, And extracts frame images of the same area by collating the image information stored in the memory with image information obtained by a predetermined algorithm, And a microprocessor for outputting the output signal.

According to an aspect of the present invention, there is provided an LED package comprising: a first illumination unit for irradiating R, G, B, W, and UV direct rays to an upper portion of a lens of an LED package; G, B, W, and UV light of the first illumination unit is irradiated to the lens of the LED package by the R, G, and B light of the second illumination unit, , B, W, and UV oblique light, it is possible to enlarge the inspection area width on the lens outer surface and to inspect defects in a wider area.

In addition, since the present invention irradiates the R, G, B, W, UV direct light and oblique light sequentially from the first illumination unit and the second illumination unit, it is possible to inspect small and various defects in the lens appearance of the LED package It is possible to provide an effect that can be greatly improved.

1 is a block diagram of a lens appearance inspection apparatus of a conventional LED package
2 is a diagram showing a lens defect detection diagram of a lens appearance inspection apparatus of a conventional LED package
3 is a block diagram of a lens appearance inspection apparatus of an LED package of the present invention
4 is a control block diagram of the lens appearance inspection apparatus of the LED package of the present invention
FIG. 5A is a schematic view of the lens appearance inspection apparatus of the LED package of the present invention. FIG.
FIG. 5B is a graph showing the relationship between the reflected light image information of the scratch-defective lens at the time of irradiation of the first illumination unit and the second illumination unit in the lens appearance inspection apparatus of the LED package of the present invention
FIG. 5C is a view showing the defect image information of the reflected light image information of the scratch-
FIG. 5D is a view for explaining the operation of the combined image information of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a block diagram of a lens appearance inspection apparatus of an LED package of the present invention, and FIG. 4 is a control block diagram of a lens appearance inspection apparatus of an LED package of the present invention.

3, the inspection apparatus 30 of the present invention includes a first illumination unit 31 and a second illumination unit 32 for irradiating light to the lens 2 of the LED package 1, A camera 33 for acquiring reflected light irradiated and reflected by the lens 2 of the LED package 1 in the illuminating unit 31 and the second illuminating unit 32; And a display 35 for displaying image information controlled by the control unit 34. The display unit 35 displays the image information,

The first illuminating unit 31 irradiates light to the lens 2 of the LED package 1 and the first illuminating unit 31 is formed of a cylindrical body 311. The inside of the cylindrical body 311 And a first light source unit 313 that irradiates at least one light to the lower bottom surface of the cylindrical body 311. The first light source unit 313 includes a first through hole 312 passing through the center of the first through-

The first light source unit 313 includes a plurality of lamps arranged in a circular shape along the circumference of the bottom surface of the cylindrical body 311 from the inner side to the outer side of the cylindrical body 311. The first light source unit 313 includes a plurality of lamps R, G, ), And ultraviolet (UV) lamps.

The first illuminating unit 31 includes a first illuminating unit 311 and a second illuminating unit 312. The first illuminating unit 31 illuminates the first illuminating unit 313 with red (R), green (G), blue (B) And sequentially irradiates the respective direct rays of light to the outer surface of the lens 2 of the LED package 1, and sequentially irradiates the direct rays of light to the lens 2 of the LED package 1, (2), passes through a first through-hole heel 312 formed at the center of the inside of the cylindrical body 311, and is incident on a camera 33 described later.

Here, the first light source unit 313 of the first illumination unit 31 sequentially turns on according to the control signal of the control unit 34, which will be described later.

The second illuminating unit 32 is positioned directly above the first illuminating unit 31 and irradiates light to the outer area of the lens 2 of the LED package 1 which is not illuminated by the first illuminating unit 31 .

The second illuminating unit 32 is formed of a cylindrical body 321 having a diameter smaller than the diameter of the first illuminating unit 31. The second illuminating unit 32 includes a cylindrical body 321, And a second through hole 322 having a predetermined diameter communicating with the through hole 312.

