KR102246098B1 - Work splitting device and work splitting method - Google Patents

Abstract

A work dividing apparatus and a work dividing method capable of solving the problem of dividing a line to be divided, which occurs when the chip size is a small chip, can be solved. The frame 4 of the wafer unit 2 is fixed by the frame fixing portion 12 of the expansion regulating ring 16. Next, the expand ring 14 is moved upward, and expansion of the entire area of the annular portion region 3B is started. Next, when the amount of upward movement of the expand ring 14 exceeds the thickness of the frame 4, the annular portion region 3B abuts against the expansion restricting portion 17, and in the annular portion region 3B , The expansion of the outer circumferential region 3E located on the outer circumferential side is regulated. Next, by continuing the upward movement of the expand ring 14 and continuing to expand the inner circumferential region 3F excluding the outer circumferential region 3E among the annular region 3B. , The wafer 1 is divided into individual chips 6.

Description

Work splitting device and work splitting method

The present invention relates to a work dividing apparatus and a work dividing method, and more particularly, to a work dividing apparatus and a work dividing method for dividing a work such as a semiconductor wafer into individual chips along a line to be divided.

Conventionally, in the manufacture of a semiconductor chip (hereinafter referred to as a chip), a semiconductor wafer (hereinafter referred to as a wafer) in which a line to be divided has been formed in advance by forming a modified region by half-cutting by a dicing blade or by laser irradiation. A work dividing device for dividing) into individual chips along a line to be divided is known (see Patent Document 1, etc.).

22 is an explanatory view of the wafer unit 2 to which the disk-shaped wafer 1 divided by the work dividing device is affixed, and FIG. 22(A) is a perspective view of the wafer unit 2, FIG. 22B is a cross-sectional view of the wafer unit 2.

The wafer 1 is affixed to the central portion of a dicing tape (also referred to as an expansion tape or an adhesive sheet) 3 having a thickness of about 100 µm in which an adhesive layer is formed on one side, and the dicing tape 3 is attached to the outer periphery thereof. The corner is fixed to a rigid ring-shaped frame (hereinafter referred to as a frame) 4.

In the work dividing apparatus, the frame 4 of the wafer unit 2 is fixed by a frame fixing member (also referred to as a frame fixing mechanism) 7 indicated by a chain two-dotted line. Thereafter, from the bottom of the wafer unit 2, the expand ring (also referred to as the push-up ring) 8 shown by the double-dashed line is moved upward, and the dicing tape 3 is pressed by the expand ring 8 It expands radially. The tension of the dicing tape 3 generated at this time is applied to the line 5 to be divided of the wafer 1, so that the wafer 1 is divided into individual chips 6. The lines to be divided 5 are formed in the X and Y directions intersecting each other. In the case where the number parallel to the X direction and the number parallel to the Y direction are the same number, and the intervals in each direction are equal, the divided chips 6 are The shape becomes square. Further, when the number parallel to the X direction and the number parallel to the Y direction are different, and when the intervals in the respective directions are equal, the shape of the divided chips 6 is rectangular.

By the way, the dicing tape 3 has a low Young's modulus and is a flexible member. For this reason, in order to smoothly divide the wafer 1 into individual chips 6, the dicing tape 3 is cooled, and the dicing tape 3's spring constant is increased. It is conceivable to expand the sinking tape 3.

The tape expansion device (work dividing device) of Patent Document 2 is provided with a cold air supply means. According to Patent Document 2, the dicing tape is cooled by operating the cold air supply means to supply cold air into the processing space, and cooling the inside of the processing space to, for example, 0°C or less.

On the other hand, in the chip dividing and separating device of Patent Document 3 (work dividing device), a film surface support mechanism is provided to focus on the anisotropy of the dicing tape and to uniformly expand the dicing tape by adding the anisotropy. I'm doing it. This film surface support mechanism includes a plurality of independent support mechanisms in the circumferential direction, and by individually controlling the relative heights of the plurality of support mechanisms to adjust the tension of the dicing tape, elongation of the dicing tape in the X direction and The Y-direction elongation is independently controlled.

Here, in the specification of the present application, a circular area in the dicing tape 3 when viewed from a plane to which the wafer 1 is affixed is referred to as the central region 3A, and the outer edge of the central region 3A The donut-shaped region in plan view provided between the 緣部 and the inner edge of the frame 4 is referred to as a ring-shaped region 3B, and the outermost fixed to the frame 4 When viewed from the plane of the circumferential portion, the donut-shaped region is referred to as the fixed portion region 3C. The annular portion region 3B is a region pressed by the expand ring 8 to expand.

In addition, the force required to divide the wafer 1, that is, the tension that must be generated in the annular region 3B in order to divide the wafer 1, increases as the number of lines 5 to be divided increases. It is known that you have to make it big. Regarding the number of lines to be divided 5, for example, in the case of a wafer 1 having a diameter of 300 mm and a chip size of 5 mm, approximately 120 lines (60 each in the XY direction) to be divided. Is formed, and when the chip size is 1 mm, approximately 600 division scheduled lines 5 are formed. Therefore, the tension that must be generated in the annular portion region 3B must be increased as the chip size decreases.

Japanese Unexamined Patent Publication No. 2016-149581 Japanese Unexamined Publication No. 2016-12585 Japanese Unexamined Patent Publication No. 2012-204747

By the way, the inner diameter (diameter of the inner edge of the frame) of the frame 4 on which the wafer 1 having a diameter of 300 mm is mounted is the SEMI standard (Semiconductor Equipment and Materials International standards) (G74-0699 A tape frame for a 300 mm wafer). It is set to 350mm by According to this standard, as in the longitudinal sectional view of the wafer unit 2 in FIG. 23, between the outer edge of the wafer 1 and the inner edge of the frame 4, an annular portion region 3B having a width dimension of 25 mm. Will exist. In addition, the frame fixing member 7 for fixing the frame 4 is formed by the expand ring 8 as shown in the longitudinal sectional view of the main part of the work dividing device shown in FIGS. 24A and 24B. It is provided at a position spaced outward from the annular region 3B in the in-plane direction of the dicing tape 3 indicated by arrow A so as not to contact the expanded annular region 3B.

For this reason, the force to divide the wafer 1 generated by the raising operation of the expand ring 8 is (i) the force to expand the entire area of the annular region 3B, and (ii) the wafer 1) It is decomposed into three forces: the force dividing into chips 6, (iii) the force extending the dicing tape 3 between the adjacent chips 6 and the chips 6.

As in the operation diagram of the work dividing device shown in Figs. 25A to 25E, the expand ring 8 abuts against the annular region 3B of the dicing tape 3, and the expand ring 8 When the dicing tape 3 is started to expand by the rising motion of (Fig. 25(A)), first of all, the expansion of the annular part region 3B having the lowest spring constant is started (Fig. 25(B)). )). Accordingly, tension is generated in the annular region 3B, and when this tension is increased to some extent, the increased tension is transmitted to the wafer 1 and the division of the wafer 1 into the chips 6 is started (Fig. Of 25 (C)). When the wafer 1 is divided into individual chips 6, the expansion of the annular region 3B and the expansion of the dicing tape 3 between chips proceed simultaneously (Figs. 25D to 25E). ).

In the conventional work dividing apparatus, in the case of a wafer 1 having a diameter of 300 mm, when the chip size is 5 mm or more, it is divided into individual chips 6 by the tension generated in the annular region 3B. Could. However, with the miniaturization of the circuit pattern formed on the wafer 1, chips with a smaller chip size of 1 mm or less also appeared. In this case, due to the increase in the number of the scheduled division lines 5 dividing the wafer 1, the force required for dividing the wafer 1 increases, and the tension due to the expansion of the annular region 3B There were cases where more power was needed. Then, as in the longitudinal cross-sectional view of the wafer unit 2 in Fig. 26, even when the expansion operation by the expand ring 8 is finished, a part of the line to be divided 5 formed on the wafer 1 is not divided but is in a state of being undivided. There was a problem that it remained.

The problem of fine division of the line 5 to be divided cannot be solved even if the expansion amount or expansion speed of the dicing tape 3 is increased. This is because, for example, when the expansion amount of the dicing tape 3 is increased, the annular portion region 3B starts plastic deformation. Since the spring constant of the annular region 3B during plastic deformation is smaller than the spring constant during elastic deformation, in the region exceeding the elastic deformation of the annular region 3B, the wafer 1 is replaced with individual chips 6 There is no tension divided by ). On the other hand, even when the expansion speed of the dicing tape 3 is increased, a part of the annular region 3B starts plastic deformation, so the tension that divides the wafer 1 into individual chips 6 Does not occur. This is because since the frequency response of the dicing tape 3 is low, no force is transmitted to the entire dicing tape 3 without a time difference.

