JP2013215813A - Method for carrying workpiece in/out in double disk grinding and double disk grinder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a workpiece in a carrier from dropping when the workpiece is carried in/out, and to prevent damage of the workpiece previously.SOLUTION: A double disk grinding is configured so that both sides of a workpiece W are ground by a pair of grinding stones while rotating the workpiece W by a carrier 7, wherein the workpiece is held under static pressure by a pair of static pressure pads 1, 2 and has a thin plate shape. When the workpiece W is sucked and attached to be carried in/out of the carrier 7 between both static pressure pads 1, 2 by carrying-in/out means 8, 9, the workpiece W in the carrier 7 is held among the carrying-in/out means 8, 9 and the right static pressure pad 2 and then while the workpiece W in the carrier 7 is held, the workpiece W in the carrier 7 is sucked and attached by the right static pressure pad 2 existing at an advance holding position X1.

Description

  The present invention relates to a work loading / unloading method in double-head surface grinding and a double-head surface grinding machine.

  When grinding both sides of a thin plate workpiece such as a silicon wafer with a horizontal double-sided surface grinder, the workpiece is rotated by a carrier while the workpiece is held statically from both sides in the plate thickness direction by a pair of static pressure pads. Then, both sides of the workpiece are ground to a predetermined thickness by a pair of grinding wheels.

  This type of horizontal double-sided surface grinding machine is equipped with loading / unloading means having a suction cup. When loading and unloading a workpiece before and after grinding, the workpiece is held between the hydrostatic pads with the suction cup adsorbing one side of the workpiece. The carrier is loaded and the workpiece in the carrier is taken out (Patent Document 1).

  That is, when loading a workpiece, the loading / unloading means that sucks the workpiece is moved to the other static pressure pad in a state where one of the static pressure pads is in the forward holding position near the carrier and the other static pressure pad is moved back to the retracted position. Insert between the pressure pad and the carrier and fit the workpiece into the carrier. When the work enters the carrier, the suction by the suction cup is released, the loading / unloading means is returned, the other static pressure pad is advanced to the forward holding position, and the work in the carrier is held by static pressure. Grinding with a pair of grinding wheels while rotating the workpiece.

  Also, when unloading the workpiece in the carrier, the loading / unloading means is inserted between the other hydrostatic pad that has been retracted to the retracted position and the carrier, and the workpiece after grinding in the carrier is removed by the suction cup of the loading / unloading means. Adsorb. When the suction cup sucks the workpiece, the static pressure water is supplied from one static pressure pad to release the workpiece from the one static pressure pad, and then the workpiece is taken out from the carrier while being sucked by the suction cup.

JP 2006-332281 A

  In such a conventional work loading / unloading method, when the work is loaded and unloaded by the loading / unloading means, the work in the carrier is not held by anything other than the carrier. For this reason, when the workpiece is a thin plate such as a silicon wafer, the workpiece may incline within the carrier and fall off from the carrier, and the workpiece may come into contact with the static pressure pad or grinding wheel to cause scratches or fall. There is a problem that causes damage such as cracking or chipping of the workpiece due to impact of time.

  In view of the above-described conventional problems, the present invention can prevent the workpiece in the carrier from falling off during loading and unloading of the workpiece, and can prevent damage to the workpiece. The purpose is to provide a board.

  The present invention relates to double-head surface grinding in which both surfaces of a workpiece are ground by a pair of grinding wheels while rotating a thin plate-like workpiece held by a pair of static pressure pads by a carrier, and the workpiece is removed by carrying-in / out means. When the work is carried in and out of the carrier between the both static pressure pads by suction, the work in the carrier is sucked by one of the static pressure pads in the forward holding position.

  After the workpiece in the carrier is sandwiched between the loading / unloading means and the one static pressure pad, the workpiece may be transferred between the loading / unloading means and the one static pressure pad in that state. . After inserting the work sucked by the carry-in means into the carrier and sandwiching it between the carry-in means and the one static pressure pad, substantially simultaneously with the suction of the work by the one static pressure pad, or It is desirable to cancel the adsorption of the workpiece by the carry-in means in tandem with the adsorption of the workpiece by the one static pressure pad.

