JP7049801B2 - Grinding method for workpieces - Google Patents

Description

The present invention relates to a method of grinding a plate-shaped workpiece such as a semiconductor wafer with a grinding wheel.

A work piece on which devices such as ICs and LSIs are formed on a plurality of surfaces is ground on the back surface to be thinned to a predetermined thickness, and further divided into individual device chips by a dividing device such as a dicing device. Used for various electronic devices.
The grinding device that grinds the back surface of the workpiece rotates a chuck table that holds the workpiece to which a surface protection member made of resin or the like is attached, and a grinding wheel that grinds the workpiece held on the chuck table. It is equipped with a grinding means that supports it as much as possible and a grinding water supply means that supplies grinding water to the grinding wheel through a flow path formed in the axis of the spindle that constitutes the grinding means, and efficiently grinds the workpiece. be able to.

In recent years, in order to achieve weight reduction and miniaturization of device chips, it is required in a wafer grinding method to make the work piece thinner. However, such a thinly formed wafer has low rigidity and becomes difficult to handle, and may be damaged during wafer transportation or the like. Therefore, for example, the workpiece is thinly ground to a size of 100 μm or less, and further, only the region corresponding to the region on which the device on the front surface is formed is thinly ground on the back surface of the workpiece, and the device on the front surface is formed. There is a grinding method that facilitates the handling of thinned workpieces by leaving a ring-shaped reinforcing portion corresponding to the outer peripheral surplus region surrounding the region on the back surface (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2007-19461

However, in the above-mentioned grinding method, since the ring-shaped reinforcing portion is formed on the back surface of the workpiece, the ring-shaped reinforcing portion becomes a dike during grinding and falls off from the grinding wheel in the circular recess of the workpiece. Grinding water containing the grindstones will stay. Then, the fallen abrasive grains accumulated in the circular recess of the workpiece are caught in the grinding wheel being ground and adhere to the grinding surface at the tip of the grinding wheel. If grinding is continued with a grinding wheel in which the falling abrasive grains are attached to the ground surface at the tip, scratches are formed on the surface to be ground of the work piece or cracks occur in the work piece.

Therefore, the region corresponding to the device region in the back surface of the workpiece is ground to form a circular recess, and the ring-shaped reinforcing portion is formed in the region on the back surface of the wafer corresponding to the outer peripheral surplus region surrounding the device region. In the grinding method, it is said that scratches are not formed on the back surface of the workpiece or cracks are generated in the workpiece due to the entrainment of the falling abrasive grains of the grinding wheel during grinding. There are challenges.

The present invention for solving the above-mentioned problems is a workpiece having a device region on which a plurality of devices are formed and an outer peripheral surplus region surrounding the device region on the surface, and the back surface of the workpiece is ground with a grinding wheel. It is a grinding method, in which a surface protection step of covering the surface of the workpiece with a protective member and a surface protection step are performed, and then the grindstone is rotated on a rotation axis inclined at an angle of 45 to 90 degrees with respect to the vertical direction. A holding step for holding the protective member side of the workpiece on the holding surface of the chuck table, and a grinding wheel that rotates on a rotation axis orthogonal to the holding surface are used to grind the back surface of the workpiece corresponding to the device region with water. It is provided with a grinding step of grinding while supplying to form a circular recess and a ring-shaped reinforcing portion corresponding to the outer peripheral excess region and surrounding the circular recess. In the grinding step, the grindstone that has fallen off from the grinding wheel is provided. Since the discharge position of the grinding water containing grains is the lowest point of the chuck table on which the rotation axis is tilted, the rotation trajectory of the grinding wheel passes through the rotation center of the workpiece and the rotation trajectory of the grinding wheel. This is a grinding method in which the grinding wheel is positioned so that the discharging position of the grinding water and the discharging position of the grinding water do not overlap, and the discharge of the grinding water containing the abrasive grains that have fallen off from the grinding wheel is promoted by the inclination of the workpiece.

The protective member is, for example, an adhesive tape.

