JP2004146011A - Magnetic disk driving device, and conductive adhesive - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the reliability of a high recording density hard disk drive using a GMR head weak against an electric shock by eliminating discharges between the magnetic head and the disk. <P>SOLUTION: Concerning a spindle motor and a pivot assembly, electric conduction is secured about the part from the disk surface to the magnetic head by bonding each part by using a conductive adhesive at the time of assembly. There is little smearing by the missing filler and a favorable characteristic can be obtained by using an adhesive added with carbon nano-tubes as the filler as to the conductive adhesive. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a magnetic disk drive having a function of recording and reading signals. In particular, the present invention relates to a magnetic disk drive device using a magnetic head that is vulnerable to an electric shock, such as an MR (magnetoresistive) magnetic head or a GMR (giant magnetoresistance) magnetic head. In addition, the present invention relates to a conductive adhesive that can be used for assembling a magnetic disk drive.
[0002]
[Prior art]
With the improvement in signal recording density on magnetic disk drives, particularly for reading signals, MR magnetic heads and GMR magnetic heads have been adopted. These magnetic heads are generally susceptible to static electricity and discharge, and suffer from abnormal operation and damage. As the recording density of disks increases, magnetic heads are required to read weaker magnetic signals, and their structures are becoming more sophisticated and fragile. For this reason, charging measures for the magnetic disk drive have become important, and a structure that does not damage the magnetic head due to electric discharge or a high electric field is required.
[0003]
As a remedy, there is a method of grounding the disk to prevent electrification. For example, in Patent Document 1, in a spindle motor employing a dynamic pressure bearing fluid bearing, a conductive adhesive is used at a site where bonding is required, and the electric resistance between a magnetic disk and a motor housing is reduced. A method for avoiding charging is disclosed. Patent Document 2 discloses a technique using a conductive magnetic fluid as a lubricant for a dynamic pressure bearing.
[0004]
On the other hand, there has been proposed a method of providing a grounding means on the magnetic head side instead of the disk side. Patent Document 3 discloses a method in which a conductive surface is provided close to an MR element and grounded.
[0005]
[Patent Document 1]
JP-A-11-167765 (Claims)
[Patent Document 2]
JP-A-5-347066 (Claims)
[Patent Document 3]
JP-A-4-137212 (Claims)
[0006]
[Problems to be solved by the invention]
However, the method of providing the grounding means only on the side of the magnetic head has disadvantages such as complicating the structure of the head and increasing the cost. In addition, since the charging of the disk has not been eliminated, the possibility that a discharge occurs between the disk and the conductive surface close to the MR element and noise may not be generated cannot be excluded.
[0007]
The method of using a conductive adhesive or conductive lubricant to prevent electrification on the disk side is preferable in terms of cost because no major design change is required for the spindle motor or the like. However, antistatic is not always sufficient. Even if the disk can be completely maintained at the ground potential, static electricity is always generated in the area where the disk and the magnetic head are close to each other. This is because it has a potential with respect to. Generally, the magnetic head is mounted on a swing arm supported by a pivot mechanism, and is grounded via the pivot. However, if the grounding at the pivot is incomplete, discharge still becomes a problem.
[0008]
In addition, the conductive adhesives described above suffer from contamination problems. In order to impart conductivity to the adhesive which is an insulator, particles of conductive metal or graphite are usually added as a filler. However, some of the added particles eventually fall off the adhesive and contaminate the interior of the disk. These particles directly cause a disk operation error, but also cause more serious troubles such as promoting the charging and discharging of the disk and damaging the MR head and the GMR head.
[0009]
In other words, even if the disk is rotated in dust-free, completely clean air, static electricity is not easily generated because there is no friction, but if such dust is dispersed, the dust Through the collision, the charging of the disk is promoted. On the other hand, when the disk is in a charged state, these dusts also trigger discharge.
[0010]
As described above, the use of the conductive adhesive is problematic. However, in the spindle motor and the pivot assembly, the area where the adhesive is used is increased from the viewpoint of improving workability. It is difficult to reduce the number of parts used.
[0011]
The present invention prevents the abnormal operation and destruction of the MR magnetic head and the GMR magnetic head by taking antistatic measures on the magnetic disk and, if necessary, on the magnetic head side while minimizing the cost increase. It is another object of the present invention to provide a magnetic disk drive device in which contamination due to dust and the like is sufficiently small and an assembling operation is easy.
