JP2015076516A - Dicing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a dicing device capable of improving workability by reducing the running-in time of a spindle.SOLUTION: A temperature of a shaft 37 of a spindle 12 is monitored using temperature sensors 43a-43d. A control unit 27 stores and maps in advance a processing position deviation of the spindle 12 on the basis of the monitored temperature of the shaft 37. In a cutting and dividing work of a workpiece, the processing position deviation or the like of the spindle 12 is known from the temperature obtained by the monitoring and the mapped data. A running-in time of the spindle 12 is reduced by correcting at least one of a feed of a spindle transfer mechanism 44 and a feed of a work table feed mechanism 45.

Description

  The present invention relates to a dicing apparatus, and more particularly to a dicing apparatus that cuts and divides a workpiece such as a semiconductor wafer into chips.

  Conventionally, a dicing apparatus is used to cut and divide a workpiece such as a semiconductor wafer or electronic component material into individual chips. The dicing apparatus includes a work table on which a work is placed, a blade for cutting the work, a work table feeding mechanism for moving the work relative to the blade, and a spindle on which the blade is rotatably attached. And a spindle moving mechanism for movably supporting the spindle, rotating the blade together with the spindle shaft, simultaneously moving the spindle moving mechanism and the work table feeding mechanism, and supplying cutting water to the blade While being blown and cooled, it is cut and divided (Patent Document 1).

  By the way, in recent years, there are many semiconductor wafers with narrow streets, and there are cases where chips become defective even if the processing position is shifted by several μm.

In this type of semiconductor wafer cutting and dividing operation, it takes about 7.5 minutes, for example, as shown in FIG. 5 until the spindle displacement is stabilized after the spindle starts rotating. In FIG. 5, the vertical axis indicates the amount of displacement (μm) of the spindle, the horizontal axis indicates time (S), and the symbol SP indicates the displacement curve of the spindle.

Further, in the cutting and dividing operation on the semiconductor wafer, the cutting and dividing are performed while spraying cutting water on the blade and cooling, but before the temperature of the spindle shaft and the cutting water is stabilized, for example, as shown in FIG. It takes about a minute. In FIG. 6, the vertical axis represents temperature (° C.), the horizontal axis represents time (min), the symbol SP represents the spindle temperature curve, and C represents the cutting water temperature curve. That is, in FIG. 6, the temperature of the spindle SP is about 24.5 ° C. before the cutting water C is sprayed, decreases to about 21 ° C. when the cutting water C is sprayed, and about 21.5 after about 20 minutes. Can settle to ℃.

JP2003-163179A.

  As described above, in cutting and dividing work on semiconductor wafers, when processing a workpiece with a blade attached to the spindle shaft, the spindle (mainly the blade attachment) It is known that a change in temperature occurs in the part), and the processing position shifts due to the change in temperature. In addition, when the cutting line meanders (displacement of machining position) due to temperature change, the load on the spindle side increases accordingly, which becomes a source of vibration at the machining point. This vibration reduces processing accuracy. For this reason, a break-in time of about 30 minutes is required until the positional deviation at the machining point position is stabilized, and then the workpiece is actually machined, resulting in poor workability.

  Therefore, there is a technical problem to be solved in order to provide a dicing apparatus capable of improving workability by reducing the spindle break-in time, and the present invention aims to solve this problem. And

  The present invention has been proposed in order to achieve the above object, and the invention according to claim 1 includes a work table on which a work is placed, a blade for cutting the work, and a work on the work table. A work table feed mechanism that moves relative to the blade, a spindle on which the blade is rotatably mounted, a spindle movement mechanism that supports the spindle, a feed of the spindle movement mechanism, and a feed of the work table feed mechanism A controller for controlling the temperature of the spindle, and a temperature sensor for monitoring the temperature of the shaft of the spindle, and a feed of the spindle moving mechanism provided on the controller based on the temperature monitored by the temperature sensor. At least the feed of the work table feed mechanism And a control unit for applying a correction to the deviation or the other of the feed, and to provide a dicing apparatus.

  According to this configuration, the temperature of the shaft of the spindle is monitored by the temperature sensor, and the control unit stores in advance the positional deviation of the spindle based on the temperature of the shaft monitored by the temperature sensor and maps this, for example, in a map. . In the work cutting and dividing work, the position deviation of the spindle is known from the temperature obtained by monitoring and the mapped data, and at least one of feeding by the spindle moving mechanism and feeding by the work table feeding mechanism is used. Work while making corrections. As a result, even if the spindle break-in time is omitted, cutting division with good cutting quality can be performed, which contributes to improvement in workability and cutting quality. The feed correction may be either or both of feed on the spindle moving mechanism side and feed on the work table feed mechanism side.

