JP2012113801A - Method of manufacturing glass substrate for magnetic disk - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve circularity of outer peripheral gring surfaces when a plurality of glass substrates for magnetic disk are manufactured from a stack of a plurality of plate-like glasses.SOLUTION: The method of manufacturing the glass substrates for magnetic disk includes a stack preparation process of preparing the stack of the plurality of plate-like glasses; an immersing process of immersing the stack in a grinding liquid; and a grinding process of grinding the stack into a cylindrical shape by moving an integrated core drill, having a large-diameter cylindrical outer peripheral grinding grindstone and a small-diameter cylindrical inner-peripheral grinding grindstone arranged coaxially, in the stacking direction of the stack while rotating the integrated core drill on its axis and supplying the grinding liquid to an inner-peripheral grinding surface formed as the inner-peripheral grinding grindstone and plate-like glasses come into contact with each other.

Description

  The present invention relates to a method for manufacturing a glass substrate for a magnetic disk.

  2. Description of the Related Art Today, a personal computer, a DVD (Digital Versatile Disc) recording device, or the like has a built-in hard disk device (HDD: Hard Disk Drive) for data recording. In particular, in a hard disk device used in a portable computer such as a notebook personal computer, a magnetic disk in which a magnetic layer is provided on a glass substrate is used, and the magnetic head slightly floats above the surface of the magnetic disk. Magnetic recording information is recorded on or read from the magnetic layer by a (DFH (Dynamic Flying Height) head). As a substrate for this magnetic disk, a glass substrate is preferably used because it has a property that it is less likely to be plastically deformed than a metal substrate (aluminum substrate) or the like.

  Further, in response to a request for an increase in storage capacity in a hard disk device, the density of magnetic recording has been increased. For example, the magnetic recording information area is miniaturized by using a perpendicular magnetic recording method in which the magnetization direction in the magnetic layer is perpendicular to the surface of the substrate. Thereby, the storage capacity of one disk substrate can be increased. Furthermore, in order to further increase the storage capacity, the flying distance from the magnetic recording surface of the magnetic head can be made extremely short to further improve the accuracy of information recording / reproduction (improve the S / N ratio). Has been done. In such a magnetic disk substrate, the magnetic layer is formed flat so that the magnetization direction of the magnetic layer is substantially perpendicular to the substrate surface. For this reason, the surface irregularities of the substrate of the magnetic disk are made as small as possible.

In the process of producing the glass substrate for magnetic disk, for example, a coring process for forming a sheet glass into an annular shape, a chamfering process for chamfering the inner peripheral end face and the outer peripheral end face of the annular plate glass, And an edge polishing step of performing mirror finishing of the inner peripheral end face and the outer peripheral end face.
Conventionally, the coring process was performed individually one by one (single-wafer processing), but multiple annular glass sheets were produced at the same time by grinding multiple glass sheets at the same time. A processing method is known in which the tact time of manufacturing is shortened (Patent Document 1). According to this conventional method, an inner diameter cylindrical blade and an outer diameter cylindrical blade move in the laminating direction of the laminated body while rotating a coring cutter in which the inner diameter cylindrical blade and the outer diameter cylindrical blade are integrally formed on the same axis. By processing, the inner peripheral surface and the outer peripheral surface of the laminate are processed.

JP 2007-283651 A

By the way, in recent years, there is an increasing demand for further improvement in the roundness of the inner hole of the glass substrate for magnetic disks, for the following reason.
As described above, in the magnetic disk for the hard disk device, the magnetic recording information area using the perpendicular magnetic recording method is miniaturized, and the width of the area (magnetic domain) used for 1-bit recording is extremely narrow. The width of a plurality of tracks (storage areas) formed concentrically from the inner hole to the outer edge of the magnetic disk is also becoming extremely narrow. Therefore, if the play between the inner hole and the spindle is large when the inner hole of the magnetic disk is attached to the spindle in the hard disk device, a read error (so-called TMR: Track Miss-Read) may occur between adjacent tracks. There is. Therefore, high accuracy of, for example, 2 μm or less is required as the roundness of the inner hole of the magnetic disk glass substrate.

On the other hand, as a roundness of the inner hole of the glass substrate for magnetic disks, for example, in order to realize a high accuracy roundness of 2 μm or less, grinding is performed with high accuracy in the coring process (grinding process). This is necessary for the following reason.
That is, when the roundness of the inner hole formed in the coring process is not good, the machining allowance must be increased in the subsequent chamfering process, for example, by making the abrasive grains rough. However, if the machining allowance in the chamfering process is increased, the inner peripheral end face is likely to crack. Therefore, in order to reduce the allowance of the inner peripheral end face in the chamfering process so as not to generate cracks as much as possible, it is required to perform grinding with high accuracy in the coring process, which is the preceding process. . In the chamfering process, it is common to adjust the inner and outer diameters and form a chamfered surface by simultaneously processing the end shape using a general-purpose grindstone, that is, grinding the end surface and the chamfered surface. Known.

Here, it has become clear that if a device with a built-in hard disk is dropped, the magnetic disk is likely to be destroyed from the inner periphery, and a certain strength is maintained by eliminating cracks in the inner periphery as much as possible. There is a need.
In addition, the above-described reduction of cracks on the glass substrate for magnetic disk not only ensures the required strength in the drop test of the hard disk device, but also the following recent attempts to achieve higher density recording of the magnetic disk. It is also requested by technology.

