KR102386338B1 - Die transfer module and die bonding apparatus having the same - Google Patents

Abstract

Disclosed are a die transfer module and a die bonding apparatus including the same. The die transfer module includes a stage unit for supporting the dicing tape to which dies are attached, a swing arm configured to be swingable about a rotational axis disposed in a horizontal direction at an upper portion of the stage unit, and a lower portion of the swing arm a pickup unit for picking up a first die among the dies, and a swing driving unit for rotating the swing arm by a first angle in a first direction after the first die is picked up by the pickup unit; a die stage disposed to face the pickup unit in a state in which the swing arm is rotated in the first direction and receiving the first die from the pickup unit; and after the first die is transferred onto the die stage a first rotation driving unit for rotating the die stage so that the first die faces upward; and a second rotation for rotating the die stage with respect to a central axis of the die stage to align the first die on the die stage. includes a driving unit. The first die transferred onto the die stage is picked up by a bonding module and then bonded onto a substrate.

Description

Die transfer module and die bonding device including same

Embodiments of the present invention relate to a die transfer module and a die bonding apparatus including the same. More particularly, it relates to a die transfer module for transferring dies in order to perform a die bonding process for bonding dies on a substrate such as a printed circuit board or a lead frame, and a die bonding apparatus including the same.

In general, semiconductor devices may be formed on a silicon wafer used as a semiconductor substrate by repeatedly performing a series of manufacturing processes. A wafer on which the semiconductor devices are formed may be divided into a plurality of dies through a dicing process, and the dies may be bonded to a substrate through a bonding process.

The wafer may be transferred to a die bonding process while being attached to the dicing tape, and an apparatus for performing the die bonding process includes a wafer stage for supporting the wafer, and separating the dies from the dicing tape. It may include a die ejector for, a die transfer unit for moving the separated die onto the die stage, and a bonding unit for picking up the die on the die stage and bonding to the substrate.

The die transfer unit may include a picker for picking up the die from the dicing tape by using vacuum pressure, and a picker driver for moving the picker in vertical and horizontal directions for transferring the die. In general, the picker driving unit includes a horizontal driving unit for moving the picker in a horizontal direction, and a vertical driving unit mounted on the horizontal driving unit and moved in a horizontal direction by the horizontal driving unit and configured to move the picker in a vertical direction. can do. However, since the volume of the vertical driving unit is relatively large and its weight is relatively heavy, vibration may be generated in the process of moving the picker, and there is a limit to increasing the moving speed of the picker, so it is necessary to transport the die. There is a limit to shortening the time.

Republic of Korea Patent Publication No. 10-2017-0089269 (published on August 03, 2017) Republic of Korea Patent Publication No. 10-2018-0060254 (published on June 07, 2018)

An object of the present invention is to provide a die transfer module capable of reducing vibration in a die transfer process and shortening the time required for die transfer, and a die bonding apparatus including the same.

A die transfer module according to an aspect of the present invention for achieving the above object includes a stage unit for supporting a dicing tape to which dies are attached, and a swingable axis of rotation arranged in a horizontal direction at an upper portion of the stage unit. a swing arm configured to move, a pickup unit mounted on a lower portion of the swing arm for picking up a first die among the dies, and after the first die is picked up by the pickup unit, the swing arm is moved in a first direction a swing driving unit for rotating by a first angle; a die stage disposed to face the pickup unit in a state in which the swing arm is rotated in the first direction and receiving the first die from the pickup unit; a first rotation drive for rotating the die stage so that the first die faces upward after the first die is transferred onto the die stage; and a center of the die stage to align the first die on the die stage. A second rotation driving unit may be included to rotate the die stage based on an axis.

According to some embodiments of the present disclosure, the first rotation driving unit may include a first stage motor for rotating the die stage, a first bracket to which the first stage motor is mounted, and the second rotation driving unit mounted thereon. and a rotation bracket configured to be rotatable by the first stage motor.

According to some embodiments of the present disclosure, the second rotation driving unit may include a second bracket mounted to the rotation bracket, and a second stage motor mounted to the second bracket and configured to rotate the die stage. there is.