  According to a second aspect of the present invention, in the dicing apparatus according to the first aspect, the spindle includes a cylindrical housing, a rotor and a stator, and the rotor is disposed at one end of the shaft. A motor that is attached so as to be integrally rotatable, the stator being fixedly attached to the housing side, and a fluid bearing mechanism that generates a fluid bearing that rotatably holds the shaft in a non-contact manner in the housing, A dicing apparatus is provided in which the blade is attached to the other end of the shaft that protrudes outward from the housing.

  According to this configuration, the shaft of the spindle is rotatably supported in a non-contact manner by the fluid bearing generated by the fluid bearing mechanism. Therefore, the vibration of the shaft is suppressed by the fluid bearing, which can further contribute to the improvement of the cutting quality.

  According to a third aspect of the present invention, in the dicing apparatus according to the first or second aspect, the shaft of the spindle is formed in a hollow shape, and a plurality of the temperature sensors are accommodated in an elongated cylindrical member. A dicing apparatus is provided which is disposed in the hollow of the shaft together with the cylindrical member.

  According to this structure, a plurality of temperature sensors can be accommodated in the elongated cylindrical member and can be compactly arranged in the hollow of the shaft. Further, by making the spindle shaft hollow, the mass is reduced and the natural frequency can be increased. Thereby, the resonance region can be shifted to a higher rotational speed than the use region (for example, a maximum of 80,000 rpm), so that an effect of reducing vibration generation can be obtained.

  According to a fourth aspect of the present invention, there is provided the dicing apparatus according to the third aspect, wherein the temperature sensor is at least the other end of the shaft close to a machining position where the blade is attached in the hollow of the shaft. Provided is a dicing apparatus which is arranged at a position on the side and a position close to a position where the rotor is attached.

  According to this configuration, based on the temperature information at the position on the other end side of the shaft close to the machining position where the blade is attached, and the temperature information at the position on the shaft near the position where the rotor is attached, with a large temperature change, By correcting both or one of the feed by the spindle movement mechanism and the feed by the work table feed mechanism, cutting division with good cutting quality can be performed even if the spindle break-in time is omitted, improving workability and cutting. It can contribute to quality improvement.

  According to the present invention, the control unit knows the positional deviation of the spindle from the temperature obtained by monitoring and the mapped data, for example, and at least one of feeding by the spindle moving mechanism and feeding by the work table feeding mechanism Therefore, even if the spindle break-in time is omitted, cutting division with good cutting quality can be performed, and improvement in workability and cutting quality can be expected.

The perspective view explaining the layout of the dicing apparatus shown as one embodiment of the present invention. Explanatory drawing which shows the spindle in a dicing apparatus same as the above in the horizontal direction (axial direction). Explanatory drawing which shows the spindle in a dicing apparatus same as the above in the cross-section in the vertical direction (the figure corresponding to the AA line sectional view of FIG. 2). The block diagram explaining the structure of the controller in a dicing apparatus same as the above. The figure explaining the displacement characteristic of a spindle. The figure explaining the temperature characteristic of a spindle and cutting water.

  In order to achieve the object of the present invention to provide a dicing apparatus capable of improving workability by reducing the spindle break-in time, a work table on which a work is placed, a blade for cutting the work, A work table feed mechanism for moving a work on the work table relative to the blade; a spindle on which the blade is rotatably attached; a spindle moving mechanism for supporting the spindle; and a feed of the spindle moving mechanism And a controller for controlling the feed of the worktable feed mechanism, a temperature sensor for monitoring the temperature of the spindle shaft, and a temperature sensor provided in the controller and based on the temperature monitored by the temperature sensor Feed by the spindle moving mechanism The feed according to the work table feed mechanism was achieved by providing a control unit for applying a correction to at least one of the feed.

  Hereinafter, preferred examples of the dicing apparatus according to the embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3.

  FIG. 1 is a perspective view showing a main part layout of the dicing apparatus according to the present embodiment. A dicing apparatus 11 shown in the figure is a dicing apparatus for cutting and dividing a semiconductor wafer in this embodiment. The dicing apparatus 11 includes a spindle 12 disposed opposite to each other, a work table 13 that sucks and holds a workpiece W (not shown) (semiconductor wafer in the present embodiment), a microscope that images the workpiece W, a CCD camera, and the like. A processing unit 14 having imaging means (not shown) is provided. Although not shown in the drawing, the dicing apparatus 11 includes, in addition to the processing unit 14, a cleaning unit that spin-cleans the processed workpiece W processed by the processing unit 14 and a large number of workpieces W mounted on the frame. It is composed of a load port on which the stored cassette is placed, a transport means for transporting the workpiece W, a controller 15 (see FIG. 2) for controlling the operation of each part, and the like. These basic configurations are the same as those of the conventional dicing apparatus.

