JP7430450B2 - dresser board - Google Patents

Description

The present invention relates to a dresser board for dressing a cutting blade for cutting a workpiece.

By dividing a wafer on which a plurality of devices such as ICs (Integrated Circuits) and LSIs (Large Scale Integrations) are formed, a plurality of device chips each having a device are manufactured. Further, after mounting a plurality of device chips on a predetermined substrate, a package substrate is obtained by covering the mounted device chips with a sealing material (molding resin) made of resin. By dividing this package substrate, a package device including a plurality of packaged device chips is manufactured. Device chips and package devices are installed in various electronic devices such as mobile phones and personal computers.

When dividing a workpiece such as the above-mentioned wafer or package substrate, a holding table for holding the workpiece and a spindle (rotating shaft) to which an annular cutting blade for cutting the workpiece is attached are provided. A cutting device is used. A cutting blade is attached to a spindle and rotated to cut into a workpiece held by a holding table, thereby cutting and dividing the workpiece.

When processing a workpiece with a cutting blade, dressing is performed to intentionally wear the tip of the cutting blade for the purpose of modifying the shape of the cutting blade, ensuring the sharpness of the cutting blade, and the like. For example, dressing is performed by holding a member for dressing a cutting blade (dresser board) on a holding table of a cutting device and cutting the cutting blade into the dresser board (see Patent Document 1).

The cutting blade includes abrasive grains and a binding material that fixes the abrasive grains. When dressing is performed, the binding material comes into contact with the dresser board and wears out, making the cutting blade concentric with the spindle (rounding) and exposing the abrasive grains from the binding material (sharpening). By using a cutting blade that has been dressed in this manner, the accuracy of machining the workpiece is improved.

Japanese Patent Application Publication No. 2000-49120

Dresser boards tend to generate particles (fine particles, dust, etc.). Specifically, the dresser board is configured to include abrasive grains that contact the cutting blade and wear the cutting blade, and a binding material that fixes the abrasive grains. Then, some of the abrasive grains and bonding material may separate from the dresser board and become particles.

For example, when a dresser board is shipped, if a shock is applied to the dresser board or the dresser boards collide with each other, abrasive grains may fall off the surface of the dresser board, or the abrasive grains may fall off the surface of the dresser board. Part of the bonding material may peel off starting from the unevenness that occurs on the surface. In this case, some of the abrasive grains and bonding material separated from the dresser board become particles and adhere to the surface of the dresser board.

If particles are present on the surface of the dresser board, the particles will be scattered when the dresser board is transported to a cutting device for dressing the cutting blade. This poses a problem in that the inside of the cutting device and the clean room in which the cutting device is installed are contaminated.

The present invention was made in view of this problem, and an object of the present invention is to provide a dresser board that can prevent particles from scattering.

According to one aspect of the present invention, there is provided a dresser board for dressing a cutting blade, the dressing layer comprising abrasive grains fixed by a binder and having a first surface and a second surface; A dresser board is provided that includes a scattering prevention film that is provided so as to cover the entire first surface side and the second surface side and prevents particles from scattering from the dressing layer.

Preferably, the anti-scattering film is a water-insoluble resin film. Further, preferably, the bonding material is a resin bond. Further preferably, the dressing layer has a side surface, and the anti-scattering film covers the side surface of the dressing layer.

A dresser board according to one aspect of the present invention includes anti-scattering films provided on the first surface side and the second surface side of the dressing layer, respectively. This prevents particles from scattering from the dressing layer and prevents contamination of cutting equipment, clean rooms, etc.

FIG. 1(A) is a perspective view showing a dresser board, and FIG. 1(B) is a sectional view showing the dresser board. FIG. 2 is a perspective view of a dresser board supported by a frame. It is a perspective view showing a cutting device. FIG. 2 is a cross-sectional view showing a dresser board cut by a cutting blade. FIG. 2 is a cross-sectional view showing a dresser board provided with a scattering prevention film covering the front, back, and side surfaces of a dressing layer.