That is, in recent years, a magnetic material (high Ku magnetic material) having a high magnetic anisotropy energy such as an Fe—Pt system or a Co—Pt system is used for the purpose of achieving higher density recording of a magnetic disk. It is being considered. In order to achieve high-density recording, it is necessary to reduce the particle size of the magnetic particles. On the other hand, when the particle size is reduced, deterioration of magnetic properties due to thermal fluctuation becomes a problem. High Ku magnetic materials are less susceptible to thermal fluctuations and are expected to contribute to high density recording.
However, the high Ku magnetic material needs to obtain a specific crystal orientation state in order to realize a high Ku. Therefore, it is necessary to perform film formation at a high temperature or heat treatment at a high temperature after film formation. Therefore, in order to form a magnetic recording layer made of these high Ku magnetic materials, the glass substrate must have high heat resistance that can withstand the above high temperature processing, that is, high glass transition temperature (for example, 600 to 700 degrees Celsius). Is required. Here, when the crack has arisen in the end surface of a glass substrate, a crack progresses in the process of the said heat processing, and there exists a possibility that target intensity | strength cannot be ensured. Therefore, as a premise for achieving high density recording by using a high Ku magnetic material, there is a demand for further reduction of cracks than in the past.

As described above, the coring process is required to be performed with high accuracy in order to reduce cracks in the magnetic disk glass substrate. Here, in the grinding apparatus disclosed in Patent Document 1, it is difficult to uniformly supply the grinding liquid (coolant) to the outer peripheral grinding surface of the laminated sheet glass. As a result, the grinding resistance and the discharge rate of glass sludge are non-uniform between the portion where the coolant is likely to be supplied and the portion where the coolant is difficult to be supplied on the ground surface, resulting in non-uniform grinding of the outer peripheral grinding surface. The roundness of the outer peripheral grinding surface decreases.
In the following description, the outer peripheral grinding surface refers to the outer peripheral surface of a laminate of cylindrical plate glass that is being ground or ground (after processing) by a grinding blade, or individual circles forming the laminate. It means the outer peripheral surface of the annular glass. The inner peripheral grinding surface refers to the inner peripheral surface of a laminated sheet of cylindrical plate glass that is being ground or ground (after processing) by a grinding blade, or the inner circumference of each annular glass forming the laminated body Means the side face.

  In addition, when rotating a coring cutter in which an inner diameter cylindrical blade and an outer diameter cylindrical blade are integrally formed coaxially with respect to a laminated body of plate-like glass, the coring cutter is moved in the laminating direction of the laminated body. As the material advances in the stacking direction of the laminate, the supply of the grinding fluid to the grinding position (tip of the coring cutter) is insufficient, and the processing accuracy is likely to deteriorate. This is because the distance between the grinding fluid supply point and the grinding position is increased, and the grinding fluid supply path (the area between the coring cutter blade and the grinding surface of the laminate) is narrow. There is a tendency that the roundness of the sheet glass tends to deteriorate as the distance increases.

  When the roundness of the outer peripheral ground surface after grinding in the coring step is not good, it is difficult to improve the concentricity with the inner peripheral ground surface. If the roundness of the outer peripheral grinding surface after processing is not good, the subsequent chamfering process is performed to improve the roundness of the outer peripheral grinding surface while improving the accuracy of the concentricity between the outer peripheral grinding surface and the inner peripheral grinding surface. In this case, the machining allowance for the inner and outer peripheral grinding surfaces must be increased. In particular, if the machining allowance of the inner peripheral grinding surface is increased in the chamfering process, cracks are likely to occur on the inner peripheral end surface. Therefore, in order to reduce the machining allowance in the chamfering process and prevent the generation of cracks as much as possible, it is required to perform grinding with high accuracy in the coring process, which is the preceding process. Further, in recent years, when the rotational speed of the magnetic disk in the hard disk becomes high, there is a problem that fluttering occurs when the roundness of the outer peripheral ground surface is not good.

  Therefore, the present invention makes it possible to improve the roundness of the outer peripheral ground surface to a required level when producing a plurality of glass substrates for magnetic disks from a laminate in which a plurality of plate glasses are laminated. It aims at providing the manufacturing method of the glass substrate for magnetic discs.

  In order to solve the above problems, a method of manufacturing a glass substrate for a magnetic disk according to a first aspect includes a laminate preparation step of preparing a laminate in which a plurality of plate glasses are laminated, and immersing the laminate in a grinding liquid. An integral core drill in which a dipping process, a large-diameter cylindrical outer peripheral grinding wheel and a small-diameter cylindrical inner peripheral grinding wheel are arranged coaxially, and rotate in the stacking direction of the laminate. And a grinding step of grinding the laminate into a cylindrical shape by moving the laminate.

  In order to solve the above problems, a method of manufacturing a glass substrate for a magnetic disk according to a second aspect includes a laminate preparation step of preparing a laminate in which a plurality of plate glasses are laminated, and immersing the laminate in a grinding liquid. A dipping step, and an integrated core drill in which a large-diameter cylindrical outer peripheral grinding wheel and a small-diameter cylindrical inner peripheral grinding wheel are coaxially arranged, and the inner peripheral grinding wheel A grinding step of grinding the laminated body into a cylindrical shape by moving the laminated body in the laminating direction while supplying a grinding liquid to an inner peripheral grinding surface formed in contact with the plate-like glass. .