According to some embodiments of the present invention, the first stage motor is a direct drive motor having a hollow rotation shaft, and the rotation bracket is provided with an opening corresponding to the hollow of the hollow rotation shaft, and the second A power supply line of the stage motor may be connected to the second stage motor through the hollow of the hollow rotating shaft and the opening.

According to some embodiments of the present disclosure, the second stage motor may be a second direct drive motor having a second hollow rotation shaft, and the die stage may be mounted on the second hollow rotation shaft.

According to some embodiments of the present invention, the die stage includes a vacuum chuck for vacuum adsorbing the first die, and the vacuum chuck is configured to be connected to a vacuum pump through the hollow rotation shaft, the rotation bracket, and the second hollow rotation shaft. can be connected

According to some embodiments of the present invention, the rotation bracket is provided with a vacuum passage, and the die transfer module includes a first vacuum pipe connecting the vacuum pump and the vacuum passage through the hollow rotation shaft, and the second It may further include a second vacuum pipe connecting between the vacuum passage and the vacuum chuck through the second hollow rotation shaft.

According to some embodiments of the present disclosure, the swing driving unit may include a motor for providing a rotational force, a first link member connected to the motor so as to be rotatable by the motor, and the swing arm and the first link member It may include a second link member for connecting them.

According to some embodiments of the present invention, the pickup unit includes a vacuum picker for vacuum adsorbing the first die using vacuum pressure, and picks up the first die from the dicing tape and is on the die stage. and a picker driving unit for moving the vacuum picker in an extension direction of the swing arm to put it down.

According to some embodiments of the present invention, the die transfer module may further include a camera unit for detecting the first die attached to the dicing tape.

According to some embodiments of the present disclosure, the camera unit is disposed on the first die, the pickup unit is mounted on a lower side of the swing arm, and the first die is detected by the camera unit Then, the swing driver may rotate the swing arm so that the pickup unit is positioned between the camera unit and the first die in order to pick up the first die.

A die bonding apparatus according to another aspect of the present invention for achieving the above object includes a stage unit for supporting a dicing tape to which dies are attached, and a swingable axis of rotation arranged in a horizontal direction at an upper portion of the stage unit. a swing arm configured to move, a pickup unit mounted on a lower portion of the swing arm for picking up a first die among the dies, and after the first die is picked up by the pickup unit, the swing arm is moved in a first direction a swing driving unit for rotating by a first angle; a die stage disposed to face the pickup unit in a state in which the swing arm is rotated in the first direction and receiving the first die from the pickup unit; a first rotation drive for rotating the die stage so that the first die faces upward after the first die is transferred onto the die stage; and a center of the die stage to align the first die on the die stage. It may include a second rotation driving unit for rotating the die stage based on an axis, and a bonding module for picking up the first die on the die stage and bonding the first die to the substrate.

According to some embodiments of the present disclosure, the die bonding apparatus may further include a camera unit disposed on the die stage and configured to detect the first die on the die stage.

According to some embodiments of the present invention, the bonding module includes a substrate stage for supporting the substrate, a bonding head for picking up the first die from the die stage using vacuum pressure, and the first die It may include a head driving unit for moving the bonding head in vertical and horizontal directions in order to bond on the substrate.

According to some embodiments of the present invention, the die bonding apparatus is disposed under the dicing tape supported by the stage unit and separates the first die from the dicing tape. a die ejector that raises the die; a stage driver that horizontally moves the stage unit so that the first die among the dies is positioned above the die ejector; and the first die positioned above the die ejector is detected. It may further include a camera unit for

According to some embodiments of the present disclosure, the camera unit is disposed on the first die, the pickup unit is mounted on a lower side of the swing arm, and the first die is detected by the camera unit Then, the swing driver may rotate the swing arm so that the pickup unit is positioned between the camera unit and the first die in order to pick up the first die.

According to the embodiments of the present invention as described above, the dies may be transferred from the dicing tape onto the die stage by the swing arm and the pickup unit. As a result, as compared with the prior art, vibration due to inertia can be greatly reduced. In particular, by configuring the swing driving unit using the first and second link members, it is possible to further reduce vibration due to inertia that may be generated in the rotational operation of the swing arm. In addition, compared with the prior art, the transport distance of the dies may be shortened, and accordingly, the time required for the transport of the dies may be greatly reduced.

