SYSTEM AND METHOD OF INTRODUCING A PREFERENTIAL CURVATURE TO A FLEXIBLE MEDIUM FOR REDUCED MEDIUM VIBRATION AND SENSOR TO MEDIUM SPACING WITH A DISK DRIVE HEAD STACK ASSEMBLY HAVING A NON-ZERO STATIC ROLL ATTITUDE

A head stack assembly is provided for interfacing with a flexible medium of a disk. The head stack assembly includes a first head and a second head located substantially adjacent to the first head wherein the flexible medium may be disposed between the first head and the second head. The first head and the second head are substantially parallel to each other and disposed at a static roll angle θa and a static roll angle θb, respectively, from the flexible medium to impart a curvature to the flexible medium of a disk. The curvature reduces out-of-plane vibrations of the flexible medium and thereby enhances the electrical communicative signal between the flexible medium and the first and the second heads.

FIELD OF THE INVENTION

The present invention generally relates to the field of flexible medium disk drives, more particularly, the present invention relates to a disk drive head gimbal assembly with a flexure roll that imparts a curvature in a flexible medium, thereby reducing out-of-plane vibration of the flexible medium in the region near a sensor and providing enhanced electrical communication between the flexible medium and the disk drive.

BACKGROUND OF THE INVENTION

In a typical flexible medium disk drive system, the flexible medium of the disk has signals magnetically encoded on the flexible medium. The disk rotates and a disk drive sensor senses the magnetic signals as the flexible medium rotates past the disk drive sensor. The disk drive sensor converts the magnetic signals to electrical signals for use by other systems.

The magnetic signal levels of the disk decrease substantially exponentially with the distance from the flexible medium of the disk. Therefore, it is desired to place the disk drive sensor as close as possible to the flexible medium. Additionally, the speed of current disk drives causes the flexible medium to vibrate out-of-plane, which in turn, may decrease the accuracy of the communication between the flexible medium and the disk drive. Therefore, it is desired to reduce vibration of the flexible medium in the region near the disk drive sensor.

A typical disk drive system includes a head head stack assembly including two head gimbal assemblies positioned such that their heads face each other and are placed on opposite sides of the flexible medium. The heads include sensors for sensing the magnetic signals of the flexible medium. A force is applied to the two heads, sandwiching the flexible medium between the two heads. The sandwiching of the flexible medium between the two heads decreases the out-of-plane vibration of the flexible medium in the region of the heads, resulting in increased accuracy of communication between the flexible medium and the disk drive. Generally, increasing the force will reduce the out-of-plane vibration of the flexible medium and increase the accuracy of the communication.

However, increasing the force too much may adversely affect the system by increasing the wear of the flexible medium and/or the heads. To further explain, a rotating disk in conjunction with the heads creates an area of increased air pressure near the surface of the disk and beneath the heads that pushes the head gimbal assembly slightly away from the surface of the flexible medium. This phenomena causes portions of the heads to “fly” slightly above the surface of the flexible medium.

Because portions of the heads are “flying” above the surface of the flexible medium, the head gimbal assembly does not significantly wear the flexible medium. However, because portions of the heads are flying above the surface of the flexible medium, the flexible medium is allowed to vibrate, albeit less than if the flexible medium were not sandwiched between the two heads of the head stack assembly.

Therefore, if the forces pushing the heads of the head stack assembly together are increased significantly, the disk drive heads may rub against the flexible medium with a relatively large force, which in turn may increase the wear of the flexible medium and/or the head. Thus, simply increasing the forces pushing the heads together is of limited value in further reducing out-of-plane vibration of the flexible medium. Conventional techniques disclose keeping the disk drive heads as parallel as possible to the flexible medium and selecting a force that minimizes both vibration and wear.

In view of the above problems, there is a recognized need for a system and method of reducing flexible medium out-of-plane vibration to increase the accuracy and speed of a disk drive. The present invention satisfies this need.

SUMMARY OF THE PRESENT INVENTION

The present invention is directed to a disk drive head gimbal assembly with a flexure roll that imparts a curvature in a flexible medium, thereby reducing out-of-plane vibration of the flexible medium in the region near a sensor and providing enhanced electrical communication between the flexible medium and the disk drive.

According to an aspect of the present invention, a head stack assembly is provided for interfacing with a flexible medium of a disk. The head stack assembly includes a first head and a second head located substantially adjacent to the first head wherein the flexible medium may be disposed between the first head and the second head. The first head and the second head are substantially parallel to each other and disposed at an angle θa and an angle θb, respectively, from the plane of the flexible medium.

According to another aspect of the present invention, the head stack assembly includes a first head gimbal assembly and a second head gimbal assembly. Each head gimbal assembly includes a load beam, a flexure member coupled to the load beam, and a head coupled to the flexure member. The flexure member has a static roll angle θa from the plane of the flexible medium.

