JP2016219573A - Pickup apparatus and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pickup apparatus capable of removing semiconductor chips in various adhesion states from a sheet without damaging the chips.SOLUTION: A pickup apparatus comprises: a stage 11 that has a groove 12 corresponding to the outline of one semiconductor chip and is capable of mounting a ductile sheet 20 having a surface on which a plurality of semiconductor chips separated from each other are detachably bonded, so as to fit the one semiconductor chip in a manner that the outlie of one semiconductor chip corresponds to the groove 12; a removal unit 13 that includes a holding unit 13a capable of holding the one semiconductor chip and a first drive unit 13b for driving the holding unit 13a and is capable of removing the one semiconductor chip held by the holding unit 13a from the sheet 20; and a press-down unit 14 that includes a blade 14a having a thickness narrower than a gap between adjacent semiconductor chips and a second drive unit 14b for driving the blade 14a and is capable of pressing down the part of the sheet 20 between the adjacent semiconductor chips into the groove 12, by using the blade 14a.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a pickup apparatus and method.

  Conventionally, in the process of manufacturing a semiconductor device, first, a large number of integrated circuits are two-dimensionally arranged and formed on a single silicon wafer using a microfabrication technique or the like. Next, in a state where a silicon wafer having an integrated circuit formed on the surface is detachably bonded onto an adhesive sheet, the silicon wafer is cut into individual semiconductor chips to obtain individual semiconductor chips. Next, each semiconductor chip is removed from the sheet and picked up. Each picked-up semiconductor chip is packaged, for example, to obtain an individual semiconductor device.

  In addition, with the improvement in performance of an electronic device on which a semiconductor device is mounted, a three-dimensional mounting technique for stacking a plurality of semiconductor chips is used. By using the three-dimensional mounting technology, the performance of the semiconductor device can be further improved beyond the integration of elements by two-dimensional miniaturization.

  In each semiconductor chip, a through silicon via (hereinafter also referred to as TSV) penetrating the silicon wafer is formed, and conduction between the front side and the back side of the semiconductor chip is obtained. Using TSVs and micro bumps, the semiconductor chips stacked one above the other are electrically connected.

  The TSV is formed by forming a via hole penetrating the silicon wafer and filling the via hole with a conductor. Here, the formation of via holes or the filling of conductors is restricted by the aspect ratio of TSV. Therefore, in order to obtain a preferable aspect ratio of TSV, the back surface of the silicon wafer is polished to reduce the thickness of the wafer.

  In the process of picking up individual semiconductor chips from the above-described sheet, the needle pin is pushed up from below the sheet to deform the sheet, peel off the periphery of the semiconductor chip and the sheet, and then adsorb the semiconductor chip from above. The peeling from the sheet is performed.

JP 2006-319150 A JP 11-045494 A

  However, as the thickness of the wafer has been reduced, there has been a case where the peripheral edge of the semiconductor chip and the sheet cannot be peeled even if the needle pins are pushed up. If the semiconductor chip is adsorbed from above in a state where the periphery of the semiconductor chip and the sheet are not peeled off, the semiconductor chip may not be picked up from the sheet or the semiconductor chip may be damaged.

  Therefore, in order to separate the peripheral edge of the semiconductor chip and the sheet, it has been proposed to suck the sheet from the lower side to separate the peripheral edge of the semiconductor chip and the sheet. The semiconductor chip to be picked up is arranged via a sheet on a stage having a groove corresponding to the outline of the semiconductor chip. The periphery of the semiconductor chip and the sheet are peeled off by applying a negative pressure in the groove and sucking the sheet from below to deform the sheet.

  However, in the method of sucking a sheet with a negative pressure in the groove, it is difficult to control the deformation amount of the sheet, and the range of the deformation amount that can be controlled is narrow. Therefore, there is a problem that if the suction force is strong, the semiconductor chip is damaged, and if the suction force is weak, the semiconductor chip does not peel off.

  Separation of the periphery of the semiconductor chip and the sheet is generally affected by the mechanical strength of the semiconductor chip and the adhesive force of the sheet. However, the method using suction of the sheet removes the periphery of the semiconductor chip and the sheet. The range that can be peeled off well is narrow. Therefore, this method also has a problem that it is inferior in versatility for picking up semiconductor chips having various adhesion states.

