JP2007030167A - Workpiece mounting member - Google Patents

Abstract

Provided is an object mounting member for use in a compact and simple polishing apparatus in which an object to be polished and a polishing surface plate are not easily damaged even if the polishing surface plate is uneven, and the state of the polishing surface is good.
An object attachment member 40 is attached to a polishing jig disposed on a polishing surface plate and attaches an object 3 to be polished on the polishing surface plate, and is rotated on the polishing jig. A first attachment member that is attached via a shaft and that rotates the workpiece 3 relative to the polishing surface plate to adjust the left / right inclination, and is fixed to the first attachment member, and is attached to the polishing surface plate. On the other hand, the object to be polished 3 includes a second mounting member having a function of bending so that the center portion protrudes or both end portions protrude.
[Selection] Figure 6

Description

  The present invention relates to an improvement of a workpiece attaching member used by being attached to a polishing jig used in a polishing apparatus for polishing ultra-precise processed parts.

  Conventionally, an ultra-precision machined part such as a magnetic head requires a good machined surface with very few scratches such as a final finishing process of the medium facing surface of the magnetic head. For this reason, the medium facing surface of the magnetic head is finally called a lapping device using industrial diamond having a particle size (1 μm or less) close to the minimum that can be industrially produced as abrasive powder (abrasive particles). Polishing is performed by a polishing apparatus. In addition, in the case of a magnetoresistive head (MR head), which is often used for a head of a hard disk device in particular, finishing is performed with a bar state in which several heads are aligned with an accuracy of an element height of ± 0.2 μm or less. To improve productivity.

In such a component polishing process, the following is desired.
(A) Stabilization of MR element height (b) Elimination of scratches and the like, stabilization of machining quality (c) Improvement of work efficiency (reduction of preparation time other than machining time)

  In general, as shown in FIG. 1, the MR head 2 is formed on a wafer 1 together with terminals and a recording head portion by thin film technology, and then cut into a plurality of bars 3. The bar 3 is polished by a polishing apparatus and then processed into a slider shape to become a head 4. The head 4 is attached to the tip of the arm 6 of the head actuator 5.

  As shown in FIG. 2, an ELG (Electric lapping guide) type polishing apparatus 10 that has been commercially available on the market is provided on the polishing platen 11 of the apparatus main body 10 a on the polishing platen 11 from the inner periphery to the outer periphery. An oscillating type polishing jig 12 is provided. The bar 3 described with reference to FIG. 1 is attached to the lower surface of the polishing surface plate 11, and slurry containing abrasive powder made of industrial diamond is supplied from the slurry supply device 13 onto the rotating polishing surface plate 11. The In this state, the bar 3 is polished by swinging the polishing jig 12. 14 is a rocking rotation center of the polishing jig 12, 15 is a rocking mechanism, 17 is a correction ring, and 19 is a flattening mechanism (facing device) for flattening the upper surface of the polishing surface plate 11.

  Such a polishing jig 12 is provided with a correction mechanism 16 that corrects the difference between the left and right polishing amounts of the bar 3, for example, a mechanism that presses to the left and right and the center. A correction mechanism 16 for correcting is provided. The correction mechanism 16 is connected to a control device 18 using a computer, and the correction mechanism 16 is operated by a correction signal from the control device 18. Although not shown, a piezoelectric element is arranged on a transfer jig (abrasive object mounting member) to which the bar 3 is attached, and the piezoelectric element is energized from the control device 18 to correct the warping of the bar 3. In some cases, a mechanism such as

However, when the bar 3 of the MR head is polished by a conventional polishing apparatus having a swinging mechanism, there are the following problems.
(1) The surface of the bar 3 may be faithfully transferred to the unevenness in the circumferential direction on the upper surface of the polishing surface plate 11, and the unevenness is generated on the surface of the bar 3. This problem occurs particularly when the polishing platen 11 is stopped, and in order to improve the flatness of the bar 3 to be polished, the upper surface of the polishing platen 11 must be flattened with an extremely high precision. There is a problem that the cost of the supporting mechanism (facing device) increases.

(2) Since the polishing jig 12 is of a swinging type, a moment is applied to the end face of the bar 3 when the swinging direction is changed after the bar 3 has moved to the innermost or outermost periphery of the polishing surface plate 11. The end surface of the bar 3 or the polishing surface plate 11 is easily damaged.
Therefore, the object of the present invention is to eliminate the problems of the conventional polishing apparatus, and even if there are irregularities in the circumferential direction of the upper surface of the polishing surface plate 11, there is no fear that the irregularities are transferred to the surface of the bar 3. In addition, there is provided an object attachment member to be attached to a polishing jig used in a polishing apparatus in which a moment is not applied to the end face of the bar 3 during polishing and the bar 3 and the polishing surface plate 11 are hardly damaged. is there.

  A first form of the workpiece mounting member of the present invention that achieves the above object is mounted on a polishing jig disposed on a polishing surface plate, for mounting an object to be polished on the polishing surface plate. A first attachment member that is attached to a polishing jig via a rotating shaft and adjusts the right and left inclination by rotating the object to be polished with respect to the polishing surface plate, It is fixed to the first mounting member, and has a function of bending the object to be polished with respect to the polishing surface plate so that the center part protrudes or both end parts protrude.

  In addition, a second form of the workpiece mounting member of the present invention that achieves the above object is mounted on a polishing jig disposed on a polishing surface plate and mounts an object to be polished on the polishing surface plate. An attachment member body having a bottom surface for attaching an object to be polished, and provided in a central portion of the attachment member body and rotating to rotate the attachment member body with respect to a polishing jig A tilt adjustment mechanism is provided that rotates the mounting member main body around the mechanism and the rotation mechanism to adjust the left and right tilt of the object to be polished with respect to the polishing surface plate.

  Furthermore, the third form of the object mounting member of the present invention that achieves the above object is mounted on a polishing jig disposed on a polishing surface plate, and attaches an object to be polished on the polishing surface plate. An upper frame made of a material that expands and contracts by heating and cooling, an upper frame, a lower frame to which the object is attached to the lower surface, and a rectangular frame portion having left and right side frames, an upper frame Two oblique frame portions that connect the both ends of the frame and the midpoint of the lower frame, a center frame that connects the midpoint of the upper frame and the midpoint of the lower frame, and includes means for attaching to the polishing jig A fixed heater, a first heater provided adjacent to the upper frame, and a second heater provided adjacent to each of the two oblique frame parts. Current flow Accordingly, the both ends of the lower frame are curved so as to protrude toward the polishing surface plate, and the center portion of the lower frame is curved so as to protrude toward the polishing surface plate according to the energization amount to the second heater. It is a workpiece attachment member to be polished.

  Furthermore, a fourth embodiment of the workpiece mounting member of the present invention that achieves the above object is a polishing object mounted on a polishing surface plate and polished on the polishing surface plate. A workpiece mounting member for mounting, which is made of a member that expands and contracts by heating and cooling, and has an upper frame, a lower frame to which the workpiece is mounted on the lower surface, and a rectangular frame having left and right side frames, and a side frame The upper frame and the lower frame are connected in parallel to each other, and at least three intermediate frames provided between the side frames are connected to the upper frame in a space between the two intermediate frames, to the polishing jig. The fixing portion provided with the attachment means, the side frame, and the intermediate frame are provided adjacent to each other, and each frame is provided with a heater that can be heated independently. Depending on the power supply amount to, it is characterized by a workpiece mounting member the height from the polishing table can be partially modified in the lower frame.

  In this way, in the present invention, a polishing jig that can be rotated on the polishing apparatus is newly created, and the polishing jig is rotated on the polishing platen. A driving signal for the mechanism and the polishing position signal are supplied to the rotating unit via a slip ring or the like. The left / right difference correction mechanism for the object to be polished is configured by rotatably attaching the second attachment member to the first attachment member of the polishing jig. Torque is applied, and the left and right polishing ratios are adjusted.

The warpage correction mechanism includes a frame structure in which the height of the mounting surface of the object to be polished from the polishing surface plate can be partially changed by heat inside the second mounting member made of the same member. By adjusting the heat applied to the frame structure, the mounting surface of the object to be polished can be deformed in the direction opposite to the direction of warping of the object to be polished, and flat polishing is performed while suppressing the warping of the object to be polished. be able to.
With such a configuration, a right / left difference correction mechanism and a warpage correction mechanism for a member to be polished can be formed with a compact structure. Furthermore, by having the correction mechanism in the rotary jig structure, a polishing apparatus that is compact and has a high flatness of the polished object can be obtained.

