KR102206767B1 - Apparatus for Testing LED Back Light Unit - Google Patents

Abstract

The present invention relates to an LED backlight unit test device which accurately detects only defective elements of a light unit and enables more efficient repair. According to one aspect of the present invention, provided is the LED backlight unit test device including: a frame; a stage unit on which a plurality of LED-mounted substrates are carried; a power supply unit for supplying power to the substrate carried on the stage; an alignment unit for recognizing the position of the substrate carried into the stage unit; a vision unit for photographing the substrate operated by the power supply unit; a probe unit for individually operating each LED by contacting an individual electrode of each individual LED mounted on the substrate; and a control unit for controlling the power supply unit, the alignment unit, the vision unit, and the probe unit. According to the present invention, it is possible to identify a really defective LED element among the LED elements in a defective operation area among the LED substrate.

Description

LED Back Light Unit Test Equipment{Apparatus for Testing LED Back Light Unit}

The present invention relates to an LED backlight unit test equipment, and more particularly, to an LED backlight unit test equipment that accurately detects only defective elements of the backlight unit and enables more efficient repair.

Since flat panel display devices such as LCDs were developed, their use has been increasing. For example, flat panel displays are used in mobile phones, monitors, and TVs.

In such a flat panel display device, a backlight unit serving as a light source is provided behind the display panel.

In the past, in the past, a cold cathode tube (CCFL) was disposed on the side, and the cold cathode tube was disposed near one edge of the liquid crystal panel, and a light guide plate that evenly distributes and diffuses the light emitted from the cold cathode tube on the flat panel display panel. It is equipped.

On the other hand, as flat panel display devices are being made thinner, in recent years, instead of the cold cathode tube, an LED element that is advantageous in terms of thickness, heat generation, luminance, lifespan, and weight has been adopted.

In addition, as the display panel becomes larger, the method through the light guide plate is insufficient to meet the screen uniformity criterion, and the use of a direct type method in which a plurality of LEDs are densely arranged directly behind the display panel is gradually increasing.

In such a direct type backlight unit, an LED substrate having a predetermined area is disposed on the rear side of a display panel, and a plurality of LED elements are closely disposed on the LED substrate.

However, as shown in FIG. 1, even if a failure occurs in one of the plurality of LED elements 14 disposed on the substrate 12 according to the circuit pattern arrangement on the substrate, the defective LED element Poor operation 20 may occur in the surrounding area. Such a defective operation may be caused by poor lighting and poor brightness.

However, it was difficult to determine which of the LED elements corresponding to the defective operation LED area 20 is really a defective LED element, so the entire LED element in the defective operation area was replaced. Since the majority of LED devices are used, waste of devices is caused, and due to the large number of replacements of the LED devices, it takes a long time to repair and increases cost.

Korean Patent Registration KR 10-1318366

The present invention has been made to solve the above problems, and it is an object of the present invention to provide an LED backlight unit test equipment capable of identifying a truly defective LED element among LED elements in a defective operation area of the LED substrate.

The problems of the present invention are not limited to the problems mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

In order to solve the above problems, according to one embodiment of the present invention, a frame, a stage portion in which a substrate on which a plurality of LEDs are mounted is carried, a power supply portion for supplying power to the substrate carried in the stage, and the stage portion are carried in. Alignment unit for recognizing the position of the substrate, vision unit for photographing a substrate operated by the power supply unit, a probe unit for operating each LED by contacting individual electrodes of each individual LED mounted on the substrate, and the power supply unit And an LED backlight unit test device including a control unit for controlling the alignment unit, the vision unit, and the probe unit.

The stage unit may include a stage on which the substrate is mounted, a chuck for fixing the substrate carried in the stage unit in a flat state, and a stage moving unit for moving the stage.

The power supply unit may include a power supply terminal to apply power or a signal by contacting a terminal of a substrate carried in the stage unit.

An X-axis rail and a Y-axis rail for moving the alignment part, the vision part, and the probe unit in a plane may be further included.