  Furthermore, in order to peel the peripheral edge of the semiconductor chip and the sheet, it has been proposed to blow air from above the semiconductor chip to peel the peripheral edge of the semiconductor chip and the sheet. The semiconductor chip to be picked up is arranged via a sheet on a stage having a groove corresponding to the outline of the semiconductor chip. In a state where the pressure in the groove is negative, air is blown from above the semiconductor chip to the periphery of the semiconductor chip to separate the periphery of the semiconductor chip from the sheet.

  However, the distance between the semiconductor chips cut and separated is about 100 μm. It is very difficult to accurately blow a strong wind that separates the semiconductor chip and the sheet against such a small gap. Another problem is how to discharge air blown between the semiconductor chip and the sheet through the gap. As described above, it is not practical in commercial production to separate the periphery of the semiconductor chip and the sheet by using air blowing.

  This specification makes it a subject to provide the pick-up apparatus which can solve the problem mentioned above.

  Another object of the present specification is to provide a method that can solve the above-described problem.

  According to an embodiment of the pickup device disclosed in the present specification, a plurality of semiconductor chips which have a groove corresponding to the outline of one semiconductor chip and are separated from each other are detachably bonded to the surface. A sheet, a stage on which one semiconductor chip can be placed so that the outline of the one semiconductor chip corresponds to the groove, a holding part capable of holding one semiconductor chip, and a first for driving the holding part A detachable portion capable of removing one semiconductor chip held by the holding portion from the sheet, a blade having a thickness narrower than an interval between adjacent semiconductor chips, and a second for driving the blade. And a push-down portion that can push down a portion of a sheet between adjacent semiconductor chips into the groove using the blade.

  Further, according to one mode of the method disclosed in this specification, a duct having a ductility sheet in which a plurality of semiconductor chips separated from each other are detachably bonded to the surface is formed in a groove corresponding to the outline of the one semiconductor chip. The one semiconductor chip is placed on the stage so that a plurality of semiconductor chips are exposed and the outline of the one semiconductor chip corresponds to the groove, and the one semiconductor chip is placed on the stage. The sheet portion between adjacent semiconductor chips is pushed down into the groove, and the sheet portion between adjacent semiconductor chips is pushed down into the groove. One semiconductor chip is removed from the sheet.

  According to one embodiment of the pickup device described above, it is possible to remove various bonded semiconductor chips from the sheet without damaging them.

  Moreover, according to one form of the method mentioned above, the semiconductor chip of various adhesion | attachment states can be removed from a sheet | seat, without damaging.

  The objects and advantages of the invention will be realized and obtained by means of the elements and combinations particularly pointed out in the appended claims.

  Both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention as claimed.

(A) is a figure which shows one Embodiment of the pick-up apparatus disclosed by this specification, (B) is a top view which shows the principal part of a pick-up apparatus. It is FIG. (1) explaining the process of the pick-up method disclosed in this specification. It is FIG. (2) explaining the process of the pick-up method disclosed in this specification. It is FIG. (3) explaining the process of the pick-up method disclosed in this specification. It is a figure explaining the principal part of the pick-up method of this embodiment. It is a figure explaining the principal part of the modification 1 of a pick-up apparatus. It is a figure explaining the principal part of the modification 2 of a pick-up apparatus. (A) is a figure which shows the principal part of the modification 3 of the pick-up apparatus disclosed by this specification, (B) is a figure which shows the principal part of the modification 4. FIG.

  Hereinafter, a preferred embodiment of a pickup device disclosed in the present specification will be described with reference to the drawings. However, the technical scope of the present invention is not limited to these embodiments, but extends to the invention described in the claims and equivalents thereof.

  FIG. 1A is a diagram illustrating an embodiment of a pickup device disclosed in the present specification, and FIG. 1B is a plan view illustrating a main part of the pickup device.

  The pickup device 10 of the present embodiment (hereinafter also simply referred to as the device 10) removes (picks up) individual semiconductor chips from the sheet 20 in which a plurality of semiconductor chips separated from each other are detachably bonded to the surface. Device. The removed semiconductor chip can be transported to the next step, for example, to become a semiconductor device that is three-dimensionally mounted by being stacked and connected to other semiconductor chips.

  The apparatus 10 includes a stage 11 having a groove 12, a removal unit 13, a push-down unit 14, and a control unit 15 that controls each component.

  The sheet 20 placed on the stage 11 has an adhesive layer (not shown) made of, for example, a light softening resin, and is formed by arranging a large number of integrated circuits on the surface in a two-dimensional manner. The wafer is detachably bonded. The silicon wafer is cut along scribe lines to form individual semiconductor chips having integrated circuits. The interval between the individually cut semiconductor chips is, for example, 50 to 100 μm. A sheet 20 in which a plurality of semiconductor chips separated from each other are bonded to the surface is placed on the surface of the stage 11.