  Moreover, it is preferable to have the circulation process which circulates the said grinding fluid which immerses the said laminated body.

  Moreover, it is preferable that the count of the said inner periphery grinding stone is larger than the count of the said outer periphery grinding stone.

  Further, the count of the inner peripheral grinding wheel is preferably 150 or more and 800 or less, and the count of the outer peripheral grinding wheel is preferably 120 or more and 600 or less.

  Moreover, it is preferable to have the machining process which grind | polishes the end surface of the said plate-shaped glass substrate after the said grinding process.

  According to the method for manufacturing a glass substrate for a magnetic disk of the present invention, when a plurality of glass substrates for a magnetic disk are created from a laminate in which a plurality of plate glasses are laminated, the roundness of the outer peripheral grinding surface is required. It can be improved to the level.

It is a figure which shows an example of the cross section of the laminated body on which the some plate glass and the adhesive agent were laminated | stacked. It is a figure which shows an example of the immersion process of embodiment. It is a figure which shows an example of the grinding apparatus when grind | pulverizing the laminated body of sheet glass in the coring process of embodiment. It is sectional drawing of an example of the integrated core drill used at the coring process of embodiment.

  Hereinafter, the manufacturing method of the glass substrate for magnetic disks of this embodiment is demonstrated in detail.

[Magnetic disk glass substrate]
Aluminosilicate glass, soda lime glass, borosilicate glass, or the like can be used as the material for the magnetic disk glass substrate in the present embodiment. In particular, aluminosilicate glass can be suitably used in that it can be chemically strengthened and a glass substrate for a magnetic disk excellent in the flatness of the main surface and the strength of the substrate can be produced.

Although the composition of the glass substrate for magnetic disks of this embodiment is not limited, the composition of a preferable glass substrate is as follows.
For example, a glass substrate of this embodiment is _preferably, SiO 2: 58-75 _{wt%, Al} 2 O 3: _{5~23 wt%,} Li 2 O: _{3~10 wt%,} Na 2 O: _4~13 weight % As a main component.

Glass substrate of the present embodiment is particularly _preferred, SiO 2: _{62~75 wt%, Al} 2 O 3: _{5~15 wt%,} Li 2 O: _{4~10 wt%,} Na 2 O: _4~12 wt% ZrO ₂ : 5.5 to 15% by weight as a main component, the Na ₂ O / ZrO ₂ weight ratio is 0.5 to 2.0, and the Al ₂ O ₃ / ZrO ₂ weight ratio is 0.8. It is aluminosilicate glass which is 4-2.5.

As another suitable glass, expressed in terms of _{weight%, SiO 2: 61~70%,} Al 2 O 3: 9~18%, Li 2 O: 2~3.9%, Na 2 O: 6 ˜13%, K ₂ O: 0 to 5%, R ₂ O: 10 to 16% (provided that R ₂ O = Li ₂ O + Na ₂ O + K ₂ O), MgO: 0 to 3.5%, CaO: 1 ~7%, SrO: 0~2%, BaO: 0~2%, RO: 2~10%, ( provided _{that, RO = MgO + CaO + SrO} + BaO), TiO 2: 0~2%, CeO 2: 0~2%, Fe Mention may be made of aluminosilicate glasses containing ₂ O ₃ : 0 to 2%, MnO: 0 to 1%, TiO ₂ + CeO ₂ + Fe ₂ O ₃ + MnO = 0.01 to 3%.

  The glass substrate for a magnetic disk in the present embodiment is an annular thin glass substrate. The size of the glass substrate for the magnetic disk is not limited, but is suitable as a glass substrate for a magnetic disk having a nominal diameter of 2.5 inches or a smaller diameter (for example, 1 inch), for example.

[Method of manufacturing glass substrate for magnetic disk]
Hereinafter, the manufacturing method of the glass substrate for magnetic disks of this embodiment is demonstrated for every process. However, the order of each step may be changed as appropriate.

(1) Forming and lapping process of sheet glass by float method In the process of forming sheet glass by float process, for example, molten glass having the above-described composition is continuously poured into a bath filled with molten metal such as tin. A plate-like glass is obtained. The molten glass flows along the traveling direction in a bathtub that has been subjected to a strict temperature operation, and finally a plate-like glass adjusted to a desired thickness and width is formed. From this plate-like glass, a plate-shaped glass having a predetermined shape that is the basis of the glass substrate for magnetic disks is cut out. Since the surface of the molten tin in the bath is horizontal, the flat glass obtained by the float process has a sufficiently high flatness. The plate-like glass obtained by the above method has a thickness of 0.6 to 1.4 mm and a surface roughness Ra (arithmetic average roughness) of 0.01 μm or less.
In addition, plate glass can be manufactured using well-known manufacturing methods, such as a press molding, a down draw method, a redraw method, a fusion method, not only a float glass method.

  Next, lapping processing using alumina-based loose abrasive grains is performed on both main surfaces of the sheet glass cut into a predetermined shape, if necessary. Specifically, the lapping platen is pressed on both sides of the plate glass from above and below, a grinding liquid (slurry) containing free abrasive grains is supplied onto the main surface of the plate glass, and these are moved relatively. Perform lapping. In addition, when plate glass is molded by the float process, the lapping process may be omitted because the accuracy of the roughness of the main surface after molding is high.

