KR102377825B1 - Die transfer module and die bonding apparatus including the same - Google Patents

Abstract

A die bonding apparatus is disclosed. The die bonding apparatus includes a die transfer module for picking up and transferring a die, and a die bonding module for bonding the die transferred by the die transfer module onto a substrate. The die transfer module includes a non-contact picker for picking up the die in a non-contact manner so as not to contact the front surface of the die, and receives the die picked up by the non-contact picker and moves the die so that the front surface of the die faces downward a flipper for inverting, a non-contact die stage for supporting the inverted die in a non-contact manner, and an alignment unit for aligning the die on the non-contact die stage to a predetermined position. The die bonding module picks up the aligned die on the non-contact die stage and bonds it onto the substrate.

Description

Die transfer module and die bonding device including the same

Embodiments of the present invention relate to a die transfer module and a die bonding apparatus including the same. More specifically, a die transfer module for picking up and transferring individual dies by a dicing process in a manufacturing process of a semiconductor device, and a die transferred by the die transfer module to a printed circuit board, lead frame, semiconductor wafer, etc. It relates to a die bonding apparatus for bonding on a substrate of

In general, semiconductor devices may be formed on a silicon wafer used as a semiconductor substrate by repeatedly performing a series of manufacturing processes. The wafer on which the semiconductor devices are formed may be individualized into a plurality of dies through a dicing process, and the individual dies through the dicing process are formed on a substrate such as a lead frame, a printed circuit board, and a semiconductor wafer through a die bonding process. can be bonded to

The apparatus for performing the die bonding process may include a die transfer module for picking up and transferring the dies from the wafer divided into the dies, and a die bonding module for bonding the transferred die onto a substrate. The die transfer module includes a stage unit for supporting the wafer, a die ejector for selectively separating a die from a wafer supported by the stage unit, a picker for picking up and transferring the die from the wafer, and the transfer; and a die stage for supporting the die, wherein the die bonding module includes a substrate stage for supporting the substrate, and a bonding head for picking up a die on the die stage and bonding the die on the substrate can do.

Recently, as the degree of integration of semiconductor devices increases, the pad pitch on the die is gradually reduced. Accordingly, contamination of the front surface of the die bonded to the substrate in the die bonding process is highlighted as a problem to be solved. In particular, in the case of a TSV (Through Silicon Via) bonding process for manufacturing a stacked semiconductor device, a plurality of electrode pads may be disposed on the front surface of the die, and a problem of contamination due to contact in the process of being picked up from the wafer by the picker may occur.

Republic of Korea Patent Publication No. 10-2019-0034858 (published on April 03, 2019)

It is an object of the present invention to provide a die transfer module capable of preventing contamination of the die during pickup and transfer of the die, 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 non-contact picker for picking up the die in a non-contact manner so as not to come into contact with the front surface of the die, and receives the die picked up by the non-contact picker and the A flipper for inverting the die so that the front side of the die faces down, a non-contact die stage for supporting the inverted die in a non-contact manner, and an alignment unit for aligning the die on the non-contact die stage in a predetermined position may include

According to some embodiments of the present invention, the non-contact picker includes an ultrasonic vibration unit that provides a repulsive force for pushing the die using ultrasonic vibration, and a vacuum pressure to the die so that the die is maintained in a non-contact state. It may include a vacuum chuck that provides a suction force.

According to some embodiments of the present invention, the ultrasonic vibration unit includes an ultrasonic oscillator for generating the ultrasonic vibration, a horn for transmitting the ultrasonic vibration, and is connected to an end of the horn and vibrates by the ultrasonic vibration It may include a diaphragm.

According to some embodiments of the present invention, the vacuum chuck is configured to surround the diaphragm and may have a lower surface facing the front surface of the die.

According to some embodiments of the present disclosure, the diaphragm may have a shape of a square plate, and the vacuum chuck may have a shape of a square ring surrounding the diaphragm.

According to some embodiments of the present invention, the vacuum chuck includes a lower surface facing the front surface of the die, vacuum holes for providing the vacuum pressure, and air between the front surface and the lower surface of the die. It may include air holes for supplying.