  The surface of the stage 11 on which the sheet 20 is placed is flat, but has a groove 12 corresponding to the outline of the semiconductor chip 30a to be removed. Further, a suction port (not shown) for sucking the sheet 20 is provided on the surface of the stage 11.

  The sheet 20 is placed on the stage 11 so that a plurality of semiconductor chips are exposed and the semiconductor chip 30a to be removed is aligned with the groove 12 in the outline of the semiconductor chip 30a.

  The sheet 20 placed on the stage 11 can be moved in a two-dimensional direction by a sheet driving unit (not shown), and the semiconductor chip 30a removed from the sheet 20 is aligned with the groove 12 in the outline of the semiconductor chip 30a. It is made to be located. When the sheet 20 is moved on the stage 11, the suction of the sheet 20 is stopped. As the alignment method, a known method such as a method using image processing can be used.

  The sheet 20 has ductility, and is stretched by pulling the periphery of the sheet 20 outward to be flattened. Further, by reducing the pressure from the suction port of the stage 11, the sheet 20 is placed on the stage 11. It is fixed in close contact with.

  As shown in FIG. 1B, the semiconductor chip 30 a that is removed from the sheet 20 by the apparatus 10 is disposed so as to be positioned at the center of the stage 11. Around the semiconductor chip 30a, another semiconductor chip 30b to be removed next is located. In addition, illustration of the sheet | seat 20 is abbreviate | omitted in FIG. 1 (B). In practice, a silicon wafer portion other than the semiconductor chip is bonded onto the sheet 20, but the illustration of this portion is also omitted. Furthermore, the number of semiconductor chips illustrated in FIG. 1B is an example, and the number of semiconductor chips bonded to the sheet is not limited.

  The shape of the semiconductor chip 30a in plan view is a rectangle. The shape of the groove 12 in plan view is also a rectangle corresponding to the outline of the semiconductor chip. The groove 12 surrounds the outline of the semiconductor chip 30a in plan view.

  The groove 12 has a predetermined width, and when the semiconductor chip 30a is arranged on the stage 11 with the contour aligned with the groove 12, the portion inside the groove 12 (indicated by a chain line in FIG. 1B) Is located inside the semiconductor chip 30a with respect to the periphery of the semiconductor chip 30a. That is, the outer dimension of the groove 12 is larger than the outline of the semiconductor chip 30a, and the inner dimension of the groove 12 is smaller than the outline of the semiconductor chip 30a.

  In other words, the semiconductor chip 30 a is arranged on the stage 11 so that the peripheral edge protrudes from the inside to the outside of the groove 12.

  As shown in FIG. 5B described later, the groove 12 has two side surfaces 12a and a bottom surface 12b. One side surface 12a extends downward from the position inside the semiconductor chip 30a rather than the periphery of the semiconductor chip 30a to be removed. The other side surface 12a extends downward from the peripheral position of the semiconductor chip 30b adjacent to the semiconductor chip 30a to be removed. The bottom surface 12b connects the lower ends of the two side surfaces 12a. The two side surfaces 12a extend vertically upward from both ends of the bottom surface 12b.

  The stage 11 can be moved in a two-dimensional direction by a stage drive unit (not shown), and is positioned so that the semiconductor chip to be removed, that is, the groove 12 portion faces the removal unit 13 and the push-down unit 14. Yes. As a method for aligning the stage 11 with the removal unit 13 or the push-down unit 14, a known method such as a method using image processing can be used.

  The removal unit 13 includes a holding unit 13a that can hold the semiconductor chip 30a and a removal driving unit 13b that drives the holding unit 13a.

  The holding part 13a preferably has the same shape as the semiconductor chip 30a in plan view in order to remove the semiconductor chip 30a from the sheet 20 while compensating for the mechanical strength of the thin semiconductor chip 30a. When the holding portion 13a comes into contact with the upper surface of the semiconductor chip 30a, the mechanical strength of the semiconductor chip 30a can be compensated.

  A plurality of suction ports (not shown) are provided on the surface of the holding unit 13a that contacts the semiconductor chip 30a. By using the plurality of suction ports to suck the semiconductor chip 30a, the semiconductor chip 30a is attached. It is made possible to hold.

