Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
  • B23D—PLANING; SLOTTING; SHEARING; BROACHING; SAWING; FILING; SCRAPING; LIKE OPERATIONS FOR WORKING METAL BY REMOVING MATERIAL, NOT OTHERWISE PROVIDED FOR
  • B23D31/00—Shearing machines or shearing devices covered by none or more than one of the groups B23D15/00 - B23D29/00; Combinations of shearing machines
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B28—WORKING CEMENT, CLAY, OR STONE
  • B28D—WORKING STONE OR STONE-LIKE MATERIALS
  • B28D5/00—Fine working of gems, jewels, crystals, e.g. of semiconductor material; apparatus or devices therefor
  • B28D5/0058—Accessories specially adapted for use with machines for fine working of gems, jewels, crystals, e.g. of semiconductor material
  • B28D5/0082—Accessories specially adapted for use with machines for fine working of gems, jewels, crystals, e.g. of semiconductor material for supporting, holding, feeding, conveying or discharging work
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B28—WORKING CEMENT, CLAY, OR STONE
  • B28D—WORKING STONE OR STONE-LIKE MATERIALS
  • B28D5/00—Fine working of gems, jewels, crystals, e.g. of semiconductor material; apparatus or devices therefor
  • B28D5/04—Fine working of gems, jewels, crystals, e.g. of semiconductor material; apparatus or devices therefor by tools other than rotary type, e.g. reciprocating tools
  • B28D5/045—Fine working of gems, jewels, crystals, e.g. of semiconductor material; apparatus or devices therefor by tools other than rotary type, e.g. reciprocating tools by cutting with wires or closed-loop blades

Definitions

• the present invention relates, in general, to the field of an apparatus and method for accurately sawing a workpiece into two or more sections. More particularly, the present invention relates to an apparatus and method for cropping and/or slicing crystalline ingots, such as relatively large diameter polysilicon and single crystal silicon ingots, with great accuracy, speed and efficiency.
• the vast majority of current semiconductor and integrated circuit devices are fabricated on a silicon substrate.
• the substrate itself is initially created utilizing raw polycrystalline silicon having randomly oriented crystallites.
• the silicon does not exhibit the requisite electrical characteristics necessary for semiconductor device fabrication.
• a single crystal silicon seed may then be added to the melt and a single crystalline ingot pulled having the same orientation of the seed.
• Such silicon ingots had relatively small diameters of on the order of from one to four inches, although current technology can produce ingots of 150mm (six inches) or 200mm (eight inches) in diameter.
• Recent improvements to crystal growing technology now allow ingots of 300mm (twelve inches) or 400mm (sixteen inches) in diameter to be produced.
• the ingot Once the ingot has been produced, it must be cropped (i.e. the "head” and “tail” portions of the ingot must be removed) and then sliced into individual wafers for subsequent processing into a number of die for discrete or integrated circuit semiconductor devices.
• the primary method for cropping the ingot is through the use of a bandsaw having a relatively thin flexible blade.
• the large amount of flutter inherent in the bandsaw blade results in a very large "kerf" loss and cutting blade serration marks which must then be lapped off.
• the ID hole saw Inner diameter hole saw
• the slurry saw The former is used predominantly in the United States in order to slice single crystal silicon and is so named due to the fact that the cutting edge of the blade adjoins a centrally located hole at its inner diameter in an attempt to reduce the flutter of the blade and resultant damage to the crystalline structure
• the disadvantages inherent in this technique is that as silicon ingots increase in diameter, the ID hole saw must increase to three times the ingot diameter to allow it to cut all the way through the ingot to a point at which it becomes unwieldy if not unworkable
• the slurry saw comprises a series of mandrels about which a very long wire is looped and then driven through the ingot as a silicon carbide or boron carbide slurry is dripped onto the wire Wire breakage is a significant problem and the saw down time can be significant when the wire must be replaced Further, as ingot diameters increase to 300mm to 400mm the drag of the wire through the ingot reaches the point where breakage is increasingly more likely unless the wire gauge is increased resulting in greater "kerf" loss Importantly, a slurry saw can take many hours to cut through a large diameter ingot
• an apparatus and method for slicing a workpiece in particular, a polysilicon or single crystal silicon ingot utilizing a diamond impregnated wire in which the workpiece (or ingot) is rotated, either continuously or reciprocally back and forth about its longitudinal axis relative to the diamond wire as the diamond wire is driven orthogonally to the longitudinal axis of the workpiece and advanced from a position adjoining the outer diameter ("OD") of the ingot towards its inner diameter (“ID”)
• This relative motion between the wire and the workpiece in addition to the orthogonal wire movement is accomplished by either rotating the workpiece about its longitudinal axis or rotating the saw wire about the longitudinal axis of the workpiece during the cutting operation This rotation may be continuous or reciprocally back and forth through an arc
• the diamond wire cuts through the workpiece at a point substantially tangential to the circumference of the cut instead of through up to the entire diameter of the piece
• polysilicon or single crystal silicon ingots of 300mm to 400mm or more may be sliced into
• the method comprises the steps of providing a wire having a plurality of cutting elements affixed thereto and moving the wire orthogonally to a longitudinal axis of the workpiece while either rotating the workpiece about its longitudinal axis or rotating the wire about the workpiece longitudinal axis and advancing the wire from a first position proximate an outer diameter of the workpiece to a second position proximate its inner diameter or center.