(2) Laminate Preparation Step The plate-like glass cut out in the step (1) is, for example, a plate-like glass having a predetermined rectangular shape (for example, a square shape) slightly larger than the size of the target magnetic disk glass substrate. It is. For example, in the case of producing a 2.5-inch magnetic disk glass substrate, a 75 mm × 75 mm rectangular plate glass is cut out.

  In the laminate preparation step, a laminate in which a plurality of plate glasses are laminated is prepared by sequentially applying or sticking an adhesive and / or a spacer between two plate glasses. This laminated body is produced in order to integrally process a plurality of plate glasses in a coring process described later. Further, this laminate may be integrally processed in a chamfering process and an edge polishing process performed after the coring process.

  Here, with reference to FIG. 1, the structure of the laminated body of this embodiment is demonstrated. FIG. 1 is a cross-sectional view showing an example of a laminated body of the present embodiment. As shown in FIG. 1, the laminate 5 of the present embodiment is configured by laminating a plurality of plate glasses 5a and adhesives 5b alternately. The laminated body 5 is produced by applying or sticking an adhesive 5b between the plate-like glasses 5a.

As long as the adhesive 5b can adhere | attach or isolate | separate sheet glass 5a, what kind of thing may be sufficient as it. For example, since the ultraviolet curable resin is easily solidified by irradiation with ultraviolet rays having a predetermined wavelength, the bonding operation is easy. Further, as the ultraviolet curable resin, a resin that can easily peel off the glass sheet bonded with warm water or an organic solvent is preferable. As the adhesive, in addition to the UV curable resin, wax, photo curable resin, visible light curable resin, or the like can be used. Since the wax softens at a predetermined temperature to become a liquid and becomes a solid at room temperature, it is easy to bond and separate.
When a spacer is attached instead of the adhesive, a thin spacer made of a resin material, a fiber material, a rubber material, a metal material, or a ceramic material can be used. The thickness of the adhesive or the spacer is, for example, about 0.01 to 2 mm.

(3) Immersion process An immersion process is a process of immersing a laminated body in a grinding fluid (coolant). Hereinafter, the dipping process of the present embodiment will be described with reference to FIG. FIG. 2 is a diagram illustrating an example of the immersion process of the present embodiment. As shown in FIG. 2, the immersion container 40 is filled with an amount of coolant 42 that sufficiently immerses the laminate 5. A mounting table 30 on which the stacked body 5 is mounted is disposed on the bottom of the immersion container 40. In the dipping process of the present embodiment, the stacked body 5 is placed on the mounting table 30 and immersed in the coolant 42.
Since the coolant 42 keeps in contact with the laminated body for a long time, it is preferable that the coolant does not dissolve the adhesive of the laminated body. For example, a water-soluble one containing alkylene glycol or ethanolamine can be used. For example, Chemicool (registered trademark) C-798S and the like can be mentioned.

Here, the immersion container 40 is provided with a supply port 44 and a discharge port 46. The supply port 44 supplies the coolant 42 to the immersion container 40. The discharge port 46 discharges the coolant 42 from the immersion container 40.
A filter 48 and a pump 50 are provided between the discharge port 46 and the supply port 44. The filter 48 removes sludge generated in the coring process described later. Further, the pump 50 pumps up the coolant 42 discharged from the discharge port 46 to the supply port 44. The discharge port 46, the filter 48, the pump 50, and the supply port 44 are connected by a pipe 52, respectively.

The coolant 42 discharged from the discharge port 46 is supplied from the supply port 44 to the immersion container 40 via the filter 48 and the pump 50 and circulated. By circulating the coolant 42, it is possible to suppress the sludge generated in the coring process described later from staying in the immersion container 40.
In the present embodiment, the coolant 42 discharged from the discharge port 46 is supplied and circulated from the supply port 44 to the immersion container 40 via the filter 48 and the pump 50. However, the coolant 42 is circulated. The present invention can be applied even when not.

(4) Coring step The coring step includes grinding a laminated body 5 in which a plurality of plate glasses are laminated using an integral core drill, and a laminated body of annular plate glasses in which inner holes are formed. It is a process to do. Hereinafter, the coring process (grinding process) of this embodiment will be described with reference to FIGS. 3 and 4. FIG. 3 is a diagram showing a grinding device for grinding the laminated body 5 immersed in the coolant 42 in the immersion container 40 in the coring process of the present embodiment. FIG. 4 is a view showing a cross section of the integrated core drill used in the coring process of the present embodiment.

As shown in FIG. 3, the grinding device includes a main device 10, a shaft 12, and an integrated core drill 20. The main device 10 drives the integrated core drill 20. The main device 10 supplies coolant to the interior of the integrated core drill 20.
The integral core drill 20 is substantially cylindrical as a whole. The integrated core drill 20 is supported by a shaft 12 made of, for example, a highly rigid stainless material. The cylindrical shaft 12 is supported so as to be able to rotate with respect to the main device 10 and is driven to rotate at a desired number of rotations by a spindle motor (not shown) in the main device 10.

  The shaft 12 and the integrated core drill 20 are concentric, and the integrated core drill 20 can rotate at high speed with almost no axial center shake due to the rotation of the shaft 12. Therefore, the laminated body 5 can be ground with high precision into an annular plate-like glass laminated body having an inner hole, and the initial stage of processing in which the tip of the integrated core drill 20 contacts the surface of the laminated body 5. The glass on the surface of the laminate 5 is not damaged.