  According to the polishing apparatus that uses the workpiece mounting member of the present invention mounted on a polishing jig, an automatic correction polishing system that is compact and simple and has a good polished surface state can be achieved. A polishing system using a polishing apparatus that uses the workpiece mounting member of the present invention mounted on a polishing jig is particularly suitable for controlling the MR height of an MR magnetic head.

Embodiments of the present invention will be described below in detail based on specific examples with reference to the accompanying drawings.
FIG. 3 shows a configuration of an embodiment of the polishing apparatus 20 according to the present invention, and the same reference numerals are given to the same components as those of the conventional polishing apparatus 10 described in FIG.

  Also in the polishing apparatus 20 of this embodiment, a polishing surface plate 11 that is rotated at a constant speed in one direction by a motor (not shown) below the apparatus body 10a is provided on the upper surface of the apparatus body 10a. On the polishing surface plate 11, a correction ring 17 for flattening the surface of the surface plate and a flattening mechanism (facing device) 19 for flattening the upper surface of the polishing surface plate 11 are provided. The polishing surface plate 11 is configured by laminating or bonding 10 to 30 mm of a metal layer such as tin or copper on a surface plate (base) such as stainless steel or cast iron. A slurry containing abrasive powder made of industrial diamond is supplied onto the polishing surface plate 11 from the slurry supply device 13.

  On the other hand, the polishing jig 21 of this embodiment arranged on the polishing platen 11 of the polishing apparatus 20 is composed of a base 22 and an arm 23. On the arm 23, a polishing head 30 and a fixed head are fixed. There is a motor 24 that rotates at a rotational speed. The polishing head 30 rotates about a rotation shaft, and a slip ring 25 as an electrical connection means is attached to the upper portion of the rotation shaft. The polishing head 30 is connected to the control device 18 via the slip ring 25 and the connection cord 26, and a signal taken out from the polishing head 30 is input to the control device 18 and a control signal from the control device 18 is polished. It is transmitted to the head 30.

  The arm 23 of the polishing jig 21 may be fixed to the base 22, but the base 22 is provided with a swing mechanism to swing the arm 23 on the polishing surface plate 11 to polish the polishing head 30. The platen 11 can be moved from the inner periphery to the outer periphery. In this case, since the polishing surface of the polishing surface plate 11 is not used with a bias, the life of the polishing surface plate 11 is extended.

  FIG. 4 shows the configuration of the arm 23 of the polishing jig 21 shown in FIG. The arm 23 is disposed on the polishing surface plate 11 that is rotated by the spindle motor 11a. Provided on the arm 23 attached to the base 22 are a motor 24 for forcibly rotating the polishing head 30 and a bearing case 27 in which a bearing for supporting the rotating shaft 31 of the polishing head 30 is built. It has been. A pulley 32 is attached to the lower side of the arm 23 of the rotating shaft 31. A pulley 28 is also attached to the rotating shaft 24 a of the motor 24, and a belt 29 is stretched between the pulley 28 and the pulley 32. Accordingly, when the motor 24 rotates, the rotating shaft 31 is rotated by the belt 29 that is stretched between the pulley 28 and the pulley 32.

  Further, the rotating shaft 31 can be rotated via a bearing in the bearing case 27 and can be moved up and down by a certain distance. And the recessed part 23a for accommodating the pulley 32 is provided in the lower surface of the arm 23 which the rotating shaft 31 penetrates so that the rotating shaft 31 can be pulled up only a fixed distance. Further, the lower end side of the rotating shaft 31 has a pivot shape (described later), whereby the polishing head 30 can be attached to and detached from the rotating shaft 31.

  The polishing head 30 rotated by the rotating shaft 31 has a transfer jig 40 and its mounting member 50 as a workpiece mounting member to which the bar 3 (see FIG. 1) as the workpiece is mounted, and the dummy polished material 7. And its mounting member 70. For example, it is assumed that an MR head is built in the bar 3. A polishing correction mechanism 60 is provided between the mounting member 50 of the transfer jig 40 and the polishing head 30. The height of the polishing surface of the dummy polishing object 7 from the polishing surface plate 11 can be adjusted by a micrometer (not shown) provided on the mounting member 70.

  A signal input to the polishing correction mechanism 60 and a signal from a polishing state detection sensor (described later) provided on the bar 3 are transmitted through the electric wire 8 wired in the hollow portion of the rotating shaft 31 that is hollow. It is guided to a shaft end type slip ring 25 provided on the upper part of the rotating shaft 31 and is connected to a control device (not shown) through a connection cord 26 via the slip ring 25. Here, as described above, since the polishing head 31 is removable from the rotating shaft 31, the connector 9 is provided in the middle of the electric wire 8.

  The slip ring 25 electrically connects the rotating body and the fixed side, and includes a rotating electrode that rotates by being connected to the rotating shaft 31, and a fixed electrode that is electrically connected to the rotating electrode. In this embodiment, the electric wire 8 is connected to the rotating electrode, and the connection cord 26 is connected to the fixed electrode. In this embodiment, the number of poles of the rotating electrode and the fixed electrode in the slip ring 25 must be at least six. Further, the connection between the electric wire 8 and the connection cord 26 is not limited to the shaft end face type slip ring 25, but may be a shaft hollow type slip ring provided on the upper side of the pulley 32, for example.

  The driving power for the polishing correction mechanism 60 and the displacement mechanism of the transfer jig 40 can be supplied via the slip ring 25, and the detected polishing position signal can be transmitted wirelessly to the control device side. Furthermore, for example, a power coupler that transmits a signal between contactless electrodes from one electrode to the other electrode by an induced current can be used facing the upper surface of the rotating shaft 31. Furthermore, the driving power source of the polishing correction mechanism 60 and the displacement mechanism of the transfer jig 40 can be stored on the polishing head 30 as a battery.

In this embodiment, the following signals are extracted from the polishing head 30.
(1) A signal for reading a change in the polishing depth of the bar 3, and a signal for reading a change in the polishing depth at least at three positions of the left and right and the center of the bar 3.
(2) a drive signal to the polishing difference correction mechanism 60 for correcting the horizontal tilt of the bar 3, and
(3) A drive signal to the displacement mechanism that corrects the warping of the bar 3.

  Here, the signal for reading the change in the polishing depth of the bar 3 in (1) can be, for example, a resistance value that increases as polishing progresses by embedding a resistance pattern in the bar 3. And the signal which reads the change of the grinding | polishing depth of the bar 3 of three places is sent to the control apparatus 18 (refer FIG. 3) via the electric wire 8, the slip ring 25, and the connection cord 26. FIG. The control device 18 is composed of, for example, a computer and analyzes the detected polishing position data to detect the difference between the left and right polishing of the bar 3 and the degree of warping of the bar 3. Then, the control device 18 sends a signal for correcting the left and right polishing difference of the bar 3 to the polishing difference correction mechanism 60, and sends a drive signal for instructing warpage correction to the displacement mechanism for correcting the warpage of the bar 3. The

  5A and 5B are a plan view and a side view showing the configuration of the polishing head 30, respectively. The polishing head 30 has a substantially triangular shape in plan view, has a rotation shaft 31 at the center, and is provided with a connector 9 and a hole 33 into which a push rod 28b for pressing the polishing head 30 is inserted at a predetermined position on the upper surface. Yes. One of the three sides of the polishing head 30 is provided with a transfer jig 40 to which the polishing bar 3 is attached and its attachment member 50, and the dummy abrasive 7 and its attachment are attached to the remaining two sides. A member 70 is provided. A polishing correction mechanism 60 is provided between the mounting member 50 of the transfer jig 40 and the polishing head 30. Further, a polishing interruption mechanism 80 for interrupting the polishing of the bar 3 and the dummy polishing article 7 by the polishing head 30 is provided at each vertex portion of the triangular polishing head 30.

  The reason why the polishing head 30 has a triangular shape, the bar 3 is attached to one side thereof, and the dummy polishing object 7 is attached to the other two sides is to stabilize the polishing surface by supporting three points. It is a thing. However, the shape of the polishing head 30 in plan view may not be a triangle, and may be a quadrangle or more. Further, in order to prevent the abrasion of the dummy polished article 7, it is better to make the polishing area of the dummy polished article 7 larger than the polishing area of the bar 3. Further, in order to adjust the height of the polished surface of the dummy polished article 7, a member for adjusting the height of the dummy polished article 7, for example, a micrometer may be provided on the upper surface of the mounting member 70.

