JP2009010150A - Method for cutting plate-shaped body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for cutting a plate-shaped body that can prevent cutting wastes from sticking on an adhesive tape in a boundary region between a dicing frame and the adhesive tape when a plate-shaped body is cut. <P>SOLUTION: In the cutting means for the plate-shaped body using a cutting apparatus including: a chuck table holding the plate-shaped body 30 supported on the dicing frame through the adhesive tape 34 stuck on the annular dicing frame 36; a cutting means for rotatably supporting a cutting blade for cutting the plate-shaped body held by the chuck table; and a cutting water supply means of supplying cutting water to the cutting blade, the plate-shaped body is cut while cutting water discharge parts 66 and 68 are formed in the boundary area between the dicing frame and adhesive tape at least on the side where cutting water is scattered so that cutting wastes do not stick on the adhesive tape although the cutting water is scattered because of rotation of the cutting blade to stay at a step part between the dicing frame and adhesive tape. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a cutting method for a plate-like object by which the plate-like object is cut by a cutting device having a cutting blade.

  A cutting device such as a dicing machine cuts a plate-like object such as a resin substrate with a cutting blade that rotates at a high speed. At that time, the plate-like object is crushed by the blade and the crushed plate-like object Is discharged with cutting water as cutting waste (contamination).

  Therefore, removal of the cutting waste always generated by dicing has always been a problem. In particular, the cutting water supply means have been improved or cleaning means have been provided so as not to cause a short circuit on the surface of the plate-like object, or to impede the operation of the element, etc. In order to prevent cutting chips from adhering to the surface of the plate-like object.

  For example, in JP-A-11-267940, in addition to the cutting water supply nozzle provided conventionally, a curtain is formed by a fluid such as water or air ejected from the curtain nozzle, and the cutting waste is on the surface of the plate-like object. There has been proposed a cutting device that prevents adhesion to the surface.

  JP-A-2000-306878 discloses a cleaning ability equivalent to injecting high-pressure water without using high-pressure water by injecting a mixture of air and cleaning water from a nozzle when cutting a plate-like object. A cutting device having the same is disclosed.

As a result of these improvements, cutting waste generated when cutting a plate-like material usually passes over the plate-like material together with cutting water, and is discharged from the adhesive tape around the plate-like material to the outside of the dicing frame. .
JP-A-11-267940 Japanese Utility Model Publication No. 2000-306878

  After the cutting of the plate-like object, the plate-like object is washed by the cleaning device and then returned to the plate-like object cassette. Therefore, in the cutting devices disclosed in Patent Document 1 and Patent Document 2, cutting on the surface of the plate-like object is performed. Scrap adhesion is effectively prevented, but if the adhesive strength of the tape is strong, or if cutting water (drainage) containing cutting waste stays on the adhesive tape, the cutting waste will stick around the plate. May adhere to the surface and may not be washed away by the cleaning device.

  The cutting waste adhering to the adhesive tape may not be a problem, but after the dicing, the pick-up process is the next process (the entire adhesive tape is stretched, the cut chip is pushed up from the back of the tape and peeled off the tape, When the cutting waste rises from the adhesive tape and reattaches to the surface or side surface of the chip, the cutting waste may cause a short circuit in the chip circuit.

  The present invention has been made in view of such points, and the object of the present invention is to prevent wastewater containing cutting waste from staying at the step portion of the adhesive tape and the dicing frame, and the cutting waste is It is an object of the present invention to provide a method for cutting a plate-like object that prevents adhesion to an adhesive tape in the vicinity of a portion.

  According to the present invention, a chuck table for holding a plate-like object supported by the dicing frame via an adhesive tape attached to an annular dicing frame, and a cutting for cutting the plate-like object held by the chuck table. A cutting method of a plate-like object using a cutting device comprising a cutting means for rotatably supporting a blade, and a cutting water supply means for supplying cutting water to the cutting blade, and is caused by the rotation of the cutting blade So that the cutting water scatters and the cutting water stays in the step between the dicing frame and the adhesive tape, and the cutting waste does not adhere to the adhesive tape. A cutting method for a plate-like object is provided, wherein a cutting water discharge part is formed in the boundary region of the plate to cut the plate-like object.