Additionally, the second rotation is performed by configuring a first rotation driving unit for rotating the die stage to correspond to rotation of the swing arm and a second rotation driving unit for aligning the first die on the die stage using a direct drive motor. It is possible to facilitate the installation of a power supply line and a vacuum pipe connected to the driving unit.

1 is a schematic plan view for explaining a die bonding apparatus according to an embodiment of the present invention.
FIG. 2 is a schematic front view for explaining the die transfer module shown in FIG. 1 .
3 is a schematic front view for explaining the operation of the die transfer module shown in FIG.
Figure 4 is a schematic side view for explaining the die transfer module shown in Figure 2;
FIG. 5 is a schematic side view for explaining the rotation driving unit shown in FIG. 2 .

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention should not be construed as being limited to the embodiments described below and may be embodied in various other forms. The following examples are provided to sufficiently convey the scope of the present invention to those skilled in the art, rather than being provided so that the present invention can be completely completed.

In embodiments of the present invention, when an element is described as being disposed or connected to another element, the element may be directly disposed or connected to the other element, and other elements may be interposed therebetween. it might be Conversely, when one element is described as being directly disposed on or connected to another element, there cannot be another element between them. Although the terms first, second, third, etc. may be used to describe various items such as various elements, compositions, regions, layers and/or portions, the items are not limited by these terms. will not

The terminology used in the embodiments of the present invention is only used for the purpose of describing specific embodiments, and is not intended to limit the present invention. Further, unless otherwise limited, all terms including technical and scientific terms have the same meaning as understood by one of ordinary skill in the art of the present invention. The above terms, such as those defined in ordinary dictionaries, shall be interpreted as having meanings consistent with their meanings in the context of the related art and description of the present invention, ideally or excessively outwardly intuitive, unless clearly defined. will not be interpreted.

Embodiments of the present invention are described with reference to schematic diagrams of ideal embodiments of the present invention. Accordingly, changes from the shapes of the diagrams, eg, changes in manufacturing methods and/or tolerances, are those that can be fully expected. Accordingly, the embodiments of the present invention are not to be described as being limited to the specific shapes of the areas described as diagrams, but rather to include deviations in the shapes, and the elements described in the drawings are purely schematic and their shapes It is not intended to describe the precise shape of the elements, nor is it intended to limit the scope of the present invention.

1 is a schematic plan view for explaining a die bonding apparatus according to an embodiment of the present invention. Figure 2 is a schematic front view for explaining the die transfer module shown in Figure 1, Figure 3 is a schematic front view for explaining the operation of the die transfer module shown in Figure 2, Figure 4 is shown in It is a schematic side view for explaining the die transfer module.

1 to 4 , the die bonding apparatus 100 according to an embodiment of the present invention provides a die ( 20) can be used for bonding. The die bonding apparatus 100 may pick up the dies 20 from the wafer 10 including the individual dies 20 by a dicing process and bond them onto the substrate 30 . The wafer 10 may be provided in a state of being attached to the dicing tape 12 , and the dicing tape 12 may be mounted on a mount frame 14 having a substantially circular ring shape.

According to an embodiment of the present invention, the die bonding apparatus 100 may include a die transfer module 200 and a bonding module 300 . The die transfer module 200 may pick up a die 20 to be bonded from the dicing tape 12 and transfer the die 20 to the bonding module 300 , and the bonding module 300 may The die 20 may be bonded to the substrate 30 . In addition, the die bonding apparatus 100 includes a load port 110 supporting a cassette 50 in which a plurality of wafers 10 are accommodated, and withdrawing the wafer 10 from the cassette 50 to be described later. a wafer transfer unit 120 for loading onto a stage unit 202 , and guide rails 130 for guiding the wafer 10 between the cassette 50 and the stage unit 202 . can

The die transfer module 200 may include a stage unit 202 for supporting the wafer 10 . The stage unit 202 may include a wafer stage 204 . A circular ring-shaped support ring 206 may be disposed on the wafer stage 204 , and the support ring 206 may support an edge portion of the dicing tape 12 . In addition, the dicing tape 12 can be expanded by lowering the mount frame 14 on the wafer stage 204 while the dicing tape 12 is supported by the support ring 206 . An expansion ring 208 may be disposed.