  The processing unit 14 has an X table 16 driven in the X direction indicated by XX in the figure by a linear motor or servo motor (not shown) and a ball screw, and the X table 16 has a rotary table 22 that rotates in the θ direction. The work table 13 is provided via the.

  On the other hand, Y tables 19 and 19 are provided on the side surface of the Y base 17 and are guided by a Y guide 18 and driven in a Y direction indicated by YY in the figure by a stepping motor or servo motor (not shown) and a ball screw. Yes. Each Y table 19 is provided with a Z table 20 driven in the Z direction indicated by ZZ in the drawing by a driving means (not shown), and the Z table 20 is a built-in high-frequency motor with a blade 21 attached to the tip. The spindle 12 is fixed.

  Since the structure of the processing unit 14 is as described above, the blade 21 is index-fed in the Y direction and cut and fed in the Z direction, and the work table 13 is cut and fed in the X direction.

  Both of the spindles 12 are rotated at a high speed of 1,000 rpm to 80,000 rpm, and in the vicinity, cutting water C for immersing the workpiece W in the cutting water C is sprayed and supplied to the blade 21 disposed at the processing position. A supply nozzle (not shown) is provided.

  The blade 21 may be an electrodeposition blade in which diamond abrasive grains or CBN abrasive grains are electrodeposited with nickel, or a metal resin bond blade bonded with a resin mixed with metal powder. The dimensions of the blade 21 are variously selected depending on the processing contents. When dicing a normal semiconductor wafer as a workpiece, a blade having a diameter of 50 to 60 mm and a thickness of about 30 μm is used.

  The controller 15 that controls the operation of each part of the dicing apparatus 11 is configured as shown in FIG. 4, for example. As shown in FIG. 4, the controller 15 includes a CPU 23, a storage unit 24, a data input / output unit 25, a program generation unit 26, a control unit 27, and the like, which are connected by a bus line 28.

  The control unit 27 includes a spindle control unit 29 for controlling the feed of the spindle moving mechanism 44, an X control unit 30, a Y control unit 31, and a Z control unit for controlling the feed by the work table feed mechanism 45. 32, θ control means 33 and the like. The temperature sensors 43a to 43d connected to the control unit 27 are temperature sensors described later.

The CPU 23 performs a central processing function of the controller 15 and performs various processes. The storage means 24 is, for example, the spindle SP shown in FIG.
) And the time-displacement characteristics, and the time-temperature characteristics of the cutting water C and the spindle SP shown in FIG. 6 are stored. The data input / output unit 25 inputs data from the outside and transmits the data to the outside. The program generation means 26 creates a machining program including various data of time-displacement characteristics of the spindle SP and time-temperature characteristics of the cutting water C and the spindle SP. The controller 27 controls the operation of each part of the dicing apparatus 11 via the spindle controller 29, X controller 30, Y controller 31, Z controller 32, θ controller 33, temperature sensors 43a to 43d, and the like. Control.

  FIG. 2 is a view showing the spindle 12 as a cross section in the horizontal direction (axial direction), and FIG. 3 is a view corresponding to the cross section taken along the line AA of FIG. is there. In FIG. 2, hatching of the cross section of each member is omitted. In FIG. 2, the spindle 12 includes a housing 34, a bearing member 35, a motor 36, a shaft 37, a fluid bearing mechanism 39, and the like.

  The housing 34 is formed as a cylindrical body having both ends opened, and a shaft 37 is rotatably accommodated in the housing 34 as shown in FIG. The other end 37b of the shaft 37 protrudes from the other end of the housing 34 to the outside, and the blade 21 is attached to the other end 37b of the shaft 37 protruding from the housing 34 so as to rotate integrally. .

The motor 36 is provided on the one end 37 a (adjacent to the bearing member 35) side of the shaft 37 in the housing 34, and the shaft 37 is disposed on the outer peripheral surface of the shaft 37.
And a stator 36b attached to the inner peripheral surface of the housing 34 so as to face the rotor 36a. When a current is supplied to an armature coil (not shown) of the stator 36b, the motor 36 is excited to rotate the rotor 36a integrally with the shaft 37. Yes.

  The shaft 37 has an opening on the end surface on the one end portion 37a side, and is continuously formed along the axial center line O of the shaft 37 from the one end portion 37a to the other end portion 37b side. The center hole 41 is formed.