• an apparatus for sectioning a substantially cylindrical crystalline workpiece comprises a wire having a plurality of cutting elements affixed thereto and a wire drive mechanism for moving the wire orthogonally with respect to a longitudinal axis of the workpiece, a workpiece rotation mechanism coupled to the workpiece for rotating the workpiece about its longitudinal axis, and a wire advancing mechanism which positions the wire from a first tangential position proximate an outer diameter of the workpiece to a second position proximate an inner diameter or center thereof.
• a second embodiment is similar to the first except that the workpiece is held stationary on a frame and the wire drive mechanism is rotated about the workpiece by a rotation mechanism while the wire advancing mechanism positions the wire from the first position proximate an outer diameter of the workpiece to a second position proximate an inner diameter thereof.
• Rotation of the wire drive mechanism may be continuous in one direction or reciprocal through a predetermined arc. In the latter instance the angle of the arc may be varied depending on the depth of the cut through the ingot. For example, at the beginning of the cut through the ingot, the arc may be very small, only a few degrees and then progressively increased as the cut progresses.
• This reciprocal movement of the wire drive mechanism permits the kerf to provide lateral guidance to the wire during the cut and advantageously minimizes the effects created by surface irregularities on the ingot on the precision of the cut
• a semiconductor wafer made by a process which comprises the steps of providing a wire having a plurality of cutting elements affixed thereto, moving the wire orthogonally to a longitudinal axis of a crystalline semiconductor material ingot, rotating either the wire or ingot either reciprocally or continuously about the ingot's longitudinal axis and advancing the wire from a first position proximate an outer diameter of the ingot to a second position proximate an inner diameter thereof
• Fig 1 is a simplified representational view of an apparatus for slicing a workpiece, in particular a single crystal silicon ingot, in accordance with an exemplary implementation of the present invention
• Fig 2 is a more detailed, partially cut-away end elevational view of the apparatus of Fig 1 wherein the ingot is rotated, either continuously or reciprocally, by means of a rotating collet fixture while the cutting wire is driven substantially tangentially to the circumference of a cut in the ingot,
• Fig 3 is a detailed, partially cut-away side elevational view of the apparatus of Figs 1 and 2 illustrating the rotating collet fixtures and an associated lead screw for translationally repositioning the workpiece between cuts to define a number of wafers to be sliced from the ingot,
• Figs 4A and 4B are differing, detailed isometric views of the apparatus of Figs 2 and 3, further illustrating the interrelationship of the wire drive, workpiece rotation or reciprocation, wire advancing and workpiece repositioning mechanisms;
• Fig. 5 is an additional detailed partially cut-away side elevational view of an alternative embodiment of the present invention utilizing, for example, multiple cutting wires and wherein the ingot is rotated by means of an end mounted workpiece rotation mechanism secured adjacent an end of the ingot.
• Fig. 6A and 6B are simplified representational plan views of an apparatus for slicing a workpiece, in particular a single crystal silicon ingot, in accordance with another exemplary implementation of the present invention in which the saw is rotated about the workpiece during the cutting operation.
• FIG. 1 a simplified representational view of an apparatus 10 for slicing a generally cylindrical workpiece, for example, a polysilicon or single crystal silicon, gallium arsenide (GaAs) or other crystalline ingot, is shown.
• the apparatus 10 comprises, in pertinent part, a cutting wire 12, for example a diamond impregnated wire such as the SuperwireTM or SuperlokTM series of cutting wires available from Laser Technology West Limited, Colorado Springs, CO.