A die ejector 210 for selectively separating the dies 20 may be disposed under the wafer 10 supported on the stage unit 202 . Although not shown, the die ejector 210 includes a hood for vacuum adsorbing the dicing tape 12 in close contact with the lower surface of the dicing tape 12 , and a hood to be picked up from among the dies 20 . Ejector pins for lifting the die 20 to separate the die 20 from the dicing tape 12 may be included. For example, the hood may have a plurality of vacuum holes for vacuum adsorbing the dicing tape 12 , and the ejector pins may be inserted into some of the vacuum holes.

Meanwhile, although not shown, the stage unit 202 may be configured to be movable in the horizontal direction by a stage driving unit (not shown), and the stage driving unit guides the wafer 10 for loading and unloading. The stage unit 202 may be moved to a wafer load/unload area adjacent to the ends of the rails 130 . Also, the stage driver may move the stage unit 202 to selectively pick up the dies 20 . That is, the stage driver may adjust the position of the stage unit 202 so that the die 20 to be picked up among the dies 20 is located above the die ejector 210 .

The die transfer module 200 is a swing arm 214 configured to be able to swing based on a rotation shaft 212 disposed in a horizontal direction, for example, a Y-axis direction at the upper portion of the stage unit 202 . ) and a pickup unit 216 mounted on the lower portion of the swing arm 214 and configured to pick up one of the dies 20 . For example, the stage driver may move the stage unit 202 so that a first die 22 of the dies 20 is positioned above the die ejector 210 , and the die ejector 210 may be disposed on the stage unit 202 . ) may separate the first die 22 from the dicing tape 12 . The pickup unit 216 includes a vacuum picker 218 for vacuum adsorbing the first die 22 by using vacuum pressure, and a vacuum picker 218 for picking up the first die 22 from the dicing tape 12 . For this purpose, the vacuum picker 218 may include a picker driving unit 220 for moving in the extension direction of the swing arm 214 .

After the first die 22 is picked up by the pickup unit 216 , the die transfer module 200 moves the swing arm 214 in a first direction, for example, counterclockwise as shown. and a swing driving unit 222 for rotating by a first angle preset by A die stage 230 for receiving the first die 22 may be included.

For example, the picker driver 220 may move the vacuum picker 218 in an extension direction of the swing arm 214 to place the first die 22 on the die stage 230 . there is. The swing driving unit 222 includes a motor 224 for providing a rotational force, a first link member 226 connected to the motor 224 and configured to be rotatable by the motor 224 , and the swing arm A second link member 228 connecting the lower portion of the 214 and the first link member 226 may be included. Also, although not shown, the die stage 230 may include a vacuum chuck 232 for vacuum adsorbing the first die 22 . Although not shown, the vacuum chuck 232 may have a plurality of vacuum holes for vacuum adsorbing the first die 22 .

After transferring the first die 22 onto the die stage 230 as described above, the swing driver 222 moves the swing arm 214 so that the pickup unit 216 is positioned above the die ejector 210 . ) can be rotated in the second direction, for example, clockwise. In addition, after the first die 22 is transferred onto the die stage 230 , the die stage 230 transfers the first die 22 to the bonding module 300 . 22 may be rotated by the first rotation driving unit 234 to face upward.

Meanwhile, the die transfer module 200 may include a first camera unit 260 for detecting the first die 22 before picking up the first die 22 . The first camera unit 260 may be disposed on the die ejector 210 , and after the first die 22 is positioned on the die ejector 210 , the first die 22 . can be detected. In addition, the stage driving unit performs the stage so that the first die 22 is accurately positioned under the pickup unit 216 according to the detection result of the first die 22 by the first camera unit 260 . The position of the unit 202 can be adjusted.