  After the other static pressure pad is advanced to the forward holding position, the adsorption of the workpiece by the one static pressure pad is released, and a static pressure fluid is supplied to each static pressure pad to It is desirable to hold the pressure. After the static pressure holding of the workpiece by the both static pressure pads in the forward holding position is released and the workpiece in the carrier is adsorbed by the one static pressure pad, the other static pressure pad is moved to the forward holding position. It may be retreated from.

  The hydrostatic fluid is supplied from the other hydrostatic pad substantially simultaneously with the adsorption of the work by the one hydrostatic pad, or in synchronism with the adsorption of the work by the one hydrostatic pad. It is desirable to release the surface tension between the static pressure pad and the workpiece. After sandwiching the workpiece in the carrier between the unloading means and the one static pressure pad, substantially simultaneously with the adsorption of the workpiece by the unloading means, or before and after the adsorption of the workpiece by the unloading means, The workpiece may be separated from the one static pressure pad by releasing the adsorption of the workpiece by the one static pressure pad and supplying the static pressure fluid from the one static pressure pad.

  The present invention also provides a carrier that rotates a thin plate-shaped workpiece, a pair of static pressure pads that hold the workpiece in the carrier with static pressure, and the workpiece that is held by the static pressure pad and rotated by the carrier. In the double-head surface grinding machine comprising a pair of grinding wheels for grinding both surfaces of the head and a loading / unloading means for sucking the workpiece and loading / unloading it between the pair of static pressure pads, one of the static pressure pads is Adsorbing holes for adsorbing the workpiece in the carrier are provided at a plurality of locations in the circumferential direction including the vicinity of an engaging projection that engages with a notch portion of the workpiece.

  Advantageous Effects of Invention According to the present invention, there is an advantage that it is possible to prevent the workpiece in the carrier from dropping off when the workpiece is loaded and unloaded, and to prevent damage to the workpiece.

1 is a schematic cross-sectional view of a horizontal double-sided surface grinding machine showing an embodiment of the present invention. It is the same side view. It is a front view of the static pressure pad. It is sectional drawing of the same static pressure pad and a carrier. It is front sectional drawing of the carrying-in means. It is side surface sectional drawing of the carrying-in means. FIG. FIG. FIG. FIG. FIG. FIG. FIG. FIG. FIG. FIG. FIG. FIG. FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. 1 and 2 illustrate a horizontal double-sided surface grinding machine employing the present invention. As shown in FIGS. 1 and 2, the horizontal double-sided surface grinding machine includes a pair of left and right static pressure pads 1 and 2 that are arranged to face each other and hold a thin plate-like workpiece W such as a silicon wafer, Left and right sides for grinding the left and right side surfaces of the workpiece W, which are rotatably arranged around the left and right axial centers corresponding to the recesses 3 and 4 of the respective static pressure pads 1 and 2 and held by the static pressure pads 1 and 2 A pair of grinding wheels 5 and 6, a carrier 7 that rotates the workpiece W held by the static pressure pads 1 and 2 around the center, and a loading and unloading that loads the workpiece W into and out of the carrier 7 between the static pressure pads 1 and 2. Means 8 and 9 are provided.

  The static pressure pads 1 and 2 are movable in the left-right direction between a forward holding position X1 (grinding position) in the vicinity of the workpiece W and a backward position X2 rearward from the workpiece W. The workpiece W is held at a static pressure via a static pressure fluid (hereinafter referred to as a static pressure water) such as a static pressure water supplied to the holding surfaces 10 and 11 facing each other. As shown in FIG. 3, the holding surfaces 10 and 11 of the static pressure pads 1 and 2 receive a plurality of pockets 12 and 13 to which static pressure water is supplied and the static pressure water from the pockets 12 and 13. Discharge grooves 14 and 15 for discharging to the outside are provided.