As shown in FIG. 3, the integrated core drill 20 is disposed above the stacked body 5 placed on the placing table 30 in the dipping process. Although not shown, the mounting table 30 is provided with a stopper for the stacked body 5 so that the stacked body 5 is not displaced laterally on the mounting surface of the mounting table 30 during the grinding process. It is preferable.
The grinding apparatus of the present embodiment can move the main apparatus 10 up and down by a servo mechanism (not shown), whereby the integrated core drill 20 and the shaft 12 can be moved up and down integrally.

Here, as shown in FIG. 4, in the integrated core drill 20, a large-diameter cylindrical outer peripheral grinding stone 20a and a small-diameter cylindrical inner peripheral grinding stone 20b are arranged coaxially.
As shown in FIG. 3, the mounting table 30 on which the stacked body 5 is placed is provided with an outer peripheral grinding wheel escape groove 30a and an inner peripheral grinding wheel escape groove 30b. The outer peripheral grinding wheel escape groove 30a and the inner peripheral grinding wheel escape groove 30b are used to prevent the outer peripheral grinding wheel 20a and the inner peripheral grinding wheel 20b of the integrated core drill 20 from colliding with the mounting surface of the mounting table 30. It is a groove.

  As shown in FIG. 3, a coolant supply pipe 17 is installed inside the shaft 12. The coolant is supplied to the inner peripheral grinding surface formed by the contact between the inner peripheral grinding wheel 20b of the integrated core drill 20 and the laminated body 5 by the nozzle 17a at the tip of the coolant supply pipe 17. In the manufacturing method of the present embodiment, the integral core drill 20 and the laminate 5 are immersed in the coolant during the grinding process, and coolant is supplied to the inner peripheral ground surface to some extent by the surrounding coolant. Coolant supply by the coolant supply pipe 17 is not essential.

In the coring step of the present embodiment, the laminated body 5 is ground as follows using the grinding apparatus shown in FIG.
First, as shown in FIG. 3, the integrated core drill 20 is disposed above the stacked body 5 placed on the placing table 30 in the dipping process. Next, the shaft 12 is rotated while the main device 10 is lowered. The rotational speed of the shaft 12 is, for example, about 1500 to 15000 rpm. Accordingly, the integrated core drill 20 is moved in the stacking direction of the stacked body 5 (that is, downward) while rotating around the central axis of the shaft 12.

  The lowering of the integrated core drill 20 is performed until the integrated core drill 20 comes into contact with the outer peripheral grinding wheel escape groove 30a and the inner peripheral grinding wheel escape groove 30b of the mounting table 30. During grinding of the laminate 5 by the integrated core drill 20, the coolant 42 is supplied from the supply port 44 to the immersion container 40, and the coolant 42 is supplied from the nozzle 17 a of the coolant supply pipe 17 to the inner peripheral grinding surface. By doing so, a coolant flow from the inner peripheral grinding surface to the outer peripheral grinding surface can be created, so that the inner peripheral grinding wheel of the integrated core drill 20 and the tip of the outer peripheral grinding wheel are brought into the laminated body as the processing proceeds. Even in the advanced state, it is possible to maintain excellent discharge of sludge generated by grinding and cooling of the grinding site by the coolant flow, and the inner peripheral grinding surface and outer periphery of each sheet glass constituting the laminated body after processing It becomes possible to prevent the roundness of the ground surface from deteriorating.

  During grinding of the laminated body 5 by the integrated core drill 20, the coolant is sufficiently penetrated into the outer peripheral grinding surface and the inner peripheral grinding surface. And the coolant may be drawn into the grinding surface (especially the inner peripheral grinding surface) of the laminate 5 and the processing may proceed again. In order to increase the grinding efficiency, it is preferable that the integral core drill 20 is vibrated slightly by an ultrasonic vibrator (not shown) in the vertical direction during the grinding process. As an example of the ultrasonic vibration, the frequency is 20 kHz and the amplitude is about 5 to 7 μm.

Here, the outer peripheral grinding wheel 20a and the inner peripheral grinding wheel 20b of the integrated core drill 20 of this embodiment will be further described.
The outer peripheral grinding stone 20a and the inner peripheral grinding stone 20b are, for example, metal bond grindstones including diamond as abrasive grains and bronze or cast iron as a binder, but are not limited thereto. Not only a metal bond grindstone, but also a resin bond grindstone containing a resin-based binder, a vitrified bond grindstone containing a ceramic (glassy) binder, or an electrodeposited bond grindstone using electrolytic plating may be used. The thickness of the tip of the outer peripheral grinding stone 20a is 1 to 10 mm, and the thickness of the tip of the inner peripheral grinding stone 20b is 1 to 10 mm.