In order to solve the problem of fine division of the line to be divided 5, Patent Document 2 responds by cooling the dicing tape and increasing the spring constant of the dicing tape. You can't get enough effect on the chip.

In addition, the chip separation device of Patent Literature 3 can independently control the extension of the dicing tape in the X direction and the Y direction, but a force greater than the tension caused by the expansion of the annular region can be applied to the wafer. Therefore, it is not possible to solve the problem of differential division of the line to be divided.

The present invention has been made in view of such a problem, and an object of the present invention is to provide a work dividing apparatus and a work dividing method capable of solving the problem of dividing a line to be divided, which occurs when the chip size is small.

In the work dividing apparatus of the present invention, in order to achieve the object of the present invention, the outer periphery of the dicing tape is fixed to a ring-shaped frame having an inner diameter larger than the outer diameter of the work, and the dicing tape In a work dividing device for dividing an affixed work into individual chips along a line to be divided, a frame fixing member for fixing a ring-shaped frame, and a back surface side opposite to the affixed surface of the work in the dicing tape, , An expand ring that is smaller than the inner diameter of the ring-shaped frame and is formed in a ring shape that is larger than the outer diameter of the work, and expands the dicing tape by pressing the back surface of the dicing tape to generate tension in the dicing tape, and the die. Dicing tape formed in a ring shape having an opening smaller than the inner diameter of the ring-shaped frame and larger than the outer diameter of the expand ring, disposed on the same side as the affixed surface of the work in the sinking tape, and using an expand ring The dicing tape is provided with an expansion regulating ring which abuts at the time of expansion of the dicing tape.

According to the work dividing device of the present invention, when the dicing tape is expanded by the expand ring, the dicing tape abuts against the expansion regulating ring when the dicing tape is expanded. At this time, the dicing tape is divided into an outer circumferential side region located on the outer circumferential side and an inner circumferential side region located on the inner circumferential side with the abutting portion in contact with the expansion regulating ring as a boundary. Then, in the expansion operation by the expansion ring after the dicing tape abuts against the expansion regulation ring, the expansion of the outer circumferential side region is regulated by the expansion regulation ring, and only the inner circumferential side region is expanded. That is, the tension of the spring constant in the inner circumferential side region greater than the spring constant of the dicing tape is applied to the work. Accordingly, since the tension applied to the work increases, the problem of dividing the line to be divided, which occurs when the chip size is small, can be solved.

In one embodiment of the present invention, the expansion regulating ring has a tape position regulating portion that abuts against the dicing tape when the dicing tape is expanded by the expand ring, and the tape position regulating portion has a dicing tape of a ring-shaped frame affixed thereto. It is preferable to be disposed on the same side as the tape affixed surface, or on the side where the expand ring is disposed than on the same side.

In one embodiment of the present invention, the expansion regulating ring includes a frame fixing portion fixed to the ring-shaped frame, and a protruding portion protruding toward the dicing tape along an outer periphery of the opening of the expansion regulating ring, and the tape position regulating portion comprises a protruding portion. It is preferable to be configured by the tip of the.

In one aspect of the present invention, the expansion regulating ring is provided with a frame fixing portion disposed on the same side as the affixing surface of the work in the dicing tape, and a frame fixing portion that abuts against the ring-shaped frame and fixes the ring-shaped frame. It is desirable.

According to one aspect of the present invention, since the expansion restricting ring also has a function of fixing the ring-shaped frame, the number of parts of the work dividing device can be reduced, and furthermore, the operation of assembling the expansion regulating ring to the work dividing device The frame can be fixed by the frame fixing part.

In one aspect of the present invention, the expansion restricting ring is a frame fixing member disposed on the same side as the affixing surface of the work in the dicing tape, and is attached to and detached from the frame fixing member that fixes the ring-shaped frame through the expansion restricting ring. It is desirable to be fixed as possible.

According to an aspect of the present invention, when the chip size is a small chip, the expansion regulating ring can be assembled to the frame fixing member, and when the chip size is a large chip, the expansion regulating ring can be removed from the frame fixing member. I can. That is, even in the case of an existing work dividing device that does not have an expansion regulating ring, by attaching the extension regulating ring to the frame fixing member of the work dividing device, a work having a small chip size can be divided.

In one aspect of the present invention, it is preferable that the opening of the expansion regulating ring is formed in a circular shape.

According to an aspect of the present invention, in the X and Y directions intersecting each other, for example, in the X and Y directions, such as a work divided into square chips having the same dimensions in the X and Y directions, In the case of a workpiece having the same number (density) of the lines to be divided, it is preferable to use an expansion regulating ring having a circular opening. Similarly, in the case of a work affixed to the same dicing tape in which the spring constant in the X direction and the spring constant in the Y direction are the same, it is preferable to use an expansion restricting ring having a circular opening. Accordingly, an equal tension can be applied to the periphery of the work from the expanded inner circumferential side region, so that a suitable dividing ability for such a work can be realized.

In one aspect of the present invention, it is preferable that the opening of the expansion regulating ring is formed in an elliptical shape.

According to an aspect of the present invention, in the X and Y directions orthogonal to each other, for example, in the X and Y directions, such as a work divided into rectangular chips having different dimensions in the X and Y directions. When the number (density) of the lines to be divided is different from each other, it is preferable to use an expansion regulating ring having an oval opening.

In this case, the direction of the short diameter of the ellipse is aligned parallel to the direction of the high density of the line to be divided (the direction along the short side of the chip, the direction of the high density of the chip), and the long diameter of the ellipse ( The direction of the length is set parallel to the direction in which the density of the line to be divided is low (the direction along the long side of the chip, the direction in which the density of the chip is low). Accordingly, since the spring constant is increased in the inner circumferential region located in the direction in which the density of the scheduled division lines is high, a suitable tension for dividing the number of scheduled division lines can be applied to the work. On the other hand, in the annular portion region located in the direction in which the density of the scheduled division lines is low, the spring constant is small, but an appropriate tension for dividing the number of lines due to be divided can be applied to the work. Therefore, it is possible to realize a dividing ability suitable for such a work.

In addition, it is preferable to use an elliptical expansion restricting ring even in the case of a work affixed to a dicing tape having different anisotropy from the spring constant in the X direction and the spring constant in the Y direction.

In this case, the direction of the short axis of the ellipse is aligned parallel to the direction of the small spring constant, and the direction of the long axis of the ellipse is aligned parallel to the direction of the large spring constant. Accordingly, when the inner circumferential region is expanded, the spring constant of the inner circumferential region located in a direction parallel to the direction in which the spring constant is small is increased, and the spring constant of the inner circumferential region located in a direction parallel to the direction of the long axis of the ellipse. As it approaches, it is possible to apply an approximately equal tension to the work from the inner circumferential region. Therefore, for a work mounted on a dicing tape having anisotropy in which the spring constant in the X direction and the spring constant in the Y direction are different from each other, it is possible to realize a suitable dividing ability.

In the work dividing method of the present invention, in order to achieve the object of the present invention, the outer periphery of the dicing tape is fixed to a ring-shaped frame having an inner diameter larger than the outer diameter of the work, and the work affixed to the dicing tape is divided into a line to be divided. Accordingly, in the method of dividing the work into individual chips, the dicing tape is pressed to expand the dicing tape, thereby generating tension in the dicing tape, and the outer circumferential side of the dicing tape when the dicing tape is expanded. An expansion regulation step for regulating the expansion of the outer circumferential side area located at and a dividing step for dividing the work into individual chips while continuing to expand the dicing tape excluding the outer circumferential side area are provided.

According to the work dividing method of the present invention, it is possible to eliminate the problem of dividing a line to be divided, which occurs when the chip size is small.

Advantageous Effects of Invention According to the present invention, it is possible to solve the problem of differentiating a line to be divided, which occurs when the chip size is small.

