KR20030017440A - Chip on glass bonding equipment for lcd - Google Patents

Abstract

PURPOSE: An apparatus for bonding chip-on-glass of a liquid crystal display panel is provided to minimize the movement of a table and to reduce a period of time required for a boding process. CONSTITUTION: An apparatus for bonding chip-on-glass of a liquid crystal display panel is composed of a chip supply unit, a glass supply unit, an alignment unit, a table and a bonding unit(5). A means(60) for moving a bonding head(51) in a rectilinear direction and a means(80) for rotating the bonding head are installed on the bonding head of the bonding unit. The means for moving the bonding head in a rectilinear direction and the means for rotating the bonding head respectively include linear motors(61). A controller stores an image photographed by a micro-camera, and drives the moving means to compare a glass image and a chip image with each other to accord the central positions of the two images with each other.

Description

CHIP ON GLASS BONDING EQUIPMENT FOR LCD}

The present invention relates to a chip-on-glass bonding apparatus for a liquid crystal display panel. More particularly, the present invention relates to a linear movement means for moving the bonding head back, forth, left, and right on the bonding head portion of the bonding portion where the glass and semiconductor chips are pressed to bond. The present invention relates to a chip-on-glass bonding apparatus for a liquid crystal display panel provided with rotation moving means capable of rotating in a counterclockwise direction.

In recent years, as liquid crystal display (LCD) devices are made thin and short, a chip-on-glass method for directly attaching a liquid crystal display panel driving semiconductor chip to a TFT glass is being used.

If the semiconductor chip is directly attached to the glass as described above, complicated wiring is not required and a separate wiring space does not need to be secured.

In the conventional chip-on-glass bonding apparatus of the liquid crystal panel, the moving unit of the bonding unit is generally installed at the bottom of the table on which the glass and the semiconductor chip are placed.

However, when the bonding part or the moving means of the table is installed at the lower end of the table, the volume of the bonding apparatus is increased and the bonding means for aligning the glass and the semiconductor chip and the moving means of the table must be provided in a line. There was a problem that time was delayed.

In addition, conventionally, in order to align a semiconductor chip and glass, a physical deformation is applied to the semiconductor chip or glass, and the alignment of the deformed parts is checked and aligned, for example, a hole is formed in the semiconductor chip and glass, and the hole is formed. There is a problem in that damage to the semiconductor chip by using the alignment method to match the.

An object of the present invention is to solve the above problems, to minimize the movement of the table in which the bonding of the glass and the semiconductor chip by the pressure of the bonding head and to the front and rear left and right of the bonding head on the bonding head By installing the x-axis movement means, the y-axis movement means, and the rotation movement means for rotating the bonding head, which is a linear movement means capable of moving, the bonding head moves to the pressing surface on which the glass and the semiconductor chip are placed and freezes. The present invention provides a chip on glass bonding apparatus for a liquid crystal display panel which may be bonded after being printed.

1 is a front view of a bonding portion and a position moving means of a chip on glass bonding apparatus of a liquid crystal display panel according to the present invention.

2 is a side view of the bonding portion and the position shifting means of the chip on glass bonding apparatus of the liquid crystal display panel according to the present invention.

3 is a front view showing the overall configuration of the chip on glass bonding apparatus of the liquid crystal display panel according to the present invention.

Figure 4 is a side view showing the overall configuration of the chip on glass bonding apparatus of the liquid crystal display panel according to the present invention.

