Low speed moving magnet motor having a high inertia rotor

Electrical generator or motor structure – Dynamoelectric – Oscillating

Reexamination Certificate

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Reexamination Certificate

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06498407

ABSTRACT:

The present invention relates to a moving magnet motor and a method of operating a moving magnet motor. The present invention has particular applicability to a low speed moving magnet motor, for example a servowriter positioner motor.
In a storage medium in which data is read from and/or written to the medium by a read/write head which is movable relative to the storage medium, movement of the read/write head is usually controlled by a servo system. The servo system uses servo information which is prerecorded on the storage medium. By reading this servo information, the actual position of the read/write head relative to the storage medium can be determined and control signals sent to move the head accordingly.
In a head disk assembly, the storage medium is a magnetic “hard” disk and the read/write head or heads are mounted for movement over the disk surface by an arm which is often known as the “product arm”.
A servowriter is used to write the servo information to the disk, The servowriter has its own dedicated clock head. The servowriter clock head is offered up to the disk and used firstly to write a (usually temporary) clock track on the disk to provide a series of clock transitions indicating angular position around the disk. The servowriter has a positioner arm which is linked to the product arm such that movement of the positioner arm causes a corresponding movement of the product arm. Movement of the servowriter positioner arm is controlled very precisely by an angular detection system in the servowriter. The angular detection system may be a laser reflecting light from a very fine graticule on the positioner arm for example. After the clock track has been written, the clock transitions are read with the servowriter clock head so that the angular position of the disk relative to the servowriter is accurately known at all times. The positioner arm is moved to preselected angular positions by a positioner motor of the servowriter. The product arm moves with the positioner arm and the product read/write head is used to write the servo tracks at the required preselected angular positions on the disk.
It is important that the servo tracks be written as quickly as possible so as to achieve faster throughput of the hard disks during manufacture, especially as servowriting is typically carried out in a clean room where space is limited and expensive. It is therefore important for a servowriter to achieve quick track seek (i.e. fast movement of the head between tracks on the storage medium) and quick track settle (i.e. the head should come to rest quickly once in position over the desired track).
Conventional practice has been to mechanically link the servowriter positioner arm with the product arm so that movement of the positioner arm automatically brings about a corresponding movement of the product arm. However, this mechanical linkage between the positioner arm and the product arm increases the effective inertia of the servowriter positioner which controls movement of the positioner arm. Moreover, the positioner arm is usually connected only to the lowermost product arm of a stack of product arms. The product arms above the lowermost arm are effectively a resonant body which, because they are mechanically linked to the positioner arm, can lead to unexpected and undesired resonances. Such resonances are difficult to predict throughout the range of movement of the positioner arm and the mechanical link slows movement of the servowriter positioner arm and the product arms. More importantly in a servowriter, the resonances tend to be lower in frequency than they would be in an operational disk drive. This reduces the bandwidth of the servo which is used to control the position of the product arm during servowriting, resulting in a worsening of the seek/settle time and an increase in the track-to-track spacing. One known way of overcoming this problem is to drive the product arm via its own drive mechanism during the servowriting process and disconnect the mechanical linkage between the product arm and the positioner arm. The relative motion between the product arm and the positioner arm can be detected by a null sensor the output of which is used to control the drive current provided to the product arm drive mechanism via a separate servo so as to move the product arm in tandem with the positioner arm during servowriting. The use of this null sensor and separate servo for moving the product arm also improves the positioner servo bandwidth and therefore the seek/settle time of the positioner.
At least some prior art servowriter positioner motors for moving the positioner arm have been of the moving coil type. As such, flexible supply cables have to be connected to the moving coils of the positioner motor. These flexible cables provide an undesirable bias to the positioner arm which therefore affects movement of the positioner arm.
U.S. Pat. No. 4,775,908 discloses a moving magnet motor for moving a product arm of a hard disk drive. As the product arm must move very quickly between tracks in order to provide fast disk access times, the motor of each of the examples described in the patent specification must be a high speed motor. In one particular example described in the patent specification, the magnetic return path member moves with the moving magnet so no eddy currents are produced. In another particular example described in the patent specification and in a prior art example described as “largely hypothetical” in the patent specification, the magnetic return path member is stationary relative to the moving magnet; in this second example and the hypothetical prior art, whilst it is not specifically shown nor described, the magnetic return path member must be laminated as otherwise the eddy currents which would be produced because of the high speed of relative movement between the magnet and the magnetic return path member would inhibit movement of the product arm such that the product arm could not be moved satisfactorily.
According to a first aspect of the present invention, there is provided a low speed moving magnet motor, the motor comprising: a moving magnet; a stationary coil for carrying an electric current and disposed in relation to the moving magnet such that a magnetic field generated when, a current flows through the coil causes the moving magnet to move relative to the coil; and, a magnetic return path member fixed in relation to the coil to provide a return path for a magnetic field generated by the coil and the moving magnet; the magnetic return path member being free of insulating laminations.
With a moving magnet motor having a fixed magnetic return path member, movement of the magnet relative to the magnetic return path member generates large eddy currents in the magnetic return path member. These large eddy currents provide a bias which tends to act against movement of the moving magnet. Accordingly, it is normal practice in a moving magnet motor to laminate the magnetic return path member with layers of non-conductive material in order to reduce the magnitude of the eddy currents. Having a laminated magnetic return path member inevitably increases the cost of the motor as a whole and can in fact be a significant part of the total cost of the moving magnet motor. In accordance with this aspect of the present invention, where the moving magnet motor is a low speed motor, it has been found that the eddy currents produced are of such a low magnitude that it is not necessary to laminate the magnetic return path member with insulating material. Such a motor has particular application as a servowriter positioner motor for moving a servowriter positioner arm. Thus, this aspect of the present invention provides a moving magnet motor, thereby avoiding the need for flexible cable connection to what would otherwise be moving coils of the motor, whilst keeping down the cost of the motor by having an unlaminated magnetic return path member.
The magnetic return path member is preferably pure magnetically soft iron.
The moving magnet is preferably carried by a rotor whic

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