According to another aspect of the present invention, a method is provided for reducing out-of-plane vibration in a flexible medium in a region near a sensor of a head stack assembly having a first and second head. The flexible medium is placed between the first and second head. The first and second heads are angled such that the first and second head remain parallel but offset from the flexible medium, thereby imparting a curvature in the flexible medium, and enhancing the communicative signal between the flexible medium and the head stack assembly.

These and further aspects of the present invention will be more fully discussed herein.

DETAILED DESCRIPTION OF THE ILLUSTRATIVE EMBODIMENTS

The present invention is directed to a disk drive head stack assembly with head gimbal assemblies each utilizing suspension assemblies with static roll angles that impart a curvature in a flexible medium, thereby reducing out-of-plane vibration of the flexible medium in the region near sensors of the head stack assembly and providing enhanced electrical communication between the flexible medium and the disk drive.

Certain terminology may be used in the following description for convenience only and is not considered to be limiting. For example, the words “left”, “right”, “top”, and “bottom” designate directions in the drawings to which reference is made. Likewise, the words “inwardly” and “outwardly” are directions toward and away from, respectively, the geometric center of the referenced object. The terminology includes the words above specifically mentioned, derivatives thereof, and words of similar import.

The head stack assembly of the present invention may be employed with a flexible medium, such as the flexible magnetic medium utilized in the ZIP®100 disk cartridge, the ZIP®250 disk cartridge, the POCKETZIP®40 disk cartridge, or the POCKETZIP®100 disk cartridge (lomega Corporation, Roy, Utah). Additionally, with the development of storage media capable of greater densities, improved read/writing devices are needed. In the embodiments described below, the head stack assembly is described as a head stack assembly that is employed with magnetic storage medium. However, it should be understood that the head stack assembly of the present invention can be employed with any flexible medium.

The present invention may be employed with a variety of disk drives, including but not limited to a stand alone disk drive, a personal computer disk drive, a portable personal computer disk drive, such as in a laptop computer disk drive or a notebook type of computer disk drive, a scanner disk drive, a camera disk drive, a hand held type of computer disk drive, a digital audio player, and the like.

By way of background, the disk drive with which the head stack assembly of this invention may be employed may have a disk drive motor for operating the disk cartridge, such as, but not limited to, the disk drive as shown in U.S. Pat. No. 5,650,891. In this type of disk drive, the disk drive motor is a spindle motor that is disposed in the chassis of the disk drive. When the disk cartridge is inserted into the disk drive, the disk drive motor engages a hub of the disk cartridge. When engaged with the hub of the disk cartridge, the disk drive motor is operated by a microprocessor to rotate the hub and the attached flexible medium. The head stack assembly of the present invention is also referred to as the actuator within a disk drive.

Neither the disk drive nor the disk cartridge described above are part of this invention. However, they may be used in combination with head stack assembly10of this invention, which is described in detail below.

As shown inFIG. 1, head stack assembly10includes a first head gimbal assembly60aand a second head gimbal assembly60b. First head gimbal assembly60aincludes a first head20a, a first flexure member16a, and a first load beam12a. Second head gimbal assembly60bincludes a second head20b, a second flexure member16b, and a second load beam12b. The following discussion of first head gimbal assembly also applies to second head gimbal assembly60b.

Head20ais coupled to flexure member16aat a distal end of flexure member16a. In the present embodiment, head20ais coupled to flexure member16awith an adhesive; however, any coupling method may be used, such as, fastening, welding, and the like.

A proximal end of flexure member16ais coupled to a proximal end of load beam12a. In the present embodiment, flexure member16ais coupled to load beam12awith welds; however, any coupling method may be used, such as for example, fastening, and the like. Load beam12aincludes a dimple14athat is spring loaded against flexure member16a. Dimple14aallows flexure member16ato change the static roll angle of flexure member16a, as best shown in FIG.4and described in more detail below. Static roll angle is defined herein as the angle of the head relative to the plane of the flexible media along a radial line of the plane of the flexible medium, with no flexible medium located between the heads and no force acting to compress the heads together (i.e., no gram loading of the heads thereby, the heads being spaced apart rather than coupled together).

Flexible medium11may be disposed between first head20aand second head20b, as shown in FIG.1. Particularly, first head20amay be disposed proximal to first surface18of flexible medium11, and second head20bmay be disposed proximal to second surface19of flexible medium11. As shown, first head20ais disposed above the flexible medium and second head20bis disposed beneath the flexible medium; however, the invention is not so limited. First head20aand second head20bmust be disposed on opposing sides of the flexible medium and adjacent to each other.