The control unit may check the defective operation area through the image of the operated substrate photographed by the vision unit, and then operate the individual LED in the defective operation area through the probe unit to check the coordinates of the defective operation LED.

The control unit may determine whether the individual LED is turned on or not.

The control unit may determine whether the individual LED is defective as whether or not the individual LED satisfies the reference light intensity.

The control unit may determine whether the individual LED is defective as whether the reference potential difference of both electrodes of the individual LED is satisfied.

The individual LEDs are provided with individual electrodes for applying power to the LEDs on both sides of each LED, and the probe unit is a pair of pogo pins contacting each of the individual electrodes to apply power, and the pogo pins It may include a light receiving unit for sensing the light of the individual LED operated by the power supplied by.

The light-receiving part may be positioned above the LED between the pogo pins.

The light receiving unit includes an optical fiber extending to the other side, an optical fiber extending to the other side, and facing the other end side of the optical fiber, and a light receiving element provided to detect light emitted from the end of the optical fiber. Can include. The individual LED is provided with individual electrodes for applying power to the LED on both sides of each LED, the probe unit is provided on the upper side of the LED, a transparent block provided with a transparent material through which light, A pair of pogo pins contacting each of the individual electrodes to apply electric power, and a camera positioned above the transparent block to detect light passing through the transparent block.

The individual LED is provided with individual electrodes for applying power to the LED on both sides of each LED, the probe unit is provided on the upper side of the LED, a transparent block provided with a transparent material through which light, And a pair of pogo pins that are in contact with each of the individual electrodes to apply power, and the vision unit is positioned above the transparent block to detect light passing through the transparent block.

The individual LEDs are provided with individual electrodes for applying power to the LEDs on both sides of each LED, and the probe unit is a pair of pogo pins contacting each of the individual electrodes to apply power, and the pogo pins It may include a measuring unit for measuring the reference potential difference of the pair of individual electrodes applied by.

According to the LED backlight unit test equipment of the present invention, it is possible to accurately determine the defective element in the defective operation area of the LED substrate, so that the number of replacement of the LED element is reduced, reducing the rework time and cost of the LED substrate, resulting in reduced cost. It works.

The effects of the present invention are not limited to the effects mentioned above, and other effects that are not mentioned will be clearly understood by those skilled in the art from the description of the claims.

The summary described above, as well as the detailed description of the preferred embodiments of the present application described below, may be better understood when read in connection with the accompanying drawings. For the purpose of illustrating the present invention, preferred embodiments are shown in the drawings. However, it should be understood that this application is not limited to the precise arrangements and means shown.
1 is a view showing an LED substrate in which a defective operation zone exists;
2 is a perspective view showing an LED backlight unit test equipment according to an embodiment of the present invention;
3 is a view showing an LED substrate of the LED backlight unit;
4 is a diagram showing a first embodiment of the probe unit of FIG. 2;
5 is a view showing a second embodiment of the probe unit of FIG. 2;
Fig. 6 is a diagram showing a third embodiment of the probe unit of Fig. 2;
Fig. 7 is a view showing a fourth embodiment of the probe unit of Fig. 2;
8 is a flow chart showing a control method of the LED backlight unit test equipment according to another embodiment of the present invention;
9 is a view showing a state in which an area of an LED substrate in which a defective area exists is divided;
10 is a diagram showing a state of checking individual defective elements in a defective area.

Hereinafter, preferred embodiments of the present invention in which the object of the present invention can be realized in detail will be described with reference to the accompanying drawings. In the description of the present embodiment, the same names and the same reference numerals are used for the same components, and additional descriptions thereof will be omitted.

Hereinafter, an embodiment of the LED backlight unit test equipment 100 of the present invention will be described.

The LED backlight unit test equipment 100 according to the present embodiment is a frame 110, a stage unit 120, a power supply unit 140, an alignment unit 160, a vision unit 170, as shown in FIG. , A probe unit 180 and a controller 196 may be included.

Prior to describing the LED backlight unit test equipment 100, the LED substrate 10 of the backlight unit will be described.