Embodiments of the present invention will be described below with reference to the accompanying drawings. First, a configuration example of the dresser board according to the present embodiment will be described. The dresser board according to this embodiment is used for dressing a cutting blade that cuts a workpiece. A cutting blade is a processing tool that cuts into a workpiece to cut the workpiece, and is formed by fixing abrasive grains with a bonding material.

An example of a workpiece to be cut by a cutting blade is a silicon wafer, which has devices such as ICs and LSIs in a plurality of areas partitioned by a plurality of dividing lines (street) arranged in a grid pattern. Can be mentioned. By cutting this silicon wafer with a cutting blade and dividing it along the planned dividing line, a plurality of device chips each having a device are manufactured.

However, there are no restrictions on the material, shape, structure, size, etc. of the workpiece processed by the cutting blade. For example, the workpiece may be a wafer of any shape and size made of a semiconductor other than silicon (GaAs, InP, GaN, SiC, etc.), glass, ceramics, resin, metal, or the like. Furthermore, there are no restrictions on the type, quantity, shape, structure, size, arrangement, etc. of devices formed on the workpiece, and the workpiece does not need to have any devices formed thereon. Furthermore, the workpiece may be a package substrate such as a CSP (Chip Size Package) substrate or a QFN (Quad Flat Non-leaded package) substrate.

When processing a workpiece with a cutting blade, the cutting blade is first dressed. Dressing is performed by rotating a cutting blade attached to a spindle and causing the tip of the cutting blade to cut into the dresser board. As a result, the bonding material contacts the dresser board at the tip of the cutting blade and wears out, the shape of the cutting blade is adjusted to be concentric with the spindle (rounding), and the abrasive grains are appropriately exposed from the bonding material. (Highlight).

FIG. 1(A) is a perspective view showing the dresser board 11, and FIG. 1(B) is a sectional view showing the dresser board 11. The dresser board 11 is a plate-shaped member for dressing a cutting blade, and includes a dressing layer 13.

The dressing layer 13 is, for example, a plate-shaped member formed in a rectangular shape in plan view, and has a surface (first surface) 13a and a back surface (second surface) 13b that are generally parallel to each other, and is connected to the front surface 13a and the back surface 13b. and a side surface (outer peripheral surface) 13c. The dressing layer 13 includes abrasive grains and a bonding material that fixes the abrasive grains. For example, the dressing layer 13 is formed by fixing abrasive grains made of green carborundum (GC), white arundum (WA), or the like with a binding material such as resin bond or vitrified bond.

However, the materials of the abrasive grains and binder contained in the dressing layer 13 are not limited, and are appropriately selected depending on the material, thickness, diameter, etc. of the cutting blade to be dressed. Furthermore, there are no restrictions on the content, particle size, etc. of abrasive grains contained in the dressing layer 13. For example, the abrasive grains are contained in the dressing layer 13 in a weight ratio of 55% to 65%. Further, the average particle diameter of the abrasive grains is, for example, 0.1 μm or more and 50 μm or less.

There are no limitations on the method of forming the dressing layer 13 either. For example, after impregnating abrasive grains in a resin such as a phenol resin or an epoxy resin, the resin is formed into a plate shape and fired at a predetermined temperature (for example, 150° C. or higher and approximately 200° C. or lower), thereby forming the dressing layer 13. is formed.

Here, the dressing layer 13 has a property of easily generating particles (fine particles, dust, etc.). Specifically, some of the abrasive grains and binder contained in the dressing layer 13 may separate from the dressing layer 13 and become particles.

For example, when a shock is applied to the dresser board 11 or the dresser boards 11 collide with each other during shipping of the dresser board 11, abrasive grains may fall off on the front surface 13a side or the back surface 13b side of the dressing layer 13. A part of the bonding material may be peeled off starting from the unevenness formed on the front surface 13a or the back surface 13b of the dressing layer 13 due to the falling off of the abrasive grains. In this case, some of the abrasive grains and binder separated from the dressing layer 13 become particles and adhere to the front surface 13a side or the back surface 13b side of the dressing layer 13.