The second illuminating unit 32 receives the reflected light reflected by the lens 2 of the LED package 1 from the first light source unit 313 of the first illuminating unit 31 through the first through- .

The second through-hole heights 322 include an inclined portion 323 inclined outwardly toward the lower end of the center inner side surface, a second light source portion 324 for irradiating at least one light source to the inside of the inclined portion 323, .

The second light source unit 324 includes a plurality of lamps arranged in a circular shape along the circumference of the inclined portion 323 from the upper side to the lower side to form a plurality of lamps in red, green, blue, W), and ultraviolet (UV) lamps.

The second illuminating unit 32 includes red, green, and blue B light beams from the second light source unit 324 formed at an inclined portion 323 inclined from the top to the bottom in a five- , White (W), and ultraviolet (UV) lamps are sequentially turned on to irradiate the lens 2 of the LED package 1.

The oblique light irradiated in this way is sequentially irradiated onto the outer surface of the lens 2 of the LED package 1 through the first through hole 312 of the first illuminating unit 31, The light is successively reflected from the outer surface of the lens 2 of the package 1 and penetrates through the first through hole 312 of the first illuminating unit 31 and the second through hole 322 of the second illuminating unit 32, And then enters the camera 33.

The camera 33 is installed directly above the second through-hole 322 of the second illuminating unit 32. The camera 33 is provided with a resolution high-resolution color camera capable of inspecting defects of the lens 2 of the LED package 1. [

The camera 33 is mounted on the outer surface of the lens 2 of the LED package 1 so that the red (R), green (G), and blue (B) colors of the first light source unit 313 of the first illumination unit 31, (R), green (G), blue (B), and white (W) light of the second light source unit 324 of the second illumination unit 32, ) And an ultraviolet (UV) lamp are respectively irradiated and reflected from the outer surface of the lens 2 of the LED package 1 to be passed through the first through hole 312 and the second through hole 322 10 pieces of reflected light incident thereon are acquired, and the 10 pieces of reflected light thus obtained are converted into 10 frames of image information and transmitted to the control unit 34. [

The control unit 34 stores the 10-frame image information acquired by the camera 33 and ORs the stored image information according to a predetermined algorithm to output the OR image information.

4, the control unit 34 includes an illumination driving unit 341 and a camera driving unit 342 for selectively driving the first illumination unit 31 and the second illumination unit 32, And a microprocessor 344 for performing a logical sum operation on the image information stored in the memory 343 by a predetermined algorithm and outputting the calculated logical sum image information .

The controller 34 selectively drives the illumination drivers 341 and 342 in accordance with a predetermined algorithm to inspect the appearance of the lens 2 of the LED package 1 to detect the first The light source unit 313 and the second light source unit 324 of the second illumination unit 32 direct the direct light and the oblique light to the outer surface of the lens 2 of the LED package 1, respectively.

The first light source unit 313 of the first illumination unit 31 and the second light source unit 324 of the second illumination unit 32 emit light of red (R), green (G), blue (B) (R), green (G), blue (B), white (W) and ultraviolet (UV) oblique light sequentially after irradiating the first After irradiating the oblique light of the light source unit 324, the direct light of the first light source unit 313 is irradiated.

The light emitted from the first light source unit 313 of the first illumination unit 31 and the second light source unit 324 of the second illumination unit 32 are reflected by the outer surface of the lens 5 of the LED package 1, And enters the camera 33 through the first through-hole heights 312 and the second through-hole heights 322 formed in the first illuminating unit 31 and the second illuminating unit 32. At this time, As shown in FIG. 5A, circularly reflected light of different sizes is reflected by the first illuminating unit 31 and the second illuminating unit 32, respectively.