<Description of Symbols for Major Parts of Drawings>

1-Chip Supply Unit 2-Glass Supply Unit

3-Aligning section 4-Table

5-bonding part 6-position moving means

11-Chip Tray 12-Chip Picker

31-Microcamera 32-Monitor

41-Stage42-Pedestal

51-bonding head 52-z-axis movement

60-x-axis movement means 61-x-axis linear motor

62-x Fixed Shaft 63-x Moving Shaft

70-Y axis movement means 71-Y axis linear motor

72-y fixed axis

80-rotational means 81-axis of rotation

82-rotating plate 83-bonding head fixing member

In order to achieve the above object, the present invention provides a chip-on-glass bonding apparatus for a liquid crystal panel comprising a chip supply unit, a glass supply unit, an aligning unit, a table, and a bonding unit in order to bond a semiconductor chip to a liquid crystal display panel. A linear movement means for moving the bonding head in a linear direction and a rotation movement means for rotating the bonding head are installed on the head.

Another feature of the present invention is that the linear movement means and the rotary movement means comprises a linear motor.

Another feature of the present invention is to digitally convert an image captured by a micro-camera to the alignment unit to set its center position, store the image image, and compare the image image of the glass with the image image of the chip. It includes a control unit for driving the position moving means to match the center position of the two video images.

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

1 is a front view of a bonding portion and a position shifting means of a chip on glass bonding apparatus of a liquid crystal display panel according to the present invention, FIG. 2 is a side view of the bonding portion and a position shifting means, and FIG. 3 is a liquid crystal according to the present invention. The front side of the whole structure of the chip-on-glass bonding apparatus of a display panel is shown, and FIG. 4 shows the side surface of the whole structure.

First, the configuration of the present invention with reference to the drawings as follows.

The present invention provides a chip supply unit 1 to which a semiconductor chip is supplied, a glass supply unit 2 to which glass is to be bonded, and an aligning unit 3 to align the semiconductor chip and glass. And a table 4 on which the semiconductor chip and the glass are placed, a bonding portion 5 for bonding the semiconductor chip onto the glass, and an upper portion of the bonding portion 5 to provide the bonding portion 5. It consists of the position movement means 6 which moves.

The chip supply unit 1 is a chip tray 11 for supplying a semiconductor chip in a magazine in which a plurality of semiconductor chips are loaded, and the direction of the semiconductor chip supplied from the chip tray 11 on the table 4 up and down It consists of a chip picker (12).

The chip tray 11 is a servo motor that raises the semiconductor chip in the z-axis direction, which is the vertical direction of the plane, and moves the semiconductor chip raised in the vertical direction, to the xy plane, which is a direction parallel to the plane, to the chip picker. It consists of a servo motor supplied to (12).

At this time, the semiconductor chip loaded on the chip tray 11 is preferably placed so that the printing surface is directed to the upper side for the protection of the conductive wire printed on the semiconductor chip.

The chip picker 12 is vacuum adsorbed in contact with the semiconductor chip so that the upper and lower surfaces of the semiconductor chip supplied from the chip tray 11 are switched so that the printing surface of the semiconductor chip is in contact with the glass surface of the table 4. Means.

The glass supply unit 2 includes a glass index in which a plurality of glasses are stacked, a glass picker for moving the glass from the glass index to the table 4, and a glass aligning for aligning the glass moved by the glass picker. Means.

The glass picker is composed of a servo motor which can be moved to a table (4) where the glass laminated on the glass index is rotated by 45 ° to be bonded.

The glass aligning means is composed of a micro camera and a servo motor for aligning the glass supplied from the glass index in order to position the glass at a specific position of the table 4.

The aligning unit 3 includes a microcamera 31 installed at the lower end of the table 4, a monitor 32 installed at an upper side of the table 4, and a control unit so as to capture the semiconductor chip and glass. Not shown).

The image captured by the microcamera 31 is displayed on the monitor 32 so that the operator can correct it more precisely.

The control unit digitally converts the image image photographed by the microcamera 31, sets its center position, stores the image image, compares the image image of the glass with the image image of the chip, and compares the two image images. And a microprocessor programmed to drive the position shifting means to match the center position.

The table 4 is a surface on which the glass and the semiconductor chip are placed, and is pressed by the lowering of the bonding head 51 to form a bonding, and is composed of a stage 41 on a horizontal surface and a pedestal 42 capable of supporting it. .