In the grinding method according to the present invention, after performing the surface protection step of covering the surface of the workpiece with a protective member and the surface protection step, the grindstone is rotated on a rotation axis inclined at an angle of 45 to 90 degrees with respect to the vertical direction. A holding step that holds the protective member side of the workpiece on the holding surface of the chuck table, and a grinding wheel that rotates on a rotation axis orthogonal to the holding surface supply grinding water to the back surface of the workpiece corresponding to the device area. Since it is provided with a grinding step for forming a circular concave portion and a ring-shaped reinforcing portion surrounding the circular concave portion corresponding to the outer peripheral surplus region by grinding while grinding, the abrasive grains that have fallen off from the grinding wheel are provided in the grinding step. Since the discharge position of the grinding water including the above is the lowest point of the chuck table on which the rotation axis is tilted, the rotation trajectory of the grinding wheel passes through the rotation center of the workpiece and the rotation trajectory of the grinding wheel. The grinding wheel is positioned so that it does not overlap with the discharging position of the grinding water, and the discharge of the grinding water containing the abrasive grains that have fallen off from the grinding wheel is promoted by the inclination of the workpiece and the positioning of the grinding wheel. Grinding water containing abrasive grains that have fallen off from the grinding wheel can be discharged more efficiently, the grinding wheel is less likely to entrain the falling abrasive grains during grinding, and scratches are formed on the back surface of the workpiece. It is possible to prevent the work piece from being cracked and to form a circular recess having a flat bottom surface.

It is a perspective view which shows an example of the protection member which protects a work piece and the surface of a work piece. It is sectional drawing which shows the state which the workpiece held on the chuck table is ground by the grinding wheel. It is explanatory drawing explaining the state which the rotation locus of a grinding wheel and the discharge position of the grinding water do not overlap. It is sectional drawing which shows the state which the grinding water is discharged from the back surface of the ground work piece.

The workpiece W shown in FIG. 1 is, for example, a semiconductor wafer whose outer shape is a circular plate having a base material of silicon, and has a device region Wa1 and an outer peripheral surplus region Wa2 surrounding the device region Wa1 on its surface Wa. And are provided. The outer peripheral surplus region Wa2 is a region outside the virtual line L1 shown by the alternate long and short dash line in the surface Wa of the workpiece W in FIG. 1. The device region Wa1 is partitioned in a grid pattern by a plurality of scheduled division lines S that are orthogonal to each other, and a device D such as an IC is formed in each region partitioned in a grid pattern. The back surface Wb of the workpiece W is a surface to be ground to be ground. The workpiece W may be made of gallium arsenide, sapphire, gallium nitride, silicon carbide or the like in addition to silicon.

Hereinafter, each step in the case where the grinding method according to the present invention is carried out to grind the workpiece W shown in FIG. 1 to a predetermined thickness will be described.

(1) Surface protection step When the workpiece W is ground, for example, a circular protective member T1 having substantially the same diameter as the workpiece W is attached to the surface Wa of the workpiece W. The device region Wa1 and the outer peripheral surplus region Wa2 are covered with the protective member T1 and are protected. The protective member T1 is, for example, an adhesive tape provided with a base material layer and an adhesive layer, but is not limited to this, and a rigid hard plate such as a glass substrate is attached to the surface Wa with an adhesive. It may be used as a protective member, or the surface Wa may be coated with a liquid resin and then heated or irradiated with ultraviolet rays to cure the resin to cover the surface Wa of the workpiece W. A protective member may be formed.

(2) Holding step The workpiece W whose surface Wa is covered with the protective member T1 is conveyed to the grinding device 2 shown in FIG. The grinding device 2 includes a chuck table 3 that sucks and holds the workpiece W, and a grinding means 4 that grinds the workpiece W with a rotating grinding wheel 42b. The chuck table 3 has, for example, a circular outer shape, and includes a holding portion 30 that is made of a porous member or the like and sucks and holds the workpiece W, and a frame body 31 that supports the holding portion 30. The holding portion 30 communicates with a suction source (not shown) including a vacuum generator, a compressor, etc. via a pipe, a rotary joint, or the like, and the suction force generated by suction by the suction source (not shown) is applied to the holding surface 30a. By being transmitted, the chuck table 3 sucks and holds the workpiece W on the holding surface 30a.