If particles are present on the front surface 13a side or the back surface 13b side of the dressing layer 13, the particles will scatter when the dresser board 11 is transported to a cutting device for dressing the cutting blade. This contaminates the interior of the cutting device and the clean room in which the cutting device is installed.

Therefore, in the dresser board 11 according to the present embodiment, anti-scattering films 15 are provided on the front surface 13a side and the back surface 13b side of the dressing layer 13, respectively, to prevent scattering of particles. This prevents particles from scattering from the front surface 13a side and the back surface 13b side of the dressing layer 13, thereby suppressing contamination of the cutting device and the clean room.

As shown in FIGS. 1A and 1B, the dresser board 11 includes a scattering prevention film 15 (scattering prevention film 15A) provided on the front surface 13a side of the dressing layer 13, and a back surface 13b of the dressing layer 13. The anti-scattering film 15 (anti-scattering film 15B) provided on the side is provided. The anti-scattering film 15A is formed to cover the entire surface 13a of the dressing layer 13, and the anti-scattering film 15B is formed to cover the entire back surface 13b of the dressing layer 13.

For example, the anti-scattering film 15A and the anti-scattering film 15B are each formed into a rectangular shape in plan view, corresponding to the shapes of the front surface 13a and the back surface 13b of the dressing layer 13. However, the shapes of the anti-scattering films 15A and 15B are not limited and are appropriately set according to the shape of the dressing layer 13.

The material of the anti-scattering film 15 is not limited as long as the anti-scattering film 15 can prevent particles from scattering from the dressing layer 13 and the anti-scattering film 15 can be cut by the cutting blade to be dressed. do not have. For example, as the anti-scattering film 15, an organic film (resin film, etc.) or an inorganic film (silicon oxide film, silicon nitride film, metal film, glass film, etc.) is used.

As shown in FIGS. 1(A) and 1(B), when the scattering prevention films 15A and 15B are provided on the dressing layer 13, even if particles are generated on the front surface 13a side or the back surface 13b side of the dressing layer 13, The particles are sandwiched and confined between the dressing layer 13 and the anti-scattering films 15A and 15B. This can prevent particles from scattering around the dresser board 11. For example, even if some of the abrasive grains and binder contained in the dressing layer 13 are separated from the dressing layer 13 and powder particles are generated, scattering of these particles is prevented by the anti-scattering films 15A and 15B.

Further, the anti-scattering film 15 is made of a film that does not contain abrasive grains. Therefore, particles are not generated in the anti-scattering film 15 due to shedding of abrasive grains or peeling of the film starting from irregularities caused by shedding of abrasive grains. Therefore, contamination of the cutting equipment and the clean room due to particles scattering from the scattering prevention film 15 does not become a problem.

As will be described later, when dressing a cutting blade using the dresser board 11, cutting fluid such as pure water is supplied to the dresser board 11. Therefore, the anti-scattering film 15 is preferably water-insoluble. For example, as the anti-scattering film 15, a water-insoluble resin film made of a resin such as polystyrene, polyethylene, acrylic, phenol, or epoxy is used.

When the anti-scattering film 15 is a water-insoluble resin film, the anti-scattering film 15 remains on the front surface 13a side and the back surface 13b side of the dressing layer 13 even if the cutting blade is dressed. Therefore, particles are prevented from scattering even when the dresser board 11 is transported again after dressing the cutting blade.

The method for forming the anti-scattering film 15 can be selected as appropriate depending on the material of the anti-scattering film 15. For example, as the anti-scattering film 15, a film that can be formed using a dry process such as vapor deposition, sputtering, or CVD (Chemical Vapor Deposition), or a wet process such as coating, spin coating, spray coating, or dipping may be used on the surface of the dressing layer 13. 13a side and the back surface 13b side. The anti-scattering film 15 may be directly formed on the front surface 13a side and the back surface 13b side of the dressing layer 13, or may be formed separately from the dressing layer 13 and then attached to the dressing layer 13. .