In addition, the pedestal 42 includes a rotation motor capable of rotating the table 4 in a θ direction in a counterclockwise or clockwise direction.

The bonding portion 5 is composed of a bonding head 51 having a pressing surface for pressing the semiconductor chip, and a z-axis moving means 52 for moving the bonding head 51 up and down on the table 4. .

The bonding head 51 is formed with a pressing surface capable of pressing the entire surface to be bonded of the glass, and a heat generating means is provided therein.

When the heat generating means generates heat by the electric energy and then conducts heat to the pressing surface, the pressing surface is heated to conduct heat to the semiconductor chip aligned with the glass, thereby bonding.

In addition, the bonding head 51 is provided with a z-axis moving means 52 for moving the bonding head 51 up and down on the table (4).

The z-axis moving unit 52 is installed on one end of the z-axis servo motor and the z-axis servo motor in the same manner as the conventional bonding head 51 moving unit and connected to the bonding head 51. It consists of.

The position shifting means (6) is connected to the upper portion of the bonding head 51 of the bonding portion 5, the rotation movement means 80 for rotating the bonding head 51, and the upper portion of the rotation movement means 80 And linear moving means (60, 70) for moving the bonding head (51) in the x-axis or the y-axis on a parallel plane of the table (4).

The linear movement means is composed of the x-axis movement means 60 and the y-axis movement means (70).

The x-axis moving means 60 is a moving means for moving the bonding head 51 to the left and right when viewed from the front of the bonding apparatus, as shown in FIG. 1, an x-axis linear motor 61 and the x X fixed shaft 62 having one end fixed to the axial linear motor 61, and one end connected to one end of the x fixed shaft 62, and an x moving shaft whose lower surface is attached to the bonding head 51. It consists of 63.

The x-axis linear motor 61 is a motor that generates a linear motion without undergoing a rotational motion in the motor itself, when the x-axis linear motor 61 is operated, the x-axis shaft 63 is the x fixed shaft 62 ) And the left and right while maintaining a constant gap, the bonding head 51 connected to the lower portion of the x moving shaft 63 is moved to the left and right.

The y-axis moving means 70 is a moving means capable of moving the bonding head 51 back and forth when viewed from the front of the bonding apparatus. Referring to the side view of FIG. One end is connected to one end of the y fixed shaft 72 and one end thereof is fixed to the y axis linear motor 71, and a lower surface thereof is attached to the bonding head 51. It consists of the y moving shaft 73.

The y-axis linear motor 71 is a motor that generates a linear motion similar to the x-axis linear motor 61, the bonding is connected to the lower end of the y-axis (73) by the operation of the y-axis linear motor (71). The head 51 moves back and forth.

The rotary movement means 80 is a movement means capable of rotating the bonding head 51 in a counterclockwise or clockwise direction, and a rotary shaft 81 connected to the linear motor to rotate together with the drive of the linear motor. ), A rotary plate 82 connected to one end of the rotary shaft 81 and having a radius larger than that of the rotary shaft 81 to increase torque of the rotary shaft 81, and the rotary plate 82 and the bonding head ( 51 is composed of a bonding head fixing member 83 that secures the connection.

Next, an operation process of performing bonding using the chip on glass bonding apparatus of the liquid crystal display panel according to the present invention will be described.

First, in a magazine in which a plurality of semiconductor chips are loaded, a semiconductor chip is lifted in the z-axis direction by a servo motor and then moved in a horizontal direction to be supplied to the chip picker 12.

The semiconductor chip is loaded and transported with its printed surface facing upward for protection of the conductive wire printed on the semiconductor chip.

The chip picker 12 adsorbs the semiconductor chip by vacuum suction means so that the printing surface of the semiconductor chip supplied from the chip tray 11 is in contact with the glass, and then changes the upper and lower sides thereof to the table 4. The semiconductor chip is moved over the glass.