Fig. 1 is a structural diagram of a main part of a work dividing device according to a first embodiment.
Fig. 2 is an enlarged perspective view of a main part of the work dividing device shown in Fig. 1;
Fig. 3 is a cross-sectional view of a wafer unit showing the shape of an annular region during expansion.
Fig. 4 is an enlarged cross-sectional view of an annular portion during expansion.
5 is a flowchart of a wafer dividing method.
Fig. 6 is a structural diagram of a main part of a work dividing device according to a second embodiment.
Fig. 7 is an enlarged perspective view of a main part of the work dividing device shown in Fig. 6;
Fig. 8 is an enlarged cross-sectional view of an annular portion during expansion.
Fig. 9 is a plan view in which a wafer unit and an expansion regulating ring having a circular expansion regulating opening are overlapped.
Fig. 10 is a plan view of overlapping an extension regulating ring having an oval-shaped extension regulating opening and a wafer unit.
Fig. 11 is a graph showing the expansion rates of the annular region and the inner circumferential region when the expansion restricting ring is not used and when it is used.
Fig. 12 is a graph showing the splitting ratio of a chip when not in use and in use of an extension regulation ring.
13 is a cross-sectional view of a main part of a work dividing device according to a third embodiment.
Fig. 14 is an enlarged cross-sectional view of a main part of the work dividing device shown in Fig. 13;
15 is a cross-sectional view of a main part of a work dividing device according to a fourth embodiment.
Fig. 16 is an enlarged cross-sectional view of a main part of the work dividing device shown in Fig. 15;
Fig. 17 is an explanatory view showing a first modified example of the expansion regulation ring shown in Fig. 6;
Fig. 18 is an explanatory view showing a second modified example of the expansion regulation ring shown in Fig. 6;
19 is a graph calculating the change in the expansion rate with respect to the push-up amount.
Fig. 20 is a schematic diagram showing an operation in an extended division process.
21 is a graph calculating the change in the rate of expansion rate with respect to the pushing speed.
Fig. 22 is an explanatory diagram of a wafer unit to which a wafer is affixed.
23 is a longitudinal sectional view of the wafer unit.
Fig. 24 is a side view of a main part of the work dividing device.
Fig. 25 is an operation diagram of a work dividing device.
Fig. 26 is a longitudinal sectional view of a wafer unit in which a wafer is divided.

Hereinafter, a preferred embodiment of a work dividing apparatus and a work dividing method according to the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the following embodiments, and various modifications and substitutions can be added to the following embodiments as long as it is within the scope of the present invention.

[Work dividing device 10A of the first embodiment]

1 is a longitudinal sectional view of a main part of a work dividing apparatus 10A according to a first embodiment, and FIG. 2 is an enlarged perspective view of a main part of the work dividing apparatus 10A. In addition, the size of the wafer unit to be divided and processed by the work dividing device 10A is not limited, but in the embodiment, a wafer unit 2 on which a wafer 1 with a diameter of 300 mm shown in Fig. 23 is mounted is illustrated. .

The work dividing apparatus 10A is an apparatus that divides the wafer 1 on which the division scheduled line 5 is formed into individual chips 6 along the division scheduled line 5. A plurality of lines to be divided 5 are formed in the X and Y directions intersecting each other. In the embodiment, the number of the number of lines to be divided 5 parallel to the X direction and the number of lines to be divided 5 parallel to the Y direction are 300 respectively, and the wafers 1 with equal intervals, i.e., chip size A wafer 1 divided into chips 6 of 1 mm is illustrated.

The wafer 1 is affixed to the center portion of the dicing tape 3 to which the outer peripheral portion is fixed to the frame 4, as shown in FIGS. 1 and 2. The dicing tape 3 is viewed in a plane between the outer edge of the frame 4 and the central portion 3A of a circular shape when viewed from the plane on which the wafer 1 is affixed, and the outer edge of the central portion 3A and the inner edge of the frame 4. When it has a donut-shaped annular region 3B.

The thickness of the wafer 1 is, for example, about 50 µm. In addition, as the dicing tape 3, for example, a PVC (polyvinyl chloride)-based tape is used. Further, the wafer 1 may be affixed to the dicing tape 3 via a film adhesive material such as a die attach film (DAF). As the film-like adhesive material, for example, a PO (polyolefin: polyolefin)-based material can be used.

The work dividing device 10A includes an expansion regulation ring 16 provided with a frame fixing portion 12 for fixing the frame 4 and an annular portion region 3B of the dicing tape 3 from the lower side. It has an expand ring 14 that abuts.

The expand ring 14 is disposed on the back side of the dicing tape 3 opposite to the affixed surface of the wafer 1, is smaller than the inner diameter (350 mm) of the frame 4, and is It is formed in a ring shape having an opening 14A for expansion larger than the outer diameter of 1) (300 mm). This expand ring 14 presses the back surface of the annular portion region 3B of the dicing tape 3 to expand the annular portion region 3B. That is, the expand ring 14 is moved upward with respect to the annular portion region 3B in the direction B crossing the in-plane direction indicated by the arrow A of the dicing tape 3. Accordingly, the annular portion 3B is pushed up by the expand ring 14 to expand radially. Further, by fixing the expand ring 14 and moving the wafer unit 2 downward in the direction of the arrow C, the annular portion region 3B may be expanded by the expand ring 14.

The expansion regulating ring 16 is composed of an expansion regulating portion 17 and a frame fixing portion 12. The frame fixing portion 12 is disposed on the same side as the affixed surface of the wafer 1 in the dicing tape 3, and the frame 4 is fixed to the lower surface 12A. The expansion regulating portion 17 is extended from the frame fixing portion 12 toward the center of the expansion regulating ring 16 from the frame 4. The annular portion region 3B of the dicing tape 3 abuts against the expansion restricting portion 17 at the time of expansion by the expand ring 14. In addition, the boundary between the frame fixing part 12 and the expansion regulation part 17 is denoted by reference numeral D in FIGS. 1 and 2.

The expansion regulating portion 17 is formed in a ring shape having an expansion regulating opening (opening portion) 16A smaller than the inner diameter (350 mm) of the frame 4 and larger than the outer diameter of the expand ring 14. .

3 is a longitudinal sectional view of the wafer unit 2 showing the shape of the annular portion 3B during expansion by the expand ring 14. 4 is an enlarged cross-sectional view of the annular portion region 3B during expansion.

As shown in FIGS. 3 and 4, at the time of expansion of the annular portion region 3B by the expand ring 14, the annular portion region 3B abuts against the expansion restricting portion 17. Specifically, the annular portion region 3B abuts against the inner edge portion 16B of the expansion restricting portion 17.

In the embodiment, as shown in Fig. 1, the diameter of the expansion regulation opening 16A is set to 338 mm. Accordingly, the width dimension of the outer circumferential region 3E in which expansion is regulated by the expansion regulating unit 17 is set to 6 mm, and the inner circumferential side except for the outer circumferential region 3E among the annular region 3B. The width dimension of the region 3F is set to 19 mm.

Here, of the annular portion regions 3B, the inner circumferential region 3F in which expansion is not restricted by the expansion regulation unit 17 becomes a region that substantially contributes to the division of the wafer 1. That is, as the width dimension of the inner circumferential side region 3F is decreased, the spring constant of the inner circumferential side region 3F increases, so that the tension applied to the wafer 1 from the inner circumferential side region 3F can be increased. Therefore, it is preferable to set the width dimension of the inner circumferential side region 3F according to the number of lines to be divided 5 and the size of the chips 6.

Hereinafter, according to the flow chart of Fig. 5, a method of dividing a work by the work dividing device 10A will be described.

First, in step S100 of FIG. 5, as in FIG. 1, the frame 4 of the wafer unit 2 is fixed by the frame fixing portion 12 of the expansion regulation ring 16 (fixing step).

Next, in step S110 of FIG. 5, the expand ring 14 is moved upward from the position of FIG. 1 in the direction of the arrow B, and the entire area of the annular region 3B is started to expand (expansion process). .

Next, in step S120 of FIG. 5, when the rising movement amount of the expand ring 14 exceeds the thickness of the frame 4, the annular portion region 3B abuts against the expansion restricting portion 17. At this time, as shown in FIG. 4, the annular portion region 3B is an outer peripheral region 3E positioned on the outer peripheral side with the abutment portion 3D abutting on the inner edge 16B of the expansion regulating portion 17 as a boundary. ) And an inner circumferential region 3F located on the inner circumferential side. And, of the annular portion regions 3B, the expansion of the outer circumferential region 3E is regulated by the expansion regulation unit 17 (expansion regulation process).