• the wire 12 is utilized in conjunction with the method and apparatus 10 of the present invention to accurately and rapidly crop and saw a silicon ingot 14 into multiple wafers for subsequent processing into discrete or integrated circuit devices.
• the apparatus 10 includes a wire drive mechanism 16 for moving the wire 12 in a single direction as indicated by the arrow or in a reciprocating fashion with respect to the ingot 14.
• the wire drive mechanism 16, in the embodiment shown, may comprise a capstan 18 for alternately winding and unwinding the wire 12 about a central pulley to impart a reciprocating motion to the wire 12.
• the wire 12 may be readily moved continuously in a single direction without reversal as described more fully hereinafter.
• the wire 12 may be guided in the proximity of the ingot 14 by a pair of pulleys 20, with proper tensioning of the wire 12 being maintained by a tension pulley 22.
• the apparatus 10 further includes a workpiece rotation mechanism 24 for rotating the ingot 14 about its longitudinal axis as the wire 12 is moved orthogonally with respect to the ingot 14 in either a single direction or bidirectionally as previously described.
• the workpiece rotation mechanism 24, in the embodiment shown, may comprise one or more rotating collet fixtures 26 circumferentially surrounding the ingot 14 along its length thereof as will be more fully described hereinafter.
• the collet fixtures, and hence the ingot 14, may be rotated by means of a number of drive rollers 28 or functionally equivalent elements.
• the ingot 14 may be secured to an end mounted workpiece rotation mechanism 24 in lieu of the embodiment illustrated in this figure.
• the apparatus 10 also includes a wire advancing mechanism 30 to which, in this first embodiment illustrated, the wire drive mechanism is mounted.
• the wire advancing mechanism 30 functions to advance the moving wire 12 from an initial position 32 displaced outwardly from, and proximate to, the outer diameter ("OD") of the ingot 14 towards a final position 34 proximate the inner diameter ("ID”) of the ingot 14 to effectuate completion of a single cut.
• the motion of the wire advancing mechanism may be reversed to withdraw the wire 12 back towards the initial position 32.
• the apparatus 10 may further incorporate a workpiece repositioning mechanism 36 to enable an indexed, translational repositioning of the ingot 14 to enable the wire 12 to make repeated cuts along its length, for example, to slice a number of wafers therefrom.
• the workpiece repositioning mechanism 36 may include a programmably index driven leadscrew 38 which reposition the workpiece rotation mechanism 24 and ingot 14 as supported by a number of rollers 40 with respect to the wire 12
• the wire drive mechanism 16 and wire advancing mechanism 30 may be repositionable with respect to a generally fixed position workpiece rotation mechanism 24
• FIGs 2, 3, 4A and 4B more detailed illustrations of a particular exemplary implementation of an apparatus 10 as previously depicted and described with respect to Fig 1 are shown With respect to the apparatus 10 illustrated in these figures, like structure to that previously described and shown is like numbered and the foregoing description hereof shall suffice herefor
• the apparatus 10 may comprise a base 42 providing a worktable surface with a pair of upwardly extending upright supports 44
• One or more crossbeams 46 may extend between the distal ends of the upright supports 44 as shown
• a wire tensioner 48 for maintaining an appropriate wire 12 tension for the wire drive mechanism 16
• the wire tensioner 48 may comprise a spring or other suitable means for biasing the tension pulley 22 to maintain proper tension of the wire 12 during a sawing operation
• the wire advancing mechanism 30 is slidably supported by the upright supports 44 and may comprise a microstepper feed drive 50 in conjunction with a driven linear actuator 52 and corresponding idler linear actuator 54, each of the actuators 52, 54 being associated with a corresponding one of the upright supports 44
• the capstan 18 of the wire drive mechanism 16 may be driven by a drive motor 56 as shown while a microstepper 58 may be utilized to rotate one or both of the drive rollers 28 of the workpiece rotation mechanism 24
• the microstepper 58 may be either controlled to rotate the workpiece in one rotational direction or it can be reciprocally controlled to rotate the workpiece first in one direction through a specific angle and then reversed to rotate the workpiece back through a specified angle
• the specified angle is small, on the order of a few degrees at the beginning of the cut and is progressively increased as the cut progresses through the ingot to more than 45 degrees of rotation In this way, the wire saw effectively maintains a relatively constant tangential contact with the ingot in the cut while maintaining the advantages of sidewall guidance of the kerf during the cut in order to counter the side forces on the wire that can be present when a surface imperfection in the outer cylindrical surface of the ingot is encountered during the cut