  The holding unit 13 a can be arranged to face the semiconductor chip 30 a on the sheet 20 placed on the stage 11.

  The surface of the holding portion 13a that contacts the semiconductor chip 30a is preferably formed using a flexible material such as rubber from the viewpoint of not damaging the semiconductor chip 30a.

  The removal drive unit 13b moves the holding unit 13a up and down. When removing the semiconductor chip 30a, the removal driving unit 13b moves the holding unit 13a to a position where the holding unit 13a contacts the semiconductor chip 30a. Further, the removal driving unit 13b removes the semiconductor chip 30a from the sheet 20 by moving the holding unit 13a holding the semiconductor chip 30a by suction upward.

  The push-down unit 14 includes a blade 14a having a thickness smaller than the interval between adjacent semiconductor chips, and a push-down drive unit 14b that drives the blade 14a.

  The blade 14a is a plate-like member having a tapered cross section and having a thickness that decreases toward the tip.

  As shown in FIG. 1B, the push-down portion 14 has four blades 14a. The four blades 14a are arranged so as to correspond to the four sides of the semiconductor chip 30 having a rectangle. Specifically, each blade 14a may be disposed so as to be insertable into one side of the rectangular groove 12 so as to face the portion of the sheet 20 between adjacent semiconductor chips. In FIG. 1A, two opposing blades of the four blades 14a are shown.

  The push-down drive unit 14b moves the blade 14a up and down. When removing the semiconductor chip 30a, the push-down drive unit 14b pushes the tip of the blade 14a into the groove 12 at the portion of the sheet 20 between the adjacent semiconductor chips. After the removal unit 13 removes the semiconductor chip 30 a from the sheet 20, the push-down drive unit 14 b raises the blade 14 a and pulls up the tip of the blade 14 a from the groove 12.

  Next, the function of the push-down portion 14 when removing the semiconductor chip 30a from the sheet 20 will be described below.

  In order to remove the semiconductor chip 30a bonded on the sheet 20 from the sheet 20, the semiconductor chip 30a is lifted upward with a force larger than the adhesive force between the sheet 20 and the semiconductor chip 30a. As a precondition, it is assumed that the suction force by which the stage 11 sucks the sheet 20 is larger than the adhesive force between the sheet 20 and the semiconductor chip 30a.

  When the peripheral portion of the semiconductor chip 30a is bonded to the sheet 20, and when the peripheral portion of the semiconductor chip 30a is peeled from the sheet 20, the force for removing the semiconductor chip 30a from the sheet 20 is reduced. It has been known.

  Therefore, the apparatus 10 first deforms the sheet 20 by pushing down the portion of the sheet 20 between adjacent semiconductor chips into the groove 12 by using the blade 14 a, and the peripheral portion of the semiconductor chip 30 a is changed to the sheet 20. Remove from.

  Next, in a state where the peripheral portion of the semiconductor chip 30a is peeled off from the sheet 20, the removing unit 13 can lift the semiconductor chip 30a upward to remove the semiconductor chip 30a from the sheet 20 with a small force. .

  The above is the description of the operation of the push-down unit 14.

  The control unit 15 controls the operations of the stage 11, the removal unit 13, and the push-down unit 14 described above, and removes each semiconductor chip that is detachably bonded on the sheet 20 from the sheet 20.

  Next, an example of the operation of the apparatus 10 described above will be described below with reference to FIGS.

  First, as shown in FIG. 2A, a ductile sheet 20 in which a plurality of semiconductor chips 30a and 30b separated from each other are detachably bonded to the surface is placed on the stage 11 and adsorbed thereon. The The sheet 20 is irradiated with ultraviolet rays from the side opposite to the surface to which the semiconductor chip is bonded in advance, and the adhesive force of the adhesive formed using the light softening resin is weakened. Here, the semiconductor chip 30a to be removed is placed on the stage 11 so that the plurality of semiconductor chips 30a and 30b are exposed and the outline of the semiconductor chip 30a corresponds to the groove 12. Suction is performed from a suction port (not shown) provided on the surface of the stage 11, a negative pressure is generated between the sheet 20 and the stage 11, and the sheet 20 is sucked onto the stage 11. At this time, the pressure in the groove 12 is also negative.

  The stage 11 is driven so that the semiconductor chip 30 a removed from the sheet 20 faces the holding portion 13 a and each blade 14 a faces the groove 12 through the sheet 20.

