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Claims  |
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What is claimed is:
1. In an electrical machine having a generally annular core of
magnetically-permeable material with an aperture extending centrally
therethrough, an electrically-conductive winding mounted on said core, a
rotor having permanent magnets mounted thereon positioned in surrounding
relationship to said core and being mounted for rotation with respect to
said core about an axis, and a current transmission circuit board
extending transversely to said axis and being spaced axially from said
core for supplying electrical current to said winding and for mounting
Hall effect sensors for sensing the magnetic fields of said permanent
magnets as said permanent magnets rotate, the improvement which comprises
a member matingly insertable axially through said aperture in said core
while said winding is mounted thereon for connecting said core and circuit
board to each other, said magneticaly-permeable material of said core
having first angular orientation means formed therein and said member
having second angular orientation means matingly connectable with said
first angular orientation means upon axial insertion of said member
through said aperture while said winding is mounted on said core for
positioning said circuit board with respect to said core in a
predetermined angular relationship about said axis, said member further
having first axial orientation means matingly connectable with said core
while said winding is mounted thereon for positioning said circuit board
at a predetermined spaced axial distance from said core.
2. The apparatus of claim 1 wherein said member has means defining a
passageway extending axially therethrough.
3. The apparatus of claim 1 wherein said first axial orientation means
comprises limiting means formed on said member for matingly abutting the
periphery of said aperture of said core and thereby limiting the extent to
which said member can be inserted axially through said aperture.
4. The apparatus of claim 3 wherein said first axial orientation means
further comprises means formed on said member at a position located a
predetermined axial distance from said limiting means for matingly
interconnecting said circuit board with said member at said position.
5. The apparatus of claim 1 wherein said member further includes second
axial orientation means for matingly interconnecting with said rotor and
thereby positioning said core and said circuit board in a predetermined
axial relationship with respect to said rotor.
6. The apparatus of claim 5 wherein said member has means defining a
passageway extending axially therethrough, and wherein said apparatus has
rotor mounting means inserted axially through said passageway for
rotatably mounting said rotor, said second axial orientation means
comprising limiting means formed in said passageway for matingly abutting
said rotor mounting means and thereby limiting the extent to which said
rotor mounting means can be inserted axially through said passageway.
7. The apparatus of claim 1, said member and said circuit board
respectively including matingly connectable third and fourth angular
orientation means for positioning said circuit board with respect to said
core in a predetermined angular relationship about said axis.
8. The apparatus of claim 4 wherein said position is proximate one axial
extremity of said member.
9. In an electrical machine having a core of magnetically-permeable
material with an electrically-conductive winding mounted thereon, a rotor
having permanent magnets mounted thereon positioned in surrounding
relationship to said core and being mounted for rotation with respect to
said core about an axis by a bearing, and a current transmission circuit
board, the improvement comprising generally annular collar means for
supportably mounting said core and said circuit board with respect to each
other, said collar means having means defining a passageway extending
axially therethrough, and including first orientation means for spacing
said circuit board and said core a predetermined axial distance apart and
second orientation means for positioning said core in a predetermined
angular relationship about said axis with respect to said circuit board,
said winding being mounted on said core independently of said collar
means, and housing means, separate from said collar means, axially
insertable within said passageway of said collar means and interposed
between said collar means and said bearing for mounting said bearing, said
collar means including third orientation means for axially positioning
said collar means with respect to said housing and said bearing.
10. The apparatus of claim 9, said circuit board having a plurality of
electronic components mounted thereon and a plurality of connective means
for achieving electrical connections with said electronic components and
with said winding, said circuit board having first and second sides
respectively with said connective means on said first side and all of said
electronic components on said second side, said core and said circuit
board being mounted on said collar means so that said first side of said
circuit board faces away from said core and said second side faces toward
said core.
11. The apparatus of claim 9, wherein said winding includes an electrical
lead and said lead extends through said circuit board from said second
side to said connective means on said first side.
