Classifications

• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02K—DYNAMO-ELECTRIC MACHINES
  • H02K16/00—Machines with more than one rotor or stator
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02K—DYNAMO-ELECTRIC MACHINES
  • H02K19/00—Synchronous motors or generators
  • H02K19/02—Synchronous motors
  • H02K19/10—Synchronous motors for multi-phase current
  • H02K19/103—Motors having windings on the stator and a variable reluctance soft-iron rotor without windings
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02K—DYNAMO-ELECTRIC MACHINES
  • H02K29/00—Motors or generators having non-mechanical commutating devices, e.g. discharge tubes or semiconductor devices
  • H02K29/06—Motors or generators having non-mechanical commutating devices, e.g. discharge tubes or semiconductor devices with position sensing devices
  • H02K29/12—Motors or generators having non-mechanical commutating devices, e.g. discharge tubes or semiconductor devices with position sensing devices using detecting coils using the machine windings as detecting coil

Definitions

• the disclosed inventions relate to the field of direct energy conversion and the production of mechanical torque from the utilization of an electric current, and to the field of electric motors and to utilization of direct current as a "motive force.”
• the disclosed inventions also relate to the field of power conversion devices which transform electrical power into rotary mechanical power.
• Some disclosed embodiments relate to a class of motor having multiple stator and rotor sections, such that each rotor section is associated with a specific stator section, although attached to a single output shaft.
• the lateral axis of each rotor section may be disposed at an oblique angle with respect to the axis of the common shaft, and angularly displaced in accordance with the number of rotor sections employed, for example: 90 mechanical degrees for two rotors, 120 degrees for three rotors, etc.
• Some disclosed embodiments also relate to multiple motors having two or more motor sections, operating in parallel, each of which is comprised of a stator having two or more salient poles, and a rotor geometry devoid of coils or windings of any kind, affixed obliquely to a motor output shaft, and so disposed as to ensure a constant air gap between the rotor body and the salient poles of an associated stator section.
• Some embodiments of the invention also relate to multiple motor sections with their associated armatures, mechanically positioned out of phase with one another, but mounted so as to allow the output pinions of each individual motor to impinge upon a common output gear of larger diameter, mounted upon a separate but common output shaft, such that each individual motor's output is combined mechanically, and afforded an amplification of torque.
• Some embodiments of the invention also relate to a single motor having a stator section with salient poles, and a rotor geometry devoid of windings, affixed obliquely to a motor output shaft, and disposed as to ensure a constant air gap between the rotor body and the salient poles of the stator section.
• Some embodiments of the invention relate to a switched reluctance D.C. motor motor having a stator section with salient poles, and a rotor geometry devoid of windings, affixed obliquely to a motor output shaft, and disposed as to ensure a constant air gap between the rotor body and the salient poles of the stator section
• Patents in this area include: U.S. Pat. Nos. 2,917,699; 3,132,269; 3,321,652; 3,956,649; 3,571,639; 3,398,386; 3,760,205; 4, 639,626 and 4,659,953. Also in this area are EPO patent no. 0174290 (3/1986); German patent no. 1538242 (10/1969); French patent no. 2386181 (10/1978) and UK patent no. 1263176 (211972).
• stepper motors which utilize a magnetic "ratcheting" action upon magnetic material in the armature, in response to applied pulses of current
• various types of reluctance motors in which the rotor moves with respect to a salient pole piece, experiencing a large variation in air gap during its motion. But, these devices typically do not have a constant and continuous air gap of fixed dimension between the rotor and the stator.
• the prior art has not produced a multiple phase, multiply segmented stator with individual, obliquely disposed, laminated armatures devoted to each stator section, such that each stator/rotor combination employs a continuous air gap of constant dimension, regardless of the elliptical profile of said armatures, but not employing any current carrying conductors, coils, windings or bars within or upon the armatures, as a means of producing torque upon the output shaft.
• the prior art has arranged such motors to cooperate in "parallel fashion," through a reduction gear arrangement so as to provide an amplification of torque while sharing the mechanical load.
• Alternator of the Alternator Patent can be operated as a motor only when used in conjunction with the basic motor concepts described herein (i.e., requires field flux and current-carrying conductors).
• Alternator of the Alternator Patent makes use of an electromagnetic field winding, or a permanent magnet as its source of magnetic flux.
• Alternator of the Alternator Patent does not require a shaft position indicator, or a commutator of any kind in order to function.
• Alternator of the Alternator Patent does not require a position sensitive, electronically controlled, pulsed power supply, in order to generate electricity.
• Speed Voltage Back EMF is totally unavoidable, and in fact, is necessary for the transformation of electrical power into mechanical power in a typical motor.
• Speed Related Back EMF is its parasitic nature that serves to degrade the potential supplied to the motor from an outside source (i.e., the source voltage).
• Back EMF arises from, among other things, the mistaken assumption that Back EMF is required to produce torque. This, in turn, leads to design compromises which must be made in order to implement traditional electrodynamic machine geometries.
• a conventional DC Motor consisting of a stator with salient field poles, and a rotor-armature with a self-contained commutator.
• Application of a DC current to the rotor leads produces a rotary motion of the rotor (i.e., motor action).
• the rotation of the rotor conductors in a magnetic field also induces a voltage in the conductor that opposes the current applied to the rotor leads (i.e., generator action).
• V is the voltage developed
• B is the flux density
• 1 is the conductor length
• v is the tangential velocity of the conductor as it rotates.
• Equation 2 denotes only potential, not power. Electrical power can be expressed as the product of voltage and current. Current is missing from the second relationship (equation 2), but it can also be included by multiplication to both sides of the equation:
• V L dl/dt + 1 dL/dt.
• the first term in equation 6 is the product of inductance (L) and the rate of change of current (I) with respect to time (t). This is the previously discussed Transformer Voltage Vt.
• the second term is the product of the current (I) and the rate of change of Inductance (L) with respect to time (t). This is the previously discussed Speed Voltage Vs.
• Equation 9 expresses the quantity commonly referred to as the reactive energy.
• E T I d ⁇ + ⁇ dl.
• Equation 12 The energy relationship described in equation 1 1 can be further explained with reference to FIG. 1, which depicts a plot of flux ( ⁇ ) versus current (I) of the air gap energy components. As shown, the line 100 represents the total magnetic energy given by (equation 12):
• Em ⁇ .
• region 1 10 above line 100 indicates the (I d ⁇ ) reactive energy region and region 120 below line 100 indicates the ( ⁇ dl) dissipative energy region.
• FIGS. 2A and 2B show a cross-sectional representation of a prior art reluctance motor.
• rotor 210 is in a position between two stator 200 poles yielding the motors largest air gap 220 designated as (gl).
• the flux lines thus created will reach across this gap 220 as they are formed, and cause the rotor 210 to rotate to the position depicted in FIG. 2B, thereby reducing the reluctance in the magnetic circuit and reducing the air gap 230 to its smallest dimension designated as (g2).