Next, in step S130 of FIG. 5, the upward movement of the expand ring 14 is continued, and the inner circumferential region 3F excluding the outer circumferential region 3E among the annular portion regions 3B. ) By continuing to expand, the wafer 1 is divided into individual chips 6 (dividing step). Thereafter, the upward movement of the expand ring 14 is stopped.

In the dividing step (S130), in the expansion operation by the expand ring 14 after the annular portion region 3B abuts the inner edge portion 16B of the expansion regulation portion 17, the outer circumferential side region 3E The expansion of is regulated by the expansion regulation unit 17, and only the inner circumferential side region 3F is expanded. In other words, the tension of the spring constant of the inner circumferential region 3F, which is larger than the spring constant of the annular region 3B, is applied to the wafer 1.

Specifically, the length of the annular region 3B contributing to the division of the wafer 1 is from 25 mm (width dimension of the annular region 3B) to 19 mm (the width of the inner circumferential region 3F). Dimension), the spring constant increases in inverse proportion to it. Accordingly, even if only the inner circumferential region 3F is expanded, the spring constant of the inner circumferential region 3F is larger than the spring constant of the annular region 3B, so that individual chips ( Tension as divided by 6) can be applied to the wafer 1. Therefore, according to the work dividing device 10A, it is possible to solve the problem of dividing the line to be divided, which occurs when the chip size is a small chip (1 mm).

In addition, in the inner edge portion 16B of the expansion regulating portion 17 that is in line contact with the adhesive layer of the annular portion region 3B, as an example, a surface treatment in which the arithmetic mean roughness Ra is 1.6 (µm). This is being done. Accordingly, it is possible to prevent the inner edge portion 16B and the annular portion region 3B from relatively sliding due to the frictional force between the inner edge portion 16B and the annular portion region 3B. Further, the inner edge portion 16B is subjected to chamfering of C0.2 (0.2 mm Chamfer) as an example. Accordingly, when an expansion force is received from the annular region 3B, it is possible to prevent the annular region 3B from being damaged by the reaction force.

In addition, since the expansion restriction ring 16 of the work dividing device 10A is provided with the frame fixing portion 12, it also has a function to fix the frame 4, so that the number of parts of the work dividing device 10A is reduced. This can be reduced, and the frame 4 can be fixed by the frame fixing portion 12 by assembling the expansion restricting ring 16 to the work dividing device 10A.

Further, the expand ring 14 of the work dividing device 10A has a ring shape having an expansion opening 14A surrounding the wafer 1 of the wafer unit 2 fixed to the frame fixing part 12. Consists of. Moreover, the expansion regulation part 17 is provided with the expansion regulation opening 16A which surrounds the ring-shaped expand ring 14. Accordingly, according to the work dividing device 10A, the annular portion region 3B is equally expanded in the entire region by the ring-shaped expand ring 14, and the expansion regulation portion 17 The annular portion region 3B is in line contact with the inner edge portion 16B of the expansion regulation opening 16A evenly. Accordingly, it is possible to reliably regulate the expansion of the outer circumferential side region 3E.

[Work dividing device 10B of the second embodiment]

6 is a longitudinal sectional view of a main part of the work dividing device 10B according to the second embodiment, and FIG. 7 is an enlarged perspective view of a main part of the work dividing device 10B. In addition, about the wafer unit processed by the work dividing apparatus 10B, the wafer unit 2 on which the wafer 1 with a diameter of 300 mm shown in FIG. 23 is mounted is illustrated. In addition, members that are the same or similar to those of the work dividing device 10A shown in Figs. 1 and 2 are denoted by the same reference numerals and described.

The difference between the work dividing device 10A of the first embodiment and the work dividing device 10B of the second embodiment is the frame fixing member 7 (see Fig. 24: an existing frame fixing member) and an expansion restricting ring. The point is that (18) is individually configured, and the expansion restricting ring (18) is detachably provided with respect to the frame fixing member (7). The structure for attaching and detaching the expansion restricting ring 18 to the frame fixing member 7 is not particularly limited, but as an example, a fastening structure using a bolt may be used, or a clamp structure using a clamp mechanism may be used.

The frame fixing member 7 is disposed on the same side as the affixed surface of the wafer 1 in the dicing tape 3. In addition, the frame fixing member 7 has an annular shape in the in-plane direction of the dicing tape 3 indicated by arrow A so as not to contact the annular portion region 3B extended by the expand ring 14. It is provided at a position spaced outward from the sub-region 3B. As shown in Fig. 7, the shape of the frame fixing member 7 is a ring shape, but the shape is not particularly limited, and any shape in which the expansion regulating ring 18 can be detachably attached may be used.

The expansion regulating ring 18 has an expansion regulating opening (opening) 18A smaller than the inner diameter (350 mm) of the frame 4 and larger than the outer diameter of the expand ring 14. The diameter of the expansion regulation opening 18A is also 338 mm.

8 is a longitudinal cross-sectional view of the wafer unit 2 showing the shape of the annular region 3B during expansion by the expand ring 14.

As shown in FIG. 8, the annular portion region 3B abuts against the inner edge portion 18B of the expansion restricting ring 18 when it is expanded by the expand ring 14. Accordingly, the expansion of the outer circumferential side region 3E between the abutting portion 3D abutting on the inner edge portion 18B and the inner edge portion of the frame 4 among the annular portion regions 3B is extended Regulated by (18).

Next, a method of dividing a work by the work dividing device 10B will be described, but it is substantially the same as the method of dividing a work by the work dividing apparatus 10A.

First, as shown in Fig. 6, the frame 4 of the wafer unit 2 is fixed with the frame fixing member 7 via the expansion restricting ring 18 (fixing step).

Next, the expand ring 14 is moved upward from the position in Fig. 6 in the direction of the arrow B, and expansion of the entire area of the annular portion region 3B is started (expansion step).

Next, when the amount of upward movement of the expand ring 14 exceeds the thickness of the frame 4, the annular portion region 3B abuts against the inner edge 18B of the expansion regulating ring 18, and the annular shape Among the sub-regions 3B, the expansion of the outer circumferential side region 3E located on the outer circumference side is regulated (expansion regulation step). At this time, as shown in FIG. 8, the annular portion region 3B is positioned on the outer peripheral side region 3E located on the outer circumference side, with the abutment portion 3D abutting on the inner edge portion 18B as a boundary. It is divided into an inner circumferential side area 3F.

Next, by continuing the upward movement of the expand ring 14 and continuing to expand the inner circumferential region 3F excluding the outer circumferential region 3E of the annular region 3B, the wafer 1 ) Is divided into individual chips 6 (segmentation process). Thereafter, the upward movement of the expand ring 14 is stopped.

In the dividing step, in the expansion operation by the expand ring 14 after the annular portion region 3B abuts the inner edge portion 18B of the expansion regulation ring 18, the expansion of the outer circumferential region 3E is performed. It is regulated by the expansion regulation ring 18, and only the inner circumferential side region 3F is expanded. In other words, the tension of the spring constant of the inner circumferential region 3F, which is larger than the spring constant of the annular region 3B, is applied to the wafer 1. Accordingly, according to the work dividing device 10B, similarly to the work dividing device 10A, the problem of dividing the line to be divided can be solved when the chip size is a small chip (1 mm).

In addition, at the time of expansion of the annular portion region 3B by the expand ring 14, the expansion restricting ring 18 is held between the frame fixing member 7 and the frame 4, The expansion of the outer circumferential region 3E is regulated. That is, even when the inner diameter (for example, 361 mm) of the frame fixing member 7 is larger than 350 mm, which is the inner diameter of the frame 4, the expansion regulating ring 18A has a diameter of 338 mm. By providing 18) separately, an effect equivalent to that of the frame fixing member 7 having an inner diameter of less than 350 mm can be obtained. That is, an effect equivalent to that of the expansion regulation ring 16 (see Figs. 1 and 2) of the first embodiment can be obtained.

In addition, in the work dividing device 10B, it is preferable to provide a plurality of expansion regulating rings 18 having different diameters (inner diameters) of the expansion regulating opening 18A in advance. Accordingly, it is possible to select and use the expansion restricting ring 18 having an inner diameter designated as a processing condition in advance. In addition, since the extension restricting ring 18 can be later mounted on an existing (shipped) work splitting device that does not have the extension restricting ring 18, it is possible to use the existing work splitting device to reduce the size of a large chip. Even chips can be processed. In addition, when the chip size is a large chip, the expansion regulation ring 18 can also be removed from the existing work dividing device. In addition, as the diameter (inner diameter) of the opening 18A for expansion regulation, other than 338 mm, for example, 346 mm, 342 mm, and 334 mm can be exemplified.