In particular, the pickup unit 216 is rotated in the first direction while the first die 22 is detected by the first camera unit 260 and the position of the first die 22 is adjusted. can be maintained as After the position adjustment of the first die 22 is completed as described above, the swing driving unit 222 uses the pickup unit 216 to move the first camera unit 260 and the first die 22 to pick up the first die 22 . The swing arm 214 may be rotated to be positioned between the first dies 22 , ie, the pickup unit 216 may be positioned above the die ejector 210 . At this time, as shown in FIG. 4 , the pickup unit 216 is positioned on the lower side of the swing arm 214 so as not to interfere with the detection of the first die 22 by the first camera unit 260 . can be mounted on

The first die 22 positioned on the die stage 230 may be bonded to the substrate 30 by the bonding module 300 . The bonding module 300 includes a substrate stage 310 for supporting the substrate 30 and heating to a preset bonding temperature, and the first die 22 from the die stage 230 using vacuum pressure. and a bonding head 312 for picking up the , and a head driving unit 314 for moving the bonding head 312 in vertical and horizontal directions in order to bond the first die 22 on the substrate 30. can In particular, a second camera unit 320 for detecting the first die 22 on the die stage 230 may be disposed on the die stage 230 , and the second camera unit 320 may be disposed on the die stage 230 . After the first die 22 is detected by , the head driving unit 314 may vertically move the bonding head 312 to pick up the first die 22 .

FIG. 5 is a schematic side view for explaining the rotation driving unit shown in FIG. 2 .

Referring to FIG. 5 , the first rotation driving unit 234 includes a first stage motor 236 for rotating the die stage 230 and a first bracket to which the first stage motor 236 is mounted. 240 , and a rotation bracket 242 on which the die stage 230 is mounted and configured to be rotatable by the first stage motor 236 .

In addition, the die transfer module 200 rotates the die stage 230 with respect to a central axis of the die stage 230 in order to align the first die 22 on the die stage 230 . It may include a rotation driving unit 244 . For example, the second rotation driving unit 244 may include a second bracket 246 mounted to the rotation bracket 242 , and a second bracket mounted to the second bracket 246 to rotate the die stage 230 . It may include a second stage motor 248 for The first die 22 on the die stage 230 may be detected by the second camera unit 320 , and the second rotation driving unit 244 may be detected by the second camera unit 320 . The rotation angle of the die stage 230 may be adjusted according to the detection result of the first die 22 .

According to an embodiment of the present invention, a first direct drive motor having a first hollow rotation shaft 238 may be used as the first stage motor path 236 , and a second hollow motor path 248 may be used as the second stage motor 248 . A second direct drive motor having a rotating shaft 250 may be used.

For example, the first bracket 240 may have a first opening 240a exposing one end of the first hollow rotation shaft 238 , and the first stage motor 236 may be configured to operate the first bracket. It may be mounted on one side of the 240 . In this case, the rotation bracket 242 may be mounted on one end of the first hollow rotation shaft 238 exposed through the first opening 240a. The rotation bracket 242 may have a substantially circular disk shape, and the second bracket 246 may be mounted on one side of the rotation bracket 242 . The second bracket 246 may have a second opening 246a exposing one end of the second hollow rotation shaft 250 , and the second stage motor 248 is attached to the second bracket 246 . Can be mounted vertically. In this case, the die stage 230 may be mounted on the upper end of the second hollow rotation shaft 250 exposed through the second opening 246a.

According to one embodiment of the present invention, the rotation bracket 242 may have a third opening 242a corresponding to the hollow of the first hollow rotation shaft 238, and the second stage motor 248 The second power supply line 248a may be connected to a power supply unit (not shown) through a hollow of the third opening 242a and the first hollow rotating shaft 238 . In addition, although not shown, the second stage motor 248 includes a second encoder (not shown) for measuring the rotation angle of the second hollow rotation shaft 250 for aligning the first die 22 . A second signal line 248b connected to the second encoder also passes through the third opening 242a and the first hollow rotation shaft 238 through the first and second stage motors 236 , 248 may be connected to a controller (not shown) for controlling the operation.

The first stage motor 236 may be connected to the power supply unit through a first power supply line 236a. In addition, although not shown, the first stage motor 236 may include a first encoder (not shown) for adjusting the angle of the die stage 230 , and the first encoder is a first signal line 236b ) may be connected to the control unit.

