Control and operation of brushless continuous torque toroid motor
First Claim
1. In a brushless direct-current motor comprising a permanent magnet rotor having a plurality of magnetic poles and a stator bearing windings arranged to interact with the magnetic field produced by the magnetic poles so as to produce torque from D.C. current applied to said windings, the improvement wherein:
- said stator windings are ranged to produce an essentially continuous torque from at least two separate phase windings from D.C. current pulses each of about one-half the duration of a two-pole cycle of rotor movement,each phase winding is sub-divided into a plurality of coil groups each of which is mounted in stator mounting slots in said stator displaced from the next coil group by approximately one rotor pole pitch,each coil group is sub-divided into two parallel winding circuits wound into the same stator slots and arranged to produce a reverse polarity in each circuit upon actuation, andan electronic control circuit for the motor comprising an electronic power switch for each said winding circuit arranged to be turned on and off in parallel for those winding circuits intended to be operated in parallel.
1 Assignment
0 Petitions
Accused Products
Abstract
Novel winding arrangements and control circuits for brushless direct-current motors are described. Stator windings are arranged to produce an essentially continuous torque in each winding phase from D.C. current pulses each of about one-half the duration of a two-pole cycle or rotor movement. An electronic control circuit comprises one electronic power switch for each winding group or winding phase in the stator windings. One or two D.C. current pulses are applied to the windings for each two-pole cycle of rotor movement, depending on the arrangement of the coils. CEMF voltage generated in the coils is sensed and a change in the polarity thereof is used to control switching of the D.C. current between coils.
-
Citations
11 Claims
-
1. In a brushless direct-current motor comprising a permanent magnet rotor having a plurality of magnetic poles and a stator bearing windings arranged to interact with the magnetic field produced by the magnetic poles so as to produce torque from D.C. current applied to said windings, the improvement wherein:
-
said stator windings are ranged to produce an essentially continuous torque from at least two separate phase windings from D.C. current pulses each of about one-half the duration of a two-pole cycle of rotor movement, each phase winding is sub-divided into a plurality of coil groups each of which is mounted in stator mounting slots in said stator displaced from the next coil group by approximately one rotor pole pitch, each coil group is sub-divided into two parallel winding circuits wound into the same stator slots and arranged to produce a reverse polarity in each circuit upon actuation, and an electronic control circuit for the motor comprising an electronic power switch for each said winding circuit arranged to be turned on and off in parallel for those winding circuits intended to be operated in parallel. - View Dependent Claims (2, 3, 4, 5, 6)
-
-
7. In a brushless D.C. dynamoelectric machine, which comprises:
-
a disk-like rotor element comprising hard ferrite toroid means providing a plurality of magnetic poles of alternating polarity and mounted for rotation about its axis, a disk-like stator element comprising soft ferrite toroid means and mounted coaxially with and spaced apart from the rotor element, said soft ferrite toroid means being formed with radially-directed coil winding receiving slots having twice the number of the magnetic poles of said rotor element, and electrical coil windings mounted to said stator element in said slots and each spanning one rotor pole pitch; the improvement wherein; said electrical coil windings with respect to each spanned rotor pole pitch are electrically connected in series and are wound in successive pairs of rotor-pole pitch spaced slots alternately clockwise and counterclockwise, said electrical coil windings comprise two sets of said series-connected windings with the windings of each set being located in rotor pole-pitch pairs of said slots which are offset one half rotor pole pitch, so that the windings of each set overlap each other for half a rotor pole pitch. - View Dependent Claims (8, 9)
-
-
10. A method of operating a brushless D.C. motor, comprising a permanent magnet rotor having a plurality of magnetic poles and a stator bearing at least two separate phase windings arranged to interact with the magnetic field produced by the magnetic poles and including two sets of individual electrical coils connected in series within each set and each set spanning one rotor pole pitch, the individual coils in each set being offset from each other by one-half rotor pole pitch, which method comprises the steps of:
-
applying at least one and no more than two D.C. current pulses of one-half cycle duration to said windings for each two-pole cycle of rotor movement, effecting said D.C. current pulse application through the alternate activation and deactivation of one only electronic switch for each separate one of said phase windings, and sensing CEMF voltages in windings not carrying torque-producing electric current and employing the change in polarity of said sensed EMF voltages as control signals to effect said activation and deactivation of said electronic switches.
-
-
11. A method of controlling the alternate application of D.C. pulses to a brushless D.C. motor comprising a permanent magnet rotor having a plurality of magnetic poles and a stator bearing windings arranged to interact with the magnetic field produced by the magnetic poles and including two sets of individual electrical coils connected in series within each set and each set spanning one rotor pole pitch, the individual coils in each set being offset from each other by one-half rotor pole pitch, which comprises the steps of sensing CEMF voltage generated by the one of said sets of individual electrical coils to which a D.C. current pulse is not being applied, and controlling switching of the D.C. current to said one set of coils in response to a change in polarity of said sensed CEMF.
Specification