[0012]
[Means for Solving the Problems]
In order to solve the above-described problem, according to the invention of claim 1, a base, a spindle motor installed on the base, and a pivot unit installed on the base, the spindle motor further comprises a base plate A shaft mounted on the base plate, a sleeve accommodating the shaft, a liquid dynamic bearing mechanism rotatably supporting the sleeve with respect to the shaft, a hub rotating integrally with the sleeve, and a hub mounted on the hub. One or more magnetic disks, and the pivot portion further includes a magnetic head vulnerable to electric discharge, a swing arm holding the magnetic head and having conductivity, and supporting the swing arm. A pivot in electrical communication with the arm, the pivot further comprising a pivot shaft and a pivot sleeve, wherein the pivot sleeve is A magnetic disk drive device rotatably supported via a bearing mechanism, comprising a joining structure between the hub and the sleeve, or a joining structure between the shaft and the base plate, or a joint structure between the base plate and the base. In any one or more joint structures, a conductive adhesive is used to adhere or secure conduction, and further, a joint structure between the swing arm and the pivot sleeve, or A joint structure between the pivot sleeve and the outer ring of the ball bearing, or a joint structure between the inner ring of the ball bearing and the pivot shaft, or a joint structure between the pivot shaft and the base, In any one or more of the joining structures, a conductive adhesive is used to adhere or secure conduction. To provide a drive device.
[0013]
In order to solve the above-mentioned problem, according to the invention of claim 2, a base, a spindle motor installed on the base, and a pivot unit installed on the base, the spindle motor further comprises a base plate And a sleeve fixed to the base plate, a shaft inserted through the sleeve, a liquid dynamic pressure bearing mechanism rotatably supporting the sleeve with respect to the shaft, a hub rotating integrally with the shaft, and a hub mounted on the hub. One or more magnetic disks, and the pivot portion further includes a magnetic head vulnerable to electric discharge, a swing arm holding the magnetic head and having conductivity, and supporting the swing arm. A pivot in electrical communication with the arm, the pivot further comprising a pivot shaft and a pivot sleeve; A magnetic disk drive device rotatably supported via a ball bearing mechanism, a joint structure between the hub and the shaft, or a joint structure between the sleeve and the base plate, or the base plate In one or more joint structures between the bases, a conductive adhesive is used to adhere or secure conduction, and furthermore, a joint between the swing arm and the pivot sleeve. Structure, or a joint structure between the pivot sleeve and the outer ring of the ball bearing, or a joint structure between the inner ring of the ball bearing and the pivot shaft, or between the pivot shaft and the base. In any one or more of the joining structures of the joining structure, a conductive adhesive is used for bonding or securing conduction. The symptoms, to provide a magnetic disk drive device.
[0014]
In order to solve the above-mentioned problems, according to the invention of claim 3, a base, a spindle motor installed on the base, and a pivot unit installed on the base, the spindle motor further comprises a base plate A shaft erected on a base plate, a hub, a ball bearing mechanism rotatably supporting the hub with respect to the shaft, and one or more magnetic disks mounted on the hub; Further includes a magnetic head that is vulnerable to discharge, a swing arm that holds the magnetic head and has conductivity, and a pivot that supports the swing arm and is in electrical communication with the arm. The pivot further includes a pivot shaft and a pivot sleeve, wherein the pivot sleeve is rotatably supported via a ball bearing mechanism. A joining structure between the hub and the sleeve, or a joining structure between the sleeve and an outer ring of a ball bearing, or a joining structure between an inner ring of the ball bearing and the shaft, or In any one or more joint structures between the shaft and the base plate, or the joint structure between the base plate and the base, a conductive adhesive is used to adhere or secure conduction. Further, the joint structure between the swing arm and the pivot sleeve, or the joint structure between the pivot sleeve and the outer ring of the ball bearing, or between the inner ring of the ball bearing and the pivot shaft The conductive adhesive is connected to at least one of the joint structure and the joint structure between the pivot shaft and the base. Or it is being used for conducting secure, and wherein a point, to provide a magnetic disk drive device.