Meanwhile, a vacuum chuck 232 having a vacuum hole for vacuum adsorbing the first die 22 may be provided on the die stage 230 . The vacuum chuck 232 may be connected to the vacuum pump 252 through the first hollow rotation shaft 238 , the rotation bracket 242 , and the second hollow rotation shaft 250 . For example, a vacuum flow path 242b is provided in the rotation bracket 242 , and a first vacuum connecting the vacuum pump 252 and the vacuum flow path 242b through the first hollow rotation shaft 238 . The vacuum chuck 232 is moved to the vacuum by a second vacuum pipe 256 connecting the vacuum passage 242b and the vacuum chuck 232 through a pipe 254 and the second hollow rotation shaft 250 . It may be connected to a pump 252 . In this case, the die stage 230 may include a through hole connecting the vacuum hole of the vacuum chuck 232 and the second vacuum pipe 256 . However, unlike the above, although not shown, the die transfer module 200 is vacuumed through the hollow of the first hollow rotation shaft 238 and the hollow of the third opening 242a and the second hollow rotation shaft 250 . A vacuum pipe (not shown) connecting the pump 252 and the vacuum chuck 232 may be provided.

Referring back to FIG. 1 , the substrate 30 may be supplied from the first magazine 40 , and may be moved to the bonding area by the substrate transfer unit 140 . The substrate stage 310 may be disposed in the bonding area, and the substrate 30 on which the die bonding process is completed may be accommodated in the second magazine 42 by the substrate transfer unit 140 . Meanwhile, while the first die 22 is bonded on the substrate 30 by the bonding module 300 , the second die is transferred onto the die stage 230 by the die transfer module 200 . can be

According to the embodiments of the present invention as described above, the dies 20 are moved from the dicing tape 12 onto the die stage 230 by the swing arm 214 and the pickup unit 216 . can be transported As a result, as compared with the prior art, vibration due to inertia can be greatly reduced. In particular, by configuring the swing driving unit 222 using the first and second link members 226 and 228 , it is possible to further reduce vibration caused by inertia that may be generated in the rotational operation of the swing arm 214 . can In addition, as compared with the prior art, the transport distance of the dies 20 may be shortened, and accordingly, the time required for transport of the dies 20 may be greatly reduced.

Additionally, a first rotation driving unit 234 for rotating the die stage 230 to correspond to rotation of the swing arm 214 and a second rotation driving unit 234 for aligning the first die 22 on the die stage 230 By configuring the rotation driving unit 244 using a direct drive motor, it is possible to facilitate installation of a power supply line and a vacuum pipe connected to the second rotation driving unit 244 .

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the following claims. You will understand that there is

10: wafer 12: dicing tape
14: mount frame 20: die
30: substrate 100: die bonding device
200: substrate transfer module 202: stage unit
210: die ejector 212: rotation shaft
214: swing arm 216: pickup unit
218: picker 220: picker driving unit
222: swing driving unit 224: motor
226: first link member 228: second link member
230: die stage 234: first rotation driving unit
236: first stage motor 238: first hollow rotating shaft
240: first bracket 242: rotation bracket
244: second rotation driving unit 246: third bracket
248: second stage motor 250: second hollow rotating shaft
252: first vacuum pipe 254: second vacuum pipe
260: first camera unit 300: bonding module
310: substrate stage 312: bonding head
314: head driving unit 320: second camera unit

Claims (16)