The chuck table 3 can be reciprocated in the Y-axis direction by a Y-axis direction feeding means (not shown). Further, one end of the rotating shaft 33 is connected to the bottom surface side of the chuck table 3, and the motor 34 is connected to the other end of the rotating shaft 33. The rotation shaft 33 is tilted at an angle of 45 to 180 degrees with respect to the vertical direction (Z-axis direction), and the chuck table 3 is also tilted with respect to the vertical direction by the same angle as the tilt angle of the rotation shaft 33. There is. When the motor 34 rotates the rotating shaft 33, the chuck table 3 also rotates around the axis of the rotating shaft 33 inclined at a predetermined angle.

The grinding means 4 includes a rotary shaft 40, a motor (not shown) for rotationally driving the rotary shaft 40, a circular mount 41 connected to the lower end of the rotary shaft 40, and a grind detachably connected to the lower surface of the mount 41. It is equipped with a wheel 42. The grinding wheel 42 includes a wheel base 42a and a plurality of substantially rectangular parallelepiped grinding wheels 42b arranged in an annular shape on the outer peripheral portion of the bottom surface of the wheel base 42a. The grinding wheel 42b is formed by fixing diamond abrasive grains or the like with, for example, a resin bond or a metal bond. The grinding wheels 42b arranged in an annular shape have, for example, such that the diameter of the outermost circumference thereof is larger than the radius of the device region Wa1 of the workpiece W and smaller than the diameter of the device region Wa1 and the diameter of the innermost circumference thereof is large. It is formed so as to be smaller than the radius of the device area Wa1.

Further, the rotating shaft 40 is inclined at an angle of 45 degrees to 180 degrees with respect to the vertical direction (Z-axis direction) like the rotating shaft 33 of the chuck table 3, and the entire grinding means 4 is also inclined with respect to the vertical direction. It is tilted in the vertical direction by the same angle as the tilt angle of the rotating shaft 40. That is, for example, when the rotary shaft 33 of the chuck table 3 is tilted 45 degrees in the vertical direction, the rotary shaft 40 is also tilted 45 degrees in the vertical direction, and the grinding wheel 42b is tilted in the chuck table 3 The back surface Wb of the workpiece W is ground while rotating around the axis of the rotation axis 40 orthogonal to the holding surface 30a.
The grinding means 4 tilted at a predetermined angle in the vertical direction can be moved by a grinding feeding means (not shown) in a direction away from or close to the holding surface 30a of the tilted chuck table 3 (axial direction of the rotating shaft 40). It has become.

Inside the rotating shaft 40, a flow path 43 that serves as a passage for grinding water is formed so as to penetrate in the axial direction of the rotating shaft 40. The flow path 43 passes through the mount 41 and has an opening at the lower end side thereof so that grinding water can be ejected toward the grinding wheel 42b at the bottom surface of the wheel base 42a. Further, a grinding water supply means 44 that supplies grinding water such as pure water to the flow path 43 communicates with the upper end side of the flow path 43.

As shown in FIG. 2, in the holding step, first, the workpiece W to which the protective member T1 is attached to the surface Wa is in a state where, for example, the rotation axis 33 is tilted at an angle of 45 degrees with respect to the vertical direction. The chuck table 3 is placed on the holding surface 30a so that the center of the holding surface 30a and the center of the workpiece W are substantially aligned with each other and the back surface Wb is exposed. Then, the suction force generated by the suction source (not shown) is transmitted to the holding surface 30a, so that the chuck table 3 is in a state of sucking and holding the protective member T1 side of the workpiece W on the holding surface 30a.