[0015]
In order to solve the above-mentioned problem, the invention according to claim 4 includes a base, a spindle motor installed on the base, and a pivot unit installed on the base, wherein the spindle motor further includes a base plate. And a shaft, a ball bearing mechanism that rotatably supports the shaft with respect to the base plate, a hub, and one or more magnetic disks mounted on the hub, wherein the pivot portion further discharges A magnetic head that is vulnerable to the magnetic head, a swing arm that holds the magnetic head and has conductivity, and a pivot that supports the swing arm and is in electrical communication with the arm. The pivot further includes a pivot. A magnetic disk drive device, comprising: a shaft; and a pivot sleeve, wherein the pivot sleeve is rotatably supported via a bearing mechanism, wherein the hub The joint structure between the shafts, or the joint structure between the shaft and the inner ring of the ball bearing, or the joint structure between the outer ring of the ball bearing and the sleeve, or of the sleeve and the base plate In a bonding structure between, or a bonding structure between the base plate and the base, in any one or more bonding structure, a conductive adhesive is used for bonding or ensuring conduction, and further, A joint structure between a swing arm and the pivot sleeve, and a joint structure between the pivot sleeve and the outer ring of the ball bearing, or a joint structure between the inner ring of the ball bearing and the pivot shaft, or In one or more of the joint structures between the pivot shaft and the base, a conductive adhesive is adhered or conduction is secured. And it is characterized by the point used for, to provide a magnetic disk drive device.
[0016]
In order to solve the above problem, in the invention of claim 5, in the magnetic disk drive device of claims 1 to 4, the lubricant used for the liquid dynamic pressure bearing is provided with conductivity. Provided is a magnetic disk drive device characterized by the following points.
[0017]
According to a sixth aspect of the present invention, there is provided a magnetic disk drive according to the first to fifth aspects, wherein the conductive adhesive comprises a non-conductive adhesive formed of a fibrous conductive material. Provided is a magnetic disk drive device characterized by adding 25% by weight.
[0018]
In order to solve the above-mentioned problem, in the invention of claim 7, the carbon nanotubes are added to the non-conductive adhesive in an amount of 0.3 to 5% by weight, and the parts to be bonded are bonded or conduction is ensured. A conductive adhesive characterized in that the carbon nanotubes added are oriented at least locally in the adhesive when applied to the adhesive.
[0019]
According to an eighth aspect of the present invention, there is provided a magnetic disk drive according to the first to fifth aspects, wherein the conductive adhesive is the conductive adhesive according to the seventh aspect. A magnetic disk drive device is provided.
[0020]
According to a ninth aspect of the present invention, there is provided a magnetic disk drive according to the sixth and eighth aspects, wherein an ultraviolet-curable or anaerobic-curable adhesive is used as the non-conductive adhesive. The present invention provides a magnetic disk drive device characterized in that:
[0021]
In order to solve the above problem, according to the invention of claim 10, in the conductive adhesive according to claim 7, an ultraviolet-curable or anaerobic-curable adhesive is used as the non-conductive adhesive. The present invention provides a conductive adhesive characterized by the following.
[0022]
In order to solve the above-described problem, according to the invention of claim 11, a base, a spindle motor installed on the base, and a pivot unit installed on the base, the spindle motor further comprises a base plate A shaft mounted on the base plate, a sleeve accommodating the shaft, a liquid dynamic bearing mechanism rotatably supporting the sleeve with respect to the shaft, a hub rotating integrally with the sleeve, and a hub mounted on the hub. A magnetic disk drive device comprising: one or more magnetic disks; a joint structure between the hub and the sleeve, or a joint structure between the shaft and the base plate, or a joint structure between the base plate and the base. Use a conductive adhesive to bond or secure conduction in any one or more joint structures between , Conductive adhesive is characterized in that a conductive adhesive according to claim 7 or 10, to provide a magnetic disk drive device.
[0023]
In order to solve the above-mentioned problem, according to the invention of claim 12, a base, a spindle motor installed on the base, and a pivot unit installed on the base, the spindle motor further comprises a base plate And a sleeve fixed to the base plate, a shaft inserted into the sleeve, a liquid dynamic pressure bearing mechanism rotatably supporting the shaft with respect to the sleeve, a hub rotating integrally with the shaft, and a hub mounted on the hub. A magnetic disk drive device comprising: one or more magnetic disks; and a joint structure between the hub and the shaft, or a joint structure between the sleeve and the base plate, or the base plate and the base. In any one or more of the joint structures, a conductive adhesive may be used to adhere or secure conduction. And use, the conductive adhesive is characterized in that a conductive adhesive according to claim 7 or 10, to provide a magnetic disk drive device.
[0024]
Hereinafter, the reason why the problem is solved by these means will be described.
[0025]
According to the first aspect of the present invention, in a disk drive device equipped with a spindle motor having a shaft-fixed type liquid dynamic pressure bearing mechanism, not only the spindle motor but also the pivot side is electrically connected to the base using a conductive adhesive. By doing so, a conduction path from the disk surface to the magnetic head is secured, and discharge between the disk and the head is avoided.
[0026]
According to a second aspect of the present invention, in a disk drive device equipped with a spindle motor having a shaft rotating type liquid dynamic bearing mechanism, not only the spindle motor but also the pivot side is electrically connected to the base using a conductive adhesive. By doing so, discharge between the disk and the head is avoided.