12. A subassembly of an electrical machine of the type having a rotor with
permanent magnets mounted thereon positioned in surrounding relationship
to a core-mounted electrically conductive winding and being mounted for
rotation with respect to said winding about an axis by a bearing, said
subassembly comprising:
(a) a magnetically-permeable core having said electrically-conductive
winding mounted thereon and including a first electrical lead from said
winding;
(b) a current transmission circuit board having a plurality of electronic
components mounted thereon having respective second electrical leads
therefrom, and a plurality of connective means for achieving electrical
connections with said electronic componnets and with said winding, said
circuit board having first and second sides respectively with said
connective means on said first side and all of said electronic components
on said second side;
(c) generally annular collar means supportably mounting said circuit board
and said core with respect to each other, said collar means including
means orienting said circuit board a predetermined axial distance from
said core and in a predetermined angular relationship about said axis with
respect to said core, said first side of said circuit board facing away
from said core and said second side of said circuit board facing toward
said core, and said first electrical lead from said winding and said
second electrical leads from said electronic components extending through
said circuit board from said second side to said connective means on said
first side.
13. The subassembly of claim 12, said collar means having means defining a
passageway extending axially therethrough for receiving a separate bearing
assembly including a bearing housing, said collar means including means
cooperating with said bearing housing for axially positioning said bearing
housing with respect to said collar means. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The present invention is directed to improvements in stator assemblies for
brushless DC permanent magnet motors and generators of the type wherein
the stator is located internally of a permanent magnet rotor.
Inexpensive, high-production manufacture of the foregoing type of rotary
permanent magnet devices has been hampered in the past by difficulties in
constructing the stator assembly of the device. Such stator assemblies
normally are composed of an annular, magnetically-permeable core upon
which an electrically-conductive winding is mounted, with a circuit board
spaced axially from the core and winding which feeds electrical power to
the winding. The circuit board also mounts Hall effect sensors, which
detect the rotational attitude of the rotor's permanent magnets by sensing
their magnetic fields and cause commutation of the electrical current to
the winding in response to the magnets' positions by means of well-known
electronic circuits designed for this purpose.
At present, relatively high manufacturing costs are incurred in the process
of precisely and rigidly orienting the core and its associated winding
both angularly and axially with respect to the circuit board. Such
orientation is critical to enable high-speed automated soldering of the
winding leads to the circuit board while avoiding improper wire position
and preventing wire fatigue and resultant breaking during manufacture, and
also to orient the winding angularly with respect to the Hall effect
sensors.
Precise axial orientation of the rotor with respect to the circuit board is
also critical, so that the Hall effect sensors on the circuit board are
positioned in correct axial proximity to the permanent magnets of the
rotor for proper detection of the magnetic fields.
Currently it is a common practice to utilize multiple screws or spacers to
interconnect the core and circuit board, after the winding has been
mounted on the core, to provide the above-mentioned angular and axial
orientation between the core and circuit board. However, the installation
of the screws or spacers is time-consuming and expensive, and can also
cause damage to the winding if not very carefully performed.
Alternatively it has been known to utilize specially constructed winding
bobbins capable of providing the above-mentioned angular and axial
orientation functions, as exemplified by U.S. Pat. No. 4,259,603. However,
such bobbins provide the orientation features only as an integral part of
the structure for mounting the winding, resulting in an extremely
complicated stator assembly. Such an arrangement does not permit addition
of the orientation features to the core after the winding has been mounted
thereon, which would facilitate the process of mounting the winding on the
core, as well as simplifying the stator structure.
Accordingly, what is needed is a stator assembly for this type of
electrical device which automatically and inexpensively performs all of
the foregoing angular and axial orientation functions by means of a member
connectable to the core after the winding has been mounted thereon,
without the need for precise and time-consuming manipulations.
SUMMARY OF THE PRESENT INVENTION
The present invention satisfies the foregoing need by providing a stator
assembly which features a unique collar member which matingly connects
with the core, after the mounting of the winding thereon, to interconnect
the core and circuit board in such a way that the two elements are
automatically oriented precisely both angularly and axially with respect
to each other. The collar member also provides means for automatically
precisely orienting both the core and circuit board axially with respect
to the rotor so that the magnets of the rotor have the proper axial
proximity to the Hall effect sensors mounted on the circuit board, and are
axially aligned with the winding. In addition, the collar provides a
convenient means by which the entire stator assembly may be engaged and
handled from above during the various stages of its manufacture.
The collar member connects detachably to the core by fitting axially
through a mating aperture in the core after the winding has been mounted
on the core. Angular orientation between the circuit board and core is
obtained principally by a mating interlocking key and keyway formed in the
collar and core aperture, respectively. The circuit board may either be
permanently connected to the collar, or may likewise be detachably
connected and properly angularly oriented with respect thereto by means of
another interlocking key and keyway.