Both first head20aand second head20bhave a pair of longitudinal rails22(including longitudinal rails22a(1),22a(2),22b(1), and22b(2)), as best seen in FIG.2. Although only first head20ais shown inFIG. 2, it will be appreciated that second head20bis typically identical to first head20a. The following discussion of first head20aapplies to second head20b. Longitudinal rails22of head20amay extend the length of head20a. Each of rails22has a first longitudinal end24and a second longitudinal end26. In one embodiment, both first longitudinal end24and second longitudinal end26of rails22are beveled; however, they need not be beveled. First longitudinal end24of each of rails22may be the leading edge of rails22, and second longitudinal end26of each of rails22may be the trailing edge of each of rails22. The trailing edge is that which trails the direction of motion of the head relative to the flexible medium, and the leading edge is that which leads the direction of motion of the head relative to the flexible medium.

One of rails22of head20ahas a sensor25afor electrically communicating with a disk drive and/or a microprocessor. Similarly, one of rails22of head20bhas a sensor25b, as is best seen in FIG.4.

When assembled to flexure member16a, as shown inFIG. 1, first head20ais disposed above second head20b. Preferably, the heads are gram-loaded towards each other when assembled in the head stack assembly.

FIG. 3is a top view of flexure member16a. As shown, flexure member16aincludes a proximal end50and a distal end51. Proximal end50and distal end51are connected via a first force member35a(1) and a second force member35a(2). First force member35a(1) and second force member35a(2) may be configured to provide a static roll angle to head20a. For example, distal end51is angled with respect to proximal end50to form a static roll angle. Also, first force member35a(1) and second force member35a(2) may be configured to provide resistance to flexing. These parameters are determined by the material, thickness, and length of flexure member16a. Flexure member16aalso includes a tongue section52for mounting of head20a.

FIGS. 4 and 5depict the operation of head stack assembly10of the present invention. As shown, in the interfacing position, flexible medium11of the disk drive is disposed between first head20aand second head20b. In operation, flexible medium11is rotated by a disk drive spindle motor, or the like. The direction of rotation of flexible medium11is into leading edges24of heads20a,20b, as is best seen in FIG.1.

As is generally understood, heads20a,20bare preloaded or gram-loaded with a force towards the flexible medium. The gram-loading causes biasing of heads20a,20btowards the flexible medium.

When the flexible medium is rotated, the medium wrinkles and vibrates out-of-plane. Importantly, by imparting a curvature in the flexible medium with heads20a,20b, out-of-plane vibrations may be reduced in the region of the flexible medium near a sensor, as described in more detail below. This reduction in vibration enhances the communication between the flexible medium and sensors25a,25bof head stack assembly10.

As shown inFIG. 4, first gimbal assembly60aincludes head20a, flexure member16a, and load beam12a. Head20aincludes a body21a, first rail22a(1), second rail22a(2), and sensor25a. It should be appreciated that second head20bis substantially similar to first head20aand the following discussion applies to second head20b.

Body21ais substantially rectangular, however, body21amay be any shape. First rail22a(1) and second rail22a(2) may extend the length of head20aas discussed above. Second rail22a(2) includes sensor25afor communicating with flexible medium11.

First force member35a(1) is coupled between load beam12aand head20aproximate to first rail22a(1). Second force member35a(2) is coupled between load beam12aand head20aproximate to second rail22a(2). Force members35may be leaf springs or any other force member capable of applying a force between load beam12aand head20a.

In a similar manner, second head20bis coupled to load beam12b. Again, in a similar manner, first force member35b(1) is coupled between load beam12band head20bproximate to first rail22b(1). Second force member35b(2) is coupled between load beam12band head20bproximate to second rail22b(2).

Rail22a(2) having sensor25aof first head20ais disposed above and adjacent to rail22b(1) of second head20bthat does not have a sensor, as shown in FIG.4. Similarly, rail22b(2) of second head20bhaving sensor25bis disposed beneath and adjacent to rail22a(1) of first head20athat does not have a sensor.

In first head gimbal assembly60a, first force member35a(1) is offset from the plane of the flexible medium by an angle of θa. In second head gimbal assembly60b, first force member35b(1) is offset from the plane of the flexible medium by an angle of θb (i.e., a static roll angle). In this manner, first and second head20a,20bremain substantially parallel to each other, but are offset slightly from each other.

When the flexible medium is rotated through the first and second heads, the flexible medium deflects in a ripple or wave shape since it is deflecting both upward and downward at different points, as shown in FIG.5. The imparted curvature reduces out-of-plane vibration of the flexible medium in the region near sensors25a,25b.

For example, a rotating flexible medium can vibrate with out-of-plane displacements of 400,000 nm. Disposing the flexible medium between two heads can reduce out-of-plane displacements to within the range of about 40 nm to about 60 nm in the region near the sensors. It has been shown that the present invention may reduce out-of-plane displacements an additional about 5 nm to about 10 nm in the region near the sensors.