[0027]
According to the third aspect of the present invention, in a disk drive apparatus equipped with a fixed shaft type spindle motor having a ball bearing mechanism, not only the spindle motor but also the pivot side is electrically connected to the base using a conductive adhesive. Thus, electric discharge between the disk and the head is avoided.
[0028]
According to a fourth aspect of the present invention, in a disk drive device equipped with a rotary shaft type spindle motor having a ball bearing mechanism, not only the spindle motor but also the pivot side is electrically connected to the base using a conductive adhesive. Thus, electric discharge between the disk and the head is avoided.
[0029]
According to a fifth aspect of the present invention, in the disk drive device including the liquid dynamic pressure bearing mechanism, the disk and the base are formed by using a conductive lubricant as a lubricant used in the liquid dynamic pressure bearing mechanism. And the electrical discharge between the disk and the head is avoided.
[0030]
According to the invention described in claim 6, conductivity is imparted to the non-conductive adhesive by adding a fibrous conductive substance such as carbon fiber. Compared with the case where a non-fibrous conductive filler is added, the filler is less likely to fall off from the adhesive and less likely to cause contamination in the disk chamber.
[0031]
In the invention according to claim 7, conductivity is imparted to the non-conductive adhesive by adding carbon nanotubes as a conductive filler. Since the diameter is smaller than that of carbon fiber, sufficient conductivity can be imparted with a smaller amount of addition, and the inside of the disk chamber is less likely to be contaminated. The effect of improving the conductivity (reducing the electric resistance) can be obtained even with the addition of 0.3% by weight, and the increase in the amount increases as the amount of addition increases. Therefore, it is not within the scope of the present invention.
[0032]
Further, in the present invention, the carbon nanotubes added to the adhesive are oriented so that the fibers of the nanotubes are connected to each other, and high conductivity can be secured even with a small amount of addition. Since the addition amount can be reduced, not only the contamination in the disk chamber can be suppressed, but also the usage amount of relatively expensive carbon nanotubes can be reduced. Here, the expression that the carbon nanotubes are oriented means that the fibers of the carbon nanotubes are not dispersed in the adhesive in a random direction but are dispersed with a certain direction. Say the state.
[0033]
The higher the degree of orientation, the more likely it is that the ends of the fibers will overlap to form a conductive path, but the conductivity will improve even if the orientation is not perfect. In order to orient, it is necessary to apply shear deformation to the adhesive in a sufficiently constant direction in a state where the nanotubes are mixed. As a result, an adhesive in which the nanotubes are oriented in the shear direction is obtained. Conversely, orientation cannot be performed by performing ordinary stirring. To facilitate this operation, the adhesive should preferably have a viscosity of at least 300 cPs (centipoise). However, the viscosity must not be so large that the nanotubes cannot be mixed.
[0034]
For example, when 0.5% by weight of nanotubes are added to the heat-curable anaerobic adhesive having a viscosity of 750 cPs during the mixing operation, the fibers are shifted by 30 degrees from the most frequent orientation of the fiber in the length direction. If the orientation contains 40% of the entire fiber, high conductivity can be obtained. It is not necessary that the nanotubes are oriented in the entire adhesive, and the object of the invention can be achieved even if the nanotubes are oriented only at the minimum necessary for achieving electrical conduction.
[0035]
According to an eighth aspect of the present invention, the conductive adhesive according to the seventh aspect is applied to a disk drive device. Carbon nanotubes impart conductivity with a smaller amount of conductive filler than a fibrous conductive material such as carbon fiber as a conductive filler, and are less likely to fall off from the adhesive. Therefore, it is more effective to suppress contamination in the disk chamber.
[0036]
According to the ninth aspect of the present invention, an ultraviolet-curable adhesive or an anaerobic-curable adhesive is used as the non-conductive adhesive serving as a base of the conductive adhesive. This makes it easier to control the curing of the adhesive, thereby improving productivity.
[0037]
According to a tenth aspect of the present invention, in the conductive adhesive according to the seventh aspect, an ultraviolet curing adhesive or an anaerobic curing adhesive is used as the non-conductive adhesive serving as a base. This makes it easier to control the curing of the adhesive, thereby improving productivity.
[0038]
According to the eleventh aspect of the present invention, in a disk drive device equipped with a spindle motor having a liquid dynamic pressure bearing mechanism of a fixed shaft type, an adhesive containing carbon nanotubes is applied to each joint structure of the spindle motor. To ensure conductivity with the base.