• a torque impulse is also created during this motoring action, and the average mechanical work which is delivered on the rotor 210 will be found to be directly equal to the change in energy ( ⁇ dl) within the air gap.
• FIG. 3 is a double graph representing the energy relationship for the prior art motor illustrated in FIGS. 2A and 2B.
• the plot labeled 300 corresponding to air gap (gl) represents the relationship between the excitation flux and the excitation current at the point in time where the gap dimension is largest (e.g., air gap 220 as depicted in FIG. 2A).
• Ii the excitation current
• ⁇ the relatively lower value of the associated flux
• equation 1 1 For illustrative purposes, the following four calculations using equation 1 1 can be made representing the component energies associated with each air gap size (gl and g2).
• an exemplary standard DC motor with a power rating of 3.528 Horse Power has the following characteristics:
• Terminal Voltage 124 Volts DC.
• Full Load Current 26.326 amps.
• the DC motor has not yet begun to rotate, and there is no Back EMF, but the starting torque is relatively large at 637.986 in-lbs, which is 5.165 times the running torque.
• the Back EMF that develops as a function of the motor's increasing rotational speed reduces the start-up current of 135.965 amps down to the full load ampere (FLA) value of 26.326 amps. This "high start-up current,” behavior is standard and expected in conventional Speed Voltage dependent motors.
• An electric motor having a motor segment having a stator, having stator poles and stator windings and a rotor having a flux path element.
• the flux path element is attached to a rotor shaft at an oblique angle to the longitudinal axis of the shaft.
• the flux path element has a shape that provides a uniform constant air gap between it and the stator poles when the shaft is rotated.
• An electric motor having a plurality of motor segments, each segment having a stator, having stator poles and stator windings and a rotor having a flux path element.
• the flux path elements are attached to a rotor shaft at an oblique angle to the longitudinal axis of the shaft.
• the flux path elements have a shape that provides a uniform air gap between them and the stator poles when the shaft is rotated.
• the rotor shafts of said motor segments are mechanically coupled to each other.
• the flux path elements comprise a silicon steel lamination stack or a solid ferrite plate.
• the motor has a shaft angle sensor and a motor controller, and the motor controller receives a shaft angle from the sensor and supplies current pulses to the stator windings according to the shaft's angular position signal.
• stator poles are positioned in pole pairs with the rotor and rotor shaft between them and form isolated stator magnetic field circuits when the stator windings are supplied with electrical current, such that a magnetic field is established having a single magnetic polarity in each of the poles of said pole pairs, with each pole of the pole pairs having opposite magnetic polarity.
• more than two poles are installed in each stator section.
• the rotor flux path elements have a shape defined by the volume contained between two parallel cuts taken through a right circular cylinder at an angle other than 90 degrees with respect to the axis of symmetry of said cylinder, each flux plate element having front and back faces that are substantially elliptical, and having major and minor axes.
• the flux element angle with respect to the axis of symmetry is substantially 45 degrees.
• multiple rotors are attached to a common shaft, or independent shafts coupled through a clutch or similar selectablely engageable coupler, and the rotor flux path elements are arranged on said common shaft such that the major axes of the flux path elements are equally spaced on the shaft and wherein the stator poles are in the same position with respect to the common shaft for each motor segment.
• the motor has two motor segments and two rotor flux path elements and the rotor flux path elements are arranged on the common shaft such that their major axes are spaced 90 degrees apart.
• the motor has rotor counterweights to statically and dynamically balance the mass of the rotor flux elements.
• the motor has starter windings adapted to start the motor in a desired rotational direction.
• One advantage of the presently disclosed system and method is that it addresses the drawbacks of existing systems.
• Another advantage of the presently disclosed system is to provide a direct current motor which develops a significantly reduced Speed Voltage (Vs) component of the Back EMF.
• Vs Speed Voltage
• Another advantage of the presently disclosed system is to provide a direct current motor which makes use of a plurality of salient poles within its stator structure that may possess characteristics different than typically employed by existing Speed Voltage dependent systems.
• the stator poles should be arranged or constructed to be protected from flux movement in two directions in order to minimize eddy currents, and related iron losses.
• fabricating all or part of the pole pieces from different metals, using grain orientation, using ferrite materials, using distributed air gap materials, or laminations disposed at right angles with respect to one another are some techniques that may be implemented to inhibit the production of eddy currents, and thereby lessen iron losses.
• Another advantage of the presently disclosed system is to provide a direct current motor which employs a uniquely shaped rotor having a constant air gap with respect to the salient pole pieces.
• the constant air gap contributes to a smaller rate of change of inductance in the magnetic circuit, thereby reducing the speed voltage component Vs.
• Another advantage of the presently disclosed system is to provide a direct current motor which employs a shaped rotor having no coils, windings, conductors or bars within its structure. This also contributes to a lower speed voltage component Vs of the Back EMF.
• Another advantage of the presently disclosed system is to provide a direct current motor whose operation is governed by controller, such as an electronic controller, so designed as to orchestrate, synchronize, and control all the internal functions of the direct current motor.
• Another advantage of the presently disclosed system is to provide a direct current motor with a surplus of salient pole windings which are configured to store re-usable magnetic energy within the stator power coil windings.
• the surplus windings arise from the additional windings possible with the presently-disclosed designs compared to the amount of windings on a similar capacity, traditionally designed motor.
• stator and rotor geometries in conjunction with an electronic controller such that rotation is achieved by means of reluctance switching, synchronized by a position sensor, and acting in response to an electronic controller such that motor input power is properly managed and directed so as to produce a continuous rotation, while simultaneously recovering unused energy momentarily stored within the stator windings.
• One embodiment of the presently disclosed system employs a rotor fabricated from a stack of steel disks, chemically insulated from one another to discourage and reduce eddy currents.
• the disks may be pressed upon an arbor which, in turn, is obliquely disposed with respect to the intended axis of rotation, and suitably machined so as to produce an assembly with a peripheral contour generally equivalent to that of a cylinder.
• the stator may be composed of a plurality of salient pole sets, each set comprising a pair of poles, and associated windings, arranged 180 degrees apart from one another upon the stator, and each pole set angularly displaced from one another by a desired number of mechanical degrees.
• each pole set may also be provided with a concave pole face, whose radius is slightly greater than the radius of the rotor.
• the rotor therefore, defines an air gap of continuous dimension when rotated.
• the rotor is in magnetic series with each set of magnetic poles, thereby completing the magnetic circuit, and the rotor reacts to each set of energized poles by undergoing a mechanical displacement equal in degrees to the pole set's mechanical distribution around the periphery of the stator assembly.
• the zone in which the flux is coupled to the active pole pieces may vary in position along the length of each pole face. However, the width of the air gap separating the pole face from said rotor will not vary.
• FIG. 1 is a plot of flux versus current of air gap energy components in a typical prior art device.
• FIGS. 2A and 2B are cross sectional views illustrating a change in air gap for a prior art device.