In the integrated core drill 20 of the present embodiment, the count of the inner peripheral grinding wheel 20b is preferably set to be substantially the same as or larger than the count of the outer peripheral grinding wheel 20a. In addition, it is still more preferable that the count of the inner peripheral grinding stone 20b is set larger than the count of the outer peripheral grinding stone 20a. That is, it is preferable that the abrasive grains of the inner peripheral grinding wheel are substantially the same as or finer than the abrasive grains of the outer peripheral grinding wheel.
As for the range of the count of the inner grinding wheel, the lower limit value is determined based on the required specification of the roundness of the inner hole of the glass substrate for magnetic disks, and the upper limit value is determined by the processing time (processing tact time). The For example, in order to realize a roundness with a high accuracy of 2 μm or less as the roundness of the inner hole of the glass substrate for a magnetic disk, the surface roughness is set as close as possible to the roundness in the coring process. It is necessary. This is to reduce the allowance of the inner peripheral end face in the subsequent chamfering process so that cracks are not generated as much as possible. From this viewpoint, the count of the inner peripheral grinding wheel is preferably 150 or more. Moreover, it is preferable that the count of the inner peripheral grinding wheel is 800 or less because of the limitation of the processing time of the entire coring process.
In addition, grinding resistance of the inner peripheral grinding surface of the laminate 5 becomes larger than that of the outer peripheral grinding surface by making the abrasive grains of the inner peripheral grinding wheel finer. However, since the inner peripheral grinding surface has a shorter processing length, the grinding resistance is reduced. Increase is not at a problematic level.

  On the other hand, the range of the count of the outer peripheral grinding wheel may be generally coarser than that of the inner peripheral grinding wheel. ) Is preferably set to 120 or more. Further, since the outer peripheral grinding surface has a long processing length, it is preferable that the outer peripheral grinding wheel has a count of 600 or less so as not to hinder the grinding process due to an increase in grinding resistance.

  In the integrated core drill 20 of this embodiment, it is preferable that the tip of the inner peripheral grinding stone 20b protrudes from the tip of the outer peripheral grinding stone 20a. Thereby, an inner peripheral part will be processed ahead of an outer peripheral part, and a process axis will become easy to stabilize.

  In the coring process of the present embodiment, the laminated body 5 is ground while the laminated body 5 is immersed in the coolant 42 filled in the immersion container 40. Therefore, the coolant 42 is uniformly supplied between the outer peripheral grinding surface and the outer peripheral grinding wheel 20a during the grinding process. Thereby, compared with the past, sludge is removed more uniformly on the circumference of the outer peripheral grinding surface, the degree of grinding on the outer peripheral grinding surface becomes more uniform, and the outer peripheral grinding surface of the individual plate-like glass constituting the laminate 5 is reduced. Roundness is improved.

(5) Chamfering step After the coring step, a chamfering step of forming a chamfered surface at the end (outer peripheral end surface and inner peripheral end surface) is performed. In the chamfering step, chamfering is performed on the outer peripheral surface and the inner peripheral surface of the laminated body processed into a cylindrical shape by the coring step by, for example, a metal bond grindstone using diamond abrasive grains.

(6) End face polishing process (machining process)
Next, end face polishing (edge polishing) of the annular plate glass is performed.
In the end face polishing, the inner peripheral end face and the outer peripheral end face of the annular plate glass are mirror-finished by brush polishing. At this time, a slurry containing fine particles such as cerium oxide as free abrasive grains is used. By polishing the end face, removal of contamination such as dust, damage or scratches attached to the end face of the annular plate glass prevents the occurrence of thermal asperity and corrosion such as sodium and potassium. It is possible to prevent the occurrence of ion precipitation causing the above.

(7) Laminate Separation Process The laminate 5 is processed by the coring process, the chamfering process, and the edge polishing process, and then the laminate 5 is separated into each annular sheet glass. Is done. For example, depending on the type of the adhesive 5b, the adhesive 5b is softened by immersing the laminate in warm water (80 to 90 degrees Celsius), and the laminate 5 is separated into each annular plate-like glass. Can do.

(8) Grinding process with fixed abrasive In the grinding process with fixed abrasive, grinding is performed on the main surface of the annular plate-like glass using a double-side grinding apparatus. The machining allowance by grinding is, for example, about several μm to 100 μm. The double-sided grinding apparatus has a pair of upper and lower surface plates (upper surface plate and lower surface plate), and an annular plate glass is sandwiched between the upper surface plate and the lower surface plate. Then, by moving either the upper surface plate or the lower surface plate, or both, by moving the annular plate glass and each surface plate relatively, both of the annular plate glasses can be moved. The main surface can be ground.

(9) First Polishing (Main Surface Polishing) Step Next, first polishing is performed on the main surface of the ground annular glass sheet. The machining allowance by the first polishing is, for example, about several μm to 50 μm. The purpose of the first polishing is to remove scratches and distortions remaining on the main surface by grinding with fixed abrasive grains. In the first polishing, for example, a double-side grinding apparatus used in a grinding process using fixed abrasive grains is used. At this time, the point different from the grinding by the fixed abrasive is that a free abrasive that is turbid in the slurry is used instead of the grinding pad and a resin polisher is used.
As the free abrasive grains used for the first polishing, for example, fine particles (particle size: about 1 to 2 μm in diameter) such as cerium oxide suspended in the slurry are used.

(10) Chemical strengthening step Next, the annular plate glass after the first polishing is chemically strengthened.
As the chemical strengthening solution, for example, a mixed solution of potassium nitrate (60% by weight) and sodium sulfate (40% by weight) can be used. In the chemical strengthening, the chemical strengthening liquid is heated to, for example, 300 ° C. to 400 ° C., and the washed annular plate glass is preheated to, for example, 200 ° C. to 300 ° C., and then the annular plate glass is in the chemical strengthening solution. For example, 3 hours to 4 hours. In the case of this immersion, it can be performed in a state of being housed in a holder so that a plurality of annular plate glasses are held at the end faces so that both main surfaces of the annular plate glasses are chemically strengthened. preferable.
Thus, by immersing the annular plate glass in a chemical strengthening solution, lithium ions and sodium ions on the surface layer of the annular plate glass are sodium ions and potassium having a relatively large ion radius in the chemical strengthening solution. Each is replaced by an ion to strengthen the annular plate-like glass. The chemically strengthened annular plate glass is washed. For example, after washing with sulfuric acid, washing with pure water, IPA (isopropyl alcohol), or the like.