[0039]
By employing this method, a discharge between the disk and the head is avoided.
[0040]
According to the twelfth aspect of the present invention, in a disk drive device equipped with a spindle motor having a shaft rotating type liquid dynamic pressure bearing mechanism, an adhesive containing carbon nanotubes is applied to each joint structure of the spindle motor. To ensure conductivity with the base.
[0041]
By employing this method, a discharge between the disk and the head is avoided.
[0042]
In the claims, a somewhat ambiguous expression such as a joint structure is frequently used, and this expression will be further described. In the present invention, what is called a “joining structure between the member A and the member B” refers to all structures related to a portion where the member A and the member B are connected. In a narrow sense, it refers to the joint itself. For example, when a hub is fitted to the end of the shaft, the joint structure is a fitting surface between the shaft and the hub. However, as a method of attaching the hub to the shaft, in addition to the direct fitting, a method of connecting another member between the shaft and the hub may be used. In such a case, the entire fitting surface or joining surface between the shaft and the other member or between the other member and the hub is referred to as a joining structure. Defining the claims of the present invention using the somewhat uncommon word of the joining structure does not impair the effects of the present invention, and it is clear that the claims mean by the above description. .
[0043]
BEST MODE FOR CARRYING OUT THE INVENTION
(First Embodiment) A first embodiment according to the present invention will be described with reference to FIG.
[0044]
FIG. 1 is a schematic cross-sectional view of a hard disk drive 100 on which a rotary shaft type spindle motor 110 having dynamic pressure bearings 114 and 115 is mounted. FIG. 1 shows only main components such as a spindle motor 110, a disk 150, a pivot assembly 120, and a voice coil motor 127, and omits other components such as a control circuit and wiring. In general, a plurality of disks can be mounted on the spindle motor, but only one disk is shown in FIG. 1 for simplicity, and a spacer mounted between the disks and a clamper mounted for fixing the disks are also included. Omitted. Similarly, FIG. 1 shows only one set of the swing arm and the magnetic head attached to the tip thereof. Actually, it is mounted as many as the number of recording surfaces of the disk. For example, when two disks are mounted and the first disk uses both surfaces for recording and the second disk uses only one, three sets of swing arms and magnetic heads are mounted.
[0045]
In FIG. 1, a conductive adhesive is used in a fitting portion where the shaft 111 is fitted to the base plate 117 of the spindle motor 110, a fitting portion between the sleeve 116 and the hub 112, and a fitting portion between the base plate and the base 102. And enhances continuity. Similarly, the pivot shaft 122 is attached to the base 102 of the hard disk via a jig 128, and a conductive adhesive is also used for attaching the pivot shaft and the jig, and the jig and the base. Similarly, a conductive adhesive is also used to attach the pivot shaft and the inner ring 125 of the ball bearing, the outer ring 126 of the ball bearing and the pivot sleeve 123, and the pivot sleeve and the swing arm 121, so that conduction is enhanced.
[0046]
By using the conductive adhesive as described above, in a hard disk drive equipped with a rotating shaft type spindle motor having a dynamic pressure bearing, the disk 150 and the magnetic head 140 facing the disk 150 via a minute distance are An electrical connection with the base of each hard disk is ensured and the same potential is maintained. By doing so, it is possible to avoid discharge between the magnetic head and the disk or exposure of the magnetic head surface to a high electric field.
[0047]
(Second Embodiment) A second embodiment according to the present invention will be described with reference to FIG.
[0048]
FIG. 2 is a schematic cross-sectional view of a hard disk drive 200 equipped with a fixed shaft type spindle motor 210 having a dynamic pressure bearing. In FIG. 2, as in FIG. 1, only main components are shown, and details are omitted.
[0049]
In FIG. 2, a conductive adhesive is used in a fitting portion where the shaft 211 is fitted to the hub 212, a fitting portion between the sleeve 216 and the base plate 217, and a fitting portion between the base plate and the base 202. , Increasing continuity. Similarly, the pivot shaft 222 is attached to the base 202 of the hard disk via a jig 228, and a conductive adhesive is also used for attaching the pivot shaft and the jig, and the jig and the base. Similarly, a conductive adhesive is used to attach the pivot shaft and the inner ring 225 of the ball bearing, the outer ring 226 of the ball bearing and the pivot sleeve 223, and the pivot sleeve and the swing arm 221.