• FIG. 3 is a plot of flux versus current for the linear energy relationship in the air gap for the prior art device shown in FIGS. 2A and 2B.
• FIGS. 4A and 4B are equivalent schematic circuits for a prior art DC motor illustrating the steady-state and in-rush operation circuit values.
• FIG. 5 is an overall view of one embodiment of the invention, showing stator sections in cut-away views revealing the disposition of bearings, common output shaft, rotor assemblies, counter weights, stator power windings and stator laminations.
• FIG. 6 is a schematic diagram of an individual rotor/stator section, depicting the relationships between such components as rotor geometry, magnetic flux, air gaps, salient poles and power windings in accordance with some embodiments.
• FIG. 7 is a schematic diagram showing maximum and minimum rotor cross- sections relative to air gaps, stator poles and magnetic circuits in accordance with some embodiments.
• FIG. 8 is a block diagram of an exemplary motor system, depicting forward and rear motor sections, the motor load, the shaft position sensor, the electronic controller and the sump resistor in accordance with some embodiments.
• FIG. 9 is a diagram of a single-rotor with a constant air-gap in accordance with some embodiments.
• FIG. 10 is a diagram of a parallel output cluster of motor sections such as the one shown in FIG. 9 in accordance with some embodiments.
• FIG. 11 is a motor coil energizing scheme for the motors of FIG. 10 in accordance with some embodiments.
• FIG. 12 is a schematic of coil interconnections for eight motor sections mechanically connected in parallel in accordance with some embodiments.
• FIG. 13A is a diagram of a motor cluster having brushes and commutator for timing in accordance with some embodiments.
• FIG. 13B is a diagram of a motor cluster having an optical encoder for timing in accordance with some embodiments.
• FIGS. 14A and 14B are schematic cut-away views of a rotor and stator pole pair in accordance with some embodiments of the invention.
• FIG. 15 is an illustration of the non-linear curves representative of the flux behavior as might be measured within a structure of electrical steel of a prior art motor with a variable air gap.
• FIG. 16 is an illustration of the non-linear curves representative of the flux behavior as measured within a structure of electrical steel of the constant air gap motor of the instant disclosure (e.g., FIGS. 14A-14B).
• FIGS. 17A and 17B are schematic representations of a Transformer Voltage (Vt) dependent system in accordance with some embodiments of the present invention.
• FIG. 18 is a schematic illustration of a DC motor system in accordance with some embodiments of the disclosed inventions.
• FIGS. 19A and 19B are schematic illustrations of magnetic flux, electric field, and velocity components within stator iron.
• FIGS. 20A and 20B are schematic end view and side views of certain stator components in accordance with some embodiments of the disclosed inventions.
• FIG. 21 illustrates a conceptual diagram of the generation of an ellipse that, when rotated, has a circular cross-section.
• FIG. 22 is a depiction of some embodiments of the direct current motor shaft assembly.
• FIG. 23 is a cutaway view of some embodiments of a six pole motor stator with associated windings in place.
• FIG. 24 is a cutaway view through the vertical axis of some embodiments of the stator assembly.
• FIG. 25 shows the same cutaway view of some embodiments of the stator assembly shown in FIG. 24, however the rotor has been advanced in angular rotation by 90 mechanical degrees.
• FIG. 26 illustrates a block diagram of some embodiments of an Open Power System Configuration of the direct current motor system.
• FIG. 27 illustrates a block diagram of a Closed Power System Configuration of some embodiments of the direct current motor system.
• FIG. 28 illustrates a logic flow diagram of the functioning of the electronic controller designed to operate with some embodiments the presently disclosed direct current motor. In this case, the logic applies to the operation of one embodiment of an Open Power System Configuration.
• FIG. 29 illustrates a logic flow diagram of the functioning of the electronic controller designed to operate with some embodiments of the presently disclosed direct current motor. In this case, the logic applies to the operation of one embodiment of a Closed Power System Configuration.
• FIGS. 5-8 illustrate one embodiment of the motor disclosed herein.
• the motor consists of a double stator housing (1, 2) physically separated, but functionally joined together by means of a continuous shaft (10), upon which are mounted two armatures (3, 4), one within each stator assembly.
• the shaft is carried by bearing sets (1 1), located within end-bells (14, 15).
• Rotor assemblies (3, 4) each consist of a stack of silicon steel laminations (9), a molded ferrite core, or any other high permeability magnetic material designed to suppress eddy currents, and machined so as to produce a section of a right circular cylinder canted at an angle of 45 degrees with respect to the motor shaft (10).
• the rotor structure When viewed face on, the rotor structure appears to be elliptical in shape. However, the side view depicts a rhomboid tilted at 45 degrees. This angle may not be the most optimal angle, and it should be realized that other angles may be employed without departure from the spirit of the invention.
• the common shaft (10) may also carry counter weights (7, 8), as depicted, which function to ensure a smooth rotary motion by suppressing mechanical vibrations produced by the uneven mass distribution of the elliptical armature sections (3,4).
• each motor segment may include a clutch (25), or some other selectablely engageable coupler in order to couple independent shafts into a common shaft (10).
• a clutch 25
• motor segments from one on upwards can be coupled in this, or a similar, manner.
• Each stator assembly contains an individual stack of stator laminations (16, 17) or a magnetic ferrite cylinder, from which extend two or more salient pole projections (12, 13), each of which is wound with a power coil (18).
• the face of each pole projection (5, 6) is extended to the right and the left of center to ensure continuous air gaps of constant dimension (19, 20), which are aligned parallel to the rotor's edge contour regardless of its angular disposition.
• each stator section is parallel to each other, but the rotor sections are displaced upon the shaft by a predetermined mechanical angle: 90 degrees for two pole sets 120 degrees for three pole sets, etc.
• the motor shaft extends several inches beyond the end bell housings (14, 15) on each side of the motor.
• One end of the shaft is utilized as a take off point for mechanical power, or load, while the other side of shaft carries a shaft position indicator (21), which is an angular transducer, and may consist of a simple rotary encoder, or a more complex device containing discrete optical sensors and slotted disks.
• stator power windings may be connected in series or in parallel as preferred.
• the windings receive their drive pulses from switching transistors, MOSFETs, or other solid state switching devices within the controller (22), which in turn receive their firing instructions directly, or indirectly, from the shaft position sensor (21).
• Power resistor (23) is used as a sump to harmlessly dissipate any remaining energy associated with the collapsing magnetic fields within the stator as the motor rotates.
• FIG. 6 A Description of The Rotor Geometry [0146] Drawing attention now, to FIG. 6, it will be noted, that a cylindrical outline is depicted between the poles of an electromagnet, through which the lines of flux are directed in a upward fashion. Notice also, the solid, elliptical lines shown. These demonstrate the shape of the lamination stack or ferrite core which comprises part of this invention. The shape is described by the result of making two parallel slices through a right circular cylinder at an angle of 45 degrees, and then removing all of the cylindrical body except the elliptical core, as demonstrated.