In the LED substrate 10, as shown in FIG. 3, a plurality of LED elements 14 are mounted on a flat substrate 12 at regular intervals.

In this case, the shape of the substrate 12 is not limited, but since the display panel is generally a square shape, the substrate 12 may also be formed in a square shape. Of course, the substrate 12 may be formed in various shapes, such as a triangular shape, a circular shape, or even a wave shape, in addition to a rectangular shape, and may be formed of a flexible material that is free to bend.

A terminal portion 16 for receiving power and signals is formed on the edge of the substrate 12. Power and signals are applied to the entire LED element 14 mounted on the substrate 12 through the terminal unit 16 to be turned on.

The LED elements 14 mounted on the substrate 12 are spaced apart from each other and arranged in a row, and on both sides of each LED element 14, individual electrodes that can apply power and signals to each LED ( 18) can be formed.

That is, power and signals are applied to the LED element 14 of the entire substrate 12 through the terminal unit 16 provided on the substrate 12, and the corresponding LED element ( 14) Power and signals can be applied to one.

On the other hand, the frame 110 is placed on the installation surface, other parts are placed, and can form a frame supporting the load.

The stage unit 120 is installed on the frame 110 and is a portion on which the LED substrate 10 to be carried is placed.

Meanwhile, the stage unit 120 includes a stage 122 on which the loaded LED substrate 10 is seated and supports the LED substrate 10 in a flat state, and the substrate 12 carried in the stage 122. A chuck 124 for fixing in a flat state may be provided.

At this time, the chuck 124 may be provided in various forms and methods, but in this embodiment, it includes a plurality of suction holes formed on the surface of the stage 122, so that the LED substrate 10 is vacuumed. It may be provided to fix suction.

On the other hand, the stage moving unit 126 horizontally moves the stage 122 to move the stage 122 into a loading position 132 into which the substrate 12 is carried, an inspection position 134 to be inspected, and a substrate on which the inspection is completed. (12) can be moved to the carry-out position 136 is carried out.

The moving part of the stage 122 may include a rail for moving the stage 122 in one side and the other side on a plane, and may include a motor for moving the stage 122 on the rail.

Meanwhile, the power supply unit 140 may include a power supply terminal 142 that is in contact with the terminal unit 16 of the substrate 12 carried in the stage 122 to apply power or a signal.

The power supply terminal 142 may be provided to be movable vertically or horizontally. The LED substrate 10 to which power and signals are supplied through the power supply terminal 142 may be turned on by applying power and signals to the entire LED element 14 mounted on the substrate 12. In addition, among the individual LED elements 14 mounted on the LED substrate 10, a defective LED element or a normal LED element adjacent to the defective LED element may not be turned on or a malfunction such as low luminance may occur. The area in which the operation failure has occurred will be referred to as a defective operation area 20.

That is, there may be an LED element that is actually defective in the defective operation zone 20, or the LED element itself may be a normal LED element that is not turned on by a defective LED element around it.

In addition, an ID reader 150 may be provided. The LED substrate 10 may be assigned an ID for each substrate 12, and information on the LED substrate 10 may be input to the ID. That is, information such as the size of the substrate 12, the type of the arranged LED elements 14, the operating voltage and the reference luminous intensity, the number of LED elements 14, and the arrangement interval may be contained. Such an ID may be provided in the form of a barcode, a QR code, or an RFID, and the ID reader 150 may also be provided in a form capable of acquiring information in the above form.

The alignment unit 160 is a component that senses the exact seating position of the LED substrate 10 mounted and fixed on the stage 122, and the specific LED element 14 of the LED substrate 10 in the lit state By grasping the position, the reference position of the LED substrate 10 may be set. The alignment unit 160 may include a camera.

For example, the alignment unit 160 recognizes the LED element 14 located at the outermost edge of the lighted LED substrate 10 and identifies the position thereof, thereby determining the exact seating position of the LED substrate 10. have.