(11) Second Polishing (Final Polishing) Step Next, second polishing is performed on the annular plate glass that has been chemically strengthened and sufficiently cleaned. The machining allowance by the second polishing is, for example, about 1 μm. The second polishing is intended for mirror polishing of the main surface. In the second polishing, for example, the double-side grinding apparatus used in the grinding with the fixed abrasive and the first polishing is used. At this time, the difference from the first polishing is that the type and particle size of the free abrasive grains are different and the hardness of the resin polisher is different.
As the free abrasive grains used for the second polishing, for example, fine particles (particle size: for example, 0.01 to 0.1 μm in diameter) such as colloidal silica made turbid in the slurry are used.
The polished annular plate glass is washed with a neutral detergent, pure water, IPA or the like to obtain a glass substrate for a magnetic disk.

[Magnetic disk]
A magnetic disk is obtained as follows using a glass substrate for magnetic disk (hereinafter, glass substrate).
A magnetic disk has a configuration in which, for example, at least an adhesion layer, an underlayer, a magnetic layer (magnetic recording layer), a protective layer, and a lubricating layer are laminated on the main surface of a glass substrate in order from the side closer to the main surface. .
For example, the substrate is introduced into a film forming apparatus that has been evacuated, and a film is sequentially formed from an adhesion layer to a magnetic layer on the main surface of the substrate in an Ar atmosphere by a DC magnetron sputtering method. For example, CrTi can be used as the adhesion layer, and CrRu can be used as the underlayer. After the film formation, a magnetic recording medium can be formed by forming a protective layer using, for example, C ₂ H ₄ by CVD and performing nitriding treatment in which nitrogen is introduced into the surface in the same chamber. . Thereafter, for example, PFPE (polyfluoropolyether) is applied on the protective layer by a dip coating method, whereby a lubricating layer can be formed.

  In the following, the present invention is further illustrated by examples. However, this invention is not limited to the aspect shown in the Example.

(1) Production of molten glass The raw materials were weighed and mixed to obtain a compounded raw material so that a glass having the following composition was obtained. This raw material was put into a melting vessel, heated and melted, clarified and stirred to produce a homogeneous molten glass free from bubbles and unmelted materials. In the obtained glass, bubbles, undissolved material, crystal precipitation, refractory constituting the melting vessel and platinum contamination were not recognized.
[Glass composition]
Glass containing SiO ₂ : 58 to 75 wt%, Al ₂ O ₃ : 5 to 23 wt%, Li ₂ O: 3 to 10 wt%, Na ₂ O: 4 to 13 wt% as main components.

(2) Production of Laminate A plate-like glass having a thickness of 1.0 mm was obtained by a float method in which molten glass having the above-described composition was continuously poured into a bath filled with molten metal containing tin. The surface roughness Ra of the plate glass was 0.01 μm. The plate-like glass was cut out, and the cut-out plate-like glass was laminated on the surface after uniformly applying a visible light curable resin material as an adhesive to produce a laminate. Further, the resin material was cured by irradiating visible light while compressing the laminated body from both sides, so that the laminated glass sheets were not separated.
[Laminated body of Example]
-Size of plate glass: 75mm x 75mm
-Number of layers: 25-Adhesive: Visible light curable resin (Adel, Clearpresto (registered trademark) CP4022)
-Adhesive layer thickness: 30 μm

(3) Immersion of Laminate As described with reference to FIG. 2, the laminate was immersed in a coolant (Chemicoule (registered trademark) C-798S) filled in an immersion container. In addition, an amount of coolant of 20 liters per minute was supplied to the immersion container from the supply port, and the coolant was circulated. The filter used was a bag filter.

(4) Processing of laminated body The laminated body was fixed on the mounting table in the immersion container as shown in FIG. 3, and the coring was ground. At this time, the rotation speed of the integrated core drill was set to 5000 rpm, and grinding was performed while ultrasonic vibration (20 kHz, amplitude 5 to 7 μm) in the vertical direction, and 2.5 inch circular plate-like glass (inner hole diameter φ20 mm) , Outer diameter φ65 mm).
During the grinding process, 17 liters of coolant was supplied to the inner peripheral ground surface. Moreover, the outer periphery grinding wheel and the inner periphery grinding wheel were metal bond wheels (bonding material: cast iron) using diamond abrasive grains. The count of the inner grinding wheel was 600, and the count of the outer grinding wheel was 300. The thickness of each grinding wheel (grinding drill) was 2 mm.

  After grinding of the core ring, the laminate is taken out of the immersion container, and chamfering using an electrodeposition grindstone using diamond abrasive grains is applied to the outer peripheral surface and inner peripheral surface of the laminate processed into a cylindrical shape. Chamfered. The count of the grindstone at this time was 800.