The cutting blade is dressed using the dresser board 11 described above. When dressing the cutting blade, first, the dresser board 11 is supported by an annular frame. FIG. 2 is a perspective view showing the dresser board 11 supported by the frame 19.

A circular tape 17 is attached to the back side of the dresser board 11 (on the anti-scattering film 15B side). The tape 17 has a diameter that can cover the entire back side of the dresser board 11, and the dresser board 11 is attached to the center of the tape 17.

Note that there are no restrictions on the structure and material of the tape 17. For example, the tape 17 is a sheet-like member that includes a circular base material and an adhesive layer (glue layer) provided on the base material. The base material is made of a resin such as polyolefin, polyvinyl chloride, or polyethylene terephthalate, and the adhesive layer is made of an epoxy, acrylic, or rubber adhesive. Further, the adhesive layer may be an ultraviolet curing resin that is cured by irradiation with ultraviolet rays.

The outer periphery of the tape 17 is attached to an annular frame 19 made of metal or the like and having a circular opening 19a in the center. The diameter of the opening 19a is larger than the diameter of the circumscribed circle of the dresser board 11, and the dresser board 11 is arranged inside the opening 19a. When the tape 17 is attached to the dresser board 11 and the frame 19, the dresser board 11 is supported by the frame 19 via the tape 17.

Dressing of the cutting blade is performed by cutting the cutting blade into the dresser board 11 supported by the frame 19. A cutting device is used to dress the cutting blade. FIG. 3 is a perspective view showing the cutting device 2. As shown in FIG.

The cutting device 2 includes a holding table (chuck table) 4 that holds a workpiece or a dresser board 11 . The upper surface of the holding table 4 is formed approximately parallel to the X-axis direction (processing feed direction, first horizontal direction) and the Y-axis direction (indexing feed direction, second horizontal direction), and holds the workpiece or dresser board 11. It constitutes a holding surface 4a (see FIG. 4). The holding surface 4a is connected to a suction source (not shown) such as an ejector via a suction path (not shown), a valve (not shown), etc. formed inside the holding table 4.

A plurality of clamps (not shown) are provided around the holding table 4 to grip and fix the frame 19 that supports the dresser board 11. The holding table 4 also includes a ball screw type moving mechanism (not shown) that moves the holding table 4 along the A rotational drive source (not shown) such as a motor that rotates around a rotating shaft is connected.

A cutting unit 6 for cutting a workpiece or a dresser board 11 is arranged above the holding table 4. The cutting unit 6 includes a cylindrical housing 8, and a cylindrical spindle (not shown) is accommodated in the housing 8 in a state substantially parallel to the Y-axis direction.

A tip (one end) of the spindle is exposed outside the housing 8, and an annular cutting blade 10 is attached to this tip. Further, a rotational drive source such as a motor is connected to the base end (other end) of the spindle. The cutting blade 10 attached to the tip of the spindle is rotated by power transmitted via the spindle from a rotational drive source.

As the cutting blade 10, for example, a hub-type cutting blade is used, which is configured by integrally forming an annular base made of metal or the like and an annular cutting blade formed along the outer periphery of the base. It will be done. The cutting edge of a hub-type cutting blade is composed of an electroformed grindstone in which abrasive grains made of diamond or the like are fixed by a binding material such as a nickel plating layer. Further, as the cutting blade 10, a washer-type cutting blade may be used, which is constituted by an annular cutting blade in which abrasive grains are fixed by a binding material made of metal, ceramics, resin, or the like.