The exact position of the LED substrate 10 obtained by the alignment unit 160 and the information on the LED substrate 10 obtained through the ID reader 150 determine where the LED element 14 is arranged. You can also get information about it.

The vision unit 170 photographs the LED substrate 10 in the lighted state with a camera or the like, and can grasp the location of a region in which operation is poor, such as not being lit, blinking, or low brightness.

In addition, the probe unit 180 contacts the individual electrodes 18 of each individual LED element 14 in the area where the operation is poor, and applies power and signals through each individual LED element. By independently operating (14), it is possible to judge whether the operation is defective.

Meanwhile, the alignment unit 160, the vision unit 170, and the probe unit 180 may be provided with an X-axis rail 192 and a Y-axis rail 194 to enable movement on a plane. Of course, the alignment unit 160, the vision unit 170, and the probe unit 180 may be separately expanded or contracted to enable vertical movement or may be provided to move upward and downward.

In addition, a control unit 196 may be provided. The control unit 196 controls the power supply unit 140 and the alignment unit 160, the ID reader 150, the vision unit 170, and the probe unit 180, and aligns with the power supply unit 140. As information obtained through the worker 160, the ID reader 150, the vision unit 170, and the probe unit 180, it is possible to determine whether the LED element 14 is defective. The control unit 196 may be provided in the frame 110, or may be provided in the form of a PC provided at a separate location.

That is, power and signals are applied to the entire LED substrate 10 through the power supply unit 140 so that the LED substrate 10 is operated, and the vision unit 170 moves in a plane while the LED substrate 10 The position of the defective operation area 20 is identified, and the probe unit 180 operates each individual LED to determine the defective LED element 14.

In this case, the control unit 196 may determine whether the individual LED element 14 is turned on or not.

The probe unit 180 applies power and signals to the individual LED elements 14 through each of the individual electrodes 18, thereby determining whether the LED element 14 is normally lit.

Alternatively, the control unit 196 may determine whether the individual LED element 14 is defective as whether or not the individual LED element 14 satisfies the reference light intensity.

The probe unit 180 applies power and signals to the individual LED elements 14 through each of the individual electrodes 18, thereby determining whether the luminous intensity emitted from the LED element 14 meets the standard. To judge.

Alternatively, the control unit 196 may determine whether or not it is defective as whether or not a reference potential difference between both individual electrodes 18 of the individual LED element 14 is satisfied.

The probe unit 180 applies power and signals to the individual LED elements 14 through the respective individual electrodes 18, whereby the potential difference measured at both ends of the individual electrodes 18 of the LED element 14 It is possible to judge whether or not is defective as whether or not satisfies the reference potential difference.

In addition, the control unit 196 may record and store the location of the defective LED element 14 detected through the probe unit 180 in a format such as coordinates (X i , Y i ), and the recorded defective LED element The position of (14) can be transmitted to the outside so that it can be used for maintenance work of the LED substrate 10 in the future.

Hereinafter, various embodiments of the probe unit 180 will be introduced.

As shown in FIG. 4, the first embodiment of the probe unit 180 may include a pogo pin 182 and a light receiving element 188.

That is, the probe unit 180 may include at least one pair of pogo pins 182 each contacting the individual electrodes 18 of the individual LED elements 14 to apply power and signals. In addition, the pogo pin 182 may be installed on the probe substrate 184.

In this case, the upper side of the LED element 14 of the probe substrate 184 may be provided with an opening 186 or a transparent material such as a lens, and a light receiving element 188 may be provided directly above the probe substrate 184.

Accordingly, it is possible to determine whether the respective LED element 14 is normally turned on through the light-receiving element 188 or whether the respective LED element 14 satisfies the reference light intensity.

Here, a plurality of pogo pins 182 and light receiving elements 188 may be provided in the probe unit 180 so as to inspect the lighting of a plurality of individual LED elements 14 at once.

As shown in FIG. 5, the second embodiment of the probe unit 280 may include a pogo pin 282, an optical fiber 286, and a light receiving element 288.