  Preferably, the cutting water discharge part is configured by arranging a tape in a boundary area between the dicing frame and the adhesive tape so as to cover the stepped part, or by removing the adhesive tape in the boundary area to form a drain port. Configured.

  As an alternative, the cutting water discharge part is formed by forming a notch in the inner peripheral part of the annular dicing frame and forming a drainage port in the boundary region between the dicing frame and the adhesive tape, or the annular dicing A tapered inclined portion is formed inward in the radial direction so as to eliminate a step portion with the adhesive tape on the inner peripheral portion of the frame.

  According to the present invention, the cutting water discharge part is formed in the boundary region between the dicing frame and the adhesive tape on the side where the cutting water scatters to perform cutting of the plate-like object, so that the drainage does not stay in the step part and is smooth. Since it is discharged to the outside of the dicing frame, it is possible to prevent the cutting dust from adhering to the adhesive tape.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 shows an appearance of a cutting apparatus 2 that can divide a plate-like object such as a resin substrate into individual chips (devices).

  On the front side of the cutting device 2, there is provided operating means 4 for an operator to input instructions to the device such as machining conditions. In the upper part of the apparatus, there is provided a display means 6 such as a CRT for displaying a guidance screen for an operator and an image taken by an imaging means described later.

  As shown in FIG. 2, on the surface of the resin substrate 30 to be diced, the first street S1 and the second street S2 are formed orthogonally, and the first street S1 and the second street S2 A large number of chips (devices) 32 are formed on the resin substrate 30.

  The resin substrate 30 is attached to a dicing tape 34 that is an adhesive tape, and the outer peripheral edge of the dicing tape 34 is attached to an annular frame 36. As a result, the resin substrate 30 is supported by the frame 36 via the dicing tape 34, and a plurality of (for example, 25) resin substrates are accommodated in the resin substrate cassette 8 shown in FIG. The resin substrate cassette 8 is placed on a cassette elevator 9 that can move up and down.

  Behind the resin substrate cassette 8, a loading / unloading means 10 for unloading the resin substrate 30 before cutting from the resin substrate cassette 8 and loading the resin substrate after cutting into the resin substrate cassette 8 is disposed. Between the resin substrate cassette 8 and the loading / unloading means 10, a temporary placement area 12 that is an area on which a resin substrate to be loaded / unloaded is temporarily placed is provided. Positioning means 14 for positioning the substrate 30 at a certain position is provided.

  In the vicinity of the temporary placement region 12, a transport unit 16 having a turning arm that sucks and transports the frame 36 integrated with the resin substrate 30 is disposed, and the resin substrate 30 transported to the temporary placement region 12. Is attracted by the conveying means 16 and conveyed onto the chuck table 18 and is sucked by the chuck table 18 and is held on the chuck table 18 by fixing the frame 36 by a plurality of fixing means (clampers) 19. Is done.

  The chuck table 18 is configured to be rotatable and reciprocally movable in the X-axis direction. Above the movement path of the chuck table 18 in the X-axis direction, an alignment unit 20 that detects a street to be cut of the resin substrate 30. Is arranged.

  The alignment unit 20 includes an image capturing unit 22 that captures an image of the surface of the resin substrate 30, and can detect a street to be cut by processing such as pattern matching based on an image acquired by the image capturing. The image acquired by the imaging unit 22 is displayed on the display unit 6.

  On the left side of the alignment means 20, a cutting means 24 for cutting the resin substrate 30 held on the chuck table 18 is disposed. The cutting means 24 is configured integrally with the alignment means 20, and both move together in the Y-axis direction and the Z-axis direction.

  The cutting means 24 is configured by attaching a cutting blade 28 to the tip of a rotatable spindle 26 and is movable in the Y-axis direction and the Z-axis direction. The cutting blade 28 is located on the extended line of the imaging means 22 in the X-axis direction.

  In the cutting apparatus 2 configured as described above, the resin substrate 30 accommodated in the resin substrate cassette 8 is sandwiched by the frame 36 by the loading / unloading means 10, and the loading / unloading means 10 moves rearward (Y-axis direction). Then, when the holding in the temporary placement area 12 is released, the temporary placement area 12 is placed. And the resin substrate 30 is positioned in a fixed position by the alignment means 14 moving to the direction which mutually approaches.