• FIG. 7 illustrates a schematic cross-sectional view of the flux path of the rotor in two mechanical positions, each 90 degrees apart. Note, in FIG. 7A, that the elliptical cross-section presents a longer path to the magnetic flux than does the cross-section illustrated in FIG. 7B. Note as well that these figures represent approximate flux paths and not actual cross sectional views of the rotor.
• This process does not require the presence of a "secondary" magnetic coil, the addition of which would tend to decrease a motor's overall inductance, by means of quadrature coupling, or armature reaction, during normal operation.
• One embodiment of this invention employs two rotors, each fabricated from a stack of laminated disks, pressed upon arbors which are obliquely disposed with respect to the intended axis of rotation, and then integrally machined in order to provide both rotors with peripheral contours equivalent to that of a cylinder while retaining their overall elliptical shape.
• Each stator section is formed by a lamination stack having two, spaced-apart, salient pole projections terminating in concave pole faces whose radii are slightly larger than the radius of each rotor. Both rotors thereby define air gaps of constant dimension while rotating.
• Each rotor is in magnetic series with two air gaps and two pole pieces and a complete magnetic circuit which contains its own coils for the production of magnetic flux.
• Each magnetic rotor circuit is separate and distinct from each other magnetic rotor circuit, although they share a common output shaft.
• An angular position sensor or shaft encoder is positioned at one end of the output shaft, and sends electronic position signals to a DC power supply/controller, which in turn sends pulses to the motor stator sections as required.
• the application of a current pulse to a given set of stator coils causes the rapid rise of magnetic flux within the selected stator section and its associated rotor.
• the increased flux density then causes the rotation of the active rotor, as the flux lines "shrink" to ensure their manifestation in a circuit of minimum length.
• the output torque is produced by the laws of magnetic reluctance acting in conjunction with the innovative geometry of the rotor. No current carrying conductors are involved in the rotor.
• the shaft encoder then directs the electronic controller to send a power pulse to the second rotor, and the operation repeats itself.
• the result is a smooth angular rotation, and the production of a continuous average torque.
• a secondary result of this arrangement is the production of an electrical output from each stator section as a result of the collapsing of its magnetic field at the end of each power cycle.
• This electrical energy may be harmlessly dissipated in a sump resistor, or it may be put to use, for example in powering other devices, including lamps or heaters or recovered to supply a portion of the energy used to drive the motor.
• an exemplary motor utilizes a rotor geometry consisting of a lamination stack or a molded ferrite shape, canted at a specific angle with respect to the output shaft, while retaining a circular cross section to the axis of rotation, and presenting an overall elliptical appearance in its own plane.
• This arrangement allows for a constant air gap to be maintained between the rotor's edge and the pole pieces thereby producing mechanical torque without the utilization of coils or conductors residing anywhere upon said rotor.
• One embodiment of the motor employs a plurality of "elliptical" rotors mounted upon the same output shaft, but positioned such that each rotor section is advanced a certain number of mechanical degrees from the others such that torque production over 360 degrees of rotation is shared equally by the number of rotors utilized.
• the motor also has a plurality of pole sets and separate magnetic circuits, such that each elliptical rotor section is associated with its own external source of magnetic flux, regardless of the fact that they share a common output shaft. Accordingly, the salient stator pole projections will all reside in the same plane and be parallel to each other, while the rotor sections will be displaced upon the output shaft by predetermined mechanical angles; 90 degrees for two pole sets, 120 degrees for three pole sets, etc. Those skilled in the art will realize that this arrangement may be reversed without departing from the spirit of the invention. Likewise, those skilled in the art will also realize that it is possible to construct a single, standalone, motor utilizing a single rotor and stator section.
• the right hand rotor on the same shaft, will simultaneously present its shortest cross sectional path to its associated pole projections.
• the shaft position sensor (21) will cause the controller (22) to energize starting windings (not shown) which will rotate the motor shaft in the desired direction, while simultaneously sending a current pulse into the left hand pole set depicted in FIG. 5.
• starting windings not shown
• the average torque available on the motor output shaft will be a function of the cooperative effort developed by both rotors over each mechanical revolution.
• the output torque developed by this method is strictly a reluctance torque, generated as the lines of magnetic flux within each rotor section alternately shrink in an attempt to provide themselves with the shortest possible magnetic path between poles.
• this torque-producing mechanism does not involve any interaction of either stator' s magnetic field with a current carrying conductor of any kind, neither in the form of a Speed Voltage interaction, nor in the form of a transformer coupling with a time-varying field.
• the torque appearing on the motor shaft is a direct function of the rotor's geometry interacting with forces produced at the boundaries between the rotor body and the stator poles, and by internal cam action particular to the rotor geometry in the presence of a contracting flux.
• fly-back diodes are provided in association with each power winding.
• the diodes direct pulses generated by the collapsing fields into a sump or load resistor (23), where they may be harmlessly dissipated as excess heat.
• said energy may be used to power other electrical appliances external to the motor, or may be applied to a capacitive storage element and then utilized to send power back to the main power supply.
• an electric motor cluster comprises several stator sections each possessing a minimum of two salient pole projections, wound with power windings, and each having a single armature rotor.
• Each individual rotor is angularly displaced one from the other, while mounted upon a common frame, and geared together such that each motor section contributes to the rotation of a common output shaft.
• Such an arrangement not only allows for the combining of motor output powers and the removal of flutter from the final mechanical output, but simultaneously allows for a large increase in output torque by virtue of the necessary reduction gearing.
• the embodiment suggested within this particular disclosure lends itself perfectly to applications within the field of electric vehicle propulsion, particularly in those cases where the prime mover is to be located within the wheels of the vehicle. However, other applications are easily envisioned.
• Each motor section shall consist of stator and armature elements as described in PCT application number PCT/US09/46246, filed on June 4, 2009, and entitled "PULSED MULTI- ROTOR CONSTANT AIR GAP RELUCTANCE MOTOR.”
• the motor may consist of the following features:
• a stator consisting of a stack of laminations, or a molded ferrite core, so constructed as to provide at least one set of salient magnetic poles, spaced apart 180 mechanical degrees, and situated so as to allow an air gap to exist between the stator structure and the armature of the motor.
• Each salient magnetic pole projection may be wound with power windings, the function of which is to produce a magnetic field of considerable strength, and direct th e same through the air gaps and into the body of the motor's armature.
• An armature also consisting of a stack of laminations, or a molded ferrite shape, so designed as to present each set of field poles with a cylindrical contour, perceived beyond each air gap, while retaining an elliptical profile with respect to the output shaft.
• the armature sections carry no electrical windings of any kind, and require no slip rings or, field coils or permanent magnets.
• armature segments may require shaft-mounted counter weights to offset their eccentricity, and maintain angular balance during rotation.
• the power windings wound upon the salient pole projections are energized by pulses of electric current produced by a DC power supply and provided through an electronic controller unit, or through a mechanical commutator, etc.