• the drive rollers 28 may include a plurality of longitudinally extending teeth for engaging corresponding peripherally extending teeth of the collet fixtures 26
• the collet fixtures 26 may further comprise centering clamps (not shown) to enable the ingot 14 to be accurately centered within the collet fixtures 26 to enable accurate rotation about its longitudinal axis during operation of the apparatus 10
• the apparatus 10 may further include a microstepper 60 coupled to the leadscrew 38 of the workpiece repositioning mechanism 36 to enable the carriage supporting the ingot 14 and associated workpiece rotation mechanism 24 to be selectively moved along the worktable of the base 42 to reposition the ingot 14 with respect to the wire drive mechanism 16
• Figures 4A and 4B further illustrate that the rollers 40 may be engaged to a pair of rails 68 to facilitate accurate translational positioning of the ingot 14 by means of the microstepper 60
• the ingot 14 prior to a cropping operation which may also be performed by the apparatus 10 in addition to wafer slicing, the ingot 14 also includes a somewhat tapered head 62 and opposing flanged tail 64
• the apparatus 10 further comprises a controller 66 coupled to and operationally controlling the functionality and inter-relational operation of one or more of the microstepper feed drive 50 of the wire advancing mechanism 30, the drive motor 56 of the wire drive mechanism 16, the microstepper 58 of the workpiece rotation mechanism 24 and the microstepper 60 of the workpiece repositioning mechanism 36 as will be more fully described hereinafter.
• a controller 66 coupled to and operationally controlling the functionality and inter-relational operation of one or more of the microstepper feed drive 50 of the wire advancing mechanism 30, the drive motor 56 of the wire drive mechanism 16, the microstepper 58 of the workpiece rotation mechanism 24 and the microstepper 60 of the workpiece repositioning mechanism 36 as will be more fully described hereinafter.
• the apparatus 10 1 incorporates a plurality of cutting wires 12 1 in the form of individual closed-loop wires to enable simultaneous cuts to be made in the ingot 14 to slice individual wafers therefrom.
• the wires 12 1 of the wire drive mechanism 16 1 are supported by a number of pulleys 20 1 and may be driven by means of a capstan 18 as rotationally coupled to a single direction of rotation drive motor 56 1 .
• the wire advancing mechanism 30 1 of the apparatus 10 1 moves the wire drive mechanism 16 1 in a horizontal direction with respect to the vertically positioned ingot 14 by means of a microstepper feed drive 50 1 .
• the workpiece rotation mechanism 24 1 in the embodiment shown, is mounted and secured to a cropped end of the ingot 14 and is driven by a microstepper 58 1 .
• the apparatus 10 1 includes catch jaws 70 and a catch table 72 for wafers cut from the ingot 14 as well as an ingot feed, or workpiece repositioning mechanism, (not shown) to position the ingot 14 with respect to the wire drive mechanism 16 1 .
• the capstan 18 may hold 100 to 200 linear feet of wire 12 and reversibly drive the wire 12 at a rate of 2000 to 2500 feet/second.
• one or more continuous loops of wire 12 1 in conjunction with a wire drive mechanism 16 1 which moves the one or more wires 12 1 in a single direction only without the necessity of reversing its direction.
• a wire drive mechanism 16 1 which moves the one or more wires 12 1 in a single direction only without the necessity of reversing its direction.
• such continuous loop(s) of wire 12 1 would last longer in operation than a comparable reversing length of wire 12, would tend to seat better within the resultant cut in the ingot 14 while also obviating any serration marks that might result due to the reversing of the wire 12 and provide a significantly reduced cutting time in comparison.
• the rotation in one direction of the ingot 14 in conjunction with the motion of the wire 12 means that the wire is only in contact substantially tangentially to the circumference of the ingot 14 in the cut throughout the entire cutting operation. This results in much less drag on the wire 12 allowing for faster cutting while concomitantly providing for the use of a finer gauge wire than would otherwise be the case if the cut were to have to proceed from the ingot 14 OD to the maximum diameter of the ingot 14 through its center point.
• This potential use of a finer gauge wire 12 means that there will be less loss of the ingot 14 material in the sawing operation and the cleaner cut produced lessens the need for extensive lapping thereafter thereby reducing the cost of lapping materials and operations.
• the wire saw finishes the cut by advancing eventually completely through the ingot 14 rather than finishing the cut in the center. It has been found, however, that the improved precision achieved utilizing the reciprocal movement of the workpiece is greater than with continuous rotation when surface imperfections on the ingot 14 are substantial.