By the way, as the number of lines to be divided 5 formed on the wafer 1 increases, the force required for dividing the wafer 1 has to be increased. However, depending on the wafer, the X direction intersecting each other And in the Y direction, the number of lines to be divided 5 parallel to the X direction and the number of lines to be divided 5 parallel to the Y direction are the same number (see Fig. 9), or parallel to the X direction. The number of scheduled division lines 5 and the number of scheduled division lines 5 parallel to the Y direction are different from each other (see Fig. 10).

Fig. 9 is a plan view in which the expansion regulation ring 20 having the circular expansion regulation opening 20A and the wafer unit 2 are overlapped. The wafer 22 shown in Fig. 9 is a wafer having the same number of division scheduled lines 5 parallel to the X direction and the same number of division scheduled lines 5 parallel to the Y direction, and having the same distance between them. The shape of the resulting chip 24 is a square having the same dimensions in the X and Y directions. That is, the wafer 22 shown in FIG. 9 is a wafer having the same density of the line 5 to be divided in the X and Y directions. In the case of smoothly dividing the wafer 22, it is preferable to use a circular expansion control ring 20 for the expansion control opening 20A. That is, the wafer 22 and the expansion regulation opening 20A are circular, and when viewed in a plan view surrounded by the outer edge of the wafer 22 and the inner edge of the expansion regulation opening 20A, a donut-shaped inner circumferential region 3F ) Has the same width dimension (e) at any position in the circumferential direction.

Accordingly, an equal tension can be applied to the outer edge of the wafer 22 from the expanded inner circumferential region 3F. That is, by using the expansion regulating ring 20 having the circular expansion regulating opening 20A, it is suitable for dividing the wafer 22 having the same density of the line 5 to be divided in the X and Y directions. Tension can be applied to the wafer 22. Further, it is equivalent that the density of the line 5 to be divided in the X and Y directions is equal, and that the density of the chips 6 in the X and Y directions is equal.

Fig. 10 is a plan view in which an expansion limiting ring 26 having an elliptical expansion limiting opening 26A and a wafer unit 2 are stacked. The wafer 28 shown in FIG. 10 is a wafer in which the number of scheduled division lines 5 parallel to the Y direction is greater than the number of lines scheduled to be divided 5 parallel to the X direction. The shape is a rectangle having a short dimension in the X direction and a long dimension in the Y direction. That is, the wafer 28 shown in Fig. 10 is a wafer having different densities (densities of the chips 6) of the line 5 to be divided in the X and Y directions. In the case of smoothly dividing the wafer 28, it is preferable to use an elliptical expansion regulating ring 26 as the expansion regulating opening 26A.

In this case, the direction of the short diameter a of the ellipse of the opening 26A for expansion regulation is the X direction in which the density of the line to be divided 5 is high (the direction in which the density of the chip 30 is high, the short side of the chip 30) The direction of the long axis (b) of the ellipse is aligned in parallel with the direction parallel to the direction of the ellipse in the Y direction where the density of the line to be divided 5 is low (the direction in which the density of the chip 30 is low, the long side of the chip 30). Parallel direction) and parallel.

Accordingly, since the width dimension of the inner circumferential region 3FA located in a direction parallel to the X-direction where the density of the scheduled division line 5 is high, the spring constant is increased, so that the division scheduled line in the X-direction having a high density (5) A suitable tension for dividing can be applied to the wafer 28.

On the other hand, in the inner circumferential region 3FB located in a direction parallel to the Y direction where the density of the scheduled division line 5 is low, the width dimension is not small and the spring constant is small, but the Y direction division scheduled line ( 5) Suitable tension for dividing can be applied to the wafer 28. Therefore, it is possible to realize a dividing ability suitable for wafers 28 having different densities of the lines to be divided 5 in the X and Y directions.

In addition, in the dicing tape 3, the spring constant in the X direction and the spring constant in the Y direction are the same, or due to the direction of formation of the tape, there is a difference between the spring constant in the X direction and the spring constant in the Y direction. There is a difference between the elongation method in the and Y direction. In principle, there is a tendency that a direction parallel to the direction in which the tape is produced is easy to stretch, and a direction that intersects it is difficult to stretch.

Paying attention to the elongation characteristics of the dicing tape 3, in the case of the dicing tape 3 having the same spring constant in the X direction and the spring constant in the Y direction, the expansion control opening 20A shown in FIG. 9 is circular. It is preferable to use a phosphorus expansion regulating ring (20). Accordingly, the amount of stretching in the X direction and the amount of stretching in the Y direction of the inner circumferential region at the time of expansion becomes equal, so that equal tension can be applied to the wafer from the inner circumferential region 3F.

On the other hand, in the case of the dicing tape 3 having anisotropy in which the spring constant in the X direction and the spring constant in the Y direction are different from each other, the expansion regulating ring 26 having an elliptical expansion regulating opening 26A shown in FIG. It is preferable to use.

In this case, the direction of the short axis (a) of the ellipse is aligned parallel to the X direction of the small spring constant, and the direction of the long axis (b) of the ellipse is aligned parallel to the Y direction of the large spring constant. Accordingly, when the inner circumferential region is expanded, the spring constant of the inner circumferential region 3FA located in the X direction parallel to the direction in which the spring constant is small is increased, so that it is located in a direction parallel to the direction of the long diameter b of the ellipse. Since it approaches the spring constant of the inner circumferential side region 3FB, a substantially equal tension can be applied to the wafer from the inner circumferential side regions 3FA and 3FB. Therefore, it is possible to realize a suitable dividing ability for a wafer mounted on the dicing tape 3 having anisotropy in which the spring constant in the X direction and the spring constant in the Y direction are different from each other.

Here, in order to confirm the effect of the present invention, the results of experiments conducted by the present inventors will be described.

In the graph of Fig. 11, with respect to the wafer unit 2 of Fig. 23, the expansion ratio (diameter 350 mm) of the annular region when the expansion limiting ring is not used, and the inner circumferential side when the expansion limiting ring is used. As the expansion rate of the region, the expansion rate when the diameter of the expansion regulation opening is set to 346 mm, 342 mm, and 338 mm is shown. In addition, "MD (Machine Direction)" in FIG. 11 is a direction parallel to the feeding direction at the time of manufacture of the dicing tape 3, and is a direction in which the spring constant is small. In addition, "CD (Cross Direction)" is a direction orthogonal to MD, and is a direction having a large spring constant.

According to the experimental results of Fig. 11, the expansion ratio of the annular region when the expansion restricting ring is not used was 6.1% in "MD" and 6.0% in "CD". On the other hand, as the diameter of the opening for expansion regulation is reduced to 346 mm, 342 mm, and 338 mm, the expansion rate of the inner circumferential region increases to 6.8%, 7.5%, and 8.4% in "MD", and "CD ", it rose to 7.2%, 7.5%, and 8.1%. That is, it was confirmed that the dividing ability of the chip was improved as the diameter of the opening for expansion regulation was decreased.

In the graph of Fig. 12, with respect to the wafer unit 2 of Fig. 23, the splitting ratio of the chip when the expansion restricting ring is not used (diameter 350 mm) and the chip splitting ratio when the expansion restricting ring is used. , The split ratio when the diameter of the opening for expansion regulation is set to 338 mm is shown. In addition, the division ratio of "with DAF" in FIG. 12 is the division ratio of the chip 6 when the wafer 1 is affixed to the dicing tape 3 via the DAF, and is the division ratio of the "without DAF". The splitting ratio is the splitting ratio of the chips 6 when the wafer 1 is directly affixed to the dicing tape 3.

According to the experimental results of Fig. 12, the split ratio of the chip 6 when the extension regulating ring is not used was 15.0% in "with DAF" and 41.0% in "without DAF". On the other hand, the splitting ratio of the chip 6 when using the expansion regulating ring with the diameter of the expansion regulating opening of 338 mm increased to 61.0% in "with DAF", and increased to 100% in "without DAF". . That is, even if it is "with DAF" or "without DAF", it was confirmed that the dividing ability of the chip 6 was improved by using the extension regulation ring.