  The polishing interruption mechanism 80 includes, for example, a solenoid 81 and a plunger 82 that protrudes and retracts from the solenoid 81. There is a pad 83 at the tip of the plunger 82. The plunger 82 is usually submerged in the solenoid 81, and the height of the pad 83 at the tip of the solenoid 81 at this time from the polishing platen 11 is equal to the polishing platen 11 of the bar 3 and the dummy polishing article 7. It is higher than the height. Therefore, in a normal state, the pad 83 at the tip of the plunger 82 is not polished by the polishing surface plate 11 by the rotation of the polishing head 30. When the solenoid 81 is energized, the plunger 82 protrudes from the solenoid 81, the pad 83 is pressed against the polishing platen 11, and the polishing head 30 is pushed up from the polishing platen 11. In this state, the pad 83 at the tip of the three plungers 82 comes into contact with the polishing surface plate 11, and the bar 3 and the dummy polishing object 7 are not polished by the polishing surface plate 11. The energization of the solenoid 81 is also performed by the control device 18 through the electric wire 8 and the connection cord 26 described above.

Here, the configuration of the first embodiment of the transfer jig 40 and its mounting member 50 and the configuration of the polishing correction mechanism 60 will be described with reference to FIG.
The transfer jig 40 of the first embodiment has a rectangular frame structure of metal or ceramic that is a member that expands and contracts by heating and cooling, and includes an upper frame 41, a lower frame 42 to which the bar 3 is attached to the lower surface, and Left and right side frames 43 are provided. Then, both end portions of the upper frame 41 and the middle point of the lower frame 42 are connected to each other by two oblique frames 44. Further, the center frame 45 connecting the midpoint of the upper frame 41 and the midpoint of the lower frame 42 is separated from the grooves 48 and 49 so as to be along the upper frame 41 and the diagonal frame 44 at a portion sandwiched between the diagonal frames 44. Bulges to the left and right and has an inverted triangular shape.

  Positioning recesses 46 are provided at the left and right ends of the center frame 45, and attachment holes 47 are provided at three locations in the center. Also, the grooves 48 and 49 are provided between the center frame 45, the upper frame 41 and the oblique frame 44, respectively, so that the displacement of the upper frame 41 and the oblique frame 44 is not inhibited by the center frame 45. It is to do. The bar 3 is attached to the lower surface of the lower frame 42 of such a transfer jig 40.

  The mounting member 50 to which the transfer jig 40 of the first embodiment is attached is a rectangular parallelepiped whose outer shape is slightly larger than the transfer jig 40, and a mounting base 51 is provided at a position overlapping the center frame 45 of the transfer jig 40. ing. Positioning pins 52 that are inserted into the positioning recesses 46 of the transfer jig 40 are projected from both ends of the mounting base 51, and mounting holes 53 are formed at positions corresponding to the mounting holes 47 of the transfer jig 40. Is provided. The transfer jig 40 is fixed to the mounting member 50 by passing the screw 39 through the mounting holes 47 and 53 after positioning by inserting the positioning pin 52 into the positioning recess 46.

In the state where the transfer jig 40 of the first embodiment is fixed to the mounting member 50, the bar 3 attached to the lower surface of the lower frame 42 of the transfer jig 40 is as shown in FIG. , Projecting below the bottom surface of the mounting member 50.
Further, in this embodiment, heaters 54 and 55 for heating the upper frame 41 and the oblique frame 44 are provided at a portion of the mounting member 50 facing the upper frame 41 and the oblique frame 44 of the transfer jig 40. ing. Further, a mounting hole 56 is provided in the central portion of the mounting member 50. The mounting member 50 is fixed to the rotary shaft 34 provided on one side surface 30 a of the polishing head 30 by a screw 57 inserted through the mounting hole 56.

  As shown in FIG. 7, the rotation shaft 34 is rotatably supported by a bearing 35 embedded in the polishing head 30. Therefore, the attachment member 50 is attached to the one side surface 30a of the polishing head 30 so as to be rotatable. On the other hand, a pivot 36 is provided between the polishing head 30 and the rotating shaft 31, and the rotating shaft 31 and the rotating head 30 can be separated via the pivot 36. When the rotary head 30 is separated from the rotary shaft 31, the rotary shaft 31 may be lifted by a certain distance. The rotation of the rotary shaft 31 is transmitted to the polishing head 30 by engaging the push rod 28b with the hole 33 of the polishing head 30, as described with reference to FIG. The push rod 28b is fixed to one end of a pulley 32 attached to the rotary shaft 31 via the arm 28a. Accordingly, when the pulley 32 is rotated by the belt 29, the push rod 28b is also rotated, and the polishing head 30 engaged with the rotating push rod 28b through the hole 33 is rotated.

  The polishing correction mechanism 60 corrects the rotation of the mounting member 50 to the left and right. As shown in FIG. 6, the polishing correction mechanism 60 is attached to both sides of a post 61 provided on the upper surface of the attachment member 50, a leaf spring 62 having a base attached to the post 61, and a distal end portion of the leaf spring 62. The iron piece 63, two solenoids 64 provided on the upper surface of the polishing head 30 via a supporter 65, and a stopper 66.

  When the attachment member 50 is attached to the rotary shaft 34 by the screw 57, the iron piece 63 is positioned with a gap G of about 1 mm between the two solenoids 64, as shown in FIG. The stopper 66 is provided to restrict the position of the upper surface of both ends of the mounting member 50. When the mounting member 50 is mounted on the rotating shaft 34, the stopper 66 and the upper surface of the mounting member 50 There is also a predetermined gap between the two. The signal input terminal of the solenoid 64 is connected to the connector 9 shown in FIG.

In the polishing correction mechanism 60, when one of the solenoids 64 is energized, the energized solenoid 64 attracts the iron piece 63. Then, the leaf spring 62 having the iron piece 63 at the tip is warped, and accordingly, a force (torque) for the attachment member 50 to rotate is generated.
FIG. 8 illustrates the operating principle of the polishing correction mechanism 60. When the switch 67 is switched as indicated by a broken line and the battery 68 passes a current through one side of the solenoid 64, the leaf spring 62 bends toward the solenoid 64 that is energized. Due to the bending of the leaf spring 62, the mounting member 50 rotates, and torque is applied to the left or right side thereof. As a result, the pressing force of the bar 3 attached to the bottom surface of the transfer jig 40 on the torque-applied side to the polishing surface plate 11 increases, and on the other hand, the pressing force decreases to change the polishing amount.

The difference between the left and right polishing amounts is given by the following equation.
S = (P + ΔP) × a ÷ (P−ΔP)
Here, 0 <a ≦ 1, P is a polishing pressure when not corrected, K is a constant, S is a right / left ratio of the polishing depth, and ΔP is a change in polishing pressure applied to the left and right portions due to torque application.
Therefore, ΔP needs to be smaller than P, and the larger the ΔP is, the greater the effect of improving the polishing difference between the left and right of the bar 3. If the improvement effect is too great, the time required to improve the left and right polishing difference is too short, and conversely difficult to control. Therefore, in view of the control capability of the control device, it is desirable that the value of S is 2 or more and 5 or less.

Further, in the above embodiment, the polishing correction mechanism 60 is incorporated in the rotatable polishing head 30, but the polishing correction mechanism 60 of this embodiment is attached to a conventional polishing jig that only swings. You can also.
As means for giving displacement to the leaf spring 62, in addition to the solenoid 64, there are displacement means by a linear actuator (automatic micrometer) and electromagnetic solenoid drive. Further, by providing the second stopper 66 for preventing the rotation of the rotatable mounting member 50, it is easy to attach the polishing head 30 to the rotating shaft 31 and to remove the polishing head 30 from the rotating shaft 31. Become.

Next, a correction mechanism when the bar 3 attached to the transfer jig 40 of the first embodiment configured as described above is warped will be described with reference to FIGS. 9 (a) and 9 (b). To do. Here, the total length L of the bar 3 attached to the transfer jig 40 is about 3 to 7 cm.
As described in FIG. 6, the transfer jig 40 includes an upper frame 41, a lower frame 42 to which the bar 3 is attached to the lower surface, left and right side frames 43, both ends of the upper frame 41, and a middle point of the lower frame 42. It consists of two diagonal frames 44 to be connected and an inverted triangular center frame 45 connecting the midpoint of the upper frame 41 and the midpoint of the lower frame 42. Further, only the center frame 45 of the transfer jig 40 is fixed to the mounting member 50, and other parts can be freely deformed. In a state where the transfer jig 40 is fixed to the mounting member 50, the bar 3 attached to the lower surface of the lower frame 42 of the transfer jig 40 protrudes below the bottom surface of the mounting member 50.