(3) Grinding step Next, the chuck table 3 holding the workpiece W moves in the Y-axis direction to the bottom of the grinding means 4 in a state of being inclined at an angle of 45 degrees with respect to the vertical direction, and the grinding means 4 The grinding wheel 42 prepared for the above and the workpiece W are aligned with each other. In this alignment, for example, the virtual line L1 and a part of the outermost periphery of the rotation trajectory of the grinding wheel 42b overlap on the inner peripheral edge of the outer peripheral excess region Wa2 of the workpiece W, that is, on the back surface Wb, and the grinding wheel 42b The rotation trajectory is performed so as to pass through the rotation center of the workpiece W. Further, in the main grinding step, the discharge position of the grinding water containing the abrasive grains that have fallen off from the grinding wheel 42b, which will be described later, is the lowest point shown in FIGS. .. Therefore, as shown in FIG. 2, for example, the grinding wheel 42b is on the + Y direction side of the workpiece W so that the rotation locus of the grinding wheel 42b shown by the dotted line in FIG. 3 and the discharge position of the grinding water do not overlap. It is positioned at a predetermined position on the −Y direction side opposite to the center from the discharge position. The positioning of the grinding wheel 42b is not limited to the example in the present embodiment, and the grinding wheel 42b is positioned at a predetermined position on the back surface Wb of the workpiece W to draw any rotation locus shown by the alternate long and short dash line in FIG. May be positioned so that the discharge position of the grinding water including the dropped abrasive grains and the rotation locus of the grinding wheel 42b do not overlap.

As shown in FIG. 2, after the grinding wheel 42b and the workpiece W are aligned, the grinding wheel 42b rotates as a motor (not shown) rotationally drives the rotary shaft 40. Further, the grinding means 4 is grounded in the direction of arrow E shown in FIG. 2 approaching the holding surface 30a of the chuck table 3, and the rotating grinding wheel 42b abuts on the back surface Wb of the workpiece W to cause the back surface Wb. Grinding is done. Further, during the grinding process, the workpiece W held on the chuck table 3 is held as the chuck table 3 rotates around the axis of the rotating shaft 33 inclined at an angle of 45 degrees with respect to the vertical direction. Also rotates.

During the grinding process, for example, the grinding wheel 42b rotates so that the center of rotation of the workpiece W is always located inside the outermost circumference of the rotating track of the grinding wheel 42b and outside the inner circumference of the rotating track. do. Further, the outermost circumference of the rotational track of the grinding wheel 42b does not come into contact with the outer peripheral region of the back surface Wb corresponding to the outer peripheral surplus region Wa2 of the workpiece W, that is, it does not protrude to the outside more than the virtual line L1. The grinding wheel 42b rotates. Therefore, the grinding wheel 42b grinds the central region of the back surface Wb corresponding to the device region Wa1 of the workpiece W into a circular concave shape, and as shown in FIG. 4, the central region of the back surface Wb corresponding to the device region Wa1. A circular recess Wb1 is formed in the space. Further, a ring-shaped reinforcing portion Wb2 corresponding to the outer peripheral surplus region Wa2 and surrounding the circular recess Wb1 is formed on the back surface Wb of the workpiece W so as to project in the + Z direction.

During the grinding process, the grinding water M is supplied to the contact portion between the grinding wheel 42b and the workpiece W through the flow path 43 in the rotary shaft 40, and the grinding wheel 42b and the back surface Wb of the workpiece W are contacted with each other. Cool and clean the contact area. The washing water that has reached the contact portion flows out from the gap between the grinding wheels 42b together with the abrasive grains that have fallen off from the grinding and grinding wheels 42b due to the centrifugal force generated by the rotation of the chuck table 3. In the grinding method according to the present invention, the grinding water M containing the abrasive grains that have fallen off from the grinding wheel 42b due to the inclination of the workpiece W that is sucked and held on the chuck table 3 that is inclined by 45 degrees with respect to the vertical direction. Flows on the circular recess Wb1 toward the discharge position shown in FIG. Then, the grinding water M is accelerated by the inclination of the workpiece W, and is discharged to the outside of the workpiece W over the ring-shaped reinforcing portion Wb2 at the discharge position. Further, since the discharge position of the grinding water M and the rotation locus of the grinding wheel 42b do not overlap, the discharge of the grinding water M including the abrasive grains dropped by the grinding wheel 42b is not hindered.
After grinding the workpiece W to a desired thickness while supplying the grinding water M, the grinding means 4 is separated from the workpiece W and the grinding is completed.