From the above experimental results, according to the work dividing devices 10A and 10B of the embodiment, the expansion of the outer circumferential region 3E is regulated by the expansion restricting ring 16, and only the inner circumferential region 3F is expanded, Since the expansion ratio is increased compared to the annular region 3B and the tension applied to the wafer 1 can be increased, the problem of dividing the line to be divided 5 that occurs when the chip size is small can be solved. It could be confirmed that there is.

[Work dividing device 10C of the third embodiment]

13 is a cross-sectional view of a main part of a work dividing device 10C according to a third embodiment.

The difference between the structure of the work dividing device 10C of Fig. 13 and the work dividing device 10A shown in Fig. 1 is that the protrusion 34 is provided on the expansion restricting ring 32 of the work dividing device 10C of Fig. 13. Is at the point.

In the description of the expansion restricting ring 32 of FIG. 13, members identical or similar to those of the expansion restricting ring 16 of FIG. 1 are denoted by the same reference numerals, and the description thereof will be omitted.

The expansion regulation ring 32 in FIG. 13 is provided with a frame fixing portion 12 and a protrusion 34 protruding toward the affixed surface 3G of the dicing tape 3. The protrusion 34 is provided along the periphery of the expansion regulation opening 32A of the expansion regulation ring 32. In addition, a tape position regulating portion is formed by the tip portion 34A of the protruding portion 34, and the tip portion 34A is the back surface of the frame 4 (tape affixing) to which the outer peripheral portion of the dicing tape 3 is fixed (attached). Surface) It is arrange|positioned at the position on the same surface as (4A). That is, the tip 34A of the protrusion 34 constituting the tape position regulating portion is on the same plane as the affixed surface 3G of the dicing tape 3 when the frame 4 is fixed to the expansion regulating ring 32 It is placed in the position of.

According to the expansion regulating ring 32 of FIG. 13, the distal end 34A of the protruding portion 34 of the expansion regulating ring 32 is diced in a state before the dicing tape 3 is expanded by the expand ring 14. It has already abutted against the affixed surface 3G of the tape 3. That is, the expansion of the outer circumferential region 3E of the dicing tape 3 is regulated by the expansion regulating ring 32 in the state before the dicing tape 3 is expanded by the expand ring 14.

Accordingly, according to the work dividing device 10C of FIG. 13, the expansion of the inner circumferential region 3F of the dicing tape can be started immediately after the expand ring 14 abuts the dicing tape 3. Therefore, according to the work dividing device 10C, the problem of differentiating the line to be divided, which occurs when the chip size is small, compared to the case of using the expansion restricting ring 14 of Fig. 1 which does not have the protrusion 32. Can be solved more efficiently.

In addition, in the work dividing device 10A of Fig. 1 and the work dividing device 10C of Fig. 13, when the height of the end position of the expanding operation of the expand ring 14 is the same, the work dividing device of Fig. 13 In (10C), the expansion amount (tension) of the inner region 3F of the dicing tape 3 increases from the work dividing device 10A of FIG. 1. Therefore, according to the work dividing device 10C of Fig. 13, the problem of dividing the line to be divided, which occurs when the chip size is small, can be further solved.

On the other hand, when the amount of expansion of the inner region 3F of the dicing tape 3 at the end of the expansion operation of the expand ring 14 is based on the dicing apparatus 10A of FIG. 1, FIG. In the work dividing apparatus 10C of 13, compared with the work dividing apparatus 10A of FIG. 1, the height of the extension operation end position of the expand ring 14 can be made lower by the thickness of the frame 4. Accordingly, according to the work dividing device 10C of Fig. 13, a sufficient amount of expansion (tension) can be obtained even with a small amount of rising movement of the expand ring 14, so that the differentiation of the scheduled division line generated when the chip size is small You can solve the problem more efficiently.

Specifically, as shown in the enlarged cross-sectional view of the main part of the work dividing device 10C shown in FIG. 14, when the expansion limiting ring 32 is used, the expansion limiting ring of FIG. 1 without the protrusion 34 ( Compared to the case of using 14), the height of the end position of the expansion operation of the expand ring 14 can be lowered by the thickness of the frame 4, and a division scheduled line generated when the chip size is small by that amount. It is possible to efficiently solve the problem of differential division. In addition, in FIG. 14, when the expansion restrict|regulation ring 14 which does not have the protruding part 32 is used, the expansion|extending operation end position of the expansion ring 14 is shown by the double-dashed line.

Further, according to the work dividing device 10C, in the distal end 34A of the protrusion 34 of the expansion regulating ring 32, as in the inner edge 16B of the expansion regulating ring 14 in FIG. 1, as an example. Surface processing is performed so that the arithmetic mean roughness Ra becomes 1.6 (µm). Accordingly, the frictional force between the tip portion 34A and the annular portion region 3B prevents the tip portion 34A and the annular portion region 3B from relatively sliding.

[Work dividing device 10D of the fourth embodiment]

15 is a cross-sectional view of a main part of a work dividing device 10D according to a fourth embodiment.

The difference between the structure of the work dividing device 10D in Fig. 15 and the work dividing device 10C shown in Fig. 13 is that the distal end 38A of the protrusion 38 of the expansion restricting ring 36 of the work dividing device 10D is , In that it is arranged on the side where the expansion ring 14 before the expansion operation is disposed than on the same surface as the affixed surface 3G of the dicing tape 3.

In the description of the expansion restricting ring 36 of FIG. 15, members identical or similar to the expansion restricting ring 32 of FIG. 13 are denoted by the same reference numerals, and the description thereof will be omitted.

According to the expansion regulating ring 36 in FIG. 15, in the state before the dicing tape 3 is expanded by the expand ring 14, the affixed surface 3G of the dicing tape 3 is the expansion regulating ring 36 ) Is already pressed against the distal end 38A of the protrusion 38. That is, in the state before the expansion of the dicing tape 3 by the expand ring 14, the expansion of the outer circumferential region 3E of the dicing tape 3 is regulated by the expansion regulating ring 32, and the inner circumference The side region 3F has already been expanded. Therefore, according to the work dividing device 10D, compared with the work dividing device C of Fig. 13, the problem of dividing a line to be divided, which occurs when the chip size is small, can be more efficiently solved.

In addition, in the work dividing device 10D of Fig. 15 and the work dividing device 10C of Fig. 13, when the height of the end position of the expanding operation of the expand ring 14 is the same, the work dividing device of Fig. 15 In (10D), the expansion amount (tension) of the inner region 3F of the dicing tape 3 increases from the work dividing device 10C of FIG. 13. Therefore, according to the work dividing device 10D of Fig. 15, the problem of dividing the line to be divided, which occurs when the chip size is small, can be further solved.

On the other hand, when the amount of expansion of the inner region 3F of the dicing tape 3 at the end of the expansion operation of the expand ring 14 is based on the dicing device 10C of FIG. 13, FIG. In the work dividing device 10D of 15, the height of the extended operation end position of the expand ring 14 is compared with the work dividing device 10C of FIG. 13, and the protrusion of the protrusion 38 with respect to the protrusion 34 It can be made as low as the difference in length. Accordingly, according to the work dividing device 10D of FIG. 15, the problem of differentiating a line to be divided, which occurs when the chip size is small, can be more efficiently solved than the work dividing device 10C of FIG. 13.

Specifically, as shown in the enlarged cross-sectional view of the main portions of the work splitting device 10D shown in FIG. 16, when the expansion restricting ring 36 is used, the extension restricting ring 32 of FIG. 13 provided with the protrusion 32 ), the height of the expansion end position of the expand ring 14 can be shortened by the difference of the protrusion length of the protrusion 38 with respect to the protrusion 34, and the chip size is reduced by the difference. In the case of small chips, the problem of differentiating a line to be divided can be efficiently solved. In addition, in FIG. 16, when the expansion limiting ring 32 provided with the protrusion part 32 is used, the expansion|finishing operation end position of the expansion ring 14 is shown by the double-dashed line.

In addition, according to the work dividing device 10D, in the distal end 38A of the protrusion 38 of the expansion regulating ring 36, as in the inner edge 16B of the expansion regulating ring 14 in FIG. 1, as an example. Surface processing is performed so that the arithmetic mean roughness Ra becomes 1.6 (µm). This prevents the distal end 38A and the annular region 3B from relatively sliding due to the frictional force between the distal end 38A and the annular region 3B.

[Work dividing device 10E of the fifth embodiment]

17 is an enlarged cross-sectional view of a main part of a work dividing device 10E according to a fifth embodiment.

