Abstract:
Alternating Current (A.C.) Motors are modified in such a way as to provide zero to full nameplate torque, by inserting magnetic rods into elongate control-rod-receptive channelways in the stator. By moving the rods in and out of their respective channelways the magnetic path of the stator flux will change. With the rods all the way out of the stator full nameplate torque is achieved. As the rods are inserted deeper into the stator, the output torque of the rotor will decrease proportionally to a minimum value.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The field of the invention is directed to the provision of a simple yet highly effective method of and means for providing A.C. motors with an infinitely adjustably output torque within the limits of zero to full nameplate rating. 
     2. Description of the Prior Art 
     Applicant is aware of the following patents which, in his opinion, are most relevant to the subject invention. 
     U.S. Pat. No. 2,748,334 to G. L. Miller dated May 29, 1956 discloses two variants of a VARIABLE SPEED INDUCTION MOTOR wherein means are provided for imparting endwise axial movement to the stator 26 relative to the outer periphery of rotor 12 for selectively varying the amount of magnetically responsive flux introduced into the magnetic field at any time by the stator. The rotor is provided with a first portion 18 and a second portion 20 wherein the portion of the circumference of portion 22 is cut away at 26 to provide an annular groove or gap which completely encircles the periphery of portion 22. This reference in FIGS. 4-7 also illustrates means whereby the rotor, per se, is mounted for endwise axial movement relative to the stator which is fixedly mounted relative to the inner surfaces of the motor housing. 
     The change in the axial relationship of the axially shiftable stator relative to the axially fixed rotor, or the change in the axial relationship of the axially displacable rotor relative to the axially fixed stator is utilized to alter the path for the stator flux in such a manner as to achieve a change in output speed of the rotor. The invention of the subject application is distinguishable from the disclosure of this reference since in applicant&#39;s device both the rotor and the stator are at all times fixed against a relative axial movement, and control of the flux is accomplished by advancing or retracting magnetic control rods axially into and out of control-rod-receptive channels provided through the stator. 
     U.S. Pat. No. 2,959,694 dated Nov. 8, 1960 discloses an ADJUSTABLE SPEED SQUIRREL CAGE INDUCTION MOTOR of the type which includes a stator which is axially shiftable relative to and along the length of the rotor for thereby altering the path of the stator flux to the rotor to control the rotational speed of the rotor wherein the rotor includes a low resistance induction section 19 which is disposed adjacent and in axial alignment with a high resistance induction section 20. The stator element 22 is provided with conventional polyphase windings 23 said stator being longitudinally slideable internally of the motor frame relative to the outer periphery of the rotor. 
     The operation of U.S. Pat. No. 2,959,694 is described in column 4, lines 24-50 as follows: 
     &#34;In operation, at start, with the stator 22 over only the nondriving, noninductive rotor section 21, the latter provides a magnetic body of low reluctance acting as a shunting element for the stator field to maintain a high counter electromotive force in the stator winding and avoid undue current drain on the line. To start rotation of the rotor at low speed, the reversible control motor 33 is operated to move the stator from right to left (FIG. 1), gradually bringing the stator over the high resistance rotor section 20 to give the motor high starting torque with high slip and low current drain from the line. Then further operation of the control motor 33 to move the stator on over the low resistance section 19, further reduces the effective resistance of the combined driving rotor sections 19 and 20 gradually bringing the motor to a characteristic giving low slip and substantially constant speed with load changes.&#34; 
     &#34;To reduce speed or bring the motor to a stop, the control motor 33 is reversed; moving the stator back toward the nondriving, rotor section until the desired reduction in motor speed is obtained, or all the way to the nondriving section if stoppage is desired. Intermediate positions of the stator will give intermediate speeds which may be maintained for a considerable time without undue heating due to the effective cooling system for dissipating heat generated in the windings, particularly the high resistance winding.&#34; 