  In this embodiment, the transfer jig 40 configured as described above is an integral body made of metal or ceramic. A heater 54 is provided between the upper frame 41 and the attachment member 50, and a heater 55 is provided between the oblique frame 44 and the attachment member 50. For this heater, a linear or planar heating wire is usually used, but other heat sources and cooling means such as Peltier elements may be used.

  First, consider a case where the bar 3 attached to the lower frame 42 has a convex warp upward. In this case, the heater 55 provided between the oblique frame 44 and the mounting member 50 is energized, and the temperature of the heater 55 rises. Then, only the oblique frame 44 that overlaps the heater 55 is heated and expands in the direction indicated by the arrow in FIG. 9A, and the other portions do not expand. At this time, due to the groove 49, the displacement of the oblique frame 44 is not inhibited by the center frame 44. As a result, the left and right side frames 43 are pushed up by the oblique frame 44, and the center frame 45 is pushed down by the oblique frame 44, so that the central portion of the bar 3 attached to the lower frame 42 protrudes downward. To curve. Thereby, the convex warpage on the bar 3 is corrected.

  Next, consider a case where the bar 3 affixed to the lower frame 42 has a downward convex warp. In this case, the heater 54 provided between the upper frame 41 and the attachment member 50 is energized, and the temperature of the heater 54 rises. Then, only the upper frame 41 that overlaps the heater 54 is heated and expands in the direction indicated by the arrow in FIG. 9B, and the other portions do not expand. At this time, due to the groove 48, the displacement of the upper frame 41 is not hindered by the center frame 44. As a result, the left and right side frames 43 are pushed down by the upper frame 41, so that the bar 3 attached to the lower frame 42 is curved so that both end portions protrude downward. As a result, the warp convex under the bar 3 is corrected.

  Further, in order to increase the displacement of the transfer jig 40 and prevent heat transfer of the heater, notches may be provided at both ends of the upper frame 41 and the diagonal frame 44 facing the heaters 55 and 54. The amount of warping of the bar 3 using the transfer jig 40 can be proportionally controlled because the amount of warping of the bar 3 changes in proportion to the amount of heat generated by the heater (wattage).

Here, the heaters 54 and 55 can be configured as follows.
(1) In the case where the heater is directly attached to the upper frame and the oblique frame In this case, as shown in FIG. 10 (a), the thin film heaters 54 and 55 are wound around each side of the upper frame 41 and the oblique frame 44, This is fixed by a pressing spring 58. The thin film heaters 54 and 55 may be copper or nichrome FPC (flexible printed cable), or may be a metal foil sandwiched between insulators. The conductive pattern of the thin film heaters 54 and 55 can be a copper pattern or a nichrome pattern. Further, the heaters 54 and 55 may be formed by winding a nichrome wire around each side of the upper frame 41 and the oblique frame 44.
(2) When a heater is attached to the mounting member facing the upper frame and the diagonal frame In this case, as shown in FIG. 10 (b), a recess is formed on the mounting member 50 side where the upper frame 41 and the diagonal frame 44 face each other. 50a is provided, and rod-shaped ceramic heaters 54 and 55 are inserted therein, and these are lightly pressed against the upper frame 41 and the oblique frame 44 by the pressing spring 58. At this time, since the ceramic heaters 54 and 55 want to heat only the portions to be heated, the contact surfaces other than the heating portions of the heaters 54 and 55 are covered with the heat insulating member 59 so that the heat is not transmitted to other portions. It is recommended to take measures such as providing
(3) When a heater is provided between the upper frame and the oblique frame In this case, as shown in FIG. 10 (c), in the space between the upper frame 41 and the mounting member 50 facing the oblique frame 44 Heaters 54 and 55 are provided. The heaters 54 and 55 are installed on an insulating plate 59 a, and a pressing spring 59 a is inserted between the insulating plate 59 a and the attachment member 50. The heaters 54 and 55 are lightly pressed against the upper frame 41 and the oblique frame 44 by the pressing spring 58a. Reference numerals 54a and 55a denote electrodes of the heaters 54 and 55, and when the electrodes 54a and 55a at both ends of the heater are energized, the heaters 54 and 55 generate heat.

Further, the heat source may be a cooling source instead of a heater. In this case, the operation is the reverse of that of the heater, and when the central part of the bar 3 is to be projected downward, the upper frame 41 is cooled, and both ends of the bar 3 are projected downward to cause the central part to be depressed. If desired, the oblique frame 44 may be cooled.
Such a transfer jig 40 of the first embodiment can be attached to the polishing head 30 described so far, and can also be attached to a conventional rocking-only polishing jig. Further, when polishing is performed using the transfer jig 40, the polishing correction mechanism 60 corrects the polishing difference between the left and right of the bar 3 from time to time according to the degree of polishing of the bar 3 as the polishing progresses. Thus, the warp correction of the bar 3 can be performed by the transfer jig 40. When the thickness (polishing amount) of the bar 3 reaches a predetermined value, the polishing is finished by stopping the rotation of the polishing platen 11 and the polishing head 30.

  FIG. 11A shows an example of detecting the degree of polishing of the bar 3. In the bar 3 of this embodiment, in addition to the MR head element (not shown), ELG elements 37 having predetermined resistance values are embedded at both ends and the center of the bar 3, respectively. Both end portions of each ELG element 37 are connected to terminals 38 provided on the side surfaces of the bar 3, respectively, and a resistance value of each ELG element 38 can be detected by passing a current between the terminals 38. When the MR head is polished, the ELG element 37 is also polished, and the resistance value between the terminals 38 changes.

  FIG. 11B shows changes in the MR head height and the resistance value of the ELG element 37 in the bar 3. In the figure, HA indicates the polishing reference height of the MR head. The polishing reference height of the MR head can be obtained by monitoring the resistance value of the ELG element. In addition, if the resistance value of the ELG element 37 increases evenly during the polishing of the bar 3, it can be seen that the bar 3 is evenly polished. On the other hand, when the resistance value of the ELG element 37 varies, it can be seen that the bar 3 is not evenly polished. In such a case, the bar 3 is displaced by the transfer jig 40 or the polishing correction mechanism 60 described above according to the type of variation in resistance value of the ELG element 37 so that the polishing is performed uniformly. Can do.

FIGS. 12A and 12B show a correction process according to the variation in the height of the MR element detected through the resistance value of the ELG element in the polishing process.
The example shown in FIG. 12 (a) is a case where the height of the MR element is increased in the center when the polishing time is t1 after the polishing is started. In this case, as described with reference to FIG. 9 (a), the correction process for energizing the heater 55 that overlaps the oblique frame 44 of the transfer jig 40 to project the central portion of the bar 3 toward the polishing surface plate 11 side. I do. It is assumed that the MR element height increases at both ends when the polishing time reaches t2 by this process. In this case, the heater 54 overlapping the upper frame 41 of the transfer jig 40 is energized to perform a correction process for projecting both ends of the bar 3 toward the polishing surface plate 11 side. By this processing, when the polishing time reaches t3, it is assumed that the height of the MR element becomes equal at the center and both ends. In this case, the electric power supplied to the heater 54 is held. By displacing the transfer jig 40 in this way, the bar 3 is evenly polished to the reference value.

  In the example shown in FIG. 12 (b), after the polishing is started, when the polishing time reaches T1, the height of the MR element increases on the left side and the bar 3 tilts to the right side. In this case, as described with reference to FIG. 8, the left solenoid 64 provided in the polishing head 30 is energized to rotate the mounting member 50 to the left and perform the correction process to tilt the bar 3 to the left. By this processing, when the polishing time reaches T2, the height of the MR element is increased on the right side, and the bar 3 is inclined to the left side. In this case, the right solenoid 64 provided in the polishing head 30 is energized to perform correction processing for rotating the mounting member 50 to the right and tilting the bar 3 to the right. By this processing, when the polishing time reaches T3, it is assumed that the height of the MR element becomes equal at the center and both ends. In this case, the power supplied to the solenoids 64 on both sides is stopped and the power is turned off. Thus, by rotating the attachment member 50 slightly, the bar 3 is evenly polished to the reference value.