  Next, as shown in FIG. 2B, the detaching unit 13 moves the holding unit 13a to bring the holding unit 13a into contact with the upper surface of the semiconductor chip 30a. The removing unit 13 uses the holding unit 13a to attract the semiconductor chip 30a and fixes the removed semiconductor chip 30a so as not to move on the stage 11.

  Next, as shown in FIG. 3A, the push-down portion 14 pushes down the tip of the blade 14a into the groove 12 at the portion of the sheet 20 between adjacent semiconductor chips.

  Details of the process shown in FIG. 3A will be described below with reference to FIG.

  FIG. 5A is an enlarged view of the main part of FIG. The blade 14 a is disposed so as to face the portion of the sheet 20 between the adjacent semiconductor chips 30 a and 30 b placed on the stage 11. 5B and 5C are enlarged views of a portion surrounded by a rectangle in FIG. 5A. 5A to 5C do not show a holding portion or the like for easy understanding.

  Next, as shown in FIG. 5B, the blade 14a descends and the tip of the blade 14a begins to push down the portion of the sheet 20 between the adjacent semiconductor chips 30a, 30b into the groove 12. The portion of the sheet 20 between the adjacent semiconductor chips 30a and 30b is deformed so as to extend while being pushed down by the blade 14a. Since the upper surface of the semiconductor chip 30a is covered with the holding portion 13a having the same shape in plan view, the mechanical strength of the semiconductor chip 30a is compensated, so that the blade 14a pushes down the sheet 20 into the groove 12. Sometimes, the semiconductor chip 30a is prevented from being damaged.

  Next, as shown in FIG. 5C, the blade 14 a is lowered, and the portion of the sheet 20 between the adjacent semiconductor chips 30 a and 30 b is pushed down until the tip of the blade 14 a contacts the bottom surface 12 b of the groove 12. The portion of the sheet 20 between the adjacent semiconductor chips 30a and 30b is deformed, and the portion of the sheet 20 that is adhered to the periphery of the semiconductor chip 30a is peeled off from the semiconductor chip 30a. The sheet 20 has ductility, but the amount of the portion of the sheet 20 that is pushed down by the blade 14a extends is small. Therefore, when the portion of the sheet 20 between the adjacent semiconductor chips 30a and 30b is pushed down by the blade 14a, the portion of the sheet 20 adhered to the periphery of the semiconductor chip 30a is peeled off from the semiconductor chip 30a.

  Next, as shown in FIG. 3B, in the state where the portion of the sheet 20 between the adjacent semiconductor chips 30a and 30b is pushed down into the groove 12 by the blade 14a, the detaching portion 13 has the holding portion 30a. The adsorbed semiconductor chip 30 a is removed from the sheet 20.

  Next, as shown in FIG. 4, the push-down drive unit 14 b raises the blade 14 a and lifts the blade 14 a from the groove 12. The removed semiconductor chip 30a is transported to the next step, and can be, for example, a semiconductor device that is three-dimensionally mounted by being stacked and connected to other semiconductor chips.

  Subsequently, after the sheet 20 is moved on the stage 11 and the other semiconductor chip 30b is positioned on the stage 11 so that the outline of the semiconductor chip corresponds to the groove 12, the same as described above. It is removed from the sheet 20.

  According to the pickup device of the present embodiment described above, the semiconductor chip can be removed from the sheet without being damaged. Further, in the pickup device of this embodiment, the blade is physically pushed down to deform the sheet portion between adjacent semiconductor chips, and the peripheral edge of the semiconductor chip and the sheet are peeled off. Therefore, the pickup device of the present embodiment can be applied to the adhesive force of a wide range of semiconductor chips or a wide range of sheets.

  Next, modified examples 1 to 4 of the above-described pickup device according to the present embodiment will be described below with reference to FIGS.

  6 (A) to 6 (C) are diagrams illustrating a main part of Modification 1 of the pickup device. 6B and 6C are enlarged views of a portion surrounded by a rectangle in FIG. 6A. 6A to 6C do not show a holding portion or the like for easy understanding.

  As shown in FIG. 6B, the groove 12 of the stage 11 of the pickup device of the first modification includes a side surface 12 a that extends vertically downward with respect to the surface on which the sheet 20 of the stage 11 is placed, and the stage 11. A bottom surface 12b that is inclined with respect to a surface on which the sheet 20 is placed and extends downward.

  The side surface 12a extends downward from the peripheral position of the semiconductor chip 30b adjacent to the semiconductor chip 30a to be removed, and has the same configuration as that of the above-described embodiment. The bottom surface 12b extends from the position inside the semiconductor chip 30a to the lower end of the side surface 12a rather than the peripheral edge of the semiconductor chip 30a.