     U.S. Pat. No. 4,025,840 to G. E. Brissey et al dated May 24, 1977 discloses a PERMANENT MAGNET GENERATOR WITH OUTPUT POWER ADJUSTMENTS BY MEANS OF MAGNETIC SHIMS which are designated by the numeral 11 and which, as clearly illustrated in FIGS. 1 and 3, are disposed in fixed, overlying relationship with the outer surface of nonmagnetic insulated wedges 24 which in turn overlie the upper portions of the slot liners 23 which encapsule coils 20, 21, and 22 wound around the pole stems located in compartments which are disposed in slots 12 between adjacent teeth 13 which extend radially from yoke 14 of the stator. The stator teeth 13 are of the salient or overhanging type and include a pair of oppositely extending salient tip portions 15. Magnetic shims 11 are inserted endwise into one or more of a plurality of the stator slots 12 being wedged beneath overhanging portions 15 of the stator teeth and the upper surface of the insulating wedge 24 after which the triangular ends 26 of the magnetic shims (not FIG. 2) are turned upward for engaging the opposite ends of tip portions 15 of a stator tooth 13 to thereby effectively prevent the endwise removal of a shim until and unless an upturned end 26 thereof has been bent downwardly back to the plane of the shim, per se, after which it may be slid endwise from between adjacent teeth 13. 
     This reference teaches that by the judicious selection and placing of shims in certain specific selected slots of the stator, the flux leakage between the stator and rotor at the location of the shims may be increased whereby the leakage inductance of the windings in those slots in which the shims have been placed will, under increased load, reduce the output from the selected windings without in any way effecting the output from the other windings of those particular slots which have not been provided with a magnetic shim strip 11. 
     U.S. Pat. No. 2,342,720 dated Feb. 29, 1944 to J. H. Blankenbuehler discloses a WELDING GENERATOR wherein the reluctance of the path of the magnetic leakage flux between the arcuate shoe member 19 and 20 and the field pole members 11 and 12 are selectively varied by means of a movable magnetic shunt member 34 which is positioned in bridged relation between the adjacent portions of the shoe members 19 and 20 and wherein the movable shunt member 34 is suitably mounted for endwise axial movement relative to said pole members, thereby changing the output welding current as delivered by the generator. 
     Abstract #209,189 published Apr. 21, 1953, of H. K. Ziegler discloses an ALTERNATING CURRENT MACHINE which has a stationary armature 33 with a winding thereon, a rotor 21 for producing a permanent magnetic field, and a housing 30. A laminated soft iron ring-shaped magnetic shunt member is supported coaxially of the rotor shaft 28 and is adjustably attached to the housing 30 and/or the rotor shaft 28. The ring-shaped magnetic shunt is adjustable axially of the rotor shaft by means of a suitable mechanism in order to vary the amount of flux from the permanent magnet rotor which links both the rotor and the armature winding. If desired a damper winding 27 may also be provided. 
     U.S. Pat. No. 978,638 to C. A. Parsons et al dated Dec. 13, 1910 relates to REGULATION OF DYNAMO ELECTRIC MACHINERY wherein the A.C. output voltage of a polyphase A.C. generator is regulated by providing a secondary winding for the leakage path of the flux. 
     U.S. Pat. No. 1,231,588 to L. T. Frederick et al dated July 3, 1977 discloses MAGNETIC MATERIAL from which magnetic shims are produced for reducing the eddy current loss in a stator or rotor by narrowing the air gap in the stator or rotor slot openings. The composite shim material is composed of both nonmagnetic and magnetic material. 
     Applicant is also aware of the disclosure of German Pat. No. 817,008 310/190--German Pat. No. 233,235 310/190--and German Pat. No. 159,241 310/190, and he is also aware of U.S. Pat. No. 3,226,582 to S. Beckwith dated Dec. 28, 1965 which discloses ADJUSTABLE TORQUE INDUCTION MOTORS and U.S. Pat. No. 3,042,820 dated July 3, 1962 to A. Diamond which discloses a SERVO MOTOR WITH ADJUSTABLE VELOCITY DAMP. However, it is considered that none of the last 5 mentioned references are as relevant as any of the first seven mentioned references, the disclosures of which have been more fully discussed hereinabove. 