According to some embodiments of the present invention, the non-contact die stage includes an ultrasonic vibration unit that provides a repulsive force for floating the die using ultrasonic vibration, and a vacuum pressure so that the die is maintained in a floating state. It may include a vacuum stage that provides a suction force to the die.

According to some embodiments of the present invention, the ultrasonic vibration unit of the non-contact die stage includes an ultrasonic oscillator for generating the ultrasonic vibration, a horn for transmitting the ultrasonic vibration, and an end of the horn connected to the ultrasonic wave It may include a diaphragm vibrating by vibration.

According to some embodiments of the present disclosure, the vacuum stage may have an opening in which the diaphragm is disposed, and an upper surface facing the front surface of the die.

According to some embodiments of the present disclosure, the vacuum stage may have vacuum holes disposed in a ring shape to surround the opening.

According to some embodiments of the present invention, the vacuum stage is disposed between the vacuum holes and may have air holes for supplying air between the front surface and the upper surface of the die.

According to some embodiments of the present disclosure, the die transfer module may further include a flipper driving unit that moves the flipper toward the non-contact die stage.

According to some embodiments of the present invention, the alignment unit includes alignment members disposed to face side surfaces of the die on the non-contact die stage, and for adjusting positions of the alignment members according to the size of the die. It may include position adjusters.

A die bonding apparatus according to another aspect of the present invention for achieving the above object includes a die transfer module for picking up and transferring a die, and a die bonding module for bonding the die transferred by the die transfer module onto a substrate may include, wherein the die transfer module receives a non-contact picker for picking up the die in a non-contact manner so as not to come into contact with the front surface of the die, and receives the die picked up by the non-contact picker, and the front surface of the die is below a flipper for inverting the die to face A bonding module may pick up the aligned die on the non-contact die stage and bond it onto the substrate.

According to the embodiments of the present invention as described above, the die may be picked up and transported by the non-contact picker, inverted by the flipper, and then placed on the non-contact die stage, on the non-contact die stage may be aligned by the alignment unit. As described above, contact with the front portion of the die can be prevented during the pickup and transfer of the die, and accordingly, contamination due to contact can be sufficiently prevented, and defects due to die contamination in the die bonding process are greatly reduced. can be

1 is a schematic configuration diagram for explaining a die transfer module and a die bonding apparatus including the same according to an embodiment of the present invention.
FIG. 2 is a schematic configuration diagram for explaining the die transfer module shown in FIG. 1 .
3 is a schematic cross-sectional view for explaining an example of the non-contact picker shown in FIG.
FIG. 4 is a schematic bottom view for explaining another example of the vacuum chuck shown in FIG. 3 .
FIG. 5 is a schematic cross-sectional view for explaining an example of the non-contact die stage shown in FIG. 2 .
6 is a schematic plan view for explaining another example of the vacuum stage shown in FIG. 5 .
7 is a schematic plan view for explaining an example of the alignment unit shown in FIG.

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 to have 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 configuration diagram for explaining a die transport module and a die bonding apparatus including the same according to an embodiment of the present invention, FIG. 2 is a schematic configuration diagram for explaining the die transport module shown in FIG. am.

1 and 2 , a die bonding apparatus 10 according to an embodiment of the present invention picks up individualized dies 22 by a dicing process in a semiconductor device manufacturing process to form a lead frame and a printed circuit. It may be used for bonding on a substrate 30 such as a substrate or a semiconductor wafer. The die bonding apparatus 10 includes a die transfer module 100 for picking up and transferring the die 22 , and bonding the die 22 transferred by the die transfer module 100 onto the substrate 30 . It may include a die bonding module 700 for As an example, the die transfer module 100 may pick up and transfer the die 22 from the wafer 20 including a plurality of individual dies 22 by a dicing process.

The wafer 20 may be provided with the dies 22 attached to the dicing tape 24 . In particular, the rear surfaces of the dies 22 may be attached to the dicing tape 24 so that the front surfaces of the dies 22 face upward, and the dicing tape 24 has a substantially circular ring shape. It can be mounted on the mount frame 26 having a.