  Next, the frame 36 is adsorbed by the conveyance means 16, and the resin substrate 30 integrated with the frame 36 is conveyed to the chuck table 18 by the conveyance means 16 turning and held by the chuck table 18. Then, the chuck table 18 moves in the X-axis direction, and the resin substrate 30 is positioned immediately below the alignment means 20.

  The image used for pattern matching at the time of alignment in which the alignment unit 20 detects a street to be cut needs to be acquired in advance before cutting. Therefore, when the resin substrate 30 is positioned immediately below the alignment unit 20, the imaging unit 22 images the surface of the resin substrate 30 and causes the display unit 6 to display the captured image.

  The operator of the cutting apparatus 2 operates the operation means 4 to move the image means 22 slowly and also move the chuck table 18 as necessary to search for a pattern that is a pattern matching target.

  When the operator determines a key pattern, an image including the key pattern is stored in a memory provided in the alignment unit 20 of the cutting apparatus 2. Further, the distance between the key pattern and the center line of the streets S1 and S2 is obtained by a coordinate value or the like, and the value is also stored in the memory.

  Further, by moving the image pickup means 22, an interval between the adjacent streets (street pitch) is obtained by a coordinate value or the like, and the street pitch value is also stored in the memory of the alignment means 20.

  When the resin substrate 30 is cut along the street, the alignment unit 20 performs pattern matching between the stored key pattern image and the image actually acquired by the imaging unit 22.

  When the pattern matches, the cutting means 24 is moved in the Y-axis direction by the distance between the key pattern and the street center line, thereby aligning the street to be cut with the cutting blade 28.

  When the street to be cut and the cutting blade 28 are aligned, the chuck table 18 is moved in the X-axis direction, and the cutting means 24 is lowered while rotating the cutting blade 28 at a high speed. The street was cut.

  When cutting the resin substrate 30, the cutting water is ejected from a shower nozzle provided on the front side of the cutting blade, and the cutting water is fan-shaped from the blade cooler nozzle provided so as to sandwich the cutting blade from both sides. And the resin substrate 30 is cut. The cutting water to be ejected is preferably pure.

  By performing cutting while feeding the cutting means 24 in the Y-axis direction by the street pitch stored in the memory, all the streets S1 in the same direction are cut. Further, when the chuck table 18 is rotated by 90 ° and then the same cutting as described above is performed, the streets S2 are all cut and divided into individual chips 32.

  After the cutting, the resin substrate 30 is moved in the X-axis direction by the chuck table 18 and is then held by the transfer means 25 that can move in the Y-axis direction and transferred to the cleaning device 27. The cleaning device 27 cleans the resin substrate by rotating the resin substrate 30 at a high speed (for example, 3000 rpm) while jetting water from the cleaning nozzle.

  After cleaning, air is ejected from the air nozzle to dry the resin substrate 30, the resin substrate 30 is adsorbed by the conveying means 16 and returned to the temporary storage area 12, and the original storage of the resin substrate cassette 8 is further performed by the loading / unloading means 10. The resin substrate 30 is returned to the place.

  Next, before describing a method for cutting a resin substrate according to an embodiment of the present invention, problems of the prior art will be described in detail with reference to FIGS. 3 and 4. FIG. 3 shows a plan view of a conventional method for cutting a resin substrate. Actually, the cutting blade 28 is arranged perpendicularly to the resin substrate 30 to cut the resin substrate 30. A state where the blade 28 is tilted sideways is shown.

  As shown in the sectional view of FIG. 4, the resin substrate 30 mounted on the chuck table 18 is sucked by the chuck table 18 and held by the clamper 19 by clamping the dicing frame 36. The

  While moving the chuck table 18 in the X-axis direction (arrow 46 direction in FIG. 3), the resin blade 30 is cut by the cutting blade 28 while rotating the cutting blade 28 in the arrow 40 direction at high speed.

  At this time, as described above, the resin substrate 30 is cut while supplying the cutting water 44 to the cutting blade 28 from the cutting water supply means 42 having the shower nozzle and the blade cooler nozzle. ) Hits the stepped portion 50 between the dicing frame 36 and the adhesive tape 34 as shown by the outflow path of the arrow 52, and a part of the drainage is bent.