  As shown in FIGS. 1 to 3, one of the pair of static pressure pads 1 and 2 includes a plurality of, for example, six suction holes in the circumferential direction on the outer peripheral portion of the holding surface 11. 16 is provided. The suction hole 16 is for sucking the work W and releasing the suction of the work W, and at least one suction hole 16 is used when the carrier 7 is stopped at the reference stop position as described later. It is arranged in the vicinity of the engaging protrusion 18 that engages with the notch 17 of the workpiece W.

  Note that the number of suction holes 16 may be appropriately determined in consideration of the size of the workpiece W and the like. The plurality of suction holes 16 are preferably arranged at substantially equal intervals in the circumferential direction. However, a plurality of (for example, two) suction holes 16 are arranged in the vicinity of both sides of the engagement protrusion 18. There may be some variation in the interval between the suction holes 16.

  Each pocket 12 and 13 is connected to a static water source 19 through a control valve or the like, and each suction hole 16 is discharged from a suction source 21 such as a vacuum source or an air source through a pressure sensor 20 or a control valve circuit 32 or the like. A source 22 is switchably connected. The grinding wheels 5 and 6 are cup-shaped or the like, and are provided at the tip of a left and right grindstone shaft (not shown). The grinding wheels 5 and 6 move in the left-right direction between the forward end Y1 and the backward end Y2, and on the forward end Y1 side. The workpiece W is ground during the forward movement.

  As shown in FIG. 4, the carrier 7 has a thin carrier plate 24 with a carrier hole 23 formed substantially concentrically on the inner periphery and thinner than the workpiece W, and a carrier ring that holds the outer periphery of the carrier plate 24. 25 and a presser ring 26, and are rotatably held around the center of the workpiece W by a plurality of support rollers 27 in the circumferential direction. The workpiece W is detachable with respect to the carrier hole 23, and an engagement protrusion 18 that engages with the notch portion 17 of the workpiece W is provided in the carrier hole 23.

  The carrier ring 25 is substantially concentric with the carrier 7. A ring gear 28 is provided concentrically on the inner periphery of the presser ring 26, and a drive gear 29 is engaged with the ring gear 28 from the inner periphery side. The drive gear 29 is driven by a drive source (not shown) through a drive shaft 31 inserted through the through hole 30 of the right static pressure pad 2.

  As shown in FIG. 1, the loading / unloading means 8 and 9 include a movable frame 33 provided so as to be movable in the left-right direction and the front-rear direction, and a loading means 8 provided separately and vertically movable on the movable frame 33 and The unloading means 9 is provided, and the workpiece W is sucked by the suction cups 34 and 35 of the loading means 8 and the unloading means 9 so that the workpiece W is loaded into and unloaded from the carrier 7 between the static pressure pads 1 and 2. Yes.

  The carry-in means 8 and the carry-out means 9 do not interfere with each other such that the carry-out means 9 rises when the work W is carried in by the carry-in means 8 and the carry-in means 8 rises when the work W is carried out by the carry-out means 9. Retreats to the retreat position.

  As shown in FIGS. 5 and 6, the carrying-in means 8 includes a support frame 37 provided on the movable frame 33 so as to be movable up and down in the vertical direction, and static pressure through the support frame 37 via the upper and lower support means 38 and 39. The floating frame 40 provided so as to be floatable in the in-plane direction of the holding surfaces 10 and 11 of the pads 1 and 2, the suction cup 34 provided on one side of the lower side of the floating frame 40, and the floating frame 40 serve as the carrier 7. Guide means 41 for guiding the floating frame 40 so that the workpiece W sucked by the suction cup 34 substantially coincides with the carrier hole 23 of the carrier 7 when approaching the side.

  The support frame 37 is arranged in the vertical direction, and a plate-like floating frame 40 is mounted on one side surface of the support frame 37 via a support means 38 so as to be floatable up and down and front and rear. In the floating frame 40, guide rollers 42 constituting guide means 41 are rotatably supported by an inclined support shaft 44 via a bracket 43 on both front and rear sides in the middle in the vertical direction. When the floating frame 40 approaches the carrier 7 side, the guide roller 42 is guided in contact with the outer periphery of the carrier ring 25.