The die transfer module 100 includes a wafer stage 110 supporting the wafer 20 , and is disposed under the dicing tape 24 to separate the die 22 from the dicing tape 24 . A die ejector 200 and a non-contact picker 300 for picking up the die 22 in a non-contact manner so as not to come into contact with the front surface of the die 22 in order to prevent contamination of the front surface of the die 22; A flipper that receives the die 22 picked up by the non-contact picker 300 and inverts the die 22 so that the front side of the die 22 faces down and the back side of the die 22 faces up; 400; flipper), a non-contact die stage 500 for supporting the inverted die 22 in a non-contact manner, and an alignment for aligning the die 22 on the non-contact die stage 500 to a preset position It may include a unit 600 .

Referring to FIG. 2 , a support ring 112 for supporting the dicing tape 24 may be disposed on the wafer stage 110 . For example, the support ring 112 may support the dicing tape 24 between the dies 22 and the mount frame 26 . Also, clamps 114 for gripping the mount frame 26 may be disposed on the wafer stage 110 . The clamps 114 may be moved downward by a clamp driver (not shown), whereby the dicing tape 24 may be sufficiently expanded to facilitate pickup of the dies 22 .

A die ejector 200 for separating the dies 22 from the dicing tape 24 may be disposed under the dicing tape 24 supported on the wafer stage 110 . As an example, the die ejector 200 may separate the die 22 from the dicing tape 24 by raising the die 22 to be picked up using ejector pins (not shown), After the die 22 is raised, the non-contact picker 300 may be lowered to support the die 22 in a non-contact manner. After the die 22 is supported by the non-contact picker 300 , the ejector pins may be lowered, whereby the die 22 may be completely separated from the dicing tape 24 .

The non-contact picker 300 may be moved in vertical and horizontal directions by a picker driving unit 302 , and the die 22 picked up and transported by the non-contact picker 300 is transferred to the flipper 400 . can

The flipper 400 includes a vacuum hand 410 for vacuum adsorbing the rear surface of the die 22 , a rotation driving unit 420 for rotating the vacuum hand 410 , and a vacuum hand 410 for rotating the vacuum hand 410 . A flipper driver 430 for moving the non-contact die stage 500 may be included. The die 22 picked up by the non-contact picker 300 may be placed on the vacuum hand 410 , and after being inverted and moved by the vacuum hand 410 , it is placed on the non-contact die stage 500 . can be placed Although not shown, the vacuum hand 410 may include vacuum holes (not shown) for vacuum adsorbing the rear surface of the die 22 , and the flipper driver 430 may For delivery, the vacuum hand 410 may be moved in vertical and horizontal directions.

The die bonding module 700 includes a substrate stage 710 for supporting the substrate 30 , and a method for picking up the die 22 from the non-contact die stage 500 and bonding the die 22 onto the substrate 30 . It may include a bonding head 720 and a head driving unit (not shown) for moving the bonding head 720 in vertical and horizontal directions for pickup and bonding of the die 22 . Although not shown in detail, the bonding head 720 may include a bonding tool (not shown) for vacuum adsorbing the back surface of the die 22 placed on the non-contact die stage 500 in the inverted state. In addition, the bonding tool may include vacuum holes (not shown) for vacuum adsorbing the rear surface of the die 22 .

As described above, the non-contact picker 300 picks up the die 22 so as not to come into contact with the front surface of the die 22 , and the flipper 400 vacuum-sucks the back surface of the die 22 to remove the die 22 . By inverting ( 22 ), the non-contact die stage 500 may support the die 22 so as not to come into contact with the front surface of the die 22 . Accordingly, contamination of the front surface of the die 22 can be sufficiently prevented in the process of picking up and transferring the die 22 , and thus, bonding defects caused by contamination can be sufficiently reduced.

3 is a schematic cross-sectional view for explaining an example of the non-contact picker shown in FIG.