Then, the glass loaded on the glass index is rotated by 45 ° by the glass picker and moved to the table 4.

In addition, before being supplied to the table 4, the image of the semiconductor chip is imaged in advance by the microcamera 31, the image is digitized, and the center position thereof is set and stored. After taking the image again and digitizing the image, the center position is set, and the image image of the semiconductor chip previously captured and stored is compared with the image image of the semiconductor chip again to compare the center position of the image. Due.

When the center positions of the two images do not coincide with each other, the semiconductor chip may be driven by driving the x-axis linear motor 61, the y-axis linear motor 71, or the rotary axis linear motor provided in the position shifting means 6. To be in a position where it can be pressed.

In addition, the position shifting means is moved to compare and align the image image of the semiconductor chip with the image image of the glass so that the semiconductor chip is exactly positioned on the adhesive portion on the glass.

When the alignment is performed by comparing the image images of the semiconductor chip and the glass as described above, the alignment can be performed without damaging the semiconductor chip and the glass.

In addition, while the image of the glass and the semiconductor chip captured by the micro-camera 31 is transferred to the monitor 32 to see the screen displayed on the monitor 32, the operator is provided with a control unit provided in the aligning unit 3 May be manually converted and then aligned by driving the position shifting means 6.

After the alignment of the semiconductor chip and the glass is completed, the bonding head 51 is lowered by driving the z-axis servo motor of the z-axis moving means 52 installed in the bonding part 5. The pressing surface of pressurizes the glass and the semiconductor chip.

Heat generated from the heat generating means provided in the bonding head 51 is transferred to the pressing surface and then transferred to the glass and the semiconductor chip, and bonding is performed for a predetermined time.

After the bonding is completed, the bonding head 51 is lifted by the z-axis moving means 52, and the table 4 is rotated by a separate rotating means provided at the lower end thereof and transported to the next process.

At this time, a plurality of bonding positions are set on the table 4, and glass and semiconductor chips are pre-aligned at each bonding position, and the bonding head 51 is positioned on the position shifting means 6 provided thereon. As a result, the bonding process may be performed after the linear movement of the glass and the semiconductor chip is performed by linearly moving the x-axis or the y-axis, or by rotating the bonding portion to the central axis. In this case, the bonding time is further shortened.

In the above embodiment, only the case where the semiconductor chip is bonded to the liquid crystal panel has been described, but the same may also be applied to the case where the flexible printed circuit board (FPC) is bonded.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

As described above, according to the present invention, the movement of the table on which the glass and the semiconductor chip are bonded by the pressing of the bonding head is minimized, and the bonding portion provided with the bonding head moves linearly on the x-axis or the y-axis, or the center of the bonding portion. Since the bonding is performed by moving to the surface on which the glass and the semiconductor chip are placed while rotating in the axis, the bonding process can be shortened.

In addition, the present invention has an effect that the bonding time of the semiconductor chip and the glass and the pressing by the bonding head can be simultaneously performed at the upper portion of the bonding portion, thereby reducing the bonding time.

In addition, the present invention compares the image images of the semiconductor chip and the glass and aligns the same, thereby preventing damage to the semiconductor chip or the glass.

Claims (3)

In the chip-on-glass bonding apparatus of a liquid crystal panel comprising a chip supply unit, a glass supply unit, an aligning unit, a table and a bonding unit for bonding a semiconductor chip to the liquid crystal panel, And a linear movement means for moving the bonding head in a linear direction and a rotation movement means for rotating the bonding head on an upper portion of the bonding head of the bonding portion. The method of claim 1, And the linear movement means and the rotation movement means comprise a linear motor. The method of claim 1, Digitally convert the image captured by the micro camera to the alignment unit A control unit for setting the core position, storing the video image, and comparing the video image of the glass and the video image of the chip to drive the position shifting means to match the center positions of the two video images. A chip on glass bonding apparatus for a liquid crystal display panel.