• the wire 12 speed imparted by the wire driving mechanism 16, the ingot 14 rotation speed imparted by the workpiece rotation mechanism 24 and the advance of the wire 12 into the ingot 14 due to the wire advancing mechanism 30 must be accurately controlled, for example by the controller 66 (Fig 3) Functionally, it is most desirable that the surface speed of the wire 12 with respect to the material of the ingot 14 be held relatively constant Therefore, the relative speed of the wire 12 has to be reduced as the cut proceeds from the ingot 14 OD to its ID to keep the surface rate substantially constant
• the cutting pressure of the wire 12 is determined by the wire advancing mechanism 30
• water may be utilized in the cutting operation as a lubricant for the wire 12 to wash off the crystalline debris and prolong the cutting life of the wire 12
• Other suitable techniques may also be employed with respect to the embodiment shown in Fig 5
• the ingot 14 is rotated relative to the wire 12 while the wire 12 is either tangentially reciprocated or continuously advanced
• the cut is tangentially made around the circumference of the ingot as the wire 12 advances from the OD to the ID or center of the ingot 14
• the cut is tangentially made through an arc and thus forms an arcuate cut through the ingot
• the advancing mechanism 30 moves the wire 12 completely through the ingot 14 This same relative motion may be accomplished by holding the ingot 14 stationary and instead rotating the wire 12 about the longitudinal axis of the ingot 14 as the wire 12 is reciprocated or continually advanced
• FIG. 6A shows the apparatus with the wire saw at an intermediate cut depth between the OD and the ID of the ingot 14
• Fig 6B shows the apparatus with the wire saw against the OD of the ingot 14 and at a different angular position as will be described further below
• the apparatus 100 comprises, in pertinent part, a cutting wire 102, for example a diamond impregnated wire such as the SuperwireTM or SuperlokTM series of cutting wires available from Laser Technology West Limited, Colorado Springs, CO
• the wire 102 is utilized in conjunction with the method and apparatus 100 of the present invention to accurately and rapidly crop and saw a silicon ingot 14 into multiple wafers for subsequent processing into discrete or integrated circuit devices by rotating the saw relative to a stationary ingot 14
• the apparatus 100 includes a stationary frame 104 and a wire drive mechanism 106 for moving the wire 102 in a single direction as indicated by the arrow "a" or in a reciprocating fashion with respect to the ingot 14
• the wire drive mechanism 106 in the second embodiment shown, may comprise a capstan 108 for alternately winding and unwinding the wire 102 about a central pulley to impart a reciprocating motion to the wire 102
• the wire 102 may be readily moved continuously in a single direction without reversal
• the wire 102 may be guided in the proximity of the ingot 14 by a pair of pulleys 110 with proper tensioning of the wire 102 being maintained by a tension pulley 112
• the capstan and pulleys are all mounted to a wire drive mechanism frame 113
• the apparatus 100 further includes a wire (i e saw) drive mechanism rotation mechanism 114 for rotating the wire drive mechanism 106 about the ingot's longitudinal axis as the wire 102 is moved orthogonally with respect to the ingot 14 in either a single direction or bidirectionally, i e reciprocally as previously described
• a wire (i e saw) drive mechanism rotation mechanism 114 for rotating the wire drive mechanism 106 about the ingot's longitudinal axis as the wire 102 is moved orthogonally with respect to the ingot 14 in either a single direction or bidirectionally, i e reciprocally as previously described
• the wire saw rotation mechanism 114 in the second preferred embodiment shown in Fig 6, may comprise a stationary peripheral ring gear 116 centered about the support for the ingot 14 on the stationary frame 104, an annular support disk 118 concentrically mounted about the longitudinal axis of the ingot 14 for rotation therearound within the ring gear 116 and a drive motor and gear 120 mounted on either the frame 104 or the support disk 118 to rotate the annular support disk 118 about its central axis and thus the longitudinal axis of the ingot 14
• the ingot 14 is mounted in a chuck held in a stationary position on the frame 104
• the drive motor 120 is mounted on one leg 119 of the annular support disk 118
• the support disk 118 is shown as having a generally trapezoidal shape with three legs 119 spaced 120 degrees apart and a central generally rectangular opening 121 around the ingot 14
• Each leg 119 supports a gear 123 which engages the teeth on the ring gear 112 and thus ensures that the support disk 118 remains centered about the ingot 14
• Two of the gears 123 are simply followers
• the gear 123 meshed with the drive gear on the motor 120 is the driven gear which rotates the trapezoidal annular disk 114