The circular reflected light of different sizes is irradiated from the first illumination unit 31 and the second illumination unit 32 when the lens 5 of the LED package 1 has defects such as scratches, As shown in FIG. 5B, the reflected light is incident on the camera 33, and the camera 33 is caused to enter the inside and the outside of the reflected light. And the defective portion is converted into white image information and transmitted to the control unit 34. The control unit 34 determines whether or not the optical information is defective.

The control unit 34 controls the memory 343 by the microprocessor 344 to store the image information transmitted from the camera 33 in the memory 343 so that the image information transmitted from the camera 33, (R), green (G), blue (B), white (W), and ultraviolet (UV) direct light and oblique light from the first illuminating unit 31 and the second illuminating unit 32, Image information, that is, 10-frame image information.

Next, the control unit 34 causes the microprocessor 344 to output 10 frame image information stored in the memory 343 to the 5-frame image information of the first illumination unit 31, 2 frame of the first illuminating unit 31 and the second illuminating unit 31 by performing OR operation on the extracted same area frame images, 32 are combined into one image information.

The image information outputted from the controller 34 is output to the display 35 and displayed to inspect the appearance of the lens 2 of the LED package 1 through the display 35. [

As described above, in the present invention, scratch defects are described in the outer appearance of the lens of the LED package. However, it is also possible to inspect defects such as foreign matter, dirt, bubbles, have.

One; LED package 2; lens
31; A first illumination unit 311; Cylindrical body
312; First through-hole middle 313; The first light source unit
32; A second illumination unit 321; Cylindrical body
322; A second through-hole middle 323; Inclined portion
324; A second light source unit 33; camera
34; Control units 341 and 342; [0030]
343; Memory 344; A microprocessor 37; display

Claims (7)

A first illuminator positioned above the LED package to be inspected and irradiating a light source to the lens of the LED package;
A second illuminating unit located above the first illuminating unit and irradiating a light source to a lens area of the LED package that is not illuminated by the first illuminating unit;
A camera for acquiring image information of a light source irradiated from the first illumination unit and the second illumination unit and reflected from a lens of the LED package;
A controller for storing the image information acquired by the camera, ORing the stored image information according to a preset algorithm, and outputting the calculated OR image information; And
And a display unit for displaying image information output from the control unit. The method according to claim 1,
Wherein the first illuminating unit is formed as a cylindrical body having a first through-hole in which reflected light is incident on a center of the inside at a predetermined diameter,
And a first light source unit for irradiating at least one direct light to the bottom bottom surface of the cylindrical body. 3. The method of claim 2,
Wherein the first light source unit comprises a red, a green, a blue, a white, and an ultraviolet lamp in a circular shape along the circumference of the first light source unit from the inside to the outside. The method according to claim 1,
The second illuminating unit may have a diameter smaller than that of the first illuminating unit, and a second through-hole in the center of the second illuminating unit. The second illuminating unit has a second through-hole in which a reflected light is incident on the first illuminating unit. Lt; / RTI >
An inclined portion formed at a central inner side surface of the second through-hole middle portion so as to be inclined outwardly toward a lower end;
And a second light source unit for irradiating at least one oblique light to the inside of the inclined portion. 5. The method of claim 4,
Wherein the second light source unit comprises a red, a green, a blue, a white, and an ultraviolet lamp in a circular shape along a circumference at an inclined portion from top to bottom. The method according to claim 1,
The camera acquires 10 frame images including R, G, B, W, UV direct ray 5 frame images of the first illumination unit and R, G, B, W, UV oblique light 5 frame images of the second illumination unit A lens appearance inspection device of an LED package. The method according to claim 1,
The control unit may include an illumination driving unit for individually driving R, G, B, W, and UV direct rays of the first illumination unit and R, G, B, W, and UV oblique lights of the second illumination unit,
A memory for storing image information acquired from the camera;
And a microprocessor for extracting frame images of the same region by collating the image information acquired by the predetermined algorithm with the image information stored in the memory and performing a logical sum operation on the extracted same region image to output a frame image A lens appearance inspection device of an LED package.

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