In the work dividing device 10E of FIG. 17, the expansion restricting ring 40 is provided on the frame fixing member 7 so that attachment and detachment is possible. In the description of the expansion limiting ring 40, members identical or similar to those of the expansion limiting ring 32 of Fig. 13 are denoted by the same reference numerals, and the description thereof will be omitted.

In the expansion regulation ring 40 of FIG. 17, a protrusion 34 toward the affixed surface 3G of the dicing tape 3 is provided along the outer edge of the expansion regulation opening 40A of the expansion regulation ring 40. have. Further, the distal end 34A of the protruding portion 34 is disposed at a position (see FIG. 13) on the same surface as the affixed surface 3G of the dicing tape 3.

Accordingly, according to the work dividing device 10E of FIG. 17, the expansion of the inner circumferential region 3F of the dicing tape can be started immediately after the expand ring 14 abuts the dicing tape 3. Therefore, according to the work dividing device 10E, the problem of differentiating the line to be divided, which occurs when the chip size is small, compared to the case of using the expansion restricting ring 14 of Fig. 1 which does not have the protrusion 32. Can be solved more efficiently.

[Work dividing device 10F of the sixth embodiment]

18 is an enlarged cross-sectional view of a main part of a work dividing device 10F according to a sixth embodiment.

In the work dividing device 10F of FIG. 18, an expansion restricting ring 42 is provided on the frame fixing member 7 so as to be detachable. In the description of the expansion restricting ring 42, members identical or similar to those of the expansion restricting ring 36 in Fig. 15 are denoted by the same reference numerals, and the description thereof will be omitted.

In the expansion regulation ring 42 of FIG. 18, a protrusion 38 toward the affixed surface 3G of the dicing tape 3 is provided along the outer edge of the expansion regulation opening 42A of the expansion regulation ring 42. have. Further, the distal end 38A of the protrusion 38 is disposed on the side where the expand ring 14 before the expansion operation is disposed.

Accordingly, according to the work dividing device 10F of Fig. 18, since the expansion of the inner circumferential region 3F of the dicing tape is started before the expand ring 14 abuts the dicing tape 3, the protrusion Compared to the case of using the expansion regulation ring 40 of Fig. 17 provided with 34, it is possible to more efficiently solve the problem of dividing the line to be divided, which occurs when the chip size is small.

By the way, in the post-process of the dividing process S130 shown in FIG. 5, an expansion holding ring called a sub-ring is fitted to the frame 4, and the dicing tape 3 may maintain the expanded state. This expansion retaining ring is fitted to the frame 4 in a state where the outer circumferential side region 3E is stretched out. By using the expansion retaining ring, contact between adjacent divided chips can be regulated, and thus there is an effect that damage to the chips can be prevented.

According to the described work dividing devices 10C to 10F of Figs. 13 to 18, the expansion of the outer circumferential region 3E can be regulated by the tip portions 34A and 38A of the protrusions 34 and 38. Therefore, it is possible to prevent the dicing tape 3 in the outer circumferential side region 3E from being stretched and its thickness to be thin. Therefore, even when the expansion retaining ring is attached to the frame 4 in a state where the outer circumferential region 3E is stretched, it is possible to prevent the outer circumferential region 3E from being damaged.

In addition, in the subsequent step of the dividing step S130 shown in FIG. 5, a heating step in which the dicing tape 3 in the stretched outer circumferential side region 3E after expansion is thermally contracted by light heating and tensioned again may be performed. By performing this heating process, there is an effect that the dicing tape 3 in the outer circumferential region 3E can be tensioned again, and the processing in the subsequent process of the dividing process S130 becomes easy.

According to the described work dividing devices 10C to 10F of Figs. 13 to 18, since the thickness of the outer circumferential region 3E is not thin, in the heat shrinking step of the outer circumferential region 3E by light heating, the outer circumferential side The light absorption rate of the region 3E increases, and the conversion efficiency from light to heat increases. Accordingly, the outer circumferential region 3E can be thermally contracted in a short time.

In the graph of Fig. 19, the expansion rate (%) of the dicing tape 3 is shown on the vertical axis, and the amount of push-up (mm) of the annular portion region 3B due to the upward movement of the expand ring 14 is the horizontal axis. It is shown in.

Further, in Fig. 19, it is shown that the expansion rate according to the push-up amount is different for each of the expansion regulating rings 16, 18, 32, 36, 40, and 42, as described later. In addition, since the expansion rate by the expansion regulation ring 18 is equal to the expansion rate by the expansion regulation ring 16, the explanation of the expansion rate by the expansion regulation ring 18 is omitted. Similarly, the expansion rate by the expansion regulation ring 40 is equal to the expansion rate by the expansion regulation ring 32, and the expansion rate by the expansion regulation ring 42 is the expansion rate by the expansion regulation ring 36 Since it is the same as, the explanation of the expansion rate by the expansion regulation rings 40 and 42 is also omitted.

The line A in Fig. 19 shows the change in the expansion rate when the expansion limiting ring is not used (the diameter of the expansion limiting opening 16A is 350 mm). Line B shows the change in the expansion rate when the expansion limiting ring 16 having a diameter of 338 mm of the expansion limiting opening 16A is applied. Line C shows a change in the expansion rate when the expansion limiting ring 32 having a diameter of 338 mm of the expansion limiting opening 32A is applied. Line D shows a change in the expansion rate when the expansion limiting ring 36 having a diameter of 338 mm of the expansion limiting opening 36A is applied. In addition, as an example, the protruding length of the protruding portion 34 of the expansion regulating ring 32 is set to 1.5 mm equal to the thickness of the frame 4 as described later, and the protruding portion 38 of the expansion regulating ring 36 The protruding length of was set to 4.5 mm.

Fig. 20 is a schematic diagram showing the operation of the expand ring 14 during the expansion and division process. In Fig. 20, dimensions of each member for calculating the expansion ratio of lines A, B, C, and D shown in Fig. 19 are shown.

According to Fig. 20, the inner diameter D1 of the frame 4 is 350 mm, the thickness t of the frame 4 is 1.5 mm, and the expansion regulation openings 16A of the expansion regulation rings 16 (32, 36) It is shown that the diameter D2 of (32A, 36A) is 338 mm.

In addition, reference numeral x in FIG. 20 denotes the amount of push up of the annular portion region 3B due to the upward movement of the expand ring 14. Further, at the upper end of the expand ring 14, a roller 44 that reduces the frictional force with the dicing tape 3 is disposed, and it is shown that the arrangement diameter D3 of the roller 44 is 323.2 mm. Reference numeral d in FIG. 20 denotes the diameter of the roller 44. In addition, the expansion rate (%) of the line A is calculated as the diameter (d) of the roller 44 is 5 mm, and the expansion rate (%) of the lines B, C, and D is the diameter of the roller 44 ( d) was calculated as 7 mm.

Hereinafter, based on FIG. 19, each expansion rate of the expansion regulation rings 16, 32, 36 is demonstrated.

First, when the expansion restricting ring 16 is applied (see line B), the annular portion region 3B is pushed up by the upward movement of the expand ring 14 to contact the expansion restricting ring 16. The expansion rate immediately after the contact becomes higher than the expansion rate when the expansion regulation ring is not applied (see line A). That is, when the expansion restricting ring 16 is applied, the expansion rate after the push-up amount exceeds about 5.0 mm is higher than the expansion rate when the expansion restricting ring is not applied.

Further, when the expansion restricting ring 32 is applied (see line C), the tip portion 34A of the protruding portion 34 abuts against the annular portion region 3B in advance. For this reason, when the expansion limiting ring 32 is applied, the expansion rate immediately after the expansion ring 14 comes into contact with the annular portion region 3B is when the expansion limiting ring 16 is applied (line B (Refer to).

In addition, when the expansion restricting ring 36 is applied (refer to line D), the distal end 38 of the protruding portion 38 presses down the annular portion region 3B in advance, so that the annular portion region 3B Before the expand ring 14 comes into contact, the expansion rate has already exceeded 0%. For this reason, when the expansion limiting ring 36 is applied, the expansion rate immediately after the expansion ring 14 comes into contact with the annular portion region 3B is when the expansion limiting ring 32 is applied (line C (Refer to).

Here, FIG. 21 is a graph showing the change in the rate of increase per unit time (hereinafter referred to as the rate of expansion (%/sec)) of each expansion rate (%) of lines A, B, C, and D shown in FIG. 19 Is shown.