Precise axial spacing of the core and its related winding with respect to
the circuit board is obtained by a shoulder structure formed on the
external surface of the collar member which limits the axial insertion of
the collar through the core's aperture. If the circuit board is detachably
connected to the collar, a flange is provided on the collar at a
predetermined axial distance from the shoulder structure to position the
circuit board axially on the collar, such that the combination of the
shoulder and flange provide the necessary axial spacing.
Axial orientation of the core and circuit board with respect to the rotor
is provided by a second shoulder structure formed on the wall of an
interior passageway extending axially through the collar. This shoulder
structure establishes the axial relationship between the stator assembly
and the rotor, thus enabling the collar to precisely establish the
relative axial position of the magnets in the rotor, with respect to the
core, and the Hall effect sensors on the circuit board.
The internal axial passageway in the collar further permits insertion of an
expandable plug or similar mechanical device to facilitate engagement and
handling of the stator assembly from above during its various
manufacturing steps, especially during automated soldering of the winding
leads to the underside of the circuit board.
Accordingly, it is a principal objective of the present invention to
provide a stator assembly structure featuring a core and its associated
winding matingly interconnected with a circuit board for transmitting
current to the winding by means of a member which automatically orients
the core and circuit board both angularly and axially with respect to each
other, and which is connectable to the core after the winding has been
mounted thereon.
The foregoing and other objectives, features, and advantages of the
invention will be more readily understood upon consideration of the
following detailed description of the invention, taken in conjunction with
the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a cross-sectional side view of an exemplary embodiment of a
permanent magnet motor constructed in accordance with the present
invention.
FIG. 2 is a view taken along line 2--2 of FIG. 1, with the permanent magnet
rotor removed and other parts broken away to reveal underlying structure.
FIG. 3 is a sectional view of the collar member taken along 3--3 of FIG. 2.
FIG. 4 is a perspective view of the collar member.
DESCRIPTION OF THE PREFERRED EMBODIMENT
The permanent magnet motor shown in FIG. 1 is of a type specially designed
for computer disk drive applications, it being understood that the
invention is applicable as well to other configurations of external-rotor
permanent magnet devices. The motor of FIG. 1 comprises a rotor mount 10,
adapted for mounting to some convenient supporting structure (not shown),
and having a hub portion 10a containing a pair of bearings 12 which
rotatably journal a drive shaft 14 for rotation about an axis of rotation
15. Fixedly attached to one end of the drive shaft 14 is a disk drive
spindle 16 which is rotatably driven through shaft 14 by a rotor 18
likewise fixedly attached to the shaft 14. The rotor 18 is in the shape of
a flat cup and has permanent magnets 20 distributed around the inside
surface of its periphery, such magnets being radially magnetized. Mounted
on the hub 10a of the rotor mount 10, and surrounded by the rotor 18, is a
stator assembly composed of a magnetically-permeable, generally annular
core 22 having an electrically-conductive winding 24, a circuit board 26
for supplying electrical power to the winding 24, and a collar member 28
rigidly interconnecting the core 22 and circuit board 26.
The collar member 28 is of an annular, generally frusto-conical shape
having an inner wall defining an internal passageway 30 extending axially
through the collar member. Although the circuit board 26 could conceivably
be an integral part of the collar member 28, it is preferable that the
circuit board 26 be a separate piece which is detachably connectable to
the base of the collar member. The various angular and axial orientation
features of the collar member 28 will now be described with relation to
the procedure for manufacturing the motor of FIG. 1.
Prior to the assembly of the various components of the stator structure,
the winding 24 is mounted on the core 22. During mounting of the winding
on the core, it is preferable that the collar 28 and circuit board 26 be
separate from the core so as not to interfere with the winding process.
After the winding has been mounted on the core, the circuit board and
collar member are interconnected with the core and winding assembly by
first mounting the circuit board 26 on the base of the collar member 28 by
sliding the periphery of the circuit board's central circular aperture 26a
(FIG. 2) into mating abutment with the collar member's annular base flange
32. The periphery of the aperture 26ain the circuit board has a keyway
(not shown) which mates with a key 34 on the collar member adjacent the
flange 32 so as to angularly orient the circuit board 26 with respect to
the collar member 28. If desired, the circuit board 26 can be fastened by
any suitable adhesive or ultrasonic heat staking to the flange 32,
although a close-tolerance fit may make such adhesion or staking
unnecessary.