     The disclosure of none of the 12 aforementioned references when considered singly or in combination neither teach nor disclose the inventive concept for accomplishing the concept of torque control of an alternating motor as disclosed in this application, nor is the invention of this application obvious, as that term is used in U.S. C. Title 35, Section 103. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a partial end view partly in section illustrating the relationship between the stator and rotor of a typical, or conventional, A.C. motor, showing the path of magnetic flux between the stator to the rotor. 
     FIG. 2 is a view generally similar to FIG. 1 but from which it differs in that it illustrates and embodies the inventive concept of the present invention. 
     FIG. 3 graphically illustrates the relationship between current-torque and the rotor r.p.m. of an A.C. motor which embodies the teachings of the present invention. 
     FIG. 4 graphically illustrates the relationship between the torque and r.p.m. of an A.C. motor which embodies the teachings of the present invention. 
     FIG. 5 is a perspective view illustrating the torque-control-rods and the manner in which they are anchored to a common mounting-control ring. 
     FIG. 6 is a vertical sectional view through one end-adjacent portion of a typical A.C. motor, the housing of which has been extended to accommodate the overall length of endwise, axial travel of the torque-control-rods of FIG. 5 in their respective elongate channelways through the stator, and which further illustrates manually operable means for selectively advancing or retracting the control rods relative to the stator. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     By way of background, and with particular reference to FIG. 1, the relationships between the stator and the rotor of a conventional electric A.C. motor have been illustrated as representing prior art, wherein the letter a designates the stator yoke; S stator slots in the yoke in which slots the primary windings S&#39; of the stator are housed; b stator teeth which are disposed between adjacent stator slots; c the air gap between the adjacent peripheral surfaces 10 and 12 of the stator yoke a and the rotor yoke e. Rotor yoke e is provided with a plurality of circumferentially spaced U-shaped rotor teeth d which are defined by open ended slots f which are open at their outer ends to air gap c, and each of slots f house a rotor bar g. 
     The stator a is suitably anchored by any suitable means, not illustrated, relative to the interior of the motor housing 60, FIG. 6, whereas the rotor yoke e is secured to and carried by a drive shaft 30 the opposite ends or end-adjacent portions of which are rotatably mounted in bearings. It should be understood that one end of shaft 30 projects axially from and beyond an end of the motor housing as conventional in electric motors. 
     It should be understood that for ease of understanding only one of the slots of the stator and rotor have been provided with coils, and magnetic members are associated with all of the slots S and f. 
     FIG. 1 illustrates the flux path between the stator and rotor of the conventional or prior art A.C. electric motors. 
     Classical theory states that the magnetic flux originating in the stator windings S&#39; of an A.C. motor provides a magnetic coupling with rotor bars g, and that flux which does not penetrate the air gap c does not contribute to turning torque of the rotor. 
     Referring again to FIG. 1 it will be noted and understood that the lines of flux indicated by φ 1  and φ 2  contribute to rotor torque, it being noted that the output torque of the rotor is proportional to the square of this flux density, whereas lines of flux φ 3  do not contribute to rotor torque. 
     The most widely used methods of reducing flux φ 1  for providing reduced starting current, reduced torque, or reduced speed has been to reduce the primary, that is the stator winding voltage by means of an auto transformer, solid state SCR Controller or some other suitable voltage reducing device. 
     The present invention, as illustrated in FIG. 2, relates to a method of and means for selectively changing the proportion of the flux of φ 1  and φ 3  without changing the applied stator voltage. Maximum torque in rotor shaft 30 is accomplished when φ 1  is a maximum and φ 3  is minimum, and conversely minimum torque is accomplished when φ 1  is minimum and φ 3  is maximum. 
