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Description  |
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FIELD OF INVENTION
This invention relates to an improved magnetic bearing system for
translational motion, and more articularly to such a bearing system which
directly replaces air bearings in present optical disk data-storage
devices.
BACKGROUND OF INVENTION
Non-contact bearings are essential in the support and positioning of
optical read/write heads of high-density, high-data rate, high-performance
optical disks. Air bearings are used for this purpose in a number of
applications, but they suffer from a number of shortcomings. One problem
is that they need a complete pneumatic system--pumps, valves, seals,
conduits--for their operation. Another problem is that they require air,
an element not readily available in space applications where
high-performance optical disk data-storage systems are the technology of
choice. In any environment the air supply system adds significant cost,
size and weight to the bearing package and introduces the inherent
reliability problems associated with pneumatic systems components such as
pumps and seals. The air bearings themselves are difficult and expensive
to manufacture because of the small tolerance required, in the order of
one ten thousandth of an inch. Air bearings are highly susceptible to
contaminants: a particle of dust can interfere with air gaps as small as
four ten-thousandths of an inch and clog pores of the graphite or other
diffusive coating.
SUMMARY OF INVENTION
It is therefore an object of this invention to provide an improved
non-contact bearing for translational motion.
It is a further object of this invention to provide such a bearing which
permits precise and accurate movement and positioning of the parts.
It is a further object of this invention to provide such an improved
bearing which is relatively easy to manufacture, low in cost and weight,
small in size, and has none of the problems associated with air bearing
systems.
It is a further object of this invention to provide such a bearing which
has good resistance to contamination problems and has relatively large
manufacturing and operating tolerances.
It is a further object of this invention to provide such an improved
bearing which uses a magnetic bearing system.
It is a further object of this invention to provide such an improved
bearing which directly replaces air bearing systems in present
high-performance optical read/write heads for optical disk data-storage
devices.
This invention results from the realization that a truly effective magnetic
bearing for replacing existing air bearings in optical storage devices can
be achieved by employing the same shaft and carriage assembly using
magnetic bearings and channels to precisely, gently and frictionlessly
guide the carriage movement on the shafts.
This invention features a magnetic bearing system for enabling
translational motion. There are carriage means and shaft means for movably
supporting the carriage means. There is at least a first magnetic bearing
means fixed to one of the carriage and shaft means and slidably received
in a first channel of the other of the carriage and shaft means. The first
channel is generally "U" shaped, with two side walls and a back wall. The
magnetic bearing means includes a magnetic bearing having a pair of spaced
magnetic pole pieces, each pole piece having a pair of electromagnetic
coils mounted on poles on opposite ends of the pole piece proximate the
side walls, and a third electromagnetic coil mounted on a pole of the pole
piece proximate the back wall. There are means for sensing the motion,
transitionally along two axes and rotationally about three axes, of the
carriage means and shaft means relative to each other. Means responsive to
the means for sensing generate correction signals to drive the coil, to
compensate for any misalignment sensed between the carriage and shaft
means.
In preferred embodiments the pair of electromagnetic coils mounted on the
poles at opposite ends of the pole piece are electrically connected in
series. The first magnetic bearing means may include permanent magnet
means associated with the pole pieces for establishing a steady biasing
magnetic field in the pole pieces. The system may include a second
magnetic bearing fixed to one of the carriage means and shaft means and
slidably received in a second channel in the other of the carriage and
shaft means. The second channel also has two side walls and a back wall.
The two channels face in the opposite direction. The second magnetic
bearing means may include a pair of spaced pole pieces, each pole piece
having a pair of electromagnetic coils mounted on poles on opposite ends
of the pole piece proximate the side wall, and a third electromagnetic
coil mounted on the pole of the pole piece proximate the back wall. The
pairs of electromagnetic coils mounted on the pole pieces of the second
magnetic bearing means at opposite ends of the pole pieces may be
electrically connected in series. The second magnetic bearing means may
include permanent magnet means associated with the pole pieces for
establishing a steady biasing magnetic field in the pole pieces. The third
electromagnetic coil mounted on the pole of each pole piece in the first
magnetic bearing means may be electrically connected in series with the
corresponding third electromagnetic coil means mounted on a pole of each
pole piece in the second magnetic bearing means. The channel means may be
in the shaft means and the bearing means may be in the carriage means, or
conversely.