• This motor 120 may be a stepper motor or other suitable fine controllable motor to effectuate the required angular velocity required for the cutting operation as is more fully described with reference to the first embodiment set forth above
• the shape of the disk 114 being trapezoidal is purely exemplary
• the shape may be circular, triangular or have a different shape all together, but, in this embodiment, it is generally annular with a central opening positioned around the support for the ingot 14
• the annular support disk or plate 118 rotates around the ingot 14 since the wire drive mechanism 106 is fastened to the annular support disk 118 Since the annular support disk 118 rotates around the ingot 14, the wire 102 in turn rotates around the ingot 14 while remaining tangential to the cut in the ingot 14 as the wire 102 is driven by the wire drive mechanism 106
• the apparatus 100 also includes a wire advancing mechanism 30 as in the first embodiment 10 to which, in the second embodiment 100 illustrated in Figs 6A and 6B, the wire drive mechanism 106 is mounted
• the wire advancing mechanism 30 acts as a radially move the frame 113 for the wire drive mechanism 106 and is itself fastened to the rotating annular support disk 118
• the wire advancing mechanism 30 functions to advance wire drive mechanism 106, and thus the moving wire 102, from an initial position, as is shown in Fig 6B, proximate to the outer diameter ("OD") of the ingot 14, through an intermediate position as shown in Fig 6A, towards a final position proximate the inner diameter ("ID”) of the ingot 14 to effectuate completion of a single cut while the saw rotation system 114 continuously rotates the entire wire advancing mechanism 30 and the wire drive mechanism 106 around the ingot 14 via the motor 120
• the wire 102 reaches the inner diameter or center longitudinal axis of the ingot 14, the ingot 14 is severed and the motion of the wire advancing mechanism
• the saw rotation system 114 may be reciprocally driven back and forth through a set or variable arc rather than continuously as above described
• the wire saw 102 cuts a curved cut with the wire saw 102 substantially tangent to the curve throughout the cut through the diameter of the ingot 14
• the wire saw 102 is advanced entirely through the ingot 14 in this alternative
• the arc angle or arc length of the reciprocal rotation may be varied in a predetermined manner throughout the cut
• the arc angle in each direction may be small at the beginning and end of the cut through the diameter of the ingot 14 and larger, e g about 45 degrees toward the middle of the cut through the ingot 14
• the purpose of the rotation however remains the same That is to maintain the wire saw substantially tangent to the cut This minimizes the side forces on the wire saw caused by imperfections or undulations in and on the outer surface of the ingot 14
• the speed imparted to the wire 102 by the wire driving mechanism 106, the saw rotation speed imparted by the saw rotation mechanism 114 and the radial inward advance of the wire 102 into the ingot 14 due to the wire advancing mechanism 30 all must be accurately controlled Functionally, it is most desirable that the surface speed of the wire 102 with respect to the material of the ingot 14 be held relatively constant Therefore, as in the first embodiment, the relative speed of the wire 102 with respect to the ingot 14 has to be reduced as the cut proceeds from the ingot 14 OD to its center or ID to keep the surface rate substantially constant As in the first embodiment, the cutting pressure of the wire 102 is determined by the wire advancing mechanism 30
• the two embodiments 10 and 100 described and shown function very similarly from the perspective of the ingot 14
• the wire 12 and 102 moves around the circumference of the ingot 14, either continuously or reciprocally, while at the same time cutting tangentially into the ingot 14 orthogonally to the longitudinal axis of the ingot
• This relative motion between the saw wire and the ingot 14 results in an extremely narrow cut and uniform kerf being maintained in the ingot during the cut Reciprocal rotation minimizes the effects on the wire of variations in the outer ingot surface shape
• Continuous rotation minimizes the depth of cut required to sever the ends of the ingot and/or wafers from the ingot

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• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• Processing Of Stones Or Stones Resemblance Materials (AREA)
• Mechanical Treatment Of Semiconductor (AREA)

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• 1998
  • 1998-07-06 EP EP98933215A patent/EP1009569A2/de not_active Withdrawn
  • 1998-07-06 JP JP2000501861A patent/JP2001510742A/ja not_active Withdrawn
  • 1998-07-06 WO PCT/US1998/014040 patent/WO1999002295A2/en not_active Application Discontinuation
  • 1998-07-06 KR KR1020007000097A patent/KR20010021539A/ko not_active Application Discontinuation

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