  In addition, although the groove | channel 12 of the modification 1 prescribed | regulated that it has the side surface 12a and the bottom face 12b, the groove | channel 12 has the side surface 12a and the side surface which inclines with respect to the surface where the sheet | seat 20 of the stage 11 is mounted. It may be defined as having no bottom surface. It is a matter of convenience to refer to the surface that is inclined with respect to the surface on which the sheet 20 of the stage 11 is placed as the bottom surface or the side surface. This also applies to the second modification described later.

  Next, referring to FIGS. 6A to 6C, a process in which the push-down unit 14 pushes down the tip of the blade 14a and the portion of the sheet 20 between adjacent semiconductor chips into the groove 12 is described below. Explained.

  FIG. 6A corresponds to an enlarged view of the main part of FIG. The blade 14 a is disposed so as to face the portion of the sheet 20 between the adjacent semiconductor chips 30 a and 30 b placed on the stage 11.

  Next, as shown in FIG. 6B, the blade 14a descends, and the tip of the blade 14a begins to push down the portion of the sheet 20 between the adjacent semiconductor chips 30a, 30b into the groove 12. The portion of the sheet 20 between the adjacent semiconductor chips 30a and 30b is deformed so as to extend while being pushed down by the blade 14a.

  Next, as shown in FIG. 6C, the blade 14 a is lowered, and the portion of the sheet 20 between the adjacent semiconductor chips 30 a and 30 b is pushed down until the tip of the blade 14 a comes into contact with the bottom surface 12 b of the groove 12. Since the tip of the blade 14a moves while sliding toward the semiconductor chip 30b along the inclination of the bottom surface 12b, the sheet 20 positioned under the periphery of the semiconductor chip 30a to be removed is compared with FIG. Then, it is pushed down toward the bottom of the groove 12 while pulling more strongly in the lateral direction. As a result, the portion of the sheet 20 between the adjacent semiconductor chips 30a and 30b is deformed, and the portion of the sheet 20 adhered to the periphery of the semiconductor chip 30a is peeled off from the semiconductor chip 30a.

  FIG. 7A to FIG. 7C are diagrams for explaining a main part of a second modification of the pickup device. FIGS. 7B and 7C are enlarged views of a portion surrounded by a rectangle in FIG. 7A. 7A to 7C do not show a holding portion or the like for easy understanding.

  As shown in FIG. 7B, the groove 12 of the stage 11 of the pickup device of Modification 2 has a side surface 12a that extends vertically downward with respect to the surface on which the sheet 20 of the stage 11 is placed, and the stage 11 A bottom surface 12b that is inclined with respect to a surface on which the sheet 20 is placed and extends downward.

  The side surface 12a extends downward from the position inside the semiconductor chip 30a rather than the periphery of the semiconductor chip 30a to be removed, and has the same configuration as in the above-described embodiment. The bottom surface 12b extends from the peripheral edge of the semiconductor chip 30b adjacent to the semiconductor chip 30a to be removed toward the lower end of the side surface 12a.

  Next, referring to FIGS. 7A to 7C, a process in which the push-down unit 14 pushes down the tip of the blade 14a and the portion of the sheet 20 between adjacent semiconductor chips into the groove 12 is described below. Explained.

  FIG. 7A corresponds to an enlarged view of the main part of FIG. The blade 14 a is disposed so as to face the portion of the sheet 20 between the adjacent semiconductor chips 30 a and 30 b placed on the stage 11.

  Next, as shown in FIG. 7B, the blade 14a descends, and the tip of the blade 14a begins to push down the portion of the sheet 20 between the adjacent semiconductor chips 30a, 30b into the groove 12. The portion of the sheet 20 between the adjacent semiconductor chips 30a and 30b is deformed so as to extend while being pushed down by the blade 14a.

  Next, as shown in FIG. 7C, the blade 14 a is lowered, and the portion of the sheet 20 between the adjacent semiconductor chips 30 a and 30 b is pushed down until the tip of the blade 14 a comes into contact with the bottom surface 12 b of the groove 12. Since the tip of the blade 14a moves while sliding toward the semiconductor chip 30a to be removed along the inclination of the bottom surface 12b, the sheet 20 positioned under the periphery of the semiconductor chip 30a to be removed is shown in FIG. As compared with the above, the groove 12 is pushed downward while being pulled more strongly in the vertical direction. As a result, the portion of the sheet 20 between the adjacent semiconductor chips 30a and 30b is deformed, and the portion of the sheet 20 adhered to the periphery of the semiconductor chip 30a is peeled off from the semiconductor chip 30a.