DISCLOSURE OF PREFERRED EMBODIMENT
Other objects, features and advantages will occur to those skilled in the
art from the following description of a preferred embodiment and the
accompanying drawings, in which:
FIG. 1 is a diagrammatic top plan view of an optical read/write head for an
optical disk data-storage device using the magnetic bearings according to
this invention;
FIG. 2 is a sectional view taken along lines 2--2 of FIG. 1, extended into
a three-dimensional diagram showing one of the magnetic bearings of FIG. 1
according to this invention;
FIG. 3 is a view similar to that of FIG. 2 illustrating a steady state
magnetic field provided by a permanent magnet in the magnetic bearing;
FIG. 4 is a diagrammatic cross-sectional view taken along lines 4--4 FIG.
1;
FIG. 5 is an exploded three-dimensional view showing the relative
positioning and interconnection of the coils illustrated in 1, 2 and 4;
FIG. 6 schematic of the coil winding interconnections and current flows of
one of the groups of coils of FIG. 5;
FIG. 7 enlarged three-dimensional view of the carriage of FIG. 1
illustrating the location of the position sensors;
FIG. 8 schematic block diagram of the correction circuit which senses the
position of the carriage and shaft relative to one another and provides
compensating signals to the coils to correct any misalignment; and
FIG. 9 an axonometric view of a bearing similar to that shown in FIG. 2,
arranged for use singly.
There is shown in FIG. 1 a read/write head assembly 10 for an optical
storage disk 12. Read/write head assembly 10 includes an iron frame 14
suspended across which are two iron shafts 16 and 18. A carriage 20 slides
to and fro on shafts 18 and 20 in the direction indicated by arrows 22 and
24 radially back and forth across optical disk 12, which is rotating as
indicated by arrow 26. Carriage 20 is driven by a pair of linear motors in
a conventional manner. One linear motor is comprised of permanent magnet
30 which interacts with the current in coil 32 fixed to carriage 20. The
second linear motor is comprised of permanent magnet 34 which interacts
with the current in coil 36, also fixed to carriage 20. The magnetic
fields between the permanent magnets 30 and 34 and the current in their
respective coils 32 and 36 generate Lorentz forces which move the carriage
back and forth on shafts 16 and 18 in a conventional manner.
In this particular embodiment there are two magnetic beaings 40 and 42
which may be referred to as first and second magnetic bearing means
respectively and are included in the magnetic bearing system. Magnetic
bearing 40 is fixed to carriage 20 in passageway 44, where it is received
in channel 46 in shaft 16 which forms a first assembly A. Magnetic bearing
42 is fixed to carriage 20 in passageway 50 and is received in channel 52
in shaft 18 to constitute assembly B. Although the channels are shown
disposed in the shafts and the magnetic bearings are shown attached to the
carriage, this is not a necessary limitation of the invention. The
bearings can be on the shafts and the channels could be formed in the
carriage, or one bearing could be formed on the carriage and one on a
shaft with the channels in complementary positions.
Assembly A is illustrated in greater detail in FIG. 2, where bearing 40 is
shown slidably received in channel 46 of shaft 16. Bearing 40 includes two
pole pieces 60 and 62. Channel 46 includes two side walls 64 and 66, and a
back wall 68 and is therefore generally "U"-shaped. Pole piece 60 includes
a pair of poles 70 and 72 on opposite ends of pole piece 60 facing side
walls 64 and 66. A third pole piece 74 faces back wall 68. The gap 76
between the poles and channel 46 is typically on the order of ten to
twenty thousandths of an inch. A pair of coils 80, 82 are mounted on poles
70 and 72, and a third coil 84 is mounted on pole 74. The second pole
piece 62 includes similar pole pieces 86, 88 and 90 with similar coils 92,
94, and 96.
A permanent magnet 98 may be provided to establish a steady magnetic field
through the pole pieces and channel, as shown in FIG. 3, where the steady
field provided by magnet 98 is shown in solid lines 100 and the field
provided by the coils 80 and 82 is shown in dashed lines 102. In FIG. 3
the coils have been eliminated for clarity. It can be seen here that while
tee two fields add in pole 72 and side wall 66, they subtract in pole 70
and side wall 64 to provide the adjusting magnetic forces, as is explained
hereafter. Although in this embodiment a permanent magnet is shown as part
of a magnetic bearing, this is not a necessary limitation of the
invention. A permanent magnet is used when a linear, low-power force
adjustment is desirable. In applications where that is not required, the
magnet is not used and corrections are applied only through the
electromagnetic coil.