[0050]
By using the conductive adhesive in this manner, in a hard disk drive equipped with a fixed shaft type spindle motor having a dynamic pressure bearing, the disk 250 and the magnetic head 240 facing the disk 250 via a minute distance are respectively Electrical conduction with the base of the hard disk is ensured, and the same potential is maintained. By doing so, it is possible to avoid discharge between the magnetic head and the disk or exposure of the magnetic head surface to a high electric field.
[0051]
(Third Embodiment) A third embodiment according to the present invention will be described with reference to FIG.
[0052]
FIG. 3 is a schematic cross-sectional view of a hard disk drive 300 equipped with a fixed shaft type spindle motor 310 in which a shaft is supported by ball bearings. In FIG. 3, as in FIGS. 1 and 2, only the main components are shown, and details are omitted.
[0053]
In FIG. 3, a fitting portion where the shaft 311 is fitted to the hub 312, a fitting portion between the shaft and the ball bearing inner ring 314, a fitting portion between the ball bearing outer ring 315 and the sleeve 316, a fitting portion between the sleeve and the base plate 317, a base plate A conductive adhesive is used in a fitting portion between the base and the base 302 to enhance conduction. Similarly, the pivot shaft 322 is attached to the base 302 of the hard disk via a jig, and a conductive adhesive is also used for attaching the pivot shaft and the jig, and the jig and the base. Similarly, the conductive shaft is used to attach the pivot shaft and the inner ring 325 of the ball bearing, the outer ring 326 of the ball bearing and the pivot sleeve 323, and the pivot sleeve and the swing arm 321.
[0054]
By using the conductive adhesive in this manner, in a hard disk drive equipped with a fixed shaft type spindle motor whose shaft is supported by ball bearings, the magnetic head 340 opposing the disk 350 via a very small distance to the disk 350 Are electrically connected to the hard disk base, and are kept at the same potential. By doing so, it is possible to avoid discharge between the magnetic head and the disk or exposure of the magnetic head surface to a high electric field.
[0055]
(Fourth Embodiment) In the first to third embodiments, the conductive adhesive to be used can obtain the effect even if a normal conductive adhesive is used. By using the conductive adhesive provided with the conductive filler, the dropout of the conductive filler is reduced, and it becomes easy to maintain high cleanliness in the disk chamber.
[0056]
(Fifth Embodiment) In contrast to the first to third embodiments, when carbon nanotubes are used as a filler, sufficient conductivity is imparted even with an addition amount of less than 1%. In addition, higher cleanliness can be maintained.
[0057]
FIG. 4 is a schematic diagram of a test piece used for measuring electric resistance when carbon nanotubes are added. A spacer was formed by sandwiching a resin film having a thickness of 12 μm between a piece of aluminum and a piece of stainless steel, and the resulting gap was filled with a conductive adhesive whose electrical resistance was to be measured.
[0058]
As the adhesive, a heat-curable anaerobic adhesive (TB1353) was used, and three types of adhesives in which carbon nanotubes were mixed at a weight ratio of 0.2%, 0.5%, and 2.0%, respectively. Was prepared. Among them, particularly, with the addition of 0.5%, the deformation just to stretch the noodles was repeatedly applied, and the shearing deformation was applied to orient the carbon nanotubes. After filling, the adhesive was cured by heating at 90 ° C. for 1 hour.
[0059]
FIG. 5 shows the results obtained by applying a voltage of 1 V between aluminum and stainless steel and measuring the electrical resistivity of the test piece obtained in this manner.
[0060]
In FIG. 5, the value indicated by the dotted line is the required electric resistance, and it can be seen that the required value is achieved when the carbon nanotube is added in an amount of more than 0.2%. The adhesive with 0.5% addition showed a relatively low electric resistance as compared with the other conditions. This is considered to be because only the sample was subjected to the above-described orientation treatment.
[0061]
The embodiments described above do not limit the embodiments of the present invention. For example, the embodiment does not disclose an example of a hard disk equipped with a spindle motor in which a shaft is fixed and a shaft is supported by a ball bearing, but it is apparent that the present invention can be applied to such a condition. Also, a sufficient effect can be obtained. The adhesive is not limited to the heat-curable anaerobic adhesive, and other types of adhesive such as an ultraviolet-curable adhesive do not cause a substantial problem in the practice of the invention.
[0062]
【The invention's effect】
As described above, according to the present invention, the following beneficial effects can be obtained.
[0063]
In a hard disk drive compatible with high-density recording, the potential difference between the magnetic head and the disk surface can be reduced, so that the magnetic head can be prevented from being damaged by electric discharge or the like.
[0064]
Since a conductive adhesive that does not cause contamination of the disk chamber due to dust or the like can be used, it is possible to prevent damage to the magnetic head and maintain cleanliness of the disk chamber.