  The support means 38 is provided between a pair of upper and lower support portions 45 and 46 provided between the support frame 37 and the floating frame 40 and between the support frame 37 and the floating frame 40 and biases the floating frame 40 downward. And an urging portion 51 to be operated.

  The support portions 45, 46 are openings 47, 48 such as through holes and notches formed in the floating frame 40, and are fixed to the support frame 37 through the openings 47, 48 and receive the floating frame 40. Receiving members 49 and 50. The upper contact edges 47a, 48a of the openings 47, 48 are arcuate in the front-rear direction and the lower side is horizontal in the front-rear direction, and the arc-shaped receiving edge of the receiving member 49 is received by the arc-shaped contact edge 47a. The surface 49a is in contact with the lower side. The horizontal abutting edge 48a is close to the upper side of the arcuate receiving surface 50a of the receiving member 50, so that both abut when the floating frame 40 floats to the maximum amount. The receiving members 49 and 50 have detachment preventing portions 49b and 50b so that the floating frame 40 can be detached from the upper side.

  The urging portion 51 includes a pressed body 52 horizontally provided in the front-rear direction at the upper end of the floating frame 40, and a plurality of urging portions 51 that are held downward by the support frame 37 and contact from above the pressed body 52. It has a pressing body 53 and springs 54 that urge the pressing body 53 downward, and is provided at three locations on the vertical line of the support portions 45 and 46 and on both the front and rear sides thereof. The central pressing body 53 is in contact with the recess 52 a of the pressed body 52, and the front and rear pressing bodies 53 are slidably contacted with the pressed body 52. Therefore, the floating frame 40 after floating returns using the upper support portion 45 as a fulcrum.

  The pressing body 53 and the spring 54 are provided on the protruding portion 55 on the side surface of the support frame 37. The support portions 45 and 46 may be provided with openings 47 and 48 in the support frame 37 and receiving members 49 and 50 in the floating frame 40, respectively. Further, the urging portion 51 may employ a tension spring in addition to the compression spring.

  The suction cups 34 are for vacuum-sucking the workpiece W, and are arranged at three locations on the upper side of the substantially central portion of the workpiece W and on both the front and rear sides below the workpiece W. Note that the number of suction cups 34, the interval between the suction cups 34, and the like may be appropriately determined in consideration of the size of the workpiece W and the like.

  As shown in FIG. 1, the carry-out means 9 includes a vertical support frame 56 and a suction cup 35 attached to the lower end portion of the support frame 56. One suction cup 35 is provided corresponding to the approximate center of the workpiece W, but may be two or more.

  Next, a method for loading and unloading the workpiece W in the horizontal double-sided surface grinding machine will be described. The double-sided surface grinding of the workpiece W is performed as one cycle from the loading step of loading the workpiece W to the unloading step of unloading the workpiece W after grinding through the grinding step of grinding the workpiece W.

  FIG. 7 shows a state before the work W is carried in, the left and right grinding wheels 5 and 6 are at the retracted end Y2, the left static pressure pad 1 is at the retracted position X2, and the right static pressure pad 2 is advanced near the carrier 7. Each is located at the holding position X1.

  Therefore, when the work W is loaded and mounted on the carrier 7 between the static pressure pads 1 and 2, the work W is first sucked by the suction cup 34 of the loading means 8. Next, as shown in FIG. 8, the loading means 8 is caused to enter between the carrier 7 and the left static pressure pad 1 so that the workpiece W is opposed to the axis of the carrier hole 23 of the carrier 7. And the carrying-in means 8 is moved to the carrier 7 side, and the workpiece | work W is inserted in the carrier hole 23 of the carrier 7, as shown in FIG.

  At this time, as shown in FIG. 2, the carrier 7 is positioned so that the engaging protrusion 18 is positioned at a predetermined position, and the work W has its notch 17 corresponding to the engaging protrusion 18 of the carrier 7. Therefore, the notch portion 17 of the workpiece W can be engaged with the engagement protrusion 18 of the carrier 7 by moving the loading means 8 toward the carrier 7 side.