The above is a simple correction example. Actually, however, the control device 18 described with reference to FIG. 3 reads changes in resistance values of the three ELG elements and controls the transfer jig 40 and the polishing correction mechanism 60 in a complicated manner. The bar 3 is evenly polished.
In the above-described embodiment, as a method for monitoring the polishing state, the resistance of the ELG element, which is the monitor resistance provided on the bar 3 on which the MR head is formed, is detected. However, the resistance of the MR element itself is detected. Then, the polishing state may be monitored. In the above embodiment, the terminal 38 is provided on the side surface of the bar 3. However, when the resistance value of the ELG element 37 is detected from the terminal 38, as shown in FIG. This is performed via a relay printed circuit board 75 provided on the side surface of 40. That is, the terminal 38 on the bar 3 is connected to a terminal (not shown) on the relay printed board 75 by wire bonding 74, and the resistance value is drawn from the relay printed board 75 by the probe 76. The probe 76 can be attached to the attachment member 50 or the polishing head 30.

  FIG. 14 shows the configuration of a polishing apparatus 20 'according to another embodiment of the present invention. In the polishing apparatus 20 described with reference to FIG. 3, only one polishing jig 21 is disposed on the polishing surface plate 11. In this embodiment, two polishing jigs 21 are disposed on the polishing surface plate 11. Has been. The embodiment of FIG. 14 has the same configuration as the polishing apparatus 20 described in FIG. 3 except that there are two polishing jigs 21 on the polishing surface plate 11. The same reference numerals are given and description thereof is omitted. Thus, two or three polishing jigs 21 can be attached to one polishing apparatus.

  By the way, when a plurality of polishing jigs 21 are arranged on the polishing surface plate 11, it is rare that the polishing heights of the bars 3 attached to the polishing heads 30 of the plurality of polishing jigs 21 reach the specified value at the same time. It is. When one of the plurality of bars 3 has been polished first, it is necessary to interrupt the polishing and take out the bar 3 that has been polished first. The polishing interruption mechanism 80 described with reference to FIG. 5 is used for polishing interruption in such a case.

  When one of the plurality of bars 3 has finished polishing first, the solenoid 81 of the polishing interruption mechanism 80 described in FIG. 5 is energized, the plunger 82 protrudes from the solenoid 81, and the pad 83 is fixed. The polishing head 30 is pushed up from the polishing table 11 by being pressed against the plate 11. In this state, the pad 83 at the tip of the three plungers 82 comes into contact with the polishing surface plate 11, and the bar 3 and the dummy polishing object 7 are not polished by the polishing surface plate 11. By this polishing interruption mechanism 80, the timing of separation from the polishing surface plate 11 is changed for each polishing jig 21, and polishing can be finished at the thickness set for each polishing jig 21.

  When the combination of the transfer jig 40 and the mounting member 50 of the first embodiment described above is used, as shown in FIG. 15A, when the bar 3 has a symmetrical warp W, the warp W is As indicated by the symbol F, it is corrected to be flat. However, as shown in FIG. 15 (b), if the bar 3 has a parabolic shape deviating from the center, or a complicated warp AS such as a cubic curve or a quartic curve, the first embodiment will be described. If a combination of the transfer jig 40 and the mounting member 50 is used, an error will inevitably occur in the corrected shape IM of the warp AS. In such a case, the flattened state indicated by the symbol F must be obtained by precisely controlling the protrusion / recess of the transfer jig 40 and the inclination of the mounting member 50 while interpolating using the measured value of the initial warp of the bar 3. In other words, extra polishing time is required.

Thus, in order to improve the polishing accuracy of the bar 3 even when the bar 3 has an asymmetric warp with respect to the center, the number of correction points between both ends of the bar 3 is changed from one place in the above-described embodiment. What is necessary is just to increase to multiple places.
FIG. 16 shows the configuration of the transfer jig 140 and the mounting member 150 in the second embodiment in which the number of correction points between both ends of the bar 3 is increased to three. Also in the second embodiment, the same components as those in the first embodiment will be described with the same reference numerals.

  The transfer jig 140 of the second embodiment has a rectangular frame structure made of metal or ceramic, which is a member that expands and contracts by heating and cooling. The upper frame 141, the lower frame 142 to which the bar 3 is attached to the lower surface, And left and right side frames 143. The midpoint of the upper frame 141 and the midpoint of the lower frame 142 are connected by a center frame 145. Further, an intermediate frame 144 is provided in parallel between the center frame 145 and the left and right side frames 143 in parallel with the center frame 145, respectively. In this embodiment, the transfer jig 140 is formed of the same member and with the same thickness, but the transfer jig 140 may not necessarily have the same thickness. The frames 141 to 145 have substantially the same shape. In addition, the width of the lower frame 142 is thicker than the width of the upper frame 141 in order to increase the displacement of the heater per calorific value, which will be described later.

  A connecting portion of the side frame 143, the intermediate frame 144, and the center frame 145 with the upper frame 141 has a long hole 148 for making it difficult for the heat of the heater to be transmitted to the upper frame 141. Further, a connection portion between the side frame 143, the intermediate frame 144, and the lower frame 142 of the center frame 145 has a notch 149 for making it difficult for the heat of the heater to be transmitted to the lower frame 142. The positions of the long holes 148 and the notches 149 may be reversed, or only one of them may be provided in the connection portion.

  There are attachment pieces 147 connected to the upper frame 141 on both sides of the center frame 145, and attachment holes 147a are formed in the attachment pieces 147. Further, the connecting portion with the upper frame 141 of the attachment piece 147 is constricted, and a positioning recess 146 is formed. Furthermore, grooves 142 a are provided at equal intervals in the width direction of the bar 3 on the mounting surface of the bar 3 of the lower frame 142. The groove 142a is for deforming the lower frame 142 into a complicated shape.

  The mounting member 150 to which the transfer jig 140 of the second embodiment is attached has a rectangular parallelepiped mounting base 151B whose outer shape is slightly larger than the transfer jig 140, and a flange portion integrally provided on the upper side of the mounting base 151B. 151A. The post 61 of the polishing correction mechanism 60 similar to that of the first embodiment is installed on the upper surface of the flange portion 151A. A positioning pin 152 for restricting the position of the upper end surface of the transfer jig 140 is provided on the end surface of the flange portion 151A on the transfer jig 140 side. Further, the mounting base 151B has a mounting hole 156 in the center thereof, and is fixed to the rotary shaft 34 provided on one side surface 30a of the polishing head 30 by a screw 57 inserted through the mounting hole 156. It has become. On both sides below the mounting hole 156, mounting holes 153 are provided at positions corresponding to the mounting holes 147a of the transfer jig 140. A hole 157 formed in the mounting base 151B outside the two mounting holes 153 is for attaching an insulating plate 130 described later.

  On the mounting base 151B of the transfer jig 140, a leaf spring 120 for biasing the insulating plate 130 is installed. The leaf spring 120 includes a rectangular frame 121, a spring portion 122 extending obliquely from one side of the frame 121, a pressing portion 123 parallel to the frame body 121 connected to the tip of the spring portion 122, and And an attachment portion 125 having an attachment hole 124. The mounting hole 124 is provided at a position overlapping the hole 157 formed in the mounting base 151B when the leaf spring 120 is placed on the mounting base 151B. The attachment part 125 provided with the frame body 121, the spring part 122, the pressing part 123, and the attachment hole 124 can be made by punching one sheet-like spring material.

An insulating plate 130 having a heater 131 is inserted between the leaf spring 120 and the transfer jig 140. The insulating plate 130 is for insulating the electrode 132 of the heater 131. The installation position of the heater 131 on the insulating plate 130 is a position facing the side frame 143, the intermediate frame 144, and the center frame 145 of the transfer jig 140 superimposed on the insulating plate 130. On the insulating plate 130, two pins 133 inserted into the positioning recess 146 of the transfer jig 140 are projected and two attachment holes 134 through which the screw 135 is inserted are provided. . The installation position of the attachment hole 134 is a position that overlaps the attachment hole 124 opened in the plate spring 120 when the insulating plate 130 is superimposed on the plate spring 120.
In the second embodiment, first, the plate spring 120 is placed on the mounting base 151B of the mounting member 150 in a state where the mounting hole 124 is superimposed on the hole 157, and the mounting spring 124 is placed on the plate spring 120. The insulating plate 130 is overlaid with the mounting holes 134 overlaid. The leaf spring 120 and the insulating plate 130 are attached to the mounting base 151 </ b> B of the mounting member 150 by screws 135. Thereafter, the transfer jig 140 is overlaid on the insulating plate 130 with the positioning recess 146 inserted through the pin 133 protruding from the insulating plate 130. At this time, the mounting hole 153 on the mounting base 151B, the mounting hole 135 on the insulating plate 130, and the mounting hole 147a on the transfer jig 140 are coincident with each other. The jig 140 is attached to the attachment base 151 </ b> B of the attachment member 150. At this time, each heater 131 on the insulating plate 130 is urged by the spring portion 122 of the leaf spring 120, so that it closely contacts the back surface of each frame 141 to 145 of the transfer jig 140.