[Brief description of the drawings]
FIG. 1 is a schematic sectional view of a hard disk drive according to a first embodiment of the present invention.
FIG. 2 is a schematic sectional view of a hard disk drive according to a second embodiment of the present invention.
FIG. 3 is a schematic sectional view of a hard disk drive according to a third embodiment of the present invention.
FIG. 4 is an explanatory view of a test piece for measuring the electric resistance of the conductive adhesive.
FIG. 5: Electrical resistivity of carbon nanotube-added adhesive
[Explanation of symbols]
100, 200, 300 hard disk drive
101, 201, 301 Hard disk cover
102,202,302 base
110, 210, 310 Spindle motor
111, 211, 311 shaft
112, 212, 312 sleeve
113,213 Thrust plate
313 Hard Disk Ball Bearing
114,214 thrust dynamic pressure bearing
314 Inner ring of hard disk ball bearing
115,215 Radial dynamic pressure bearing
315 Hard disk ball bearing outer ring
116,216,316 sleeve
117,217,317 Base plate
120, 220, 320 pivot assembly
121,221,321 swing arm
122, 222, 322 pivot shaft
123, 223, 323 pivot sleeve
124,224,324 pivot ball bearings
125,225,325 Pivot ball bearing inner ring
126,226,326 Pivot ball bearing outer ring
127, 227, 327 Voice coil motor
128,228,328 Jig
140, 240, 340 magnetic head
150, 250, 350 disks

Claims (12)

A base, a spindle motor installed on the base, and a pivot unit installed on the base,
The spindle motor further includes a base plate, a shaft erected on the base plate, a sleeve accommodating the shaft, a liquid dynamic bearing mechanism rotatably supporting the sleeve with respect to the shaft, and integrally rotating with the sleeve. Having a hub and one or more magnetic disks mounted on the hub,
The pivot portion further includes a magnetic head that is vulnerable to discharge, a swing arm that holds the magnetic head and has conductivity, and a pivot that supports the swing arm and is in electrical communication with the arm. And
The pivot further includes a pivot shaft and a pivot sleeve, wherein the pivot sleeve is rotatably supported via a ball bearing mechanism.
A magnetic disk drive device,
In a joint structure between the hub and the sleeve, or a joint structure between the shaft and the base plate, or a joint structure between the base plate and the base, a conductive adhesive Is used to adhere or secure conduction.
A joint structure between the swing arm and the pivot sleeve, or a joint structure between the pivot sleeve and the outer ring of the ball bearing, or a joint structure between the inner ring of the ball bearing and the pivot shaft, Alternatively, in any one or more joint structures of the joint structure between the pivot shaft and the base, a conductive adhesive is used for bonding or securing conduction.
A magnetic disk drive device characterized by the following points. A base, a spindle motor installed on the base, and a pivot unit installed on the base,
The spindle motor further includes a base plate, a sleeve fixed to the base plate, a shaft inserted into the sleeve, a liquid dynamic pressure bearing mechanism that rotatably supports the sleeve with respect to the shaft, and rotates integrally with the shaft. Having a hub and one or more magnetic disks mounted on the hub,
The pivot portion further includes a magnetic head that is vulnerable to discharge, a swing arm that holds the magnetic head and has conductivity, and a pivot that supports the swing arm and is in electrical communication with the arm. And
The pivot further includes a pivot shaft and a pivot sleeve, wherein the pivot sleeve is rotatably supported via a ball bearing mechanism.
A magnetic disk drive device,
In one or more joint structures of the joint structure between the hub and the shaft, or the joint structure between the sleeve and the base plate, or the joint structure between the base plate and the base, Adhesive is used to bond or secure conduction.
A joint structure between the swing arm and the pivot sleeve, or a joint structure between the pivot sleeve and the outer ring of the ball bearing, or a joint structure between the inner ring of the ball bearing and the pivot shaft, Alternatively, in any one or more joint structures of the joint structure between the pivot shaft and the base, a conductive adhesive is used for bonding or securing conduction.
A magnetic disk drive device characterized by the following points. A base, a spindle motor installed on the base, and a pivot unit installed on the base,
The spindle motor further includes a base plate, a shaft erected on the base plate, a hub, a ball bearing mechanism that rotatably supports the hub with respect to the shaft, and one or more magnetic disks mounted on the hub. , And
The pivot portion further includes a magnetic head that is vulnerable to discharge, a swing arm that holds the magnetic head and has conductivity, and a pivot that supports the swing arm and is in electrical communication with the arm. And
The pivot further includes a pivot shaft and a pivot sleeve, wherein the pivot sleeve is rotatably supported via a ball bearing mechanism.