  Further, even when the workpiece W does not coincide with the carrier hole 23 due to variations in the position of the loading means 8 in the vertical and longitudinal directions, if the loading means 8 is moved to the carrier 7 side, a pair of floating frames 40 Since the guide roller 42 is guided in contact with the outer periphery of the carrier ring 25, the floating frame 40 supported by the support frame 37 via the support means 38 so as to be able to float follows the carrier ring 25 and performs a floating operation. For this reason, when the carrying-in means 8 moves to the carrier 7 side, the workpiece W can be aligned with the carrier hole 23, and the workpiece W can be inserted into the carrier hole 23.

  When the workpiece W enters the carrier hole 23, the workpiece W is brought into contact with the holding surface 11 of the right static pressure pad 2 at the forward holding position X1, and the right static pressure pad 2 and the loading means 8 are brought into contact as shown in FIG. The workpiece W in the carrier 7 is sandwiched from both sides, and is then sucked through the suction holes 16 of the right static pressure pad 2 to suck the workpiece W onto the holding surface 11 of the static pressure pad 2. Whether or not the right static pressure pad 2 has sucked the workpiece W is confirmed by the presence or absence of a suction signal from the pressure sensor 20.

  When the notch 17 of the workpiece W rides on the engagement protrusion 18 of the carrier 7, one suction disposed in the vicinity of the notch 17 among the plurality of suction holes 16 of the right static pressure pad 2. Since the hole 16 sucks outside air, the right static pressure pad 2 cannot suck the work W, and the suction signal of the pressure sensor 20 is not output. Therefore, after the carrier 7 is rotated together with the workpiece W by a slight angle (predetermined angle), the workpiece W is attracted again by the right static pressure pad 2.

  In this way, by arranging the suction holes 16 at a plurality of locations including the vicinity of the notch portion 17 of the workpiece W, it is easy to determine whether or not the notch portion 17 of the workpiece W rides on the engagement protrusion 18 of the carrier 7. I can grasp it.

  When the workpiece W is mounted on the carrier 7, the engagement protrusion 18 of the carrier 7 and the notch portion 17 of the workpiece W are always engaged. However, when a situation occurs in which the notch portion 17 does not engage with the engaging protrusion 18 due to a mistake in suction of the workpiece W by the loading means 8 or the like, the automatic cycle of the loading operation is stopped and the operator is notified. .

  When the right static pressure pad 2 sucks the workpiece W, the suction of the workpiece W by the suction cup 34 of the loading means 8 is released almost simultaneously with the suction, and the workpiece W is transferred from the loading means 8 to the right static pressure pad 2. . Therefore, even if the carrying-in means 8 is retracted from between the static pressure pads 1 and 2 thereafter, the workpiece W in the carrier 7 can be held by the right static pressure pad 2 as shown in FIG.

  After the workpiece W is sandwiched from both sides by the right static pressure pad 2 and the loading means 8 as described above, when the workpiece W is sucked by the right static pressure pad 2, the suction of the workpiece W by the loading means 8 is released almost simultaneously. By transferring W from the loading means 8 to the right static pressure pad 2 and continuing the suction with the right static pressure pad 2 even after the transfer, the workpiece W in the carrier 7 is formed despite the thin plate shape. It is possible to prevent the workpiece W from being inclined and the workpiece W from falling off the carrier 7.

  The workpiece W may be transferred from the loading means 8 to the right static pressure pad 2 in a state where the workpiece W is sandwiched from both sides by the right static pressure pad 2 and the loading means 8. What is necessary is just to cancel | release adsorption | suction of the workpiece | work W by the carrying-in means 8 after adsorption | suction of W. Conversely, the suction of the work W by the carrying-in means 8 may be canceled and then the work W may be sucked by the right static pressure pad 2.