     In FIG. 2 the overall shape of the stator slots are defined by an inner channelway 2m and a radially spaced outer channelway 2S, and a pair of air gaps 2h 1  and 2h 2 , wherein air gap 2h 1  is narrower than and extends between said inner and outer channelways, and wherein inner air gap 2h 2  is narrower than and extends between said inner channelway to the inner periphery 10 of the stator in open communication with air gap 2c between the adjacent surface 10 and 12 of stator and rotor. 
     Torque control rods 2r fabricated from magnetic material are dimensioned to make a snug, but slip fit with the interior of the inner channelways 2m, said rods being of an overall length whereby to extend the full length of the inner channelways when disposed in a fully advanced position within and relative to the stator yoke. 
     Since the magnitude of the flux φ 1 , φ 2 , and φ 3  of FIG. 1 and 2φ 1  and 2φ 3  of FIG. 2 are dependent upon their respective path resistance, the highest flux resistance is defined by the air gaps c and 2c. 
     In FIG. 2 the outer channelway 2S is provided with turns or windings 2S&#39;. The inner channelway 2m may be empty, in which event it constitutes part of an overall air gap 2h 1 , 2hm, and 2h 2 , or said inner channelway may be partially or completely filled with a magentic rod 2r. 
     In order to change the relationship of flux 2φ 1  to flux 2φ 3  the magnetic flux path resistance is changed by moving rods 2r in their respective channelways. With the rods withdrawn the air gap of 2φ 3  is defined as 2h 1 , plus 2hm plus 2h 2 , whereas flux 2φ 1  has but two air gaps, viz 2c. Therefore, with the inner channelways empty the magnetic path of flux 2φ 3  has a substantially greater resistance than the magnetic path of flux 2φ 1  and maximum turning torque will be applied to the rotor. 
     However, with the inner channelways filled with magnetic rods 2r, the magnetic path of flux 2φ 3  has a lower magnetic resistance than flux path 2φ 1  and the output turning torque of the rotor will be a minimum because the flux is, in effect, short circuited through said rods. 
     In FIG. 3 curve T 1  is a typical Nema curve as occurs when flux 2φ 1  is at a maximum. 
     If the flux 2φ 1  is reduced by one-half by inserting the magnetic rods 2r into the inner channelways of the stator the torque of the motor rotor will be reduced to one-quarter of maximum torque 2φ 1  as indicated by curve T 2 . 
     It has also been established that whenever flux 2φ 3  and 2φ 1  are equal, in FIG. 2, the output turning torque of the rotor will be one-quarter rated torque of the motor. 
     FIG. 3 further discloses that the maximum torque T 1  has a corresponding maximum starting current I 1 , and the relative values of starting current I 2  for torque T 2  has been indicated. 
     With the magnetic control rods 2r inserted longitudinally into their respective inner channelways 2m to a point where the flux 2φ 1  equals the flux 2φ 3 , the starting current will be approximately one-half of the maximum starting current, and the starting torque will be approximately one-quarter of the maximum starting torque T 1 . Under these conditions it is noted from FIG. 3 that a typical load curve L 1  intersects the reduced speed-torque-curve T 2  at RPM 2 , and that the said load curve L 1  intersects the maximum torque-curve T 1  at RPM 1  when the magnetic rods 2r are completely withdrawn from their channelways in the stator. 
     FIG. 4 shows that with the magnetic control rods of FIG. 2 withdrawn from the stator, and with 2φ 1  at maximum, a high slip motor will generate a speed-torque curve similar to T 3 . By inserting the magnetic control rods longitudinally into slots 2m FIG. 2 an infinite family of speed-torque curves would be generated from T 3  to T∞. With a load curve similar to L 2  the insertion of the magnetic control rods will also generate an infinite variety of running speeds depending on where the load curve intersects the corresponding torque curve. The same would be true of loads similar to L 3  and L 4 . 