A magnetic disk drive device,
The joint structure between the hub and the sleeve, or the joint structure between the sleeve and the outer ring of the ball bearing, or the joint structure between the inner ring of the ball bearing and the shaft, or the shaft and the shaft A bonding structure between base plates, or a bonding structure between the base plate and the base, in any one or more bonding structure, a conductive adhesive is used for bonding or ensuring conduction,
A joint structure between the swing arm and the pivot sleeve, or a joint structure between the pivot sleeve and the outer ring of the ball bearing, or a joint structure between the inner ring of the ball bearing and the pivot shaft, Alternatively, in any one or more joint structures of the joint structure between the pivot shaft and the base, a conductive adhesive is used for bonding or securing conduction.
A magnetic disk drive device characterized by the following points. A base, a spindle motor installed on the base, and a pivot unit installed on the base,
The spindle motor further has a base plate, a shaft, a ball bearing mechanism that rotatably supports the shaft with respect to the base plate, a hub, and one or more magnetic disks mounted on the hub,
The pivot portion further includes a magnetic head that is vulnerable to discharge, a swing arm that holds the magnetic head and has conductivity, and a pivot that supports the swing arm and is in electrical communication with the arm. And
The pivot further includes a pivot shaft and a pivot sleeve, wherein the pivot sleeve is rotatably supported via a bearing mechanism.
A magnetic disk drive device,
The joint structure between the hub and the shaft, or the joint structure between the shaft and the inner ring of the ball bearing, or the joint structure between the outer ring of the ball bearing and the sleeve, or the sleeve In a bonding structure between the base plates, or a bonding structure between the base plate and the base, in any one or more bonding structures, a conductive adhesive is used for bonding or ensuring conduction, Further, a joint structure between the swing arm and the pivot sleeve, and a joint structure between the pivot sleeve and the outer ring of the ball bearing, or a joint between the inner ring of the ball bearing and the pivot shaft A conductive adhesive is adhered or adhered to at least one of a joint structure and a joint structure between the pivot shaft and the base. Are being used for through secure,
A magnetic disk drive device characterized by the following points. 5. The magnetic disk drive according to claim 1, wherein:
A magnetic disk drive device, wherein the lubricant used for the liquid dynamic pressure bearing is provided with conductivity. 6. The magnetic disk drive according to claim 1, wherein the conductive adhesive is obtained by adding a fibrous conductive material to a non-conductive adhesive in an amount of 10 to 25% by weight. Drive device. In a state where 0.3 to 5% by weight of carbon nanotubes are added to a non-conductive adhesive and the parts to be bonded are adhered or applied to secure conduction, the added carbon nanotubes A conductive adhesive characterized in that it is oriented at least locally in the adhesive. 6. The magnetic disk drive according to claim 1, wherein the conductive adhesive is the conductive adhesive according to claim 7. 9. The magnetic disk drive according to claim 6, wherein an ultraviolet-curable or anaerobic-curable adhesive is used as said non-conductive adhesive. The conductive adhesive according to claim 7, wherein an ultraviolet-curable or anaerobic-curable adhesive is used as the non-conductive adhesive. A base, a spindle motor installed on the base, and a pivot unit installed on the base,
The spindle motor further includes a base plate, a shaft erected on the base plate, a sleeve accommodating the shaft, a liquid dynamic bearing mechanism rotatably supporting the sleeve with respect to the shaft, and integrally rotating with the sleeve. Having a hub and one or more magnetic disks mounted on the hub,
A magnetic disk drive device,
In one or more joint structures of the joint structure between the hub and the sleeve, or the joint structure of the shaft and the base plate, or the joint structure of the base plate and the base, Use the agent to adhere or secure conduction,
A magnetic disk drive device, wherein the conductive adhesive is the conductive adhesive according to claim 7. A base, a spindle motor installed on the base, and a pivot unit installed on the base,
The spindle motor further includes a base plate, a sleeve fixed to the base plate, a shaft inserted through the sleeve, a liquid dynamic bearing mechanism rotatably supporting the shaft with respect to the sleeve, and a shaft that rotates integrally with the shaft. A magnetic disk drive device comprising a hub and one or more magnetic disks mounted on the hub,
In one or more joint structures between the hub and the shaft, or the joint structure between the sleeve and the base plate, or the joint structure between the base plate and the base, the conductive structure Use an adhesive to bond or secure conduction,
A magnetic disk drive device, wherein the conductive adhesive is the conductive adhesive according to claim 7.

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