  Next, as shown in FIG. 11, after the left static pressure pad 1 is advanced to the advance holding position X1, the adsorption of the work W by the right static pressure pad 2 is released. At this time, since the workpiece W in the carrier 7 is sandwiched by both the static pressure pads 1 and 2 from both sides, the workpiece W is removed from the carrier 7 even if the adsorption of the workpiece W by the right static pressure pad 2 is released. There is no fear. Thereafter, as shown in FIG. 12, static pressure water is supplied to both the static pressure pads 1 and 2 to hold the workpiece W in the carrier 7 with static pressure. Then, while the carrier 7 is driven by the drive gear 29 and the workpiece W in the static pressure holding state is rotated, both grinding wheels 5 and 6 are advanced as shown in FIG. 13 to grind both surfaces of the workpiece W.

  After the grinding of the workpiece W, as shown in FIG. 14, the grinding wheels 5 and 6 are retracted to the retracted end Y2, and the rotation of the carrier 7 is stopped. At this time, the carrier 7 is stopped at a fixed position in order to facilitate the insertion of the next workpiece W. Thereafter, when the supply of the static pressure water from both the static pressure pads 1 and 2 is stopped, the workpiece W is adsorbed by the right static pressure pad 2 substantially simultaneously with the stop or after the stop. Also at this time, it is confirmed by the pressure sensor 20 whether or not the right static pressure pad 2 has attracted the workpiece W. Then, when a suction error that prevents the right static pressure pad 2 from sucking the workpiece W occurs, the workpiece W may be damaged, so the automatic cycle operation is stopped and the worker is notified.

  After the workpiece W is adsorbed by the right static pressure pad 2 and before the left static pressure pad 1 is retracted to the retracted position X2, as shown in FIG. The surface tension between the pad 1 and the workpiece W is eliminated. That is, since the gap between the workpiece W and the left static pressure pad 1 is actually about 0.1 mm, even if the right static pressure pad 2 attracts the workpiece W, the gap between the workpiece W and the left static pressure pad 1 is The surface tension between them is not lost.

  Therefore, first, the static pressure water is supplied from the left static pressure pad 1 to eliminate the surface tension between the left static pressure pad 1 and the workpiece W, and then the left static pressure pad 1 is retracted to the retreat position X2. Accordingly, the left static pressure pad 1 can be retracted to the retracted position X2 while preventing the workpiece W from being damaged by the surface tension between the two when the left static pressure pad 1 is retracted.

  After the left static pressure pad 1 is retracted to the retracted position X2, the unloading means 9 is caused to enter between the carrier 7 and the left static pressure pad 1 as shown in FIG. Then, as shown in FIG. 17, the unloading means 9 is moved to the carrier 7 side, and the workpiece W in the carrier 7 is sandwiched from both sides by the unloading means 9 and the right static pressure pad 2.

  Next, as shown in FIG. 18, the work W in the carrier 7 is sucked by the suction cup 35 of the unloading means 9. Simultaneously with or after suction of the workpiece W by the suction cup 35, the suction hole 16 of the right static pressure pad 2 is switched from the suction source 21 to the discharge source 22, and air is discharged from the suction hole 16 to discharge the right static pressure pad 2. The vacuum between the workpiece and the workpiece W is broken, and at the same time or after the vacuum break, the static pressure water is supplied from the right static pressure pad 2 to release the workpiece W from the right static pressure pad 2.

  Then, as shown in FIG. 19, the unloading means 9 is moved backward to take out the workpiece W after grinding from the carrier 7. Note that the discharge of air from the right static pressure pad 2 and the supply of static pressure water are terminated at an appropriate time after the workpiece W is separated.

  In this manner, with the right static pressure pads 1 and 2 and the unloading means 9 sandwiching the workpiece W from both sides, the workpiece W is first sucked by the suction cup 34 of the unloading means 9 and then sucked by the right static pressure pad. By releasing and transferring the workpiece W from the right static pressure pad 2 to the unloading means 9, it is possible to prevent the workpiece W from dropping off from the carrier 7.

  In addition, after the suction of the workpiece W by the right static pressure pad 2 is released, air is discharged from the suction hole 16 to break the vacuum suction. This vacuum breakage is, for example, a low pressure of about 0.1 to 0.2 MPa. To do. By breaking the vacuum at a lower pressure in this way, it is possible to eliminate phenomena such as the workpiece W vibrating due to a sudden large force acting on the workpiece W due to a sudden vacuum breaking when releasing the vacuum suction. W damage can be prevented.