  As a result, since the streets S1 and S2 are formed at right angles to each other on the resin substrate 30, the boundary between the dicing frame 36 and the adhesive tape 34, which is the flow direction of the cutting water indicated by the arrows 46 and 48 in FIG. Cutting waste (contamination) adheres to the regions 54 and 56.

  The cutting waste adhering to the boundary regions 54 and 56 may rise from the adhesive tape 34 in the pick-up process, which is the next process after dicing, and reattach to the surface or side surface of the chip. Hereinafter, each embodiment of the cutting method of the plate-shaped object of the present invention which prevents reattachment of the cutting waste will be described in detail with reference to FIG.

  FIG. 5A shows a plan view of the resin substrate assembly 35 of the first embodiment used in the resin substrate cutting method of the present invention. The resin substrate assembly 35 includes an annular dicing frame 36, a dicing tape 34 that is an adhesive tape having an outer peripheral edge attached to the dicing frame 36, and a resin substrate 30 attached to the dicing tape 34.

  As shown in FIG. 2, a plurality of first streets S1 extending in the direction of arrow 46 and a plurality of second streets S2 extending in the direction of arrow 48 orthogonal to the first street S1 are formed on the surface of the resin substrate 30. Has been.

  Therefore, since the dicing by the cutting device 2 is performed along the first street S1 and the second street S2, the outflow paths of the cutting water (drainage) are two directions of the arrow 46 direction and the arrow 48 direction orthogonal to each other.

  Therefore, in the resin substrate assembly 35 of the first embodiment, tapes (for example, UV tape D-174 manufactured by Lintec Corporation) 58 and 60 are attached to the boundary region between the dicing frame 36 and the adhesive tape 34 on the side where the cutting water scatters. Thus, as shown in FIG. 7, the cutting water discharge portion was formed so as to cover the stepped portion 50 between the dicing frame 36 and the adhesive tape 34 with the tapes 58 and 60.

  Thereby, the cutting water 44 supplied from the cutting water supply means 42 at the time of cutting the resin substrate is stuck to the step portion 50 as shown in the plan view at the time of cutting the resin substrate shown in FIG. 6 and the cross-sectional view of FIG. Since it is guided by the tape 58 and smoothly discharged out of the dicing frame 36 without staying in the stepped portion 50 as indicated by an arrow 64, it is placed on the adhesive tape 34 in the boundary region between the dicing frame 36 and the adhesive tape 34. It is prevented that cutting waste (contamination) adheres.

  FIG. 5B shows a plan view of a resin substrate assembly 35A of the second embodiment used in the cutting method of the present invention. In the resin substrate assembly 35A of the second embodiment, the stepped portion 50 between the dicing frame 36 and the adhesive tape 34 is covered with an annular tape 62 over the entire circumference.

  Even in the resin substrate assembly 35A of the present embodiment, the waste water containing cutting waste is smoothly discharged outside the dicing frame 36 without staying at the step portion 50 when the resin substrate is cut, so that the dicing frame 36 and the adhesive tape 34 It is prevented that the cutting waste adheres to the adhesive tape 34 in the boundary region.

  FIG. 8A shows a plan view of a resin substrate assembly 35B according to the third embodiment of the present invention. In the resin substrate assembly 35B of the present embodiment, a hole 66 serving as a drain port is provided in the adhesive tape 34 in the vicinity of the dicing frame 36 in the direction of arrows 46 and 48 shown in FIG. , 68 are formed.

  In this embodiment, when cutting the resin substrate, the cutting water (drainage) flows out through the holes 66 and 68 acting as drainage ports, so that the cutting waste is prevented from adhering to the adhesive tape 34.

  FIG. 8B shows a plan view of a resin substrate assembly 35C according to the fourth embodiment of the present invention. The resin substrate assembly 35C of the present embodiment is formed by forming notches 70 and 72 on the inner peripheral side of the dicing frame 36 in a direction in which cutting water is mainly discharged.

  When the resin substrate is cut, cutting water is discharged from these notches 70 and 72. Therefore, it is necessary to devise so that the entire surface of the notches 70 and 72 is not blocked by the adhesive tape 34. In this embodiment, the same effects as those of the first to third embodiments described above can be obtained.