  Further, as shown in FIG. 2, between the other end portion 37b of the shaft 37 and the rotor 36a of the motor 36, the inner peripheral surface of the housing 34 has an outer peripheral surface of the shaft 37 as shown in FIG. The hydrodynamic bearing mechanism 39 is disposed in a state where a slight gap 42 is formed between the hydrodynamic bearing mechanism 39 and the hydrodynamic bearing mechanism 39. Air is blown into the gap 42 from the air injection nozzle 39a of the fluid bearing mechanism 39, and a fluid bearing is generated by the air. Therefore, the shaft 37 is rotatably supported by the fluid bearing in a non-contact state. This fluid dynamic bearing is a well-known technique.

  The temperature sensor member 40 includes a plurality (four in this embodiment) of the temperature sensors 43a, 43b, 43c, and 43d in an elongated cylindrical member 40a having a diameter of about 3 to 4 mm. The temperature sensor member 40 is inserted and disposed in the center hole 41 formed at the shaft center of the shaft 37 in a state where one end side is rotatably held by the bearing member 35. Further, a rotary contact 46 divided into a plurality of parts is provided on the outer peripheral surface on one end side of the cylindrical member 40a. The rotary contacts 46 are electrically connected to the corresponding temperature sensors 43a to 43, respectively. The rotary contact 46 is in contact with the tip of an energizing brush 47 attached to the bearing member 35. And the temperature information monitored by each temperature sensor 43a-43d is taken out from the one end side of the cylindrical member 40a through the rotary contact 46 and the electricity supply brush 47, and is input into the control part 27 of the said controller 15. Yes. 2, among the four temperature sensors 43a to 43d, the temperature sensor 43a is the closest position of the blade 21 on the other end 37b side of the shaft 37 to which the blade 21 is attached, that is, machining. The ambient temperature in the vicinity of the machining position of the shaft 37 that is arranged near the point position and changes due to the supply of the cutting water C is monitored. The temperature sensor 43d is disposed on the one end 37a side of the shaft 37 to which the rotor 36a of the motor 36 is attached, at a position close to the position where the rotor 36a is attached, and the shaft changes due to the heat generated by the motor 36. Monitor 37 ambient temperature. The temperature sensors 43b and 43c monitor the temperature at each location of the shaft 37 between the temperature sensor 43a and the temperature sensor 43d.

  Next, the operation of the processing unit of the dicing apparatus 11 configured as described above will be described. In addition, since the operation | movement of the whole dicing apparatus 11 is known, description is abbreviate | omitted. Prior to machining, the operator inputs the workpiece type, workpiece size, machining depth, index size, spindle rotation speed, grinding feed rate, and other machining conditions, alignment conditions, and the like from the operation / display unit.

  In the controller 15 of the dicing apparatus 11, a machining program is generated by the program generation means 26 from the input machining conditions. At the same time, the controller 27 detects the temperature of the shaft 37 of the spindle 12 from the information obtained from the temperature sensors 43a to 43d, and this is detected by the time-displacement characteristics of the spindle stored in the storage means 24 and the cutting water. The processing point position shift due to temperature rise is estimated in correspondence with various data maps such as time-temperature characteristics in the spindle and cutting is performed while correcting the feed in the spindle movement control means 29 and the feed on the work table feed mechanism side. Split work. As a result, even if the running-in time of the spindle 12 that has conventionally required about 20 minutes is omitted or shortened, cutting division with good cutting quality can be performed, which contributes to improvement in workability and cutting quality.

  Further, in the dicing apparatus 11 of the present embodiment, the spindle 12 includes a cylindrical housing 34, a rotor 36a, and a stator 36b, and the rotor 36a can be rotated integrally with the one end 37a side of the shaft 37. A motor 36 having a stator 36b fixed to the housing 34 side, and a fluid bearing mechanism 39 for generating a fluid bearing that rotatably holds the shaft 37 in the housing 34 without contact; The blade 21 is attached to the other end portion 37b side of the shaft 37 protruding outward from the other end portion side. Since the shaft 37 of the spindle 12 is rotatably supported by the fluid bearing generated by the fluid bearing mechanism 39 in a non-contact manner, the vibration of the shaft 37 is suppressed by the fluid bearing, and the cutting quality is further improved. Can contribute.