Unlike the first embodiment described above, in the probe unit 280 of the present embodiment, the light-receiving element 288 does not need to be positioned directly above the individual LED elements 14, and may be positioned at any place. In addition, one end of an optical fiber 286 is provided on a portion directly above the light receiving element 288, and the optical fiber 286 may extend to the light receiving element 188 provided at the arbitrary position.

Accordingly, light is transmitted to the light-receiving element 188 through the optical fiber 286, and it is determined whether the respective LED element 14 is normally lit, or whether the respective LED element 14 satisfies the reference light intensity. Can judge.

The third embodiment of the probe unit 380 may include a pogo pin 382 and a potential difference measuring unit 388 as shown in FIG. 6.

That is, the probe unit 380 may include at least a pair of pogo pins 382 each contacting the individual electrodes 18 of the individual LED elements 14 to apply power and signals. In addition, the pogo pin 382 may be installed on the probe substrate 384.

In addition, the potential difference measuring unit 388 may measure a potential difference measured at both individual electrodes 18 through the pogo pin 182.

That is, if the individual LED elements 14 operate normally, the potential difference measured by the respective individual electrodes 18 will also fall within the reference range, otherwise it may be determined as a defect.

The fourth embodiment of the probe unit 480 may include a transparent block 484, a pogo pin 482, and a camera 488, as shown in FIG. 7.

The transparent block 484 is formed of a transparent material such as glass or transparent polycarbonate through which light can be transmitted, and may be positioned above the LED element 14.

In addition, the pogo pin 482 may be provided under the transparent block 484 or may be installed through the transparent block 484.

In addition, a camera 488 may be provided above the transparent block 484.

Accordingly, the light of the LED element 14 that is lit by the power and signal transmitted by the pogo pin 482 may be directed toward the camera through the transparent block 484. The camera 488 may be provided to receive light from a plurality of LED elements 14 or may be provided to receive light from one LED element 14 at a time.

Alternatively, the camera 488 may be separate from the vision unit 170, or the vision unit 170 may function as the camera without installing a separate camera 488.

Hereinafter, a method of controlling the LED backlight unit test equipment 100 according to an embodiment of the present invention will be described.

The control method of the LED backlight unit test equipment 100 according to the present embodiment, as shown in Fig. 8, the board loading step (S110), the ID verification step (S120), the entire substrate operation step 130, the alignment step ( S140), a defective operation zone check step (S150), an individual device operation step (S160), a defective device detection step (S170), and a defective device location acquisition step (S180).

The substrate carrying step (S110) is a step of carrying the LED substrate 10 into the stage 122 of the LED backlight unit test equipment 100 described above. In this case, the stage 122 may be brought in the LED substrate 10 while being moved to the carrying position 132, and then moved to the inspection position 134.

After the LED substrate 10 is loaded, the chuck 124 is operated to adsorb and fix the LED substrate 10.

The ID verification step S120 is a step of checking the ID of the substrate 12 carried into the stage 122 through the ID reader 150.

The LED substrate 10 may be assigned an ID for each substrate 12, and information on the LED substrate 10 may be input to the ID. That is, information such as the size of the substrate 12 or the type of the arranged LED elements 14, operating voltage and reference luminance, the number of LED elements 14, and the arrangement interval may be contained. Such an ID may be provided in the form of a barcode, a QR code, or an RFID, and the ID reader 150 may also be provided in a form capable of acquiring information in the above form.

The whole board operation step 130 applies power and signals to the LED board 10 carried in through the power supply terminal 142 of the power supply unit 140, so that the entire LED mounted on the LED board 10 The element 14 can be turned on.

In addition, among the individual LED elements 14 mounted on the LED substrate 10, the defective LED element 14 or the normal LED element 14 adjacent to the defective LED element 14 is not lit or has low luminance. A defective operating area 20 may occur.

That is, there may be an LED element that is actually defective in the defective operation zone 20, or the LED element itself may be a normal LED element that is not turned on by a defective LED element around it.