• the pulses are automatically applied to the salient pole nearest the longest flux path available through a particular rotor section, as determined by a shaft position sensor, or the geometry of a commutator.
• the shaft position sensor Upon detecting motion, the shaft position sensor communicates the change in position of the output shaft to the electronic controller, and current flow is then terminated in each active stator section, and instantly initiated in the stator section windings next scheduled to be activated.
• the shaft position sensor communicates the change in position of the output shaft to the electronic controller, and current flow is then terminated in each active stator section, and instantly initiated in the stator section windings next scheduled to be activated.
• FIGS. 9-13 illustrate one embodiment of the motor cluster disclosed herein. Reviewing FIG. 9, it may be seen, that each motor section consists of a metallic housing 1 containing a stator stack 16 and an armature assembly 3, which is mounted upon an output shaft 10, which is carried by two sets of bearings 11, located within end bells 14.
• the rotor assembly 3 within each motor section consists of a stack of silicon steel laminations 9, or a molded ferrite of appropriate shape, or any other high permeability magnetic material designed to suppress eddy currents, machined so as to produce a section of a right circular cylinder canted at an angle of 45 degrees with respect to the motor output shaft 10.
• the rotor structure appears to be circular in shape.
• the side view depicts an ellipse tilted at 45 degrees. This angle may not be the most optimal angle, and it should be realized that other angles may be employed without departing from the spirit of the invention.
• Each motor shaft 10 may also carry counter weights 7, as depicted, which function to ensure a smooth rotary motion by suppressing mechanical vibrations produced by the mass distribution of the eccentric armature design 3.
• Each motor shaft carries a high speed output pinion 24 which s designed to mesh with the main output gear as shown in FIGS. 9 and 10.
• Each stator assembly contains an individual stack of stator laminations 16 or a magnetic ferrite cylinder, from which extend two or more salient pole projections 12, each of which is wound with a power coil 18.
• the face of each pole projection 5 is extended to the right and the left of center to ensure continuous air gaps 19 of constant dimension.
• the pole faces are aligned parallel to the rotor's edge contour regardless of its angular disposition.
• each motor element consists of a laminated, four pole stator stack 62, an air gap 68, an elliptical rotor 67, an individual motor output shaft 64, and an output pinion 63. Further, it will be noted, that each output pinion is in mesh with a central output gear or "bull gear" 65 which drives the main output shaft 66.
• This arrangement allows for four motors to be energized at any one time, with power overlaps and torque-sharing occurring at 45 degree intervals. This feature serves to smooth out the total torque delivered to the output shaft, allowing for a more continuous delivery of power, as each contributing motor develops its output torque out of phase with respect to each of the others.
• Total motor action during operation may be appreciated by studying the coil energizing truth table depicted in FIG. 1 1, while the power coil interconnection schematic may be reviewed in FIG. 12.
• FIG. 11 the horizontal portions of each chart depict energized coils and the sloped portions of the chart represent the magnetic reset of the energized coils. There are shown coil sets for eight motors as described in the above text with respect to FIG. 10.
• switches S 1A through S8A, and switches S IB through S8B are used to control the power winding coil sets in each motor section.
• the coil sets are labeled A, A' and B, B' for each motor as shown in FIG. 10.
• These switches are schematically accurate, but may represent either solid state switching devices located within the electronic motor controller, or actual contact bars located upon a more traditional commutating device. These distinctions are more clearly explained in FIG. 13.
• FIGS. 13A and 13B depict two variations of some embodiments of the present invention.
• FIG. 13 A demonstrates the parallel motor cluster concept employing a traditional electro-mechanical commutating device 56, 57
• FIG. 13B demonstrates a more modem approach employing a shaft-mounted encoder 59, a micro-processor, and an electronic motor controller.
• both systems require a source of DC power, as well as a capacitive power sump 58, into which excess "inductive energy” is directed.
• This "sump” may be equipped with a resistive load, which will consume said inductive energy, or the accumulated potential may be utilized to supply other worthwhile power requirements.
• each arrangement contains a motor cluster housing 51, a plurality of high speed motor pinions 52 mounted upon individual motor output shafts 53, and a central bull gear 54 mounted upon a main output shaft 55.
• FIG. 13 A makes use of a mechanical commutation device 56 with standard carbon brush contactors 57, while the device shown in FIG. 13B employs a shaft encoder 59 and an encoder pick-up device 60.
• FIG. 13B it will be noted that electronic signals obtained from the encoder assembly are transmitted to the micro-processor and the electronic motor controller, while power pulses are independently directed to individual motor windings via output conductors energized by the motor controller.
• the arrangement shown in FIG. 13 A accomplishes these functions electro-mechanically, which may be
• both systems produce the results depicted in FIG. 11, and both systems ultimately direct inductive energies from collapsing magnetic fields into the capacitive sump indicated by network 58.
• Vt Transformer Voltage
• FIGS. 14A and 14B are schematic cut-away views of a rotor and stator pole pair in accordance with some embodiments of the invention.
• stator poles 500 form a pair on either side of rotor shaft 510.
• Magnetically conductive rotor stack 520 is mounted on shaft 510 and depicted in a first position in FIG. 14A.
• rotor stack 520 may comprise a shape that is designed to present a substantially cylindrical profile when rotated about shaft 510.
• rotor stack 520 may comprise a substantially elliptical shape that is mounted on shaft 510 in an offset, or canted, fashion forming an angle ⁇ with respect to the shaft 510 as best seen in FIG. 14A.
• rotor stack 520 forms an air gap of distance gl with stator poles 500.
• the magnetic circuit formed by the stator poles 500 and rotor stack 520 can be calculated from adding the air gap to the major-axis length l ⁇ of the rotor stack 520 as follows:
• FIG. 14B shows a cross sectional view when the rotor stack 520 is rotated one-quarter turn (i.e., 90 degrees) from the position shown in FIG. 14A.
• N is the number of turns
• ⁇ the permeability
• A the cross-sectional area
• t the magnetic circuit length
• K the K constant of proportionality
• measuring a mean magnetic path around the stator equivalent to the mean circumference Cm gives 43.982 inches in length.
• Substituting and calculating corresponding values of inductance using equation 13 above gives:
• FIG. 15 shows the nonlinear curves representative of the flux behavior as might be measured within a structure of electrical steel of a prior art motor with a variable air gap.
• plots 600 and 602 are continuous, but quite non-linear. This is to be expected, because here, as in the case of B/H curves, the permeability ( ⁇ ) is not constant.
• E T I dO + ⁇ dl.
• each energy component is different in value, as might be expected.
• the total energies, ETI and E T 2 are not equal in this case. There is a substantial difference of 30.86 Joules.
• FIG. 16 is an illustration of the non-linear curves representative of the flux behavior as measured within a structure of electrical steel of the constant air gap motor of the instant disclosure (e.g., FIGS. 14A-14B).
• V L dl/dt + 1 dL/dt.
• Vt + Vs +VrI I(L dl/dt) + 1(1 dL/dt) + I 2 r.