     The configuration of the magentic torque-control rods could be any shape as long as they fill their respective channelways 2m. As earlier noted, it is important to have close physical contact between the adjacent surfaces of the magnetic rods and channelways 2m FIG. 2. These magnetic rods may be solid or laminated similar to the stator. The size of the inner channelway 2m will be dependent on the rotor output torque range requirements. The stator is wound in a conventional manner with coils inserted through openings 2h 2 , 2hm, and 2h 1 . Openings 2h 1  and 2h 2  will be sized in accordance with conventional motor design practice. Dimension 2hm FIG. 2 will be sized according to magnetic control rods selected. 
     The length and number of the magnetic control rods is contingent upon degree of torque variations required. Maximum usable rod length would be insertion to the total length of the stator, and the number of magnetic control rods would normally be the same as the number of stator slots, but this again is optional depending on range of desired control. 
     As best illustrated in FIG. 5 one end of each of the control rods 2r are fixedly secured to the inner planar surface 40 of a common mounting-control ring 42 such as, by way of example, welding W, or the like. Each of the rods are disposeds in exact parallel axial alignment whereby to be slideably received into corresponding inner channelways 2m of the stator. 
     Endwise axial movement may be imparted to ring 42 and rods 2r by any suitable means, such as, by way of example, a jackscrew J which threadably engages member 50 which spanningly engages the free outer ends of a pair of actuator shafts 52 whose opposite ends are suitably anchored to the mounting control ring 42. 
     One end of a conventional motor housing 60 may be extended by removing the conventional bell cap and replacing it with a cup-shaped housing element 61 having side walls 62 and an end wall 64, wherein the inner surface of the said end wall is spaced from the adjacent end of housing 60 by a dimension or distance to freely accommodate the position of ring 42 when the rods have been fully retracted from their channelways 2m of the stator. 
     End wall 64 may be provided with an inwardly projecting boss 66 in which a bearing 68 in which the end of the rotor shaft 30 is journaled. 
     One end of the jackscrew, which threadably engages the internally threaded bore 54 of a strut member 50, may be rotatably secured to said member by an opening in the center of a plate 56 through which reduced shank 57 of the jackscrew projects, the outer end of said shank being engaged by a washer 58 which is anchored to the shank by means of a set screw 59. The plate 56 may be securely though releaseably fastened to rear wall 64 as at 69. 
     The opposite end of the jack shaft may be engaged by a handle K, whereby rotary motion imparted to the jack shaft is translated into endwise axial movement of the magnetic torque-control rods 2r. 
     The subject invention is ideally suited for use with both single phase and polyphase A.C. motors with conventional stator windings modified to include channelways such as 2m for the reception of torque-control rods 2r. 
     Rods 2r may, in some instances, be introduced into the conventional stator slots S, as in FIG. 1, in those instances where the windings S&#39; therein do not completely fill slots S to provide an open space beneath the windings into which the rods may be inserted. However, in each instance it is imperative that the rods are disposed between the windings as S&#39; of FIG. 1 or 2S&#39; of FIG. 2 and the air gap between the slots or channelways in which the rods are received and the air gap c or 2c, respectively, between the adjacent peripheral surfaces of the stator and rotor. 
     In some cases it may be desirable to provide a control rod for each of the stator slots, whereas in other instances rods may be associated with alternate or every third slot. 
     It should be understood that the inventive concept of this application is not limited to any particular means for imparting endwise axial movement to the control rods 2r and that the means illustrated in FIG. 5 merely represent one type of means which may be utilized. The desired movement to said rods can be manual, pneumatic, hydraulic, electromechanical, or they may be activated statically or dynamically by close loop feed back transducer. 
     It should likewise be understood that the particular shape of the elongate control rod-receptive open spaces or channelways of the stator slots and the complimentary shape of the control rods need not be rectangular as illustrated in the figures, but may be of any one of a plurality of other shapes.