a stage unit for supporting a dicing tape to which dies are attached;
a swing arm configured to be swingable about a rotational axis disposed in a horizontal direction at an upper portion of the stage unit;
a pickup unit mounted to a lower portion of the swing arm and configured to pick up a first die among the dies;
a swing driving unit configured to rotate the swing arm by a first angle in a first direction after the first die is picked up by the pickup unit;
a die stage disposed to face the pickup unit in a state in which the swing arm is rotated in the first direction and configured to receive the first die from the pickup unit;
a first rotation driving unit configured to rotate the die stage such that the first die faces upward after the first die is transferred onto the die stage; and
a second rotational driving unit for rotating the die stage with respect to a central axis of the die stage to align the first die on the die stage;
The swing driving unit includes a motor for providing a rotational force, a first link member connected to the motor so as to be rotatable by the motor, and a second link member connecting the swing arm and the first link member. do,
The first rotation driving unit includes a first direct drive motor having a hollow rotating shaft, and a rotating bracket to which the second rotation driving unit is mounted and configured to be rotatable by the first direct drive motor,
The rotation bracket is provided with an opening corresponding to the hollow of the hollow rotation shaft,
A power supply line for the operation of the second rotation driving unit is connected to the second rotation driving unit through the hollow of the hollow rotating shaft and the opening. delete According to claim 1, wherein the second rotation driving unit,
a second bracket mounted on the rotating bracket;
and a second stage motor mounted on the second bracket and configured to rotate the die stage. delete 4. The method of claim 3, wherein the second stage motor is a second direct drive motor having a second hollow rotation shaft,
The die stage is a die transfer module, characterized in that mounted on the second hollow rotating shaft. 6. The method of claim 5, wherein the die stage includes a vacuum chuck for vacuum adsorbing the first die;
The vacuum chuck is connected to the vacuum pump through the hollow rotary shaft, the rotary bracket, and the second hollow rotary shaft. According to claim 6, wherein the rotation bracket is provided with a vacuum flow path,
a first vacuum pipe connecting the vacuum pump and the vacuum passage through the hollow rotating shaft;
The die transfer module further comprising a second vacuum pipe connecting between the vacuum passage and the vacuum chuck through the second hollow rotating shaft. delete According to claim 1, wherein the pickup unit,
a vacuum picker for vacuum adsorbing the first die using vacuum pressure;
and a picker driver for moving the vacuum picker in an extension direction of the swing arm to pick up the first die from the dicing tape and put it down on the die stage. The die transfer module according to claim 1, further comprising a camera unit for detecting the first die attached to the dicing tape. 11. The method of claim 10, wherein the camera unit is disposed on the upper portion of the first die, the pickup unit is mounted on a lower side of the swing arm, and after the first die is detected by the camera unit, the swing The driving unit rotates the swing arm so that the pickup unit is positioned between the camera unit and the first die to pick up the first die. a stage unit for supporting a dicing tape to which dies are attached;
a swing arm configured to be swingable about a rotational axis disposed in a horizontal direction at an upper portion of the stage unit;
a pickup unit mounted to a lower portion of the swing arm and configured to pick up a first die among the dies;
a swing driving unit configured to rotate the swing arm by a first angle in a first direction after the first die is picked up by the pickup unit;
a die stage disposed to face the pickup unit in a state in which the swing arm is rotated in the first direction and configured to receive the first die from the pickup unit;
a first rotation driving unit configured to rotate the die stage such that the first die faces upward after the first die is transferred onto the die stage;
a second rotation driving unit for rotating the die stage with respect to a central axis of the die stage to align the first die on the die stage; and
a bonding module for picking up a first die on the die stage and bonding it to a substrate;
The swing driving unit includes a motor for providing a rotational force, a first link member connected to the motor so as to be rotatable by the motor, and a second link member connecting the swing arm and the first link member. do,
The first rotation driving unit includes a first direct drive motor having a hollow rotating shaft, and a rotating bracket to which the second rotation driving unit is mounted and configured to be rotatable by the first direct drive motor,
The rotation bracket is provided with an opening corresponding to the hollow of the hollow rotation shaft,
A power supply line for the operation of the second rotation driving unit is connected to the second rotation driving unit through the hollow of the hollow rotating shaft and the opening. 13. The die bonding apparatus of claim 12, further comprising a camera unit disposed on the die stage and configured to detect the first die on the die stage. The method of claim 12, wherein the bonding module,
a substrate stage for supporting the substrate;
a bonding head that picks up the first die from the die stage using vacuum pressure;
and a head driving unit configured to move the bonding head in vertical and horizontal directions to bond the first die onto the substrate. 13. The die ejector of claim 12, further comprising: a die ejector disposed below the dicing tape supported by the stage unit and lifting the first die to separate the first die from the dicing tape;
a stage driving unit for horizontally moving the stage unit such that the first die among the dies is positioned above the die ejector;
The die bonding apparatus according to claim 1, further comprising a camera unit for detecting the first die located on the upper part of the die ejector. 16. The method of claim 15, wherein the camera unit is disposed on the upper part of the first die, the pickup unit is mounted on a lower side of the swing arm, and after the first die is detected by the camera unit, the swing A driving unit rotates the swing arm so that the pickup unit is positioned between the camera unit and the first die to pick up the first die.

Images