  FIG. 9A shows a plan view of a resin substrate assembly 35D of the fifth embodiment of the present invention. FIG. 9B is a cross-sectional view taken along line 9B-9B of FIG. In the resin substrate assembly 35D of the present embodiment, a tapered inclined portion 36a is formed on the inner peripheral portion of the dicing frame 36 so as to become thinner inward in the radial direction, so that the gap between the dicing frame 36 and the adhesive tape 34 is increased. The step is made gentle.

  In the present embodiment, the inclined portion 36a is formed over the entire circumference of the dicing frame 36. However, the tapered inclined portion 36a is formed on the inner peripheral portions of the two dicing frames 36 in the cutting water discharge direction. Anyway.

  In the present embodiment, since the step portion between the dicing frame 36 and the adhesive tape 34 is gentle, the drainage of the cutting water does not stay at the step portion and is smoothly discharged out of the dicing frame 36. . Therefore, similarly to each of the above-described embodiments, the cutting waste is prevented from adhering onto the adhesive tape 34 in the boundary region between the dicing frame 36 and the adhesive tape 34.

It is an external appearance perspective view of the cutting device suitable for implementing the cutting method of the plate-shaped object of this invention. It is a perspective view which shows the resin substrate integrated with the flame | frame. It is a top view for demonstrating the subject which this invention should solve. It is sectional drawing for demonstrating the subject which this invention should solve. FIG. 5A is a plan view of the resin substrate assembly of the first embodiment used in the cutting method of the present invention, and FIG. 5B is a plan view of the resin substrate assembly of the second embodiment. It is a top view at the time of the resin substrate cutting which uses the resin substrate assembly of 1st Embodiment. It is sectional drawing at the time of the resin substrate cutting which uses the resin substrate assembly of 1st Embodiment. FIG. 8A is a plan view of the resin substrate assembly of the third embodiment used in the plate-like object cutting method of the present invention, and FIG. 8B is a plan view of the resin substrate assembly of the fourth embodiment. . FIG. 9A is a plan view of a resin substrate assembly of a fifth embodiment used in the plate-like material cutting method of the present invention, and FIG. 9B is a cross-sectional view taken along line 9B-9B of FIG. 9A. .

Explanation of symbols

28 Cutting Blade 30 Resin Substrate 34 Adhesive Tape 35 Resin Substrate Assembly 36 Dicing Frame 36a Tapered Inclined Part 50 Stepped Part 58, 60, 62 Tape 66, 68 Hole (Drainage Port)
70, 72 notches

Claims (5)

A chuck table for holding a plate-like object supported by the dicing frame via an adhesive tape attached to an annular dicing frame, and a cutting blade for cutting the plate-like object held by the chuck table can be rotated. A cutting method of a plate-like object using a cutting device comprising a cutting means for supporting and a cutting water supply means for supplying cutting water to the cutting blade,
At least the side where the cutting water scatters so that the cutting water scatters due to the rotation of the cutting blade and the cutting water stays in the step between the dicing frame and the adhesive tape and the cutting debris does not adhere to the adhesive tape. A cutting method for a plate-shaped object, wherein a cutting water discharge portion is formed in a boundary region between the dicing frame and the adhesive tape to cut the plate-shaped object.   2. The cutting method for a plate-like object according to claim 1, wherein the cutting water discharge part is configured by arranging a tape in a boundary region between a dicing frame and an adhesive tape so as to cover the stepped part.   2. The plate-like object according to claim 1, wherein the cutting water discharge portion is configured by removing a pressure-sensitive adhesive tape in the boundary region and forming a drain outlet in a boundary region between the dicing frame and the pressure-sensitive adhesive tape. Cutting method.   The cutting water discharge part is formed by forming a notch in an inner peripheral part of the annular dicing frame and forming a drainage port in a boundary region between the dicing frame and the adhesive tape. The cutting method of the plate-shaped object of 1.   The cutting water discharge portion is configured by forming a tapered inclined portion inward in the radial direction so as to eliminate a step portion with the adhesive tape on an inner peripheral portion of the annular dicing frame. The cutting method of the plate-shaped object of Claim 1.

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