Referring to FIG. 3 , the non-contact picker 300 includes an ultrasonic vibration unit 310 that provides a repulsive force to push the die 22 using ultrasonic vibration, and the die 22 is maintained in a non-contact state. It may include a vacuum chuck 320 that provides a suction force to the die 22 using vacuum pressure. The ultrasonic vibration unit 310 may provide a repulsive force for pushing the die 22 by using the periodic air compression effect of the ultrasonic vibration. The die 22 is predetermined from the ultrasonic vibration unit 310 and the vacuum chuck 320 by the repulsive force provided by the ultrasonic vibration unit 310 and the suction force provided by the vacuum chuck 320 . It can be kept spaced apart.

As an example, the ultrasonic vibration unit 310 is connected to an ultrasonic oscillator 312 for generating the ultrasonic vibration, a horn 314 for amplifying and transmitting the ultrasonic vibration, and the horn 314, It may include a diaphragm 316 vibrating by the ultrasonic vibration. As an example, although not shown in detail, the ultrasonic oscillator 312 may include a pair of piezoelectric elements, and an alternating voltage may be applied to the piezoelectric elements to generate ultrasonic vibration. The horn 314 may have a substantially conical shape for amplification of ultrasonic vibrations, and the diaphragm 316 may be mounted at an end of the horn 314 .

A lower surface of the diaphragm 316 and a lower surface of the vacuum chuck 320 may be disposed to face the front surface of the die 22 . As an example, the diaphragm 316 may have a rectangular plate shape, and the vacuum chuck 320 may have a rectangular ring shape surrounding the diaphragm 316 . The vacuum chuck 320 may have vacuum holes 322 for providing the vacuum pressure, and the vacuum holes 322 may be connected to a vacuum source such as a vacuum ejector or a vacuum pump.

FIG. 4 is a schematic bottom view for explaining another example of the vacuum chuck shown in FIG. 3 .

Referring to FIG. 4 , the vacuum chuck 320 may include air holes 324 for supplying air between the front surface of the die 22 and the lower surface of the vacuum chuck 320 . Although not shown, the air holes 324 may be connected to an air source (not shown) for supplying the air, and the air supplied from the air holes 324 is supplied to the vacuum holes 322 . can be inhaled by In particular, a negative pressure may be formed by the air flow between the air holes 324 and the vacuum holes 322 , and the suction force for holding the die 22 by the negative pressure is the die 22 . may be authorized for As an example, the air holes 324 may be disposed between the vacuum holes 322 . However, since the arrangement of the air holes 324 and the vacuum holes 322 can be variously changed, the scope of the present invention will not be limited thereby.

FIG. 5 is a schematic cross-sectional view for explaining an example of the non-contact die stage shown in FIG. 2 .

Referring to FIG. 5 , the non-contact die stage 500 includes an ultrasonic vibration unit 510 that provides a repulsive force for floating the die 22 using ultrasonic vibration, and a state in which the die 22 is floated. It may include a vacuum stage 520 that provides a suction force to the die 22 using a vacuum pressure so as to be maintained at .

As an example, the ultrasonic vibration unit 510 includes an ultrasonic oscillator 512 for generating the ultrasonic vibration, a horn 514 for amplifying and transmitting the ultrasonic vibration, and an end of the horn 514 . It may include a diaphragm 516 that is connected and vibrates by the ultrasonic vibration. The vacuum stage 520 may have an opening 522 in which the diaphragm 516 is disposed, such that the front surface of the die 22 faces the diaphragm 516 and upper surfaces of the vacuum stage 520 . can be placed As an example, the diaphragm 516 may have a rectangular plate shape, and the opening 522 may also have a rectangular shape. Also, the vacuum stage 520 may include vacuum holes 524 arranged in a square ring shape to surround the opening 522 .

6 is a schematic plan view for explaining another example of the vacuum stage shown in FIG. 5 .