When the cutting blade 10 is attached to the tip of the spindle, the cutting blade 10 is covered by a blade cover 12 fixed to the housing 8. The blade cover 12 has a connection part 14 connected to a tube (not shown) to which cutting fluid such as pure water is supplied, and a connection part 14 connected to the connection part 14 and arranged on both sides (front and back sides) of the cutting blade 10. A pair of nozzles 16 are provided. Each of the pair of nozzles 16 is formed with an injection port (not shown) that opens toward the cutting blade 10 .

When the cutting fluid is supplied to the connecting portion 14, the cutting fluid is sprayed from the injection ports of the pair of nozzles 16 toward both sides (front and back surfaces) of the cutting blade 10. This cutting fluid cools the cutting blade 10 and the workpiece held by the holding table 4 or the dresser board 11, and washes away debris (cutting debris) generated by the cutting process.

A ball screw type moving mechanism (not shown) for moving the cutting unit 6 is connected to the cutting unit 6 . This moving mechanism moves the cutting unit 6 along the Y-axis direction and raises and lowers it along the Z-axis direction. This movement mechanism controls the position of the cutting blade 10 in the Y-axis direction and the Z-axis direction.

When dressing the cutting blade 10 using the cutting device 2, the dresser board 11 is first held by the holding table 4 of the cutting device 2. For example, the front side of the dresser board 11 (the anti-scattering film 15A side) is exposed upward, and the back side of the dresser board 11 (the anti-scattering film 15B side, the tape 17 side) is the holding surface 4a of the holding table 4 (see FIG. 4). ) The dresser board 11 is placed on the holding table 4 so as to face it. Further, a frame 19 that supports the dresser board 11 is fixed by a plurality of clamps (not shown) provided around the holding table 4.

In this state, when negative pressure from a suction source is applied to the holding surface 4a of the holding table 4, the back side of the dresser board 11 is sucked by the holding table 4 through the tape 17. Thereby, the dresser board 11 is held by the holding table 4.

Next, the cutting blade 10 is made to cut into the dresser board 11, and the dresser board 11 is cut with the cutting blade 10. By cutting the cutting blade 10 into the dresser board 11, the tip portion (cutting edge) of the cutting blade 10 is worn out, and the cutting blade 10 is dressed.

First, the holding table 4 is rotated to align the length direction of one side of the dresser board 11 with the X-axis direction. Further, the positions of the holding table 4 and the cutting unit 6 are adjusted so that the cutting blade 10 is placed on the side of the dresser board 11.

Furthermore, the position of the cutting unit 6 in the Z-axis direction is adjusted so that the tip of the cutting blade 10 cuts into the dressing layer 13 of the dresser board 11. Specifically, the height of the cutting unit 6 is adjusted so that the lower end of the cutting blade 10 is located below the front surface 13a of the dressing layer 13 and above the back surface 13b of the dressing layer 13.

Then, while rotating the cutting blade 10, the holding table 4 is moved along the X-axis direction to relatively move the dresser board 11 and the cutting blade 10 (processing feed). Thereby, the cutting blade 10 cuts into the dresser board 11 to a cutting depth that reaches the dressing layer 13 and cuts the dresser board 11. As a result, a linear cutting groove 11a is formed on the scattering prevention film 15A side of the dresser board 11.

For example, while rotating the cutting blade 10 in the direction shown by arrow A, the holding table 4 is moved in the direction shown by arrow B. In this case, the holding table 4 and the cutting blade 10 move relatively so that the moving direction of the lower end of the cutting blade 10 and the moving direction of the holding table 4 match. Then, a so-called down cut is performed in which the cutting blade 10 cuts from the front side (the anti-scattering film 15A side) of the dresser board 11 toward the back side (the anti-scattering film 15B side).

FIG. 4 is a sectional view showing the dresser board 11 cut by the cutting blade 10. The cutting blade 10 cuts into the surface 13a of the dressing layer 13 to a cutting depth that reaches the dressing layer 13. As a result, the abrasive grains contained in the dressing layer 13 come into contact with the tip (cutting edge) of the cutting blade 10, causing the tip of the cutting blade 10 to wear out.

