Digital data storage devices are used to store and retrieve large amounts of user data in a fast and efficient manner. A typical data storage device uses a head stack assembly to support an array of vertically aligned data transducers adjacent recording surfaces in a disc stack.
The disc stack is rotated at a relatively high rotational velocity by a spindle motor. An actuator motor (such as a voice coil motor, VCM) pivots the head stack assembly to align the transducers with data tracks defined on the recording surfaces to write data to the tracks and retrieve previously written data from the tracks. The transducers are typically hydrodynamically supported adjacent the recording surfaces by fluidic currents established by rotation of the disc stack.
During manufacturing, it is desirable to protect the head stack assembly during handling and installation (merging) of the transducers with the recording surfaces to prevent damage to the head stack assembly and the disc stack. In devices that employ non-contact recording, it is further generally desirable to prevent contact between the transducers and the recording surfaces during the merging operation.
While various head stack assembly protection and merging methodologies have been proposed in the art, there nevertheless remains a continued need for improvements that provide enhanced protection to the head stack assembly and the disc stack, accommodate smaller dimensional sizes and clearances within the data storage device and facilitate efficient merging of the transducers. It is to these and other improvements that the claimed invention is generally directed.
In accordance with various embodiments, a method comprises supporting a distal end of a cantilevered flexure with a carrier support surface; aligning a merge support surface of a merge tool with a medial portion of the flexure; and using the merge support surface to displace the distal end of the flexure from the carrier support surface and to advance a transducer supported by said distal end to a final position.
In accordance with other embodiments, a method comprises placing a carrier onto an actuator, the actuator comprising an actuator body and at least one cantilevered flexure which supports a transducer at a distal end thereof. The carrier is affixed to the actuator body so as to individually support each said flexure. The actuator is mounted to a base deck adjacent a rotatable medium while the carrier remains placed on the actuator. The actuator is then merged with the medium by advancing a merge tool which displaces the carrier from each said flexure and moves each said flexure to a final position adjacent the medium.
While the claimed invention has utility in any number of different applications,
A disc stack 106 is disposed within the housing 101 and includes a spindle motor 108 which supports and rotates a number of data recording discs 110 (in this case, two) at a constant high speed during operation. A head stack assembly 112 is disposed adjacent the disc stack 106 to support a corresponding array of data transducers 114 adjacent the disc surfaces.
The head stack assembly 112 includes a central body portion 115 that rotates about a cartridge bearing assembly 116 by operation of a voice coil motor, VCM 118. Rigid actuator arms 120 project toward the disc stack 106, and cantilevered flexures (suspension assemblies) 122 project from the actuator arms 120 to respectively support the transducers 114.
The flexures 122 are preferably attached to the actuator arms 120 using a swaging methodology. Annular element 124 is a swage plate for the top actuator arm/flexure combination.
As further shown in
A second retention feature 140 includes a flange 142 which extends from the body portion 132 to form a channel 144 to receive a flange 145 extending from the central body portion 115 of the head stack assembly 112, as depicted in
During placement of the carrier 130 onto the head stack assembly 112, the carrier 130 is initially aligned so that the body portion 132 is substantially perpendicular to the actuator arms 120. The carrier 130 is lowered to insert the post 146 into the aperture 148, after which the carrier 130 is rotated so that the first and second features 134, 140 engage the head stack assembly 112, resulting in the final alignment of
A flexure support member 150 preferably depends downwardly from the main body portion 132 of the carrier 130. The member 150 includes a number of flexure support surfaces 152 to contactingly engage the distal ends of the flexures 122 adjacent the transducers 114, as best viewed in
The support surfaces 152 are preferably configured such that the surfaces 152 deflect the flexures 122 so that the flexures 122 exert a continuous spring force against the surfaces 152. In this way, the flexures 122 are continuously, contactingly supported by the support surfaces 152 until the merging operation is commenced. This reduces the potential for damage to the head stack assembly 112 during handling and installation. Posts 154, 156 and 158 project from the main body portion 132 to permit optical location and automated manipulation of the carrier 130.
A merge tool 160 is shown in
As further shown in
Flexure support arms 170 extend from the distal ends of the arms 166 in a direction substantially perpendicular to the actuator arms 120. The flexure support arms 170 include merge support surfaces 172 which engage the flexures 122 during the merging process.
From
A preferred merge sequence will now be discussed with reference to
The merge tool 160 is next rotated to a second rotational position as shown by
Rotation of the merge tool 160 to the second position of
In some embodiments, the merge tool 160 is oriented such that the merge support surfaces 172 rotate to the rotational position of
However, since the novel relative arrangement of the carrier support surfaces 152 and merge comb support surfaces 172 as presented herein serves to maintain the distal ends of the flexures 122 at known, pre-established elevations, it is contemplated that the merge support surfaces 172 preferably engage and lift the flexures off of the carrier support surfaces 152 (partially or completely) as the merge tool 160 is moved to the position of
Once the merge tool 160 has engaged the head stack assembly 112, the merge tool 160 is further rotated to a third position such as represented by
As the merge tool 160 advances the transducers 114, the carrier 130 contactingly engages the edges of the discs 110, which impedes further inward movement of the carrier 130. The retention features 134, 140 thus disengage while the merge support surfaces 172 continue to advance the flexures 122 inwardly. Clearance groove 174 in the top arm 166 permits clearing movement between the top arm 166 and the retention flange 136 of the carrier 130.