• T -1 ⁇ 2 ⁇ 2 dR/dO.
• Back EMF causes significant issues in the operational characteristics of a conventional motor.
• Back EMF does not appear in the traditionally anticipated magnitude, but the motor still undergoes an acceleration.
• the motor would develop 18.221 HP, or 13,592.866 shaft watts, and would require a total input power of 16,859.670 watts. Subtracting the shaft watts from the total input power, the figure of 3,266.804 watts is obtained.
• V I dL/dt, assuming an acceleration time of 6/10 seconds, and solving for L, a value of 0.1059 H is derived, which is very much in keeping with the inductance figures described above in connection with FIGS. 4A-4B. Therefore, Vs is not required to power the presently disclosed kind of motor, instead Vt is the driving agent.
• Vt Transformer Voltage (Vt) dependent systems are many and pronounced. The most pronounced difference between Vt and Vs lies in the inductive mechanism with which each potential is associated.
• I dL/dt under dimensional analysis yields that dL/dt has the dimension Joule-seconds / coul 2 , which is representative of a resistance.
• I 2 (dL/dt) is dissipative by its very nature, while the expression VI, from which L dl/dt is derived, can easily describe a reactive condition. Energy can be extracted from a reactive situation, but not from a dissipative relationship.
• FIG. 17A is a schematic representation of a Transformer Voltage (Vt) dependent system in accordance with some embodiments of the present invention.
• a DC motor 800 has a through-put efficiency of 79.84 %, such that a power input 802 of 3,264.424 watts, minus system losses 804 of 658.128 watts, yields an output 806 on the shaft of 2,606.296 watts, or approximately 3.5 HP. Over and above this shaft output 806, the motor 800 supplies an electrical output 808 due to the re-capture ability associated with rvt. Assuming a theoretical 100% recapture is possible, then this output electrical power 808 has a maximum value of 2,606.296 watts.
• FIG. 17B where a recapture electrical output 810 figure of 90% is used.
• the power through-put from the electrical input 802 to the mechanical output 806 remains the same at 79.84%.
• the reclaimed "field energy" now delivers a useful electrical output 810 of 2,345.666 watts.
• the recaptured electrical output 810 power is the same power that was applied earlier (e.g., 802), minus all the associated losses.
• the input power 802 pulse, and the recapture power 810 pulse cannot exist at the same time. They are 180 electrical degrees out of phase with each other.
• FIG. 18 is a schematic illustration of a DC motor system in accordance with some embodiments of the disclosed inventions.
• the drive section of the electronic controller 900 contains four field poles, and so the controller 900 issues four sequential pulses into the motor every 90 degrees, each pulse containing 816.106 watts. If it is desirable to measure, or otherwise monitor, these pulses, a meter 902 can be implemented as illustrated.
• motor 904 responds by rotating, and loses 658.128 watts in heat losses 906.
• the output power 908 available at the motor 904 shaft may be approximately 3.5 HP, and the overall motor efficiency may be 79.84%, as measured by contrasting total electrical input from controller 900 to the average mechanical output 908 at the shaft.
• each collapsing motor field produces an electrical output 909 of 586.416 watts, which represents the re-captured field energy.
• These pulses 909 are then delivered to the recovery section 910 of an electronic controller, and then may be stored, for example, in the re-capture capacitor bank 912. In some embodiments, energy from this capacitor bank 912 could be removed if necessary, and used to supply power to external appliances (shown in phantom at 914, 916.
• the feedback controller 918 may automatically start sending power back to the main capacitor bank 920.
• the power delivered by this motor 904 operation may be monitored by the feedback watt meter 922.
• the line only supports the system losses, while the shaft power is supported by the change in field energy per unit time. As expected, the motor will not operate without line power.
• the DC motor as disclosed herein may include combinations of the following features: an even number of salient stator poles, salient poles that are protected from flux movement in two directions, poles that are designed to be as short as possible, and pole windings should be of adequate wire size, but with as many turns as desirable.
• stator design features are the following.
• the even number of salient poles is advantageous in establishing the flux field to impart a force on the rotor, because each pole set constitutes a complete magnetic circuit for each phase with two poles being the minimum set.
• FIG. 19A is an illustration of a portion of some stator lamination plates 1010 in accordance with some embodiments of the disclosed motor.
• Each lamination plate 1010 may also comprise an insulating coating 1012 on the outer surfaces.
• a magnetic flux field 1014 indicated as coming out of the page by the dots as shown, experiences a first velocity (vi) indicated by arrows 1016 pointing to the right, and an electric field (Ei), indicated by the arrows 1018 pointing to the top of the figure.
• This field (Ei) produces a relatively insignificant eddy current because the insulating coating 1012 between each plate inhibits the current flow.
• FIGS. 20A and 20B illustrate an end view and a side view of stator pole arrangements in accordance with some embodiments of the disclosed motor that enable the minimizing of the eddy currents in the salient poles due to flux movement in two directions as described above.
• a stator pole may comprise a top pole piece (called a shoe) comprising vertically disposed laminations 1028.
• a bottom portion of the pole may comprise standard, or radially disposed, laminations 1030.
• Other arrangements of laminations are also possible, the concept being that the layers of the various portions are arranged to minimize eddy currents by inhibiting current flow.
• stator windings 1026 for generating the magnetic flux fields
• rotor 1032 rotating about an axis of rotation 1034
• constant air gap 1036 between the edge of rotor 1032 and stator shoe 1028.
• stator poles may also be implemented to minimize eddy currents.
• another embodiment is to have the pole face, or shoe 1028, made of a material such as sintered steel, ferrite, or distributed air-gap material, and then bond, or otherwise fasten, the shoe 1028 to the bottom portion 1030 of the stator pole.
• stator pole pieces comprising grain- oriented steel, with the grain best oriented for lateral flux movement.
• Embodiments employing combinations of these techniques for eddy current minimization are also possible.
• the salient poles are designed to be as short as is optimal in order to optimize the overall magnetic circuit length. This has the advantage of also lessening motor iron losses.
• the design of the pole windings (e.g., windings 1026) is to be of adequate wire size, but with a number of turns that is optimal. This has the advantage of keeping I 2 R (i.e., copper) losses to a minimum.
• the wire size and number of turns are preferably optimized so that enough turns are used to establish a magnetic flux of sufficient magnitude, while also keeping the I 2 R losses to an optimal minimum.
• the presently disclosed stator designs will accommodate a greater number of windings per pole.
• the rotor design features of the presently disclosed invention also contribute to the herein described performance.
• an important feature of the disclosed rotor is that it be shaped to assist in the reduction of the factors that contribute to the generation of Back EMF.
• rotors that exploit Transformer Voltage (Vt) in accordance with the present disclosure will be designed to form a constant, or substantially constant, air gap with respect to the stator poles.
• a rotor designed to exploit Transformer Voltage (Vt) in accordance with the disclosed embodiments of the invention will also facilitate the creation of a variable length magnetic circuit path.