The alignment step (S140) is a step of detecting an exact seating position of the LED substrate 10 mounted and fixed on the stage 122 through the alignment unit 160. That is, the reference position of the LED substrate 10 may be set by grasping the position of the specific LED element 14 of the LED substrate 10 in a lighted state through the alignment unit 160.

On the other hand, the defective operation area checking step (S150) is a step of confirming the position of the defective operation area 20 among all the LED substrates 10 that are lit. The defective operation area checking step (S150) may include a region dividing step (S152) and a defective area checking step (S154) for each area.

When the LED substrate 10 is larger than the photographing area of the vision unit 170, the LED substrate 10 may be photographed while the vision unit 170 is horizontally moved.

In this case, as shown in FIG. 9, the entire LED substrate 10 must be divided into areas of a size that can be photographed by the vision unit 170 through the information identified in the ID verification step. This process may be performed in the region dividing step S152.

In FIG. 9, the lighted LED is indicated by a solid black line, and the non-lighted LED is not shown separately.

In addition, in the step of identifying defective zones for each area (S154), while the vision unit 170 is moved to the area divided in the area dividing step (S152), the defective operation zone ( You can check the location of 20). Here, the defective operation region 20 may mean a region in which the LED element 14 is not turned on or does not exhibit the reference light intensity.

The location of the defective operation area 20 identified in the defective area identification step S154 for each area may be transmitted to the control unit 196.

In the individual device operation step (S160), the probe unit 180 is moved to the defective operation area identified in the defective area identification step for each area, and directly to each individual LED element 14 in the defective operation area 20. This is a step of turning on the individual LED elements 14 by applying power and signals.

The defective element detection step (S170) is a step of determining whether or not each of the individual LEDs is defective through the individual device operation step (S160).

If the individual LED elements 14 to which power and signals are applied by the probe unit 180 are normal, they may be normally lit as shown in FIG. 10.

Alternatively, if the individual LED element 14 receiving power and signal applied by the probe unit 180 is defective, as shown in FIG. 10, the luminous intensity may be low (13) or may not be lit (15). There will be, and such an LED element 14 can be detected as a defective element (13, 15).

In this case, the control unit 196 may determine whether or not the LED element 14 to which power and signals are applied by the probe unit 180 is turned on or not.

Alternatively, the control unit 196 may determine whether or not the LED element 14 has been applied with power and a signal by the probe unit 180 meets the reference light intensity.

Alternatively, the control unit 196 may determine whether or not it is defective as whether or not the reference potential difference between the respective electrodes 18 of the LED element 14 to which power and signals are applied by the probe unit 180 are satisfied.

In addition, in the step of acquiring the position of the defective device (S180), the position of the LED devices 13 and 15 detected as defective in the step of detecting the defective device (S170) is acquired and stored in a coordinate format (X _i , Y _i ). It can be transmitted to other equipment.

In addition, as the location information of the LED element 14 obtained from other equipment capable of replacing the defective LED element 14 of the LED substrate 10, only the defective LED element 14 can be selected and replaced and repaired.

As described above, a preferred embodiment according to the present invention has been looked at, and the fact that the present invention can be embodied in other specific forms without departing from its spirit or scope other than the above-described embodiments is known to those skilled in the art. This is obvious to them. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description and may be modified within the scope of the appended claims and equivalents thereof.

10: LED substrate 12: substrate
14: LED element 16: terminal
18: individual electrode 20: defective operating area
100: LED backlight test unit 110: frame
120: stage unit 122: stage
124: chuck 126: stage moving unit
132: loading location 134: inspection location
136: take-out position 140: power supply
142: power supply terminal 150: ID reader
160: alignment unit 170: vision unit
180: probe unit 182: pogo pin
184: probe substrate 186: opening
188: light receiving element 192: X-axis rail
194: Y-axis rail 196: control unit
280: probe unit 282: pogo pin
286: optical fiber 288: light receiving element
380: probe unit 382: pogo pin
388: potential difference measuring unit 480: probe unit
482: pogo pin 484: transparent block
488: camera
S110: Board loading step S120: ID verification step
S130: Whole board operation step S140: Alignment step
S150: Defective operation area confirmation step S152: Area division step
S154: Step of confirming defective areas by area
S160: individual device operation step S170: defective device detection step
S180: Defective device location acquisition step