In the graph of Fig. 21, the expansion rate (%/sec) is shown on the left vertical axis, the pushing speed (mm/sec) of the annular region 3B is shown on the right vertical axis, and the expansion ring 14 rises. The amount of push up (mm) of the annular portion region 3B due to movement is shown on the horizontal axis.

In FIG. 21, as an example, the change in the expansion rate speed in the case where the pushing speed of the annular portion region 3B is made constant is shown. The higher the rate of expansion, the greater the tension generated in the dicing tape 3, and the greater the force to divide the wafer for each chip.

The line E in Fig. 21 shows the change in the pushing speed in the pushing amount from 0.00 mm to 20.00 mm. In other words, the line E represents the ascending movement speed of the expand ring 14. According to the line E, the expand ring 14 moves upward at a constant speed (200 mm/sec) within the range of 0.00 mm to about 18.50 mm, and then moves up to 20.00 mm while decelerating.

The line F in FIG. 21 shows a change in the expansion rate speed corresponding to the expansion rate of the line A in FIG. 19 without applying the expansion regulation ring.

Line G in FIG. 21 shows a change in the expansion rate speed corresponding to the expansion rate of line B in FIG. 19 when the expansion regulating ring 16 having a diameter of 338 mm of the expansion regulating opening 16A is applied. have.

Line H of Fig. 21 is an expansion corresponding to the expansion rate of lines C and D of Fig. 19 when the expansion restricting rings 32 and 36 having a diameter of the expansion restricting openings 32A and 36A are 338 mm. It shows the change in rate speed. In addition, when the expansion limiting ring 36 is applied, the annular portion region 3B is expanded in advance by the protrusions 38 before expansion by the expand ring 14, but with regard to the rate of expansion, expansion is regulated. It is the same as when the ring 32 is applied. For this reason, the change in the expansion rate speed when the expansion regulation rings 32 and 36 are applied is indicated by the same line H.

According to the respective expansion rate speeds indicated by lines F, G, and H in Fig. 21, they each increase according to the amount of push up, and at the point when the amount of push reaches about 18.50 mm, it becomes the maximum (maximum expansion rate speed), and that After that, each descends.

Here, when the expansion control ring 16 is applied (refer to line G), the annular region 3B is pushed up by the upward movement of the expand ring 14 to contact the expansion control ring 16. . The rate of expansion immediately after the contact becomes higher than the rate of expansion when the expansion control ring is not applied (see line F). Specifically, the rate of expansion after the push-up amount exceeds about 4.00 mm is higher than the rate of expansion rate when the expansion control ring is not applied, and the maximum rate of expansion rate is higher than that when the expansion control ring is not applied. Increase (from about 95%/sec to about 115%/sec).

Therefore, by applying the expansion regulating ring 16, the dicing tape 3 increases the amount of expansion (refer to FIG. 19), and the maximum rate of expansion increases, compared to the case where the expansion regulating ring is not applied. Since the tension generated in the tape 3 increases, it is possible to solve the problem of dividing the line to be divided, which occurs when the chip size is small.

In addition, when the expansion limiting rings 32 and 36 are applied (refer to line H), when the expandable ring 14 contacts the annular region 3B, the rate of expansion immediately after the contact is increased by the expansion limiting ring ( When 16) is applied (refer to line G), it is higher than the rate of expansion. Further, by applying the extension regulating rings 32 and 36, the maximum rate of expansion rate increases (increases from about 95%/sec to about 115%/sec) than when the extension regulating ring is not applied.

Therefore, by applying the expansion regulating rings 32 and 36, the expansion amount of the dicing tape 3 increases (refer to FIG. 19), and the maximum rate of expansion increases as compared to the case where the expansion regulating ring is not applied. Since the tension generated in the dicing tape 3 increases, it is possible to solve the problem of fine division described above.

As described above, by applying the expansion regulation rings 16, 18, 32, 36, 40, and 42 of the embodiment, it is possible to solve the problem of dividing the line to be divided, which occurs when the chip size is small.

1: wafer 2: wafer unit
3: Dicing tape 3A: Central area
3B: annular region 3C: fixed region
3D: abutting portion 3E: outer circumferential area
3F: inner circumferential area 3FA: inner circumferential area
3FB: Inner Peripheral Area 4: Frame
4A: Back 5: Line to be split
6: chip 7: frame fixing member
8: expand ring 10A: work splitting device
10B: work dividing device 10C: work dividing device
10D: Work splitting device 10E: Work splitting device
10F: work dividing device 12: frame fixing part
14: expansion ring 14A: opening for expansion
16: expansion regulation ring 16A: expansion regulation opening
16B: internal combustion part 17: expansion regulation part
18: expansion regulation ring 18A: opening for expansion regulation
18B: internal edge 20: expansion regulating ring
20A: expansion regulation opening 22: wafer
24: chip 26: extended regulation ring
26A: opening for expansion regulation 28: wafer
30: chip 32: extended regulation ring
32A: expansion regulation opening 34: protrusion
34A: distal end 36: expansion regulating ring
36A: expansion regulation opening 38: protrusion
38A: tip portion 40: expansion regulating ring
40A: Expansion regulation opening 42: Expansion regulation ring
42A: expansion regulation opening 44: roller

Claims (10)

The outer periphery of the dicing tape is fixed to a ring-shaped frame having an inner diameter larger than the outer diameter of the work, and the work affixed to the dicing tape is divided into a line to be divided. In the work dividing device for dividing into individual chips accordingly,
Arranged on the back side of the dicing tape opposite to the affixed surface of the work, formed in a ring shape smaller than the inner diameter of the ring-shaped frame and larger than the outer diameter of the work, and the back side of the dicing tape An expand ring for expanding the dicing tape by pressing
Arranged on the same side as the affixed surface of the work in the dicing tape, formed in a ring shape having an opening smaller than the inner diameter of the ring-shaped frame and larger than the outer diameter of the expand ring, the expand The dicing tape is provided with an expansion regulating ring to which the dicing tape abuts upon expansion of the dicing tape by a ring,
The expansion regulating ring has a tape position regulating portion that abuts against the dicing tape when the dicing tape is expanded by the expand ring,
The tape position regulating unit is disposed on a side of the ring-shaped frame on which the expand ring is disposed rather than a tape affixing surface on which the dicing tape is affixed. delete The method of claim 1,
The expansion regulating ring includes a frame fixing portion fixed to the ring-shaped frame, and a protrusion protruding toward the dicing tape along a periphery of the opening of the expansion regulating ring,
The tape position regulating portion is configured by a tip portion of the protruding portion. The method of claim 1,
The expansion control ring is a frame fixing portion disposed on the same side as the affixing surface of the work in the dicing tape, and a frame fixing portion that abuts against the ring-shaped frame and fixes the ring-shaped frame is provided. Device. The method of claim 1,
The expansion control ring is a frame fixing member disposed on the same side as the affixing surface of the work in the dicing tape, and is detachably attached to a frame fixing member that fixes the ring-shaped frame through the expansion control ring. Fixed work segmentation device. delete delete A method for dividing a work in which an outer periphery of a dicing tape is fixed to a ring-shaped frame having an inner diameter larger than the outer diameter of the work, and the work affixed to the dicing tape is divided into individual chips along a line to be divided,
Using an expand ring formed in a ring shape, which is disposed on the back side of the dicing tape that is opposite to the affixed surface of the work, is smaller than the inner diameter of the ring-shaped frame, and is larger than the outer diameter of the work, An expansion step of generating tension in the dicing tape by pressing the dicing tape to expand the dicing tape; and
Using an expansion regulating ring formed in a ring shape, which is disposed on the same side as the affixed surface of the work in the dicing tape, is smaller than the inner diameter of the ring-shaped frame, and has an opening that is larger than the outer diameter of the expand ring. In this way, when the dicing tape is expanded, the expansion regulation ring is brought into contact with the dicing tape, thereby regulating the expansion of an outer circumferential region located on the outer circumferential side of the dicing tape;
A dividing step of dividing the work into individual chips by continuing the expansion of the dicing tape excluding the outer circumferential side region,
In the expansion regulation step, a position where the expansion regulation ring abuts the dicing tape is a side on which the expand ring is disposed rather than a tape affixed surface of the ring-shaped frame on which the dicing tape is affixed. The method according to any one of claims 1, 3 to 5,
The opening of the expansion regulating ring is formed in a circular shape. The method according to any one of claims 1, 3 to 5,
The opening of the expansion regulation ring is formed in an elliptical work dividing device.

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