• Vt Transformer Voltage
• one way to design a rotor capable of creating a variable length magnetic circuit path is to create an ellipse that, when rotated, has a circular cross-section. For some embodiments, such an ellipse may be created in the manner illustrated in FIG. 21.
• FIG. 21 illustrates a conceptual diagram of the generation of an ellipse that, when rotated, has a circular cross-section.
• Such an ellipse 1000 can be generated by drawing a reference circle c with a radius r. Projecting out of the plane of the circle c, a height h is generated from r sin a, where a is that angle of inclination of the hypotenuse R (of triangle aOb) from the plane of circle c, and where ⁇ represents the angles generated about the point 0 in the plane of circle c.
• a DC motor consists of three main components; a stator assembly for supporting the magnetic field coils, a shaft-mounted armature, or rotor, for supporting windings of its own, and a commutator, also shaft-mounted, which supplies a timed switching function by means of two or more carbon brushes for controlling the supply electrical current to the rotating armature assembly from an external power supply.
• FIGS. 22 through 25 show aspects of some embodiments of the presently disclosed DC motor.
• FIG. 22 illustrates one embodiment of the motor's rotor assembly 1 190, wherein 1100 is the shaft, 1 101 are bearings, 1 102 depicts rotational stabilizers, or counterweights, desirable to offset any eccentricity of the magnetically conductive lamination stack 1104, which may be mounted upon an arbor 1 103.
• the rotor assembly 1190 may also contain a shaft position sensor 1108, which may consist of a mounting hub 1 105, and one or more encoded disks 1106. Positional information carried by the disks, is read by sensor heads 1 107, and an appropriate signal is conveyed to the electronic controller 1503 (shown in FIG. 26, but not shown in FIG. 22), for interpretation and generation of electronic control commands.
• Other embodiments of the rotor assembly 1 190, the shaft position sensor 1 108, and the components of the same, may also be implemented.
• bearings 1 101 may be single roller bearings, multiple-roller bearings, thrust bearings, conical bearings, metallic sleeve bearings, or other suitable type of bearing.
• the arbor 1103 may comprise any suitable arbor or mounting mechanism for securing the conductive stack 1104 to the shaft 1100.
• conductive stack 1104 comprises a laminate stack
• a compression arbor 1 103 that facilitates the securing and positioning of the laminate.
• arbor 1 103 may be formed from any alloy, compound or element which may serve to enhance motor performance.
• other arbors 1103 may be implemented depending upon factors such as the type of shaft 1 100, design of the conductive stack 1104, as well as other factors.
• magnetically conductive stack 1 104 may comprise a stack 1104 of individual disks laminated together.
• stack 1104 may comprise a unitary structure, or other similar solid magnetically conductive path.
• stack 1 104 may be replaced with any suitable magnetic material that enhances motor performance, including, but not limited to, various steel alloys, various paramagnetic materials, and distributed air-gap materials such as sintered steels and the like.
• the stack 1 104 is fashioned to present a substantially cylindrical profile, such as one described with reference to FIG. 12, thereby ensuring an air gap with the stator of constant, or substantially constant, dimension at the cost of a relatively slight increase in magnetic circuit length.
• a substantially cylindrical profile such as one described with reference to FIG. 12, thereby ensuring an air gap with the stator of constant, or substantially constant, dimension at the cost of a relatively slight increase in magnetic circuit length.
• Vs Speed Voltage
• shaft position sensors 1 108 may also be implemented depending upon factors such as motor design, intended implementation, and environmental circumstances.
• the shaft position sensor 1108 may be comprised of any mechanism capable of generating and sending data to an electronic controller, including, but not limited to multi-quadrant disk encoders with appropriate sensors, slotted disks with optical sensors, magnetic studs with Hall-Effect transducers, metal studs with magnetic proximity sensors, and any other arrangement that may supply necessary information to the controller, either digitally or in analogue fashion.
• some embodiments may locate components of the shaft position sensors 1108 in a variety of locations.
• FIG. 23 depicts an axial view of some embodiments of a stator stack 1200 shown in the annular section view of the stack, and including: mounting and alignment holes 1201, salient pole projections 1202, coil windings 1203, and independent coil structures 1204, either spool-mounted, of freestanding as desired.
• Dashed line 1205 represents the mean magnetic path for flux manifesting in the annular portion of the stator steel.
• independent coil structures 1204 may comprise a number of windings 1203.
• the surplus windings 1206 may be comprised of the additional amount of windings available for a given source voltage and current and due to the reduction of the Speed Voltage component (Vs) of Back EMF caused by the advantageous rotor assembly 1 190 design described herein, and which enables the overall flux density produced to remain at the desired amount.
• Vs Speed Voltage component
• a conventionally designed, variable air gap DC motor of a source voltage V and current I may include a number of windings N to produce an output power P for the given V and I.
• a constant air-gap DC motor can exploit a surplus of windings N s > N for the same V and I and deliver the same, or greater P.
• lower values of V and I can be implemented with the Back EMF reducing designs disclosed herein to deliver the same magnitude of P.
• stator poles 1202 and stator stack 1200 may comprise laminations or other material to optimize magnetic flux production without inducing detrimental eddy currents.
• Other embodiments of the stator assembly, and the components of the same, may also be implemented.
• the stator assembly 1200 may comprise silicone steel laminations, sintered steel alloys, distributed air gap material, or any other material which may suppress the formation of eddy currents and enhance motor efficiency and performance.
• the stator assembly may have at least four (4), diametrically opposed salient pole projections 1202, situated at even angular increments around the stator periphery, and aligned in pole pairs 180 mechanical degrees apart, so as to constitute a complete magnetic path through the rotor at all times.
• Other configurations are also possible.
• the embodiment shown in FIG. 23 includes six (6) salient pole projections 1202.
• each salient pole projection 1202 supports an electrical winding or coil 1203 that develops a magnetic field in response to the passage of a DC Current through the winding 1203.
• Surplus windings 1206 may likewise be integral with windings 1203 and, likewise, be energized and contribute to the magnetic field. This field provides a magnetic force which acts upon the rotor assembly 1190 and produces a useful torque.
• the windings 1203 and 1206 supported by said stator salient pole projections 1202 are inter-connected so as to produce an additive magnetic effect across the entire pole pair, regardless of the magnetic polarity provided by the electronic controller.
• Other configurations are also possible.
• FIG. 24 is a vertical cutaway view of some embodiments of the motor frame, housing 1300 and stator stack 1200, and end bells 1301, but with the entire rotor assembly 1190 left intact for ease of understanding.
• FIG. 24 illustrates the motor housing 1300, motor end-bells 1301, bearing housings 1302, as well as the relative positions of the motor stator stack 1200, and the shaft assembly 1100. Shaft position sensor 1108 is not shown in FIG. 24.
• each stator pole (e.g., 1202A and 1202D) includes a pole face 1210.
• rotor stack 1 104 rotates in the region immediately opposite the pole face 1210.