Claims (14)

frame;
A stage unit installed on the frame and into which a substrate on which a plurality of LEDs are mounted is carried;
A power supply unit for supplying power to the substrate carried in the stage;
An alignment unit for recognizing a position of a substrate carried into the stage unit;
A vision unit for photographing a substrate operated by the power supply unit;
A probe unit that individually operates each LED by contacting individual electrodes of each individual LED mounted on the substrate;
A control unit for controlling the power supply unit, alignment unit, vision unit, and probe unit;
Including,
The control unit checks the defective operation area of the substrate operated by the power supply unit as an image photographed by the vision unit, and individually operates an individual LED in the defective operation area as the probe unit to check whether there is a defective LED. LED backlight unit test equipment. The method of claim 1,
The stage part,
A stage on which the substrate is mounted;
A chuck for fixing the substrate carried in the stage part in a flat state;
A stage moving unit that moves the stage;
LED backlight unit test equipment comprising a. The method of claim 1,
The power supply unit, the LED backlight unit testing equipment including a power supply terminal for applying power or signal by contacting the terminal of the substrate carried in the stage unit. The method of claim 1,
LED backlight unit testing equipment further comprising an X-axis rail and a Y-axis rail for moving at least one of the alignment unit, the vision unit, and the probe unit in a plane. The method of claim 1,
The control unit checks the defective operation area through the image of the operated substrate photographed by the vision unit, and then operates the individual LED in the defective operation area through the probe unit to check the coordinates of the defective operation LED. Unit test equipment. The method of claim 1,
The control unit,
LED backlight unit test equipment that determines whether the individual LED is turned on or not. The method of claim 1,
The control unit,
LED backlight unit test equipment that determines whether the individual LED is defective as whether or not the individual LED satisfies the reference light intensity. The method of claim 1,
The control unit,
LED backlight unit test equipment that determines whether or not a defect is determined as whether the reference potential difference of both electrodes of the individual LED is satisfied. The method of claim 1,
The individual LED is provided with individual electrodes for applying power to the LED on both sides of each LED,
The probe unit,
A pair of pogo pins contacting each of the individual electrodes to apply power;
A light-receiving unit that senses light of an individual LED operated by power supplied by the pogo pin;
LED backlight unit test equipment comprising a. The method of claim 9,
The LED backlight unit test equipment, wherein the light receiving unit is a light receiving device positioned above the LED between the pogo pins. The method of claim 9,
The light receiving unit,
An optical fiber positioned above the LED between the pogo pins and extending to the other side;
A light-receiving device provided to face the other end of the optical fiber and configured to sense light emitted from the end of the optical fiber;
LED backlight unit test equipment comprising a. The method of claim 1,
The individual LED is provided with individual electrodes for applying power to the LED on both sides of each LED,
The probe unit,
A transparent block provided on the upper side of the LED and made of a transparent material through which light is transmitted;
A pair of pogo pins contacting each of the individual electrodes to apply power;
A camera positioned above the transparent block and detecting light passing through the transparent block;
LED backlight unit test equipment comprising a. The method of claim 1,
The individual LED is provided with individual electrodes for applying power to the LED on both sides of each LED,
The probe unit,
A transparent block provided on the upper side of the LED and made of a transparent material through which light is transmitted;
A pair of pogo pins contacting each of the individual electrodes to apply power;
Including,
LED backlight unit testing equipment for detecting light passing through the transparent block by the vision unit being positioned above the transparent block. The method of claim 1,
The individual LED is provided with individual electrodes for applying power to the LED on both sides of each LED,
The probe unit,
A pair of pogo pins contacting each of the individual electrodes to apply power;
A measuring unit for measuring a reference potential difference between a pair of individual electrodes applied by the pogo pin;
LED backlight unit test equipment comprising a.

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