  If the vacuum is further broken, the workpiece W remains adsorbed on the right static pressure pad 2 due to the surface tension of the water between the right static pressure pad 2 and the workpiece W. By supplying the pressurized water, the influence of the surface tension can be eliminated, and the workpiece W can be prevented from being damaged when the workpiece W is adsorbed by the unloading means 9.

  Thereafter, the workpiece W adsorbed by the unloading means 9 is extracted from the carrier hole 23 of the carrier 7 and unloaded from between the static pressure pads 1 and 2 to the outside.

  By adsorbing the workpiece W with the right static pressure pad 2 in this way, the workpiece W is inclined in the carrier 7 at the time of loading / unloading, and comes into contact with the grinding wheels 5, 6 or the like, or the workpiece W falls off from the carrier 7. Can be prevented, and damage to the workpiece W, the grinding wheels 5, 6 and the like can be prevented.

  Further, the suction hole 16 may be formed in the right static pressure pad 2 and the suction hole 16 may be connected to the suction source 21 and the discharge source 22 through a control valve or the like, so that it is easy and easy without introducing new equipment. There is an advantage that it can be implemented at a low cost and can prevent the double-sided surface grinding machine itself from becoming large.

  Further, when the workpiece W is attracted by the right static pressure pad 2 and the left static pressure pad 1 is moved backward while being sandwiched between the two static pressure pads 1 and 2 at the forward holding position X1, the After supplying the pressurized water and releasing the suction by the right static pressure pad 2, when the unloading means 9 that sucked the workpiece W is retracted, by supplying air and static water from the right static pressure pad 2, While preventing the workpiece W from being damaged by the surface tension of water, the left static pressure pad 1 and the unloading means 9 can be smoothly retracted, and the grinding cycle time can be shortened.

  As mentioned above, although embodiment of this invention was explained in full detail, this invention is not limited to this embodiment, A various change is possible in the range which does not deviate from the meaning of this invention. For example, in this embodiment, a horizontal double-sided surface grinder is illustrated, but a vertical double-headed surface grinder can be similarly implemented. The workpiece W may be other than a silicon wafer.

  In the embodiment, the suction hole 16 is provided in the right static pressure pad 2 of the pair of static pressure pads 1 and 2, and the workpiece W is sucked to the right static pressure pad 2 side. The suction hole 16 may be provided in the static pressure pad 1 so that the workpiece W is sucked to the left static pressure pad 1 side.

  If the work W adsorbed by the carry-in means 8 is inserted into the carrier 7 and sandwiched between the carry-in means 8 and the right static pressure pad 2, the carry-in means is substantially simultaneously with the adsorption of the work W by the right static pressure pad 2. 8 may be released, or the adsorption of the workpiece W by the loading means 8 may be released at the same time as the adsorption of the workpiece W by the right static pressure pad 2.

  Further, when the surface tension between the left static pressure pad 1 and the workpiece W is released by supplying the static pressure water from the left static pressure pad 1, the left static pressure pad 1 from the left static pressure pad 1 substantially simultaneously with the adsorption of the workpiece W by the right static pressure pad 2. The hydrostatic water may be supplied, or the hydrostatic water may be supplied from the left hydrostatic pad 1 in tandem with the adsorption of the workpiece W by the right hydrostatic pad 2.

  After the workpiece W in the carrier 7 is sandwiched between the unloading means 9 and the right static pressure pad 2, the adsorption of the workpiece W by the right static pressure pad 2 is released substantially simultaneously with the unloading of the workpiece W by the unloading means 9, and the right static pressure pad 2 is released. The static pressure water may be supplied from the pressure pad 2, or the suction of the work W by the right static pressure pad 2 is canceled at the same time as the suction of the work W by the unloading means 9, and the static pressure from the right static pressure pad 2 is released. Water may be supplied.

  When the static pressure water is supplied to the right static pressure pad 2 when the workpiece W is unloaded, it may be supplied via the supply valve using a normal static water supply system for holding static pressure. The hydrostatic water supply system for holding static pressure may be supplied from a supply system different from the supply system. Further, the carry-in means 8 and the carry-out means 9 may be provided separately, or one may be used as both.