Thereafter the top of the collar member 28 is inserted axially into the
central aperture 22a of the core 22 with a key 36 on the exterior of the
collar member aligned angularly with a mating keyway formed in the
periphery of the core aperture 22a. Fastening of the member 28 to the core
22 can likewise be by means of a close-tolerance fit, suitable adhesive,
or ultrasonic heat staking. The extent to which the collar member can be
inserted axially into the aperture 22a is limited by the abutment of an
exterior annular shoulder 38 of the collar member with the periphery of
the core aperture 22a, the shoulder 38 being located a predetermined axial
distance from the flange 32 of the collar member so as to orient the core
22 a predetermined spaced axial distance from the circuit board 26. Thus
the key 36 and shoulder 38 of the collar member 28, because of their
angular and axial orientation with respect to the circuit board 26 by
means of the key 34 and flange 32 of the collar member, serve to orient
the core 22 and winding 24 both angularly and axially with respect to the
circuit board 26. Accordingly, the winding leads, such as 40 in FIG. 2,
are thereby both angularly and axially aligned with mating apertures in
the circuit board 26 to facilitate subsequent soldering. Moreover the core
22 and winding 24 are also thereby properly angularly aligned with the
Hall effect sensors 42, to be discussed below, which are mounted on the
circuit board 26.
With the components of the stator assembly thus rigidly interconnected in
proper angular and axial orientation by the collar member 28, the stator
assembly can be easily engaged from above by inserting an expandable plug
or similar mechanical device into the top of the passageway 30 of the
collar member and engaging the inner wall of the collar member either by
friction or by mechanical engagement with an inner annular shoulder 44 to
be discussed below. By such engagement, the stator assembly can be
suspended with the circuit board 26 at the bottom and the leads 40 of the
coil protruding downwardly through the bottom of the circuit board. Such
leads 40 as well as the Hall effect sensor leads 42a) can then be soldered
to the circuit board by any known high-production method such as wave
soldering.
After the manufacture of the stator assembly has been completed, the hub
10a of the rotor mount 10 is inserted axially into the internal passageway
30 of the collar member 28 at the base thereof, the extent of such
insertion being limited by the mating abutment of the internal annular
shoulder 44 of the collar member with an external shoulder 46 (FIG. 1) on
the hub 10a, after which the rotor 18 is mounted rotatably on the rotor
mount 10 in surrounding relationship to the stator assembly. Connection of
the collar member 28 to the inserted hub 10a can be by means of a
close-tolerance fit, adhesive, or ultrasonic heat staking. The hub 10a of
the rotor mount 10 determines the axial position of the rotor 18 by the
end abutment of one of the bearings 12 therewith, the bearings 12 being
positioned in the hub 10a in predetermined axial relation to the shoulder
46. Since the hub 10a is definitely positioned axially with respect to the
collar member 28 by the abutment of the shoulders 44 and 46, respectively,
and the collar member 28 is definitely positioned axially with respect to
the circuit board 26 and core 22, it will be seen that a precise axial
orientation of the core 22 and circuit board 26 with respect to the rotor
18 is thereby automatically obtained. This is important because the axial
proximity of the Hall effect sensors 42 with respect to the permanent
magnets 20 of the rotor is critical to the proper operation of the
sensors. Also, proper axial alignment of the permanent magnets 20 with
respect to the core 22 is important to optimize performance of the motor.
It should also be noted that, although the periphery of the circuit board
26 also engages the rotor mount 10 as shown in FIG. 1, so that such
engagement could theoretically be relied on alternatively to axially
orient the rotor 18 with respect to the stator assembly, such point of
engagement is so far removed radially from the axis of rotation 15 that
reliance thereon for axial orientation would probably introduce errors in
axial alignment due to flexure of the circuit board 26. However the
engagement of the periphery of the circuit board 26 with the rotor mount
10 is significant from an angular point of view because the periphery of
the circuit board contains a keyway 26b (FIG. 2) which mates with a mating
key (not shown) in the rotor mount 10 to insure that the circuit board
leads 48 exit the rotor mount 10 at the proper angular location.
The terms and expressions which have been employed in the foregoing
specification are used therein as terms of description and not of
limitation, and there is no intention, in the use of such terms and
expressions, of excluding equivalents of the features shown and described
or portions thereof, it being recognized that the scope of the invention
is defined and limited only by the claims which follow.
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