  After the transfer jig 140 of the second embodiment is attached to the attachment member 150 together with the leaf spring 120, the insulating plate 130, and the heater 131, the attachment member 150 is attached to one end face of the polishing head 30. Is shown in FIG. As shown in FIG. 17, the transfer jig 140 is positioned by a pin 133 protruding from the insulating member 130 and a positioning pin 152 protruding from the flange 151 of the mounting member 150. The bar 3 attached to the lower surface protrudes below the bottom surface of the mounting member 150. The heater 131 provided on the insulating member 130 is biased by the leaf spring 120 and is in close contact with each frame of the transfer jig 140.

The heater 131 of the second embodiment has the configuration described with reference to FIG. 10C, but the heater 131 can have a structure as shown in FIGS. 10A and 10B.
Since the configuration of the polishing correction mechanism 60 in the second embodiment is the same as that in the first embodiment, the description thereof is omitted. Also in the second embodiment, the attachment member 150 attached to the rotary shaft 34 provided on one side surface 30a of the polishing head 30 rotates by energizing one of the solenoids 64. The bar 3 attached to the bottom surface is inclined.

  Next, a correction mechanism when the bar 3 attached to the transfer jig 140 of the second embodiment configured as described above is warped will be described with reference to FIG. As shown in FIG. 18, the transfer jig 140 of the second embodiment includes an upper frame 141, a lower frame 142 to which the bar 3 is attached to the lower surface, left and right side frames 143, a midpoint of the upper frame 141, and a lower frame 142. And a center frame 145 connecting the middle point of the center frame 145 and two intermediate frames 144 provided in parallel to the center frame 145 in the space between the side frame 143 and the center frame 145. And the heater 131 is closely_contact | adhering to the back surface side of each flame | frame 141-145, respectively. Further, the transfer jig 140 is fixed to the mounting member 150 only by a mounting piece 147 provided in a space between the center frame 145 and the two intermediate frames 144, and other portions can be freely deformed. It has become. In a state where the transfer jig 140 is fixed to the attachment member 150, the bar 3 attached to the lower surface of the lower frame 142 of the transfer jig 140 protrudes below the bottom surface of the attachment member 150.

  In this embodiment, the transfer jig 140 configured as described above is an integral body made of metal or ceramic. Usually, a linear or planar heating wire is used for this heater, but other heat sources or cooling means such as Peltier elements may be used. When the heater 131 is energized and heated, the frame in close contact with the heater 131 extends. Each frame has a long hole 148 in the connection portion with the upper frame 141, and a notch 149 is provided in the connection portion with the lower frame 142, so that the heat transferred from the heater 131 to the frame is connected to the upper frame 141. It is difficult for the lower frame 142 to escape, and the frame is efficiently heated by the heater 131 to extend.

  In the second embodiment, the transfer jig 140 has five vertical frames 141 to 145, and the lower frame 142 connected to these frames 141 to 145 can be partially deformed. A groove 142a is provided in a direction perpendicular to the longitudinal direction at a predetermined interval. Since the amount of warping of the bar 3 changes in proportion to the amount of heat generated by the heater 131 (wattage), the correction of the amount of warping of the bar 3 can be proportionally controlled by the amount of current supplied to the heater 131. Therefore, in the transfer jig 140 of the second embodiment, if the extension amounts of these five frames 141 to 145 are determined by adjusting the energization amounts to the respective heaters 131, various kinds of bars 3 can be obtained. It becomes possible to correct the warpage.

  FIG. 19 shows an example of detecting the degree of polishing of the bar 3 to be polished using the transfer jig 140 of the second embodiment. In the bar 3 of this embodiment, in addition to the MR head element (not shown), the bar 3 has predetermined resistance values at both ends and the center and at five points between the center and the ends. An ELG element 37 is embedded. Both end portions of each ELG element 37 are connected to terminals 38 provided on the side surfaces of the bar 3, respectively, and a resistance value of each ELG element 38 can be detected by passing a current between the terminals 38. When the MR head is polished, the ELG element 37 is also polished, and the resistance value between the terminals 38 changes. Changes in the MR head height and the resistance value of the ELG element 37 in the bar 3 are as described with reference to FIG.

FIGS. 20A and 20B show a correction process according to the variation in the height of the MR element detected through the resistance value of the ELG element in the polishing process.
The example shown in FIG. 20A is a correction process when the bar 3 having the five ELG elements 37 of A to E is polished as described in FIG. After the polishing is started, it is assumed that when the polishing time reaches t1, the height of the MR element is lowered at the central portion and unevenly increased between the central portion and both end portions. In this case, the heater 131 corresponding to the ELG element 37 at the positions B, C, and D is energized to perform processing for correcting the height of the MR element. After this processing, when the polishing time reaches t2, or when the polishing time reaches t3, the height of the MR element is checked again, and the corresponding heater 131 is energized so that the height becomes uniform. Thus, correction processing for increasing or decreasing the height of the bar 3 is performed. It is assumed that the MR elements have the same height in all five ELG elements 37 when the polishing time reaches t4 by this process. In this case, the electric power supplied to the heater 131 is held.

  As shown in FIG. 21 (a), the transfer jig 140 according to the second embodiment having the displacement mechanisms at the five locations as described above is provided with the ELG elements (sensors) 37 at the five locations. Even when 3 is warped asymmetrically with respect to the center as indicated by reference numeral AS, it is warped while the bar 3 is polished to the reference value by changing the amount of displacement of the five frames 141-145. Can be flattened as indicated by F.

  In addition, the bar 3 attached to the transfer jig 140 of the second embodiment can be provided with more than five ELG elements 37 as shown in FIG. In this case, a quaternary approximate curve FD is calculated on the control device 18 side described with reference to FIG. 3 based on the detected value of the asymmetric warp AS from each ELG element 37, thereby correcting five locations of the transfer jig 140. If the amount is determined and the energization amount to the five heaters 131 on the insulating plate 130 is determined, the bar 3 can be flattened as indicated by the symbol F.

  In the example shown in FIG. 20 (b), after the polishing is started, when the polishing time reaches T1, the height of the MR element is increased on the left side, and the bar 3 is tilted to the right side. In this case, as described with reference to FIG. 8, the left solenoid 64 provided in the polishing head 30 is energized to rotate the mounting member 150 to the left and perform the correction process to tilt the bar 3 to the left. By this processing, when the polishing time reaches T2, the height of the MR element is increased on the right side, and the bar 3 is inclined to the left side. In this case, the right solenoid 64 provided in the polishing head 30 is energized to perform a correction process for rotating the mounting member 150 to the right and tilting the bar 3 to the right. It is assumed that the MR elements have the same height in all five ELG elements 37 when the polishing time reaches T3. In this case, the power supplied to the solenoids 64 on both sides is stopped and the power is turned off. Thus, by rotating the attachment member 150 slightly, the bar 3 is evenly polished to the reference value.

Although the above is a simple correction example, in practice, the control device 18 described in FIG. 3 reads changes in the resistance values of the five ELG elements and controls the transfer jig 40 and the polishing correction mechanism 60 in a complicated manner. The bar 3 is evenly polished.
In the above-described embodiment, as a method for monitoring the polishing state, the resistance of the ELG element, which is the monitor resistance provided on the bar 3 on which the MR head is formed, is detected. However, the resistance of the MR element itself is monitored. You may do it. In the above embodiment, the terminal 38 is provided on the side surface of the bar 3. However, when the resistance value of the ELG element 37 is detected from the terminal 38, as shown in FIG. This is performed via a relay printed circuit board 75 provided on the side surface of 40. That is, the terminal 38 on the bar 3 is connected to a terminal (not shown) on the relay printed board 75 by wire bonding 74, and the resistance value is drawn from the relay printed board 75 by the probe 76. The probe 76 can be attached to the attachment member 50 or the polishing head 30.