  The three types described above have been described as the shape of the groove 12. By changing the shape of the groove 12, the tension or angle applied to the sheet located under the periphery of the semiconductor chip to be removed can be adjusted. Which of these three types is selected can be appropriately selected based on dimensions such as the shape or thickness of the semiconductor chip, the adhesive strength of the sheet, etc. Further, the groove 12 may have another shape as long as the blade is formed so that the sheet can be pushed down.

  FIG. 8A is a diagram illustrating a main part of Modification 3 of the pickup device, and corresponds to FIG.

  In the pickup device of Modification 3, the shape of the blade is different from that of the above-described embodiment. As shown in FIG. 8A, each of the four blades 14a of Modification 3 has a bent portion corresponding to the corner outline of the rectangular semiconductor chip 30a removed from the sheet 20 in plan view. The blade 14a has an L shape in plan view, and has a shape extending from each corner of the semiconductor chip 30a along each of two sides forming the corner. The push-down portion can be pushed down into the groove 12 by using the bent portion of the blade 14a to cut the sheet portion around the corner of the semiconductor chip to be removed. Since the thickness of the blade is usually as thin as 50 to 100 μm, the mechanical strength of the blade can be increased by forming the bent portion.

  FIG. 8B is a diagram illustrating a main part of a fourth modification of the pickup device.

  In the pickup device of Modification 4, the shape of the blade is different from that of the above-described embodiment. As shown in FIG. 8 (B), the blade 14a of the modified example 4 has a rectangular shape that is removed by connecting each of the four blades shown in FIG. It has a shape surrounding the periphery of the semiconductor chip 30a. The push-down portion 14 is configured to be able to push the portion of the sheet 20 around the entire semiconductor chip 30a to be removed into the groove 12 by using the blade 14a. The blade 14a of the modified example 4 has higher mechanical strength than the blade of the modified example 3 described above.

  In the present invention, the pickup device and method of the above-described embodiment can be modified as appropriate without departing from the spirit of the present invention.

  For example, in the embodiment described above, the groove of the stage has a closed shape so as to surround the semiconductor chip, but the groove is formed so as to correspond to at least a part of the outline of the semiconductor chip. Just do it. For example, one or more grooves corresponding to a part of the outline of the semiconductor chip may be formed on the stage.

  Hereinafter, the pickup apparatus and method disclosed in this specification will be further described using experimental examples. However, the scope of the present invention is not limited to such experimental examples.

(Experimental example 1)
The sheet was removed from the semiconductor chip using the pickup device shown in FIG. First, a silicon wafer having a thickness of 50 μm was bonded to a dicing film D-675 (manufactured by Lintec) as a sheet, and cut into individual semiconductor chips having a size of 20 × 20 mm. After cutting the silicon wafer, the sheet was irradiated with ultraviolet rays of 500 mJ / cm ² to reduce the adhesive strength of the ultraviolet softening resin that forms the adhesive layer of the sheet. The groove had the shape shown in FIGS. 1 and 5 and had a width of 1 mm and a depth of 1 mm. The holding part of the removal part was disposed so as to face the groove of the stage. The holding part had four blades arranged as shown in FIG. 1, and the thickness of each blade was 100 μm. Next, a sheet on which a plurality of semiconductor chips separated from each other were detachably bonded was placed on the stage, and the semiconductor chip to be removed was placed so that the outline of the semiconductor chip corresponds to the groove. When placing the sheet on the stage, the shape and position of the semiconductor chip were confirmed using an image processing method. The sheet was tightly fixed on the stage by reducing the pressure from the suction port of the stage in a state where the periphery of the sheet was pulled outward and extended to remove wrinkles and become flat. Next, the holding part was moved, the holding part was brought into contact with the upper surface of the semiconductor chip to be removed, and the semiconductor chip was adsorbed, and the semiconductor chip to be removed was fixed so as not to move on the stage. Next, the blade is lowered, and the portion of the sheet between the adjacent semiconductor chips is pushed down to a depth of about 500 μm in the groove, and the blade is adhered to the periphery of the semiconductor chip to be removed. This part was peeled from the semiconductor chip. With the blade pressing down the portion of the sheet 20 between adjacent semiconductor chips into the groove, the holding part that adsorbs the semiconductor chip is raised at a speed of 0.5 mm / second to remove the semiconductor chip from the sheet. Removed. The semiconductor chip was removed from the sheet without breaking.