Moreover, as illustrated inFIG. 5, the sensor is placed near the convex side of the curvature of flexible medium11to minimize the distance between flexible medium11and sensors25a,25b, further enhancing electrical communication between flexible medium11and sensors25a,25bof the head stack assembly.

In one embodiment, static roll angle θa and static roll angle θb are substantially the same and are from about 1 degree to about 2.5 degrees. In another embodiment, static roll angle θa and static roll angle θb are both about 2 degrees. It will be appreciated that the static roll angles disclosed are the angles with no flexible medium located between heads20and with the heads unloaded. With a rotating flexible medium located between the heads it is no longer a static roll, but rather a dynamic roll and the dynamic angles are usually smaller than the static angles. The actual dynamic angles will depend on which portion of the flexible medium the heads are near. For example, it is expected that with a rotating flexible medium, the actual angle will be smaller towards the center of the medium, as the medium is more rigid towards the center. Also, the actual angle will depend on the thickness of the flexible medium, the rotational speed of the flexible medium, the thickness of the flexure member, as well as other factors.

FIG. 6is a rear view of a head stack assembly in accordance with another embodiment of the present invention. As shown inFIG. 6, first head gimbal assembly60aincludes head20a, load beam12a, first force member35a(1) and second force member35a(2). Head20aincludes body21a. It should be appreciated that second head assembly60bis substantially similar to first head assembly20aand the following discussion applies to second head assembly60b.

First force member5a(1) is coupled between load beam12aand the first side of body21a. Second force member35a(2) is coupled between load beam12aand the second side of body21a. Force members35may be leaf springs or any other force member capable of applying a force between load beam12aand head20a.

In a similar manner, second head20bis coupled to load beam12b. Again, in a similar manner, first force member35b(1) is coupled between load beam12band the first side of body21b. Second force member35b(2) is coupled between load beam12band second side of body21b.

In first head gimbal assembly60a, first force member35a(1) is offset from the plane of the flexible medium by a static roll angle of θa. In second head gimbal assembly60b, first force member35b(1) is offset from the plane of the flexible medium by a static roll angle of θb. In this manner, first and second head20a,20bremain substantially parallel to each other, but are offset slightly from each other.

When the flexible medium is rotated through the first and second heads, the flexible medium deflects in a ripple or wave shape since it is deflecting both upward and downward at different points, as shown in FIG.7. The imparted curvature reduces out-of-plane vibration of the flexible medium in the region near sensors25a,25b.

The present invention may be employed with heads of a variety of sizes, including but not limited to, standard, micro, nano, and pico heads.

As is generally understood, the voltage or strength of the electrical signal between the head and the flexible medium is dependent upon the spacing between the medium and the sensor. Moreover, the accuracy of the electrical communication between the flexible medium and a disk drive depends upon constant and proximate spacing between the sensor of the head gimbal assembly and the flexible medium. Therefore, any vibration of the flexible medium in the region near the sensor is adverse to communication between the sensor and the flexible medium. For sinusoidal magnetic playback, the strength of the signal decreases in an exponential relationship with the spacing between the medium and the sensor. Thus, with the flexible medium having reduced out-of-plane vibration in the region near the sensor, electrical communication between the sensor and the flexible medium may be enhanced. This is particularly important for magnetic heads that must interface with improved magnetic medium that is capable of a relatively high density and more storage capacity. As described in further detail below, the head stack assembly of the present invention enhances electrical communication with data storage medium such as the medium employed in the ZIP®100 disk cartridge, the ZIP®250 disk cartridge, the POCKETZIP®40 disk cartridge, or the POCKETZIP®100 disk cartridge.

It is desired to increase the speed of rotation of the flexible medium to increase the data transmission rate between the medium and the sensor. However, high rotational rates generally result in larger vibrations of the medium. The present invention permits increased speeds of rotation of the medium by providing reduced out-of-plane vibration of the flexible medium allowing the sensor to remain in communication with the medium at higher speeds and thereby permit higher data transmission rates.

It is noted that the foregoing examples have been provided merely for the purpose of explanation and are in no way to be construed as limiting of the present invention. While the invention has been described with reference to exemplary embodiments, it is understood that the words which have been used herein are words of description and illustration, rather than words of limitations. Further, although the invention has been described herein with reference to particular structures, methods, materials, and embodiments, the invention is not intended to be limited to the particulars disclosed herein; rather, the invention extends to all structures, methods and uses that are within the scope of the appended claims. Those skilled in the art, having the benefit of the teachings of this specification, may effect numerous modifications thereto and changes may be made without departing from the scope and spirit of the invention, as defined by the appended claims.