  Thus, according to the polishing jig in which the leaf spring 120, the insulating plate 130, and the heater 131 as shown in the second embodiment are sandwiched between the transfer jig 140 and the mounting member 150, a simple configuration is obtained. With this, various warping of the bar 3 can be corrected.

  The present invention has been described in detail with particular reference to preferred embodiments thereof. For easy understanding of the present invention, specific embodiments of the present invention will be described below.

(Appendix 1)
A polishing object mounting member that is attached to a polishing jig disposed on a polishing surface plate and for mounting an object to be polished on the polishing surface plate, and includes the following:
A first attachment member that is attached to a polishing jig via a rotating shaft, and that adjusts a right / left inclination by rotating the object to be polished with respect to the polishing surface plate;
A second mounting member that is fixed to the first mounting member and has a function of bending the object to be polished with respect to the polishing surface plate so that a center portion thereof protrudes or both end portions thereof protrude.
(Appendix 2)
A workpiece attachment member according to appendix 1,
The first mounting member is an object mounting member that rotates by rotating a free end of a leaf spring fixed to an upper end surface thereof by a leaf spring displacing means provided on the polishing jig side.
(Appendix 3)
The workpiece attachment member according to appendix 2, wherein the leaf spring displacement means is a linear actuator.
(Appendix 4)
A workpiece attachment member according to appendix 2, wherein
An object mounting member in which the leaf spring displacing means is a magnetically sensitive material attached to a free end of the spring and a magnetic attracting means for attracting the magnetically sensitive material by an external signal.
(Appendix 5)
It is a polishing object attachment member given in any 1 paragraph of appendices 1-4,
The second mounting member is made of a material that expands and contracts by heating and cooling, and includes the following members:
A rectangular frame having an upper frame, a lower frame to which an object to be polished is attached, and left and right vertical frames;
Two oblique frame portions respectively connecting the both ends of the upper frame and the midpoint of the lower frame; and
A vertical frame connecting a middle point of the upper frame and a middle point of the lower frame, and a fixing portion provided with means for attaching to the polishing head.
(Appendix 6)
A workpiece attachment member according to appendix 5, wherein
The upper frame and the two diagonal frame portions can be independently heated at a position between the first mounting member, the upper frame of the second mounting member, and the two diagonal frame portions. Heater is provided,
In accordance with the amount of current supplied to the heater in a position overlapping the upper frame of the second mounting member, the both ends of the lower frame are curved so as to protrude toward the polishing surface plate,
Attaching an object to be bent which is curved so that the central portion of the lower frame protrudes toward the polishing surface plate according to the amount of current applied to the heater located at a position overlapping two oblique frames of the second attachment member. Element.
(Appendix 7)
A workpiece attachment member according to appendix 6, wherein
A polishing object mounting member, wherein the heater is a sheet-like heater, and is in close contact with a frame portion that requires heating of the second mounting member.
(Appendix 8)
A workpiece attachment member according to appendix 7,
A workpiece attachment member in which the sheet-like heater is a flexible printed cable or a metal foil sandwiched between insulators.
(Appendix 9)
A workpiece attachment member according to appendix 8, wherein
A workpiece mounting member in which the conductor pattern of the sheet-like heater is a copper pattern.
(Appendix 10)
A workpiece attachment member according to appendix 4, wherein
A workpiece attachment member in which the conductor pattern of the sheet-like heater is a nichrome pattern.
(Appendix 11)
The workpiece attachment member according to appendix 6, wherein the heater is a sheet-like heater, and is attached to the first attachment member side.
(Appendix 12)
A workpiece attachment member according to appendix 11, wherein
The first attachment member and the heater are workpiece attachment members that are separated by air or a heat insulating member.
(Appendix 13)
A polishing object mounting member that is attached to a polishing jig disposed on a polishing surface plate and for mounting an object to be polished on the polishing surface plate, and includes the following:
A mounting member body having a bottom surface for mounting the object to be polished;
A rotation mechanism that is provided at the center of the attachment member main body, rotates the attachment member main body with respect to the polishing jig, and rotates the attachment member main body around the rotation mechanism to A tilt adjusting mechanism that adjusts the left and right tilt of the workpiece.
(Appendix 14)
A workpiece attachment member according to appendix 13, wherein
The tilt adjusting mechanism is a polished object composed of a leaf spring fixed to the upper end surface of the mounting member body and a leaf spring displacing means provided on the grinding jig side to displace the free end of the leaf spring. Object attachment member.
(Appendix 15)
15. A workpiece mounting member according to appendix 14, wherein the leaf spring displacement means is a linear actuator.
(Appendix 16)
A workpiece attachment member according to appendix 14, wherein
An object mounting member in which the leaf spring displacing means is a magnetically sensitive material attached to a free end of the spring and a magnetic attracting means for attracting the magnetically sensitive material by an external signal.
(Appendix 17)
A workpiece mounting member that is mounted on a polishing jig disposed on a polishing surface plate and mounts an object to be polished on the polishing surface plate, and is made of a material that expands and contracts by heating and cooling. ,
A rectangular frame having an upper frame, a lower frame to which the object to be polished is attached to the lower surface, and left and right side frames;
Two oblique frame portions respectively connecting the both ends of the upper frame and the midpoint of the lower frame;
A center frame connecting a midpoint of the upper frame and a midpoint of the lower frame, and a fixing portion having means for attaching to the polishing jig;
A first heater provided adjacent to each of the upper frames, and
A second heater provided adjacent to each of the two oblique frame portions,
In accordance with the energization amount to the first heater, the both ends of the lower frame are curved so as to protrude toward the polishing surface plate,
A workpiece attachment member that is curved so that a center portion of the lower frame protrudes toward the polishing surface plate according to the amount of current supplied to the second heater.
(Appendix 18)
A workpiece mounting member that is mounted on a polishing jig disposed on a polishing surface plate and mounts an object to be polished on the polishing surface plate, and is made of a member that expands and contracts by heating and cooling. ,
A rectangular frame having an upper frame, a lower frame to which an object to be polished is attached to the lower surface, and left and right side frames;
Connecting the upper frame and the lower frame in parallel to the side frame, and at least three intermediate frames provided between the side frames;
A fixed portion provided in the space between the two intermediate frames, connected to the upper frame, and provided with means for attaching to the polishing jig; and
Provided adjacent to the side frame and the intermediate frame, respectively, and equipped with a heater capable of heating each frame independently;
A workpiece mounting member capable of partially changing the height of the lower frame from the polishing surface plate in accordance with the amount of current supplied to the heater.
(Appendix 19)
A workpiece attaching member according to appendix 18, wherein:
A polishing object mounting member in which a plurality of grooves perpendicular to the longitudinal direction of the lower frame are provided at predetermined intervals on the polishing frame mounting surface of the lower frame.
(Appendix 20)
The workpiece attachment member according to any one of appendices 17 to 19,
A polishing object mounting member in which a heat radiation preventing means for preventing heat transmitted to each frame from escaping to the upper frame and the lower frame is provided at a connection portion of each frame with the upper frame and the lower frame.
(Appendix 21)
A workpiece attaching member according to appendix 17 or 18, comprising:
A member to be polished attached, wherein the heater is a sheet-like heater, and is in close contact with the frame that requires heating.
(Appendix 22)
A workpiece attaching member according to appendix 21, wherein
A workpiece attaching member in which the sheet heater sandwiches either a flexible printed cable or a metal foil with an insulator.
(Appendix 23)
A workpiece attachment member according to appendix 22,
A workpiece mounting member in which the conductor pattern of the sheet-like heater is a copper pattern.
(Appendix 24)
A workpiece attachment member according to appendix 22,
A workpiece attachment member in which the conductor pattern of the sheet-like heater is a nichrome pattern.
(Appendix 25)
A workpiece attaching member according to appendix 17 or 18, comprising:
A workpiece attachment member attached to the polishing jig side, wherein the heater is a sheet-like heater.
(Appendix 26)
A workpiece attachment member according to appendix 25, wherein
The polishing jig and the heater are workpiece attachment members that are separated by air or a heat insulating member.