Further, in the dicing apparatus 11 of the present embodiment, the shaft 37 of the spindle 12 is formed in a hollow shape, and the temperature sensors 43a to 43d are accommodated in an elongated cylindrical member 40a, and the shaft 37 is hollow together with the cylindrical member 40a. Since it arrange | positions in the inside (center hole 41), the temperature sensors 43a-43d can be arrange | positioned in the hollow of the shaft 37 compactly. Furthermore, by making the shaft 37 of the spindle 12 hollow, the mass of the shaft 37 can be reduced and the natural frequency can be increased. As a result, the resonance area is changed to the use area (for example, 80,000 rp at maximum
Since the rotational speed can be shifted to a value higher than m), an effect of reducing the generation of vibrations can be obtained.

  Moreover, in the dicing apparatus 11 of the present embodiment, among the temperature sensors 43a to 43d, the temperature sensor 43a is disposed at a position on the other end 37b side of the shaft 37 close to the machining position where the blade 21 is attached, and the temperature sensor 43d. Is disposed at a position on the shaft 37 close to the position where the rotor 36a of the motor 36 is attached. Therefore, the temperature information on the processing position side where the blade 21 is attached and the temperature information at a position close to the motor 36 with a large temperature change. Based on the above, it is possible to correct the feed by the spindle moving mechanism and the feed by the work table feed mechanism. As a result, the cutting line can be prevented from meandering (machining position shift) due to a temperature change, and accordingly, the load received on the spindle 12 side can be reduced to suppress the generation of vibrations and improve the machining accuracy. .

In addition, in the present Example, the structure comprised so that the cylindrical member 40a of the temperature sensor member 40 was rotatably supported by the bearing member 35, and rotated integrally with the shaft 37 was disclosed. However, when the cylindrical member 40a in which the temperature sensors 43a to 43d are disposed is rotated integrally with the shaft 37, there may be an unbalance in the rotation. In such a case, one end of the cylindrical member 40a is fixed to the housing 34 side, and the cylindrical member 40a is disposed in the center hole 41 of the shaft 37 in a state of being fixed in a cantilever manner, and only the shaft 37 is rotated. The tubular member 40a may be structured not to rotate .

  The present invention can be further modified in various ways without departing from the spirit of the present invention, and the present invention naturally extends to the modified ones.

  Although the present invention has been described with respect to a dicing apparatus used for cutting and dividing work on a semiconductor wafer, it can also be applied to a dicing apparatus that cuts and divides a work such as electronic component material other than a semiconductor wafer into individual chips.

11 Dicing device 12 Spindle 13 Work table 14 Processing unit 15 Controller 16 X table 17 Y base 18 X guide 19 Y table 20 Z table 21 Blade 22 Rotating table 23 CPU
24 storage means 25 data input / output section 26 program generation means 27 control section 28 bus line 29 spindle control means 30 X control means 31 Y control means 32 Z control means 33 θ control means 34 housing 35 bearing member 36 motor 36a rotor 36b stator 37 Shafts 37a, 37b End 38 End lid 39 Fluid bearing mechanism 39a Air injection nozzle 40 Temperature sensor member 40a Cylindrical member 41 Center hole 42 Clearance 43a-43d Temperature sensor 44 Spindle moving mechanism 45 Worktable feed mechanism 46 Rotary contact 47 Energizing brush W Work SP Spindle C Cutting water

Claims (4)

A work table on which a work is placed;
A blade for cutting the workpiece;
A work table feed mechanism for moving a work on the work table relative to the blade;
A spindle on which the blade is rotatably mounted;
A spindle moving mechanism for supporting the spindle;
A controller for controlling the feed of the spindle movement mechanism and the feed of the work table feed mechanism;
In a dicing apparatus comprising:
A temperature sensor for monitoring the temperature of the shaft of the spindle;
A controller that is provided in the controller and corrects at least one of the feed of the spindle movement mechanism and the feed of the work table feed mechanism based on the temperature monitored by the temperature sensor;
A dicing apparatus comprising: The spindle is
A housing formed in a cylindrical shape;
A motor having a rotor and a stator, the rotor being attached to one end side of the shaft so as to be integrally rotatable, and the stator being fixedly attached to the housing side;
A fluid bearing mechanism for generating a fluid bearing that rotatably holds the shaft in a non-contact manner in the housing;
The dicing apparatus according to claim 1, wherein the blade is attached to the other end side of the shaft that protrudes outside from the housing. The shaft of the spindle is formed in a hollow shape,
A plurality of the temperature sensors are accommodated in an elongated cylindrical member, and are disposed in the hollow of the shaft together with the cylindrical member.
The dicing apparatus according to claim 1 or 2, wherein   In the hollow of the shaft, the temperature sensor is disposed at least at a position on the other end side of the shaft close to a processing position where the blade is attached and a position close to a position where the rotor is attached. The dicing apparatus according to claim 3.

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