  In the embodiment, the suction cup 34 is provided in the carry-in means 8 via the floating frame 40 so that it can float, and the suction cup 34 is guided via the guide means 41 so that the carrier 7 and the work W coincide with each other when the work W is mounted. Although the configuration is adopted, the work W adsorbed by the carry-in means 8 with respect to the carrier 7 stopped at the reference stop position by improving the rigidity of the carry-in means 8, improving the accuracy of the drive motor of the carry-in means 8, or the like. By improving the position accuracy, the floating frame 40 on the carry-in means 8 side can be omitted.

W Work 1, 2 Static pressure pads 5, 6 Grinding wheel 7 Carrier 8 Carry-in means 9 Carry-out means 16 Suction hole 17 Notch 18 Engagement protrusion 37 Support frame 40 Floating frame 41 Guide means 42 Guide roller X1 Advance holding position X2 Retreat position

Claims (8)

  In double-sided surface grinding in which both surfaces of the workpiece are ground by a pair of grinding wheels while rotating a thin plate-like workpiece held by a pair of static pressure pads by a carrier, the workpiece is adsorbed by carrying-in / out means The workpiece in double-head surface grinding, wherein the workpiece in the carrier is adsorbed by one of the static pressure pads in the forward holding position when the workpiece is carried in and out of the carrier between the two hydrostatic pads. Loading / unloading method.   After the workpiece in the carrier is sandwiched between the loading / unloading means and the one static pressure pad, the workpiece is delivered between the loading / unloading means and the one static pressure pad in that state. The workpiece carrying-in / out method in the double-head surface grinding according to claim 1.   After inserting the work sucked by the carry-in means into the carrier and sandwiching it between the carry-in means and the one static pressure pad, substantially simultaneously with the suction of the work by the one static pressure pad, or 3. The work loading / unloading method in double-head surface grinding according to claim 1 or 2, wherein the suction of the work by the loading means is released before or after the suction of the work by the one static pressure pad.   After the other static pressure pad is advanced to the forward holding position, the adsorption of the workpiece by the one static pressure pad is released, and a static pressure fluid is supplied to each static pressure pad to 4. The work loading / unloading method in double-head surface grinding according to claim 3, wherein pressure holding is performed.   After the static pressure holding of the workpiece by the both static pressure pads in the forward holding position is released and the workpiece in the carrier is adsorbed by the one static pressure pad, the other static pressure pad is moved to the forward holding position. 5. The work loading / unloading method in double-head surface grinding according to any one of claims 1 to 4, wherein the workpiece is moved backward.   The hydrostatic fluid is supplied from the other hydrostatic pad substantially simultaneously with the adsorption of the work by the one hydrostatic pad, or in synchronism with the adsorption of the work by the one hydrostatic pad. 5. The work loading / unloading method in double-head surface grinding according to claim 4, wherein surface tension between the static pressure pad and the work is released.   After sandwiching the workpiece in the carrier between the unloading means and the one static pressure pad, substantially simultaneously with the adsorption of the workpiece by the unloading means, or before and after the adsorption of the workpiece by the unloading means, The suction of the workpiece by the one static pressure pad is released, a static pressure fluid is supplied from the one static pressure pad, and the workpiece is separated from the one static pressure pad. The work loading / unloading method in the double-head surface grinding described.   A carrier that rotates a thin plate-shaped workpiece, a pair of static pressure pads that statically hold the workpiece in the carrier, and both surfaces of the workpiece that are held by the static pressure pad and rotated by the carrier are ground. In the double-head surface grinder comprising a pair of grinding wheels and a loading / unloading means for sucking the workpiece and loading / unloading the workpiece between the pair of static pressure pads, one of the static pressure pads is the one in the carrier. A double-sided surface grinding machine characterized in that suction holes for sucking a workpiece are provided at a plurality of locations in the circumferential direction including the vicinity of an engaging projection that engages with a notch portion of the workpiece.

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