(5) Separation of laminated body and end face polishing Next, the cylindrical laminated body was immersed in warm water (80 to 90 degrees Celsius) and separated into a plurality of annular plate glasses. At this time, no abnormality was found on the surface of each annular plate glass. Thereafter, a slurry containing fine particles of cerium oxide as free abrasive grains was used, and the inner peripheral end face and outer peripheral end face of the annular plate glass were mirror-finished by brush polishing to obtain a glass substrate.

(6) Evaluation of Roundness and Cracks After grinding the core ring, some samples were separated into a plurality of annular plate glasses without chamfering. The annular plate glass thus obtained is referred to as the annular plate glass of Example 1.
Also, without immersing the laminate in the coolant, for example, the core ring is ground while supplying the coolant from the two coolant supply nozzles, and separated into a plurality of annular plate glasses without chamfering. . The annular plate glass thus obtained is referred to as the annular plate glass of Comparative Example 1.

  When the roundness of the outer circumferences of the annular plate glasses of Example 1 and Comparative Example 1 was measured, the roundness of the outer circumference of Example 1 was 1.3 μm, and the roundness of the outer circumference of Comparative Example 1 was 6 μm. 0.0 μm. From this, it can be seen that the roundness of the outer periphery at the end of the grinding of the core ring is improved by grinding the core ring while the laminate is immersed in the coolant as in Example 1.

Moreover, while measuring the roundness of the inner periphery of the glass substrate obtained by the process of said (1)-(5), the presence or absence of the crack of the inner peripheral end surface of a glass substrate was observed with the laser microscope. Let the glass substrate obtained by the process of said (1)-(5) be the glass substrate of Example 2. FIG.
The roundness of the inner periphery of the glass substrate of Example 2 was 1.4 μm. Moreover, as a result of observing the inner peripheral end surface of the glass substrate of Example 2 with a laser microscope, no cracks were observed. Thus, according to the present Example, the target roundness (2 μm) could be achieved without generating cracks.

  Furthermore, the annular plate-like glass of Example 3 and Example 4 in which the grinding processing conditions by coring in the immersion container were the numbers of grinding wheels different from Example 1 were produced. In Example 3, the count of the inner peripheral grinding wheel was 600, and the count of the outer peripheral grinding wheel was 600. In Example 4, the count of the inner peripheral grinding wheel was 600, and the count of the outer peripheral grinding wheel was 800. Then, when the roundness of the outer periphery of the annular plate glass (maximum roundness in 25 sheets) was measured, the roundness of the outer periphery of Example 3 was 2.2 μm. The roundness was 4.5 μm. The roundness of the outer circumference of Example 3 and Example 4 is larger than that of Example 1 because the count of the outer peripheral grinding wheel is the same as or larger than the count of the inner peripheral grinding wheel, and the outer grinding is long. This is presumably because the grinding resistance at the surface has increased.

  As mentioned above, although the manufacturing method of the glass substrate for magnetic discs of this invention was demonstrated in detail, this invention is not limited to the said embodiment, In the range which does not deviate from the main point of this invention, even if various improvement and a change are carried out. Of course it is good.

DESCRIPTION OF SYMBOLS 5 Laminated body 5a Sheet glass 5b Adhesive 10 Main apparatus 12 Shaft 17 Coolant supply pipe 17a Nozzle 20 Integrated core drill 20a Outer grinding wheel 20b Inner grinding wheel 30 Mounting table 30a Outer grinding wheel escape groove 30b Inner grinding wheel escape Groove 40 Immersion container 42 Coolant 44 Supply port 46 Discharge port 48 Filter 50 Pump 52 Piping

Claims (6)

A laminate preparation step of preparing a laminate in which a plurality of plate-like glasses are laminated;
An immersion step of immersing the laminate in a grinding liquid;
By rotating an integrated core drill in which a large-diameter cylindrical outer peripheral grinding wheel and a small-diameter cylindrical inner peripheral grinding wheel are arranged coaxially and moving them in the stacking direction of the laminate, A grinding step of grinding the laminate into a cylindrical shape;
A method for producing a glass substrate for a magnetic disk, comprising: A laminate preparation step of preparing a laminate in which a plurality of plate-like glasses are laminated;
An immersion step of immersing the laminate in a grinding liquid;
An integral core drill in which a large-diameter cylindrical outer peripheral grinding wheel and a small-diameter cylindrical inner peripheral grinding wheel are coaxially arranged is rotated around an axis, and the inner peripheral grinding stone and the plate glass are rotated. A grinding process of grinding the laminate into a cylindrical shape by moving the laminate in the laminating direction while supplying a grinding liquid to the inner peripheral grinding surface formed by
A method for producing a glass substrate for a magnetic disk, comprising:   The manufacturing method of the glass substrate for magnetic discs of Claim 1 or 2 which has the circulation process which circulates the said grinding fluid which immerses the said laminated body.   The method for producing a glass substrate for a magnetic disk according to claim 1, wherein the count of the inner peripheral grinding wheel is larger than the count of the outer peripheral grinding wheel.   5. The method of manufacturing a glass substrate for a magnetic disk according to claim 4, wherein the count of the inner peripheral grinding wheel is 150 or more and 800 or less, and the count of the outer peripheral grinding wheel is 120 or more and 600 or less.   The manufacturing method of the glass substrate for magnetic discs in any one of Claims 1-5 which has a machining process which grind | polishes the end surface of the said plate-shaped glass substrate after the said grinding process.

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