Referring to FIG. 6 , the vacuum stage 520 may include air holes 526 for supplying air between the front surface of the die 22 and the upper surface of the vacuum stage 520 . Although not shown, the air holes 526 may be connected to an air source (not shown) for supplying the air, and the air supplied from the air holes 526 is applied to the vacuum holes 524 . can be inhaled by In particular, a negative pressure may be formed by the air flow between the air holes 526 and the vacuum holes 524, and the suction force for maintaining the die 22 in a floating state by the negative pressure is the may be applied to the die 22 . As an example, the air holes 526 may be disposed between the vacuum holes 524 . However, since the arrangement of the air holes 526 and the vacuum holes 524 can be variously changed, the scope of the present invention will not be limited thereby.

Referring back to FIG. 1 , the alignment unit 600 may be used to align the die 22 to a preset position on the non-contact die stage 500 . For example, the alignment unit 600 may set the die 22 so that the center of the diaphragm 516 and the center of the die 22 correspond to each other and the direction in which the die 22 is placed coincides with a preset direction. ) can be sorted.

7 is a schematic plan view for explaining an example of the alignment unit shown in FIG.

Referring to FIG. 7 , the alignment unit 600 includes alignment members 610 disposed to face side surfaces of the die 22 on the non-contact die stage 500 , and the size of the die 22 . Accordingly, it may include position adjusting units 620 for adjusting the positions of the alignment members 610 .

As an example, the alignment members 610 may be disposed to face side surfaces of the die 22 , respectively, and the position adjusting units 620 may move the alignment members 610 to the non-contact die stage ( ). The alignment members 610 may be moved toward the center of the non-contact die stage 500 or away from the center of the non-contact die stage 500 . As an example, the position adjusting units 620 may be configured using a linear motor or a pneumatic cylinder.

On the other hand, the ultrasonic vibration unit 510 provides a repulsive force for floating of the die 22 through the periodic air compression effect as well as a direction parallel to the front surface of the die 22, that is, in a horizontal direction to the die 22. Since a supporting force can be provided, when the degree of misalignment of the die 22 is not large, the die 22 can be automatically aligned by the ultrasonic vibration. In addition, the angular alignment of the die 22 may also be automatically performed within a predetermined range by the suction force provided by the vacuum holes 524 .

Accordingly, the alignment members 610 do not need to be in close contact with the side surfaces of the die 22 , and contamination due to contact between the die 22 and the alignment members 610 may be reduced. That is, the spacing between the aligning members 610 facing each other may be wider than the width of the die 22 . For example, as shown, a distance between the alignment members 610 in the X-axis direction may be wider than the width of the die 22 in the X-axis direction, and the alignment members 610 in the Y-axis direction. A gap therebetween may be wider than the width of the die 22 in the Y-axis direction. As an example, a distance between the side surfaces of the die 22 and the alignment members 610 may be set within about 1 mm.

The alignment members 610 move the die 22 toward the center of the non-contact die stage 500 when the degree of misalignment of the die 22 placed on the non-contact die stage 500 is relatively large. 22), and the die 22 moved in the center direction of the non-contact die stage 500 can be aligned on the non-contact die stage 500 by the supporting force provided in the horizontal direction by the ultrasonic vibration. there is.

According to the embodiments of the present invention as described above, the die 22 may be picked up and transferred by the non-contact picker 300 , and after being inverted by the flipper 400 , the non-contact die stage 500 . ) and may be aligned by the alignment unit 600 on the non-contact die stage 500 . As described above, in the process of picking up and transferring the die 22, contact with the front portion of the die 22 can be prevented, and thus contamination due to contact can be sufficiently prevented, and in addition, in the die bonding process, the die ( 22) Defects due to contamination can be greatly reduced.