It is a figure which shows the manufacturing process of MR head. It is a top view of the grinding | polishing apparatus provided with the conventional rocking | fluctuation type lapping mechanism. It is a top view of one Example of the polisher provided with the rotation type lapping mechanism of the present invention. It is a partial expanded side view which shows the structure of the principal part of the grinding | polishing apparatus of FIG. (a) is a plan view of a polishing head attached to the polishing jig of the polishing apparatus of FIG. 3, and (b) is a side view of the polishing head of (a) to which the transfer jig of the first embodiment is attached. . FIG. 6 is a partially enlarged assembly perspective view showing the configuration of the transfer jig of the first embodiment attached to the polishing head of FIG. 5. It is a partial expanded sectional view which shows the structure of the rotation mechanism part of FIG. It is a principle figure explaining operation | movement of the left-right difference correction mechanism of this invention. (a) is explanatory drawing which shows the structure and protrusion operation | movement of the transfer jig of 1st Example of this invention, (b) is description which shows the structure and depression operation | movement of a transfer jig of 1st Example of this invention. FIG. (a) is a partially enlarged cross-sectional view showing the configuration of a thin film heater that is directly attached to the transfer jig of the present invention, and (b) is a solid heater that is attached to the mounting member side of the transfer jig used in the present invention. FIG. 3C is a partially enlarged cross-sectional view showing the structure of the heater used between the transfer jig used in the present invention and its mounting member. (a) is a figure which shows arrangement | positioning of the ELG element of the to-be-polished object attached to the transfer jig of 1st Example of this invention, (b) is resistance value change at the time of grinding | polishing of the ELG element of (a) FIG. (a) is a figure which shows an example of the heater control according to the height change of the ELG element in the grinding | polishing process using the transfer jig of 1st Example of this invention, (b) is 1st Example of this invention It is a figure which shows an example of the electricity supply control to the solenoid according to the height change of the ELG element in the grinding | polishing process using an example transfer jig. It is a partial expanded side view which shows the structure of the probe which takes out an electric signal from the relay substrate provided in the transfer jig. It is a top view which shows the structure of another Example of the grinding | polishing apparatus of this invention. (a) is explanatory drawing which shows the correction | amendment process in case a bar has a left-right symmetrical curvature, (b) is explanatory drawing which shows the correction process in case a bar has a right-left asymmetric curvature. FIG. 6 is a partially enlarged assembly perspective view showing a configuration of a transfer jig of a second embodiment attached to the polishing head of FIG. 5. FIG. 17 is a partially enlarged side view showing a state where the transfer jig of the second embodiment of FIG. 16 is attached to the polishing head together with the attachment member. It is explanatory drawing explaining operation | movement of the transfer jig of 2nd Example. It is a figure which shows arrangement | positioning of the ELG element of the to-be-polished object which attaches to the transfer jig of 2nd Example of this invention, and is grind | polished. (a) is a figure which shows an example of heater control according to the height change of the ELG element in the grinding | polishing process using the transfer jig of 2nd Example of this invention, (b) is 2nd Example of this invention It is a figure which shows an example of the electricity supply control to the solenoid according to the height change of the ELG element in the grinding | polishing process using an example transfer jig. (a) is a figure which shows the curvature correction process of the bar | burr when five ELG elements are provided in the transfer jig of the second embodiment of the present invention, and (b) is a diagram of the second embodiment of the present invention. It is a figure which shows the curvature correction process of the bar | burr in case the ELG element is provided in the transfer jig | tool at five or more places.

Explanation of symbols

2 MR head 3 bar (object to be polished)
DESCRIPTION OF SYMBOLS 7 Dummy polishing object 9 Connector 11 Polishing surface plate 18 Control apparatus 20, 20 'Polishing apparatus 21 Polishing jig 25 Slip ring 30 Polishing head 37 ELG element 40 Transfer jig of 1st Example (attachment to be polished) Element)
41 Upper frame 42 Lower frame 43 Side frame 44 Inclined frame 45 Center frame 50 Mounting member 54, 55 Heater 59 Heat insulation member 62 Leaf spring 63 Iron piece 64 Solenoid 65 Supporter 66 Stopper 70 Dummy polishing object mounting member 75 Relay printed circuit board 76 Probe 80 Polishing interruption mechanism 120 Leaf spring 130 Insulating plate 131 Heater 140 Transfer jig 141 of the second embodiment 141 Upper frame 142 Lower frame 142a Groove 143 Side frame 144 Intermediate frame 145 Center frame 150 Mounting member 151A Hook 151B Mounting base

Claims (8)

A polishing object mounting member that is attached to a polishing jig disposed on a polishing surface plate and for mounting an object to be polished on the polishing surface plate, and includes the following:
A first attachment member that is attached to a polishing jig via a rotating shaft, and that adjusts a right / left inclination by rotating the object to be polished with respect to the polishing surface plate;
A second mounting member that is fixed to the first mounting member and has a function of bending the object to be polished with respect to the polishing surface plate so that a center portion thereof protrudes or both end portions thereof protrude. The workpiece attachment member according to claim 1,
The first mounting member is an object mounting member that rotates by rotating a free end of a leaf spring fixed to an upper end surface thereof by a leaf spring displacing means provided on the polishing jig side. The workpiece attachment member according to claim 1 or 2,
The second mounting member is made of a material that expands and contracts by heating and cooling, and includes the following members:
A rectangular frame having an upper frame, a lower frame to which an object to be polished is attached, and left and right vertical frames;
Two oblique frame portions respectively connecting the both ends of the upper frame and the midpoint of the lower frame; and
A vertical frame connecting a middle point of the upper frame and a middle point of the lower frame, and a fixing portion provided with means for attaching to the polishing head. The workpiece attachment member according to claim 3,
The upper frame and the two diagonal frame portions can be independently heated at a position between the first mounting member, the upper frame of the second mounting member, and the two diagonal frame portions. Heater is provided,
In accordance with the amount of current supplied to the heater in a position overlapping the upper frame of the second mounting member, the both ends of the lower frame are curved so as to protrude toward the polishing surface plate,
Attaching an object to be polished that is curved so that the central portion of the lower frame protrudes toward the polishing platen according to the amount of current applied to the heater at a position overlapping two oblique frames of the second attachment member. Element. A polishing object mounting member that is attached to a polishing jig disposed on a polishing surface plate and for mounting an object to be polished on the polishing surface plate, and includes the following:
A mounting member body having a bottom surface for mounting the object to be polished;
A rotation mechanism that is provided at the center of the attachment member main body, rotates the attachment member main body with respect to the polishing jig, and rotates the attachment member main body around the rotation mechanism to A tilt adjusting mechanism that adjusts the left and right tilt of the workpiece. The workpiece mounting member according to claim 5,
The tilt adjusting mechanism is a polished object composed of a leaf spring fixed to the upper end surface of the mounting member body and a leaf spring displacing means provided on the grinding jig side to displace the free end of the leaf spring. Object attachment member. A workpiece mounting member that is mounted on a polishing jig disposed on a polishing surface plate and mounts an object to be polished on the polishing surface plate, and is made of a material that expands and contracts by heating and cooling. ,
A rectangular frame having an upper frame, a lower frame to which the object to be polished is attached to the lower surface, and left and right side frames;
Two oblique frame portions respectively connecting the both ends of the upper frame and the midpoint of the lower frame;
A center frame connecting a midpoint of the upper frame and a midpoint of the lower frame, and a fixing portion having means for attaching to the polishing jig;
A first heater provided adjacent to each of the upper frames, and
A second heater provided adjacent to each of the two oblique frame portions,
In accordance with the energization amount to the first heater, the both ends of the lower frame are curved so as to protrude toward the polishing surface plate,
A workpiece attachment member that is curved so that a center portion of the lower frame protrudes toward the polishing surface plate according to the amount of current supplied to the second heater. A workpiece mounting member that is mounted on a polishing jig disposed on a polishing surface plate and mounts an object to be polished on the polishing surface plate, and is made of a member that expands and contracts by heating and cooling. ,
A rectangular frame having an upper frame, a lower frame to which an object to be polished is attached to the lower surface, and left and right side frames;
Connecting the upper frame and the lower frame in parallel to the side frame, and at least three intermediate frames provided between the side frames;
A fixed portion provided in the space between the two intermediate frames, connected to the upper frame, and provided with means for attaching to the polishing jig; and
Provided adjacent to the side frame and the intermediate frame, respectively, and equipped with a heater capable of heating each frame independently;
A workpiece mounting member capable of partially changing the height of the lower frame from the polishing surface plate in accordance with the amount of current supplied to the heater.

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