The configurations of assemblies A and B with respect to carriage 20 are
shown in section in FIG. 4, which illustrates that magnetic bearings 40
and 42 fixed to carriage 20 are slidably received in channels 46 and 52 of
shafts 16 and 18, which are themselves slidably receivable in passageways
44 and 50 of carriage 20. Magnetic force is applied by the permanent
magnet and by the coils so that the coils 84, 84', shown, and 96 and 96',
not shown, can create offsetting magnetic forces that balance the carriage
support from left to right in FIG. 4 in the same way that coils 80, 82,
80', 82', shown, and 92, 94, 92', 94', not shown, perform in the vertical
direction as shown in FIG. 4. To accomplish this, channels 46 and 52 face
in opposite directions.
The connection of the coils is shown in FIG. 5. In assembly A, coils 80 and
82 of pole piece 60 are connected in series, and coils 92 and 94 of pole
piece 62 are connected in series. Similarly, in assembly B coils 80' and
82' of pole piece 60' are connected in series, and coils 92' and 94' of
pole piece 62' are connected in series. Coil 84 of pole piece 60 is also
connected in series with coil 84' of pole piece 60', and coil 96 of pole
piece 62 is connected in series with coil 96' of pole piece 62' While this
is the preferred electrical interconnection, it is not a necessary
limitation, as each of the coils could be energized individually to
provide the proper alignment correction between carriage 20 and shafts 16
and 18.
The energization of the coils as connected in FIG. 5 is illustrated
schematically in FIG. 6. Current flowing into coil 82 at terminal 110
flows in the same direction in coil 82 and in coil 80, creating the
magnetic fields 102 which combine with the field 100 of the permanent
magnet, FIG. 3, to provide the necessary righting forces and moments to
keep the carriage and shafts properly aligned. Conversely, coils 84 and
84', FIG. 6, are interconnected so that a current introduced at terminal
112 flows in the opposite direction in coils 84 and 84', to provide the
necessary magnetic balancing forces.
In this arrangement, the relative position of shafts 16 and 18 and carriage
20 is monitored by sensors A1, A2, A3, and A4, FIG. 7, in passageway 44,
and sensors B1, B2, B3 and B4 in passageway 50. These sensors are
capacitive sensors such as concentric conductive rings or similar
elements. With these sensors, the translational motion in the lateral and
vertical directions X and Y, respectively, and the rotational motions
about the X axis, Y axis and Z axis, .theta.x, .theta..sub.y,
.theta..sub.z, may be determined, and correction signals developed where
necessary to realign carriage 20 with shafts 16 and 18.
The signals from sensors A1-A4 and B1-B4 are delivered to sensor interface
circuits 120, FIG. 8, where they are filtered, shaped and amplified, and
delivered to sensor processor circuits 122, 124, 126, 128, and 130 in the
combinations as shown in Table I.
TABLE I
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X Y .theta..sub.x
.theta..sub.y
.theta..sub.z
(122) (124) (126) (128)
(130)
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A1 x x
A2 x x
A3 x x x
A4 x x x
B1 x x
B2 x x
B3 x x x
B4 x x x
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After these signals have been resolved, conventional loop compensation is
introduced by compensation circuits 132, and signals are delivered to the
coil processors and drives 134, 136, 138, 140, 142 and 144 in the
combinations shown in Table II to provide the necessary correction signals
to the coil combinations.
TABLE II
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X Y .theta..sub.x
.theta..sub.y
.theta..sub.z
(122) (124) (126) (128)
(130)
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84,84' x x
(134)
96,96' x x
(136)
80,82 x x x
(138)
92,94 x x x
(140)
80',82' x x x
(142)
92',94' x x x
(144)
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Although in this embodiment the magnetic bearing system shown is employing
two sets of magnetic bearings, that is not a necessary limitation of the
invention. As shown in FIG. 9, a single bearing 40a could be used in
combination with a shaft 46a in channel 16a, where the force opposing the
magnetic force between poles 74 and back wall 68 is not a magnetic force
generated by another magnetic bearing, but rather is the force of gravity
indicated at arrow G.
Although specific features of the invention are shown in some drawings and
not others, this is for convenience only as each feature may be combined
with any or all of the other features in accordance with the invention.
Other embodiments will occur to those skilled in the art and are with the
following claims:
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