As described above, in the grinding method according to the present invention, after performing the surface protection step of covering the surface Wa of the workpiece W with the protective member T1 and the surface protection step, the temperature is 45 to 180 degrees with respect to the vertical direction. A holding step for holding the protective member T1 side of the workpiece W on the holding surface 30a of the chuck table 3 rotated by the rotating shaft 33 inclined at an angle, and a grinding wheel 42b rotating on the rotating shaft 40 orthogonal to the holding surface 30a. The back surface Wb of the workpiece W corresponding to the device region Wa1 is ground while supplying the grinding water M, and the circular recess Wb1 and the ring-shaped reinforcing portion Wb2 corresponding to the outer peripheral surplus region Wa2 and surrounding the circular recess Wb1 are formed. Since the grinding step to be formed is provided, in the grinding step, the discharge of the grinding water M containing the abrasive grains that have fallen off from the grinding wheel 42b is promoted by the inclination of the workpiece W, so that the grinding wheel 42b falls off during grinding. The entrainment of the abrasive grains is reduced, and it is possible to prevent scratches from being formed on the back surface Wb of the workpiece W and cracking of the workpiece W from occurring.

Further, in the grinding step, since the discharge position of the grinding water M including the abrasive grains that have fallen off from the grinding wheel 42b is the lowest point of the chuck table 3 in which the rotating shaft 33 is tilted, the rotation locus of the grinding wheel 42b and the grinding water M By positioning the grinding wheel 42b so that it does not overlap with the discharging position of the grinding wheel 42b, the grinding water M including the abrasive grains that have fallen off from the grinding wheel 42b can be discharged more efficiently.

The grinding method according to the present invention is not limited to the above embodiment, and the configuration of the grinding apparatus 2 shown in the attached drawings is not limited to this, and the effect of the present invention is exhibited. It can be changed as appropriate within the range that can be done. For example, instead of supplying the grinding water to the contact portion between the grinding wheel 42b and the workpiece W through the rotating shaft 40 of the grinding means 4, the grinding water is supplied from the outside to the grinding wheel 42b using an injection nozzle. It may be supplied to the contact portion with the workpiece W.

W: Work piece Wa: Surface of work piece Wa1: Device area Wa2: Outer peripheral surplus area S: Scheduled division line D: Device Wb: Back side of work piece Wb1: Circular recess Wb2: Ring-shaped reinforcing part T1: Protective member 2: Grinding device 3: Chuck table 30: Holding part 30a: Holding surface 31: Frame 33: Rotating shaft 34: Motor 4: Grinding means 40: Rotating shaft 41: Mount 42: Grinding wheel 42a: Wheel base 42b: Grinding Grinding stone 43: Flow path

Claims (2)

A method for grinding a work piece, which grinds the back surface of the work piece having a device area on which a plurality of devices are formed and an outer peripheral surplus area surrounding the device area on the front surface with the grinding wheel.
A surface protection step that covers the surface of the work piece with a protective member,
After performing the surface protection step, a holding step for holding the protective member side of the workpiece on the holding surface of the chuck table that rotates on the rotating shaft inclined at an angle of 45 to 90 degrees with respect to the vertical direction. When,
The back surface of the workpiece corresponding to the device region is ground with a grinding wheel that rotates on a rotation axis orthogonal to the holding surface while supplying grinding water, and the circular recess is formed corresponding to the circular recess and the outer peripheral excess region. With a grinding step, which forms a ring-shaped reinforcement that surrounds,
In the grinding step, the discharge position of the grinding water containing the abrasive grains that have fallen off from the grinding wheel is the lowest point of the chuck table on which the rotation axis is tilted, so that the rotation locus of the grinding wheel is the rotation of the workpiece. The grinding wheel is positioned so as to pass through the center and the rotation trajectory of the grinding wheel and the discharging position of the grinding water do not overlap, and the discharge of the grinding water containing the abrasive grains that have fallen off from the grinding wheel is the workpiece. A grinding method promoted by the inclination of the grinding wheel and the positioning of the grinding wheel. The grinding method according to claim 1, wherein the protective member is an adhesive tape.

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