• the stack 1 104 is designed so that, at any given moment in the rotation, the edge of the rotor stack 1104 is opposite a flux zone 1304 located on the face 1210.
• FIG. 25 shows the apparatus displayed in FIG. 24, except that the rotor assembly 1 190 and shaft 1100 have been advanced 90 mechanical degrees, thus
• FIG. 26 is a functional block diagram of the presently disclosed motor system designed for "Open System Operation,” which means that energy recaptured from the motor's inductive components during its operation, will be applied to a capacitive storage element, and utilized to supply power to some electrical load external to the motor itself, such as a lamp, a resistor, a pump, etc. Of course, any suitable external load may be powered in this manner.
• FIG. 26 the components and general layout of the Open System are as follows. Power incoming to the system from an external source 1500 may be appropriately conditioned and applied to Direct Current Power Supply 1501. Main Power Storage Capacitors 1502 are also in communication with DC power supply 1501. Electronic Motor Controller 1503 receives power from DC power supply 1501 and communicates with Motor 1504. Motor 1504 is driven by controller 1503 and turns a mechanical load 1507. Of course, mechanical load 1507 may be any suitable load according to the application and implementation.
• Motor Output Shaft 1505 may correspond to the described embodiments of shaft 1100.
• Position Sensor 1506 corresponds to the described embodiments of sensor 1108.
• Recapture Capacitor Bank 1508 may receive recaptured power from the motor 1504 via controller 1503 as described in more detail below.
• Power Inverter 1509 can be used to convert the recaptured power to alternating current (AC), for example when powering AC Load 1510.
• AC alternating current
• DC direct current
• Other configurations of Open System Operation are also possible.
• FIG. 27 is a block diagram of the presently disclosed motor system designed for "Closed System Operation,” which means that energy recaptured from the Motor's inductive components during its operation, will be applied to a capacitive storage element and then utilized to send power back to the main power supply by means of a DC to DC converter operating in conjunction with an electronic Feedback Controller.
• FIG. 28 is a block diagram representing some embodiments of the logical control steps occurring within the Electronic Controller which result in the Motor System functioning in the Open System Mode. Again, this means that energy recaptured from the Motor's inductive components (e.g., winding 1203 and surplus winding 1206) during its operation, will be applied to a capacitive storage element and then utilized to send power to some electrical load external to the motor itself, such as a lamp, a resistor, a pump, etc. Of course, any suitable external load may be powered in this manner.
• some electrical load external to the motor itself, such as a lamp, a resistor, a pump, etc.
• any suitable external load may be powered in this manner.
• 1700 may be appropriately conditioned and applied to Positive DC Power Supply 1701 and
• Negative DC Power Supply 1703. Main Positive DC Capacitor Bank 1702 and Main
• Negative DC Capacitor Bank 1704 communicate with their respective power supplies.
• Electronic Controller 1705 communicates with position Sensor 1706, which corresponds to described embodiments of sensor 1108. Controller 1705 also functions to power Motor Winding 1707, which corresponds to the described embodiments of windings 1203 and surplus windings 1206.
• Recapture Capacitor Bank 1708 stores the energy from the inductive elements (e.g., windings 1203 and 1206).
• External DC Load 1709 may be any suitable load.
• Power Inverter 1710 may be implemented to condition recaptured energy for application to External AC Load 1711, which also may comprise any suitable load.
• Motor Starter 1712 may be implemented to start rotation of the motor as described below.
• FIG. 29 is a block diagram representing the logical control steps occurring within the Electronic Controller which result in the Motor System functioning in the Closed System Mode. As described in connection with FIG. 28, similar components have similar functions.
• energy recaptured from the Motor's inductive components e.g., windings 1203 and surplus windings 1206 during its operation, will be applied to a capacitive storage element 1708 and then utilized to send power back to the appropriate Positive or Negative Main Power Supply by means of DC to DC converters 1810, 1811 operating in conjunction with an electronic Feedback Controller 1809.
• pole-coils 1202 A and 1202D which include windings 1203 and surplus windings 1206) will cause the expansion of a DC magnetic field through said pole sets, through the rotor stack 1104 and around the stator mean magnetic path 1205, such that, the magnetic flux lines will develop a reluctance torque upon the rotor stack 1104, due to its elliptical shape, and cause a maximum rotor displacement of 90 mechanical degrees, relative to pole pieces 1202A and 1202D, to the position illustrated in FIG. 25.
• an angular movement of just a few degrees may be detected by the shaft position sensor 1 108 and this information may be sent to the electronic controller 1503.
• the controller 1503 may then initiate a timing function, which will allow the rotor stack 1 104 to turn through a critical mechanical angle, (e.g., less than 90 mechanical degrees) at which point controller 1503 may cause a DC current to be applied to pole-coils 1202B and 1202E, thus locking the rotor at 30 degrees for an instant in time. Simultaneously, the controller 1503 may switch off the current in pole-coils 1202A and
• the charge and discharge rates of the magnetic fields in and through the windings involved shall be a function of factors such as, the particular embodiment's Supply Voltage developed within Power Supply 1501, the inductance-resistance time constant L/R, the value of the voltage contained within the Recapture Capacitor Bank 1508, and the impedance of the external load (e.g., 1510 or 151 1).
• This same switching procedure may be repeated for pole-coils 1202C and 1202F, and then again for 1202A and 1202D, thereby completing half a rotation, and positioning the rotor stack 1 104 properly for the next 180 degree rotation.
• the controller 1503 may always supply current of proper polarity so as to prevent reinforcement of magnetic domains within the stator 1200.
• next rotation through 180 degrees may be traversed in the same way, reenergizing pole-coils sets 1202B&E, 1202C&F, and finally 1202A&D thereby completing one complete revolution.
• controller 1503 switches off a coil set, the resulting collapse of the associated magnetic field will develop an electric pulse which is automatically delivered to the Recapture Capacitor Bank 1508.
• this Feedback action may be perfected to the point where the external power need support only the system losses.
• the power drawn by the motor will remain constant, while the external power requirements will diminish in proportion to the power contributed by the Recapture Capacitor Bank 1508.
• FIG. 28 illustrates an
• FIG. 29 illustrates an arrangement advantageous for Closed Power System Configuration.
• System Components 1700 through 1711, designated in FIG. 28, and System Components 1800 through 1811, designated in FIG. 29, define logical operations employed in the functioning of said Electronic Controller, and are explained in more detail in a related application titled "Controller for Back EMF Reducing Motor," U.S. Patent Application No.— /— ,— , filed concurrently.
• Motor Starter 1712 is mounted upon the motor output shaft 1100.
• normal starting procedure for a DC motor 1504 may involve a starting algorithm.
• Such an algorithm may be supplied by the controller 1503, which will pulse the Stator windings (e.g., 1202) in proper sequence to induce angular speed.
• the Stator windings e.g., 1202
• it may be supplied in the manner illustrated.
• a shaft-mounted device e.g., 1712

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