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: die bonding device 20: wafer
22: die 24: dicing tape
30: substrate 100: die transfer module
110: wafer stage 200: die ejector
300: non-contact picker 302: picker driving unit
310: ultrasonic vibration unit 312: ultrasonic oscillator
314: horn 316: diaphragm
320: vacuum chuck 322: vacuum hole
324: air hole 400: flipper
410: vacuum hand 420: rotation driving unit
430: flipper driving unit 500: non-contact die stage
510: ultrasonic vibration unit 512: ultrasonic oscillator
514: horn 516: diaphragm
520: vacuum stage 522: opening
524: vacuum hole 526: air hole
600: alignment unit 610: alignment member
620: position control unit 700: die bonding module
710: substrate stage 720: bonding head

Claims (14)

a non-contact picker for picking up the die in a non-contact manner so as not to contact the front side of the die;
a flipper for receiving the die picked up by the non-contact picker and for inverting the die so that the front side of the die faces down;
a contactless die stage for supporting the inverted die in a contactless manner; and
an alignment unit for aligning the die on the non-contact die stage to a predetermined position;
The non-contact picker includes an ultrasonic vibration unit that provides a repulsive force for pushing the die by using ultrasonic vibration, and a vacuum chuck that provides a suction force to the die using vacuum pressure so that the die is maintained in a non-contact state,
The vacuum chuck includes a lower surface facing the front surface of the die, vacuum holes for providing the vacuum pressure, and air holes for supplying air between the front surface and the lower surface of the die,
The alignment unit includes alignment members disposed to face side surfaces of the die on the non-contact die stage, and position adjusting units for adjusting positions of the alignment members according to the size of the die. Die transfer module. delete According to claim 1, wherein the ultrasonic vibration unit,
an ultrasonic oscillator for generating the ultrasonic vibration;
a horn for transmitting the ultrasonic vibration;
and a diaphragm connected to an end of the horn and vibrating by the ultrasonic vibration. 4. The die transfer module of claim 3, wherein the lower surface of the vacuum chuck is configured to surround the diaphragm. The method of claim 3, wherein the diaphragm has a square plate shape,
The vacuum chuck is a die transfer module, characterized in that it has a rectangular ring shape surrounding the diaphragm. delete The method of claim 1 , wherein the non-contact die stage comprises:
an ultrasonic vibration unit for providing a repulsive force for levitating the die using ultrasonic vibration;
and a vacuum stage for providing a suction force to the die by using a vacuum pressure so that the die is maintained in a floating state. The method of claim 7, wherein the ultrasonic vibration unit,
an ultrasonic oscillator for generating the ultrasonic vibration;
a horn for transmitting the ultrasonic vibration;
and a diaphragm connected to an end of the horn and vibrating by the ultrasonic vibration. According to claim 8, wherein the vacuum stage,
an opening in which the diaphragm is disposed;
A die transfer module, characterized in that it has an upper surface facing the front surface of the die. 10. The method of claim 9, wherein the vacuum stage,
The die transfer module, characterized in that it has vacuum holes arranged in a ring shape so as to surround the opening. 11. The method of claim 10, wherein the vacuum stage,
Die transfer module, which is disposed between the vacuum holes and has air holes for supplying air between the front surface and the upper surface of the die. The die transfer module according to claim 1, further comprising a flipper driving unit for moving the flipper toward the non-contact die stage. delete a die transfer module for picking up and transferring the die; and
a die bonding module for bonding the die transferred by the die transfer module on a substrate;
The die transfer module,
a non-contact picker for picking up the die in a non-contact manner so as not to contact the front side of the die; a flipper for receiving the die picked up by the non-contact picker and for inverting the die so that the front side of the die faces down; a non-contact die stage for supporting the inverted die in a non-contact manner, and an alignment unit for aligning the die on the non-contact die stage to a predetermined position;
the die bonding module picks up the aligned die on the non-contact die stage and bonds it onto the substrate;
The non-contact picker includes an ultrasonic vibration unit that provides a repulsive force for pushing the die by using ultrasonic vibration, and a vacuum chuck that provides a suction force to the die using vacuum pressure so that the die is maintained in a non-contact state,
The vacuum chuck includes a lower surface facing the front surface of the die, vacuum holes for providing the vacuum pressure, and air holes for supplying air between the front surface and the lower surface of the die,
The alignment unit includes alignment members disposed to face side surfaces of the die on the non-contact die stage, and position adjusting units for adjusting positions of the alignment members according to the size of the die. die bonding device.

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