(Experimental example 2)
The semiconductor chip was removed from the sheet in the same manner as in Experimental Example 1 described above, except that the removal unit of the pickup device had the blade shown in FIG. The semiconductor chip was removed from the sheet without breaking.

(Experimental example 3)
The semiconductor chip was removed from the sheet in the same manner as in Experimental Example 1 except that the groove of the stage of the pickup device had the shape shown in FIGS. 7A to 7C. The angle formed between the side surface and the bottom surface of the groove was 60 degrees. The semiconductor chip was removed from the sheet without breaking.

(Experimental example 4)
The semiconductor chip was removed from the sheet in the same manner as in Experimental Example 1 described above, except that the removal unit of the pickup device had the blade shown in FIG. The semiconductor chip was removed from the sheet without breaking.

(Comparative experiment example)
As a method for removing the semiconductor chip from the sheet, an attempt was made to remove the semiconductor chip from the sheet in the same manner as in Experimental Example 1 except that a conventional removal method using a needle pin was used. When the needle pin was pushed up from the bottom of the sheet by a distance of 300 μm to deform the sheet, the periphery of the sheet was not peeled off from the semiconductor chip, and the semiconductor chip was damaged and could not be removed from the sheet.

  All examples and conditional words mentioned herein are intended for educational purposes to help the reader deepen and understand the inventions and concepts contributed by the inventor. All examples and conditional words mentioned herein are to be construed without limitation to such specifically stated examples and conditions. Also, such exemplary mechanisms in the specification are not related to showing the superiority and inferiority of the present invention. While embodiments of the present invention have been described in detail, it should be understood that various changes, substitutions or modifications can be made without departing from the spirit and scope of the invention.

DESCRIPTION OF SYMBOLS 10 Pickup apparatus 11 Stage 12 Groove 12a Side surface 12b Bottom surface 13 Removal part 13a Holding part 13b Removal drive part (1st drive part)
14 Pushing part 14a Blade A Bending part 14b Pushing drive part (2nd drive part)
15 Control unit 20 Sheet 30a, 30b Semiconductor chip

Claims (6)

A duct having a duct having a groove corresponding to the outline of one semiconductor chip and having a plurality of semiconductor chips separated from each other detachably bonded to the surface, and one semiconductor chip being the outline of the one semiconductor chip A stage that can be placed so as to correspond to the groove;
A holding part capable of holding one semiconductor chip; and a first driving part for driving the holding part; and a detaching part capable of removing the one semiconductor chip held by the holding part from the sheet;
A blade having a thickness narrower than an interval between adjacent semiconductor chips, and a second driving unit that drives the blade, and using the blade, a portion of a sheet between adjacent semiconductor chips is placed in the groove. A push-down portion that can be pushed down,
A pickup device comprising:   In the state where the removal unit is fixed so that one semiconductor chip does not move on the stage using the holding unit, the push-down unit uses the blade to form a sheet portion between adjacent semiconductor chips. The pick-up device according to claim 1, which can be pushed down into the groove.   The groove has a predetermined width, and when one semiconductor chip is arranged on the stage with the contour aligned with the groove, the inner portion of the groove is one semiconductor than the periphery of the one semiconductor chip. 3. The pickup device according to claim 1, wherein the pickup device is located inside the chip.   The said groove | channel is a pick-up apparatus as described in any one of Claims 1-3 which has a surface inclined with respect to the surface where the sheet | seat of the said stage is mounted. The blade has a bent portion corresponding to the corner outline of one semiconductor chip,
5. The pickup device according to claim 1, wherein the push-down portion can push down a sheet portion around a corner of one semiconductor chip into the groove by using the bent portion. . A ductile sheet having a plurality of semiconductor chips separated from each other removably bonded to a surface is placed on a stage having a groove corresponding to the outline of one semiconductor chip, and the plurality of semiconductor chips are exposed. Placing the one semiconductor chip such that the outline of the one semiconductor chip corresponds to the groove;
With the one semiconductor chip fixed so as not to move on the stage, the portion of the sheet between adjacent semiconductor chips is pushed down into the groove,
A method of removing the one semiconductor chip from the sheet in a state where a portion of the sheet between adjacent semiconductor chips is pushed down into the groove.

Images