For reference, as desired the merge tool 160 can be provided with an additional feature (not shown) that engages another portion of the head stack assembly 112 (such as one of the rigid actuator arms 120) to further apply a rotational force to the head stack assembly to controllably move the assembly during the merging operation. In this way, the force required to advance the head stack assembly 112 and disengage the features 134, 140 is not borne solely upon the flexures 122 by the merge support surfaces 172.
Once the transducers 114 are advanced to the final desired position, the merge tool 160 retracts and the carrier 130 is removed from the head stack assembly 112. It will be noted that the merge tool is sequentially rotated in a common, unitary rotational direction through
It will now be appreciated that the foregoing embodiments provide several advantages over the prior art. In the present disclosure, the relative locations of the carrier support surfaces 152 and the merge support surfaces 172 are provided so that the carrier 130 supports the flexures 122 at the distal ends thereof adjacent the transducers 114 and the carrier 130 is “between” the transducers 114 and the merge tool 160. This is in contrast to prior art arrangements wherein these relative locations are reversed, advantageously providing improved control and protection for the head stack assembly in that the remaining distance along which the flexures/transducers remain unsupported is substantially reduced.
Also, better retention of the carrier on the head stack assembly can be generally obtained since the carrier is affixed along a longer effective length of the head stack assembly. Note that the carrier 130 disclosed herein is affixed in four different locations along the length of the head stack assembly 112: the post 146, the two retention features 134, 140, and the carrier support surfaces 152.
Another advantage is the fact that, since the carrier “fixes” the locations (elevations) of the distal ends of the cantilevered flexures, the potential risk of damage due to undesired contact between the edges of the flexures and the merge tool is greatly reduced as compared to solutions where the merge tool engages the cantilevered ends of the flexures (on the transducer side of the flexures). This is particularly useful in smaller diameter drives with substantially reduced tolerances and ranges for error.
Still another advantage is the manner in which the merge tool passes under and through the carrier during merging. This ensures proper handoff control of the flexures and greater precision in transducer placement while requiring a relatively small area within the base deck confines to operate.
In view of the foregoing discussion, it will now be appreciated that the present invention, as embodied herein and as claimed below, is generally directed to an apparatus for protecting and installing a head stack assembly (such as 112) having a cantilevered flexure (such as 122) which supports a transducer (such as 114) at a distal end thereof.
In accordance with some preferred embodiments, the apparatus comprises a carrier (such as 130) comprising a carrier support surface (such as 152) arranged to continuously, contactingly support the distal end of the flexure adjacent the transducer and to permit a subsequent engagement of a medial portion of the flexure by a merge tool (such as 160) which disengages the flexure from the carrier support surface while merging the transducer with a recording surface (such as 110).
Preferably, the carrier comprises an elongated body (such as 132) having a medial portion that extends adjacent the medial portion of the flexure and a distal end which supports the carrier support surface. The carrier further preferably comprises at least one retention feature (such as 134, 140) which engages an edge of the head stack assembly to retain the carrier on the head stack assembly.
In accordance with other preferred embodiments, the apparatus comprises a merge tool (such as 160) comprising a merge support surface (such as 172) arranged to contactingly engage a medial portion of the flexure thereby disengaging previous contacting engagement of the distal end of the flexure by a carrier (such as 130) and advancing the transducer to a final position adjacent a recording surface of the disc stack.
Preferably, the merge tool comprises a main body portion (such as 162) and a cantilevered arm which extends from the main body portion, the cantilevered arm having a first portion (such as 166) configured to extend adjacent and substantially parallel to the head stack assembly a separation distance less than a maximum width of said flexure and a second portion (such as 170) which supports the merge support surface and extends substantially perpendicular to the head stack assembly.
In other preferred embodiments, the apparatus generally comprises both the carrier and the merge tool as described above. The apparatus preferably merges the transducer by aligning the merge support surface of the merge tool with the medial portion of the flexure, and then using the merge support surface to displace the distal end of the flexure from a carrier support surface of the carrier and advance the transducer to a final position. Preferably, the merge tool is rotated in a unitary rotational direction to advance the transducer to the final position (such as 180).
In the appended claims, the phrase “continuously, contactingly support” will be understood consistent with the foregoing discussion to describe a configuration where a retention force is continuously applied by the support surface, as compared to a limiting or snubbing surface that is nominally spaced apart from the flexure and which merely limits an amount of deflection should the assembly be subjected to mechanical shock, etc.
It will be understood that even though numerous characteristics and advantages of various embodiments of the present invention have been set forth in the foregoing description, together with details of the structure and function of various embodiments of the invention, this detailed description is illustrative only, and changes may be made in detail, especially in matters of structure and arrangements of parts within the principles of the present invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed. For example, the particular elements may vary depending on the particular application without departing from the spirit and scope of the claimed invention.
This application is a divisional application of U.S. patent application Ser. No. 10/817,609 entitled “Protecting and Merging a Head Stack Assembly of a Data Storage Device,” filed Apr. 2, 2004, the contents of which are hereby incorporated by reference.
Number | Date | Country | |
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Parent | 10817609 | Apr 2004 | US |
Child | 11938159 | Nov 2007 | US |