When the cutting blade 10 cuts into the dressing layer 13, the anti-scattering film 15 (anti-scattering film 15A) provided on the surface 13a side of the dressing layer 13 is also cut by the cutting blade 10 together with the dressing layer 13. However, the anti-scattering film 15 does not contain abrasive grains and does not easily cause wear of the cutting blade 10. Therefore, even if the cutting blade 10 cuts the anti-scattering film 15, unintended excessive wear or deformation of the cutting blade 10 will not occur.

Note that the anti-scattering film 15 is preferably formed thin so that dressing of the cutting blade 10 by the dressing layer 13 is not inhibited. For example, the thickness of the anti-scattering film 15 is set to 100 μm or less.

However, the thickness of the anti-scattering film 15 is preferably such that the surfaces of the abrasive grains protruding from the bonding material on the front surface 13a and the back surface 13b of the dressing layer 13 are appropriately covered by the anti-scattering film 15. For example, the thickness of the anti-scattering film 15 is set to be 60% or more of the amount of protrusion of the abrasive grains from the binding material.

Thereafter, the cutting unit 6 is moved in the Y-axis direction (indexing feed), and the cutting blade 10 is further cut into the region of the dresser board 11 where the cutting groove 11a is not formed. Then, the same procedure is repeated until the cutting blade 10 has a desired shape and the abrasive grains appropriately protrude from the bonding material at the tip of the cutting blade 10. This completes the dressing of the cutting blade 10. Thereafter, the dresser board 11 is transported from the holding table 4 to a predetermined storage location.

As described above, the dresser board 11 according to the present embodiment includes the anti-scattering film 15 provided on the front surface 13a side and the back surface 13b side of the dressing layer 13. This prevents particles from scattering from the dressing layer 13 and suppresses contamination of the cutting equipment, clean room, etc.

In the above embodiment, the anti-scattering film 15 is provided on the front surface 13a side and the back surface 13b side of the dressing layer 13, and the dresser board 11 with the side surface 13c of the dressing layer 13 exposed (FIG. 1(A) and FIG. 1(B)) was explained. However, the anti-scattering film 15 may be provided to cover not only the front surface 13a and the back surface 13b of the dressing layer 13 but also the side surface 13c of the dressing layer 13.

FIG. 5 is a sectional view showing the dresser board 11 including the anti-scattering film 15 covering the front surface 13a, back surface 13b, and side surface 13c of the dressing layer 13. By covering the entire side surface 13c (four surfaces) of the dressing layer 13 with the scattering prevention film 15, scattering of particles from the side surface 13c of the dressing layer 13 can also be prevented. This further effectively suppresses contamination of the cutting device 2 and the clean room due to particle scattering.

In addition, the structure, method, etc. according to the above embodiments can be modified and implemented as appropriate without departing from the scope of the objective of the present invention.

11 Dresser board 11a Cutting groove 13 Dressing layer 13a Surface (first surface)
13b Back side (second side)
13c Side surface (outer surface)
15, 15A, 15B Scattering prevention film 17 Tape 19 Frame 19a Opening 2 Cutting device 4 Holding table (chuck table)
4a Holding surface 6 Cutting unit 8 Housing 10 Cutting blade 12 Blade cover 14 Connection part 16 Nozzle

Claims (4)

A dresser board for dressing a cutting blade,
a dressing layer including abrasive grains fixed by a binder and having a first side and a second side;
A dresser board comprising: a scattering prevention film that is provided to cover the entire first surface and second surface of the dressing layer and prevents particles from scattering from the dressing layer. The dresser board according to claim 1, wherein the anti-scattering film is a water-insoluble resin film. 3. The dresser board according to claim 1, wherein the bonding material is resin bond. The dressing layer comprises sides;
4. The dresser board according to claim 1, wherein the anti-scattering film covers the side surface of the dressing layer.