MATHOY, Arno (Steinbergweg 16, Grabs, CH-9472, CH)
HOLZNER, Andreas (Sulzbacher Str. 67, Inzell, 83334, DE)
MATHOY, Arno (Steinbergweg 16, Grabs, CH-9472, CH)
| Laminated rotor for rotating electric machine, in particular for a hybrid synchronous motor of vehicle drives, the rotor plates (6) of which have one or several recesses (9) as flux barrier or magnet pocket, which comprise radially innermost and outermost edge sections as rounded transition regions (13) from and to edge sections lying therebetween, wherein at least one of these transition regions is configured in a circular or ellipse shape, characterized in that each of the rounded transition regions (13) is shaped at least approximately respectively according to a part of a curve (15) of second order, and that between the adjacent recesses (9) in each case an oblique cross-piece (32) is provided, the centre line (34) of which lies obliquely to a pole axis (10) and forms therewith preferably an angle (33) of 10-50°, in particular 30°. The rotor according to Claim 1 , characterized in that to increase the torque which is able to be reached of the rotor (1 ), in particular in the hybrid synchronous motor, the rotor plates (6) are produced from an iron-cobalt alloy, preferably with a proportion of 50% cobalt and 50% iron. The rotor according to Claim 1 or 2, characterized in that each curve (15) of second order in the transition regions (13) is elliptical or is configured approximately to an ellipse (15). The rotor according to one of Claims 1 to 3, characterized in that the recesses (9) in the rotor poles (2) are configured as radial slits, wherein the curve (15) of second order is arranged as an ellipse in the radial slit (9) tangentially and symmetrically. The rotor according to Claim 4, characterized in that a main axis (16) of the tangential ellipse (15), which defines the rounding, is preferably greater by 40-60% than a width (18) of the radial slit (9), and a secondary axis (17) of the ellipse (15) is preferably smaller by 70-80% than the width (18) of the slit (9). The rotor according to Claim 4 or 5, characterized in that the recess (9) as radial slit (9) - viewed in its longitudinal axis - is divided by a bridge (19) into two parts (9A, 9B), wherein the radially inner first slit part (9A) is configured as a first flux barrier, if applicable to receive a permanent magnet (30), and the radially outer second slit part (9B) is configured as a second - radially outer - flux barrier. 7. The rotor according to Claim 6, characterized in that alternatively or additionally also the radially outer slit part (9B) receives a permanent magnet. 8. The rotor according to Claim 6 or 7, characterized in that at least the radially inner end (12 or respectively 20) of the two slit parts (9A, 9B) is configured elliptically and/or parabolically according to the curve (15) of second order. 9. The rotor according to one of Claims 6 to 8, characterized in that the radially outer end (21 ) of the first slit part (9A) is also configured elliptically and/or parabolically according to the curve (15) of second order. 10. The rotor according to one of Claims 4 to 9, characterized in that an outermost point (26) of the radial slit (9) is arranged with a radial distance (28) from the outer shell (27) of the rotor pole (4), the value of which preferably lies between 0.6-0.7 mm. 1 1 . The rotor according to one of the preceding claims, characterized in that in all recesses (9) and contour sections (27) of the rotor plate (6), the curves (15) of second order are configured elliptically in each transition region (13). 12. The rotor according to Claim 1 , characterized in that the curve (15) of second order is configured parabolically in each transition region (13). 13. The rotor according to Claim 1 , characterized in that the curve (15) is configured according to a polynomial of higher order in each transition region (13) which is stressed by notch stress. 14. The rotor according to one of Claims 1 -3, characterized in that the radially outwardly lying recesses (9) for an increased deflecting or respectively a concentration of magnetic flux lines (M) in radial direction have a ham- or kidney-like contour (according to Fig. 8). 15. A rotor, substantially as hereinbefore described and as illustrated in the enclosed drawings. 16. An electric machine rotor assembly comprising: a rotor piece, said rotor piece having at least one salient pole, said at least one salient pole having a shank, said shank having a radial shank axis, and said at least one salient pole having a shoe; a radially-extending longitudinal slot in said at least one salient pole, said radially-extending longitudinal slot having a central slot axis coincident with said shank axis, said radially-extending longitudinal slot having a first lateral side surface, said radially-extending longitudinal slot having a second lateral side surface, the distance between said first and second lateral side surfaces defining a slot width; a radially-outermost edge section of said radially-extending longitudinal slot, said radially-outermost edge section located at a radially outer end of said radially- extending longitudinal slot; said radially-outermost edge section including a curved outermost transition region, said curved outermost transition region having profile shape at least approximately in form of a curve of second order; a radially-innermost edge section of said radially-extending longitudinal slot, said radially- innermost edge section located at a radially inner end of said radially- extending longitudinal slot; said radially-innermost edge section including a curved innermost transition region, said curved outermost transition region having profile shape at least approximating an ellipse perimeter, said ellipse perimeter formed by an ellipse having major diameter of length greater than said slot width by a range of 40-60% and having minor diameter length smaller by a range of 70-80% than said slot width; a bridge spanning the slot width and connected to said first and said second lateral side surfaces, said bridge dividing said radially-extending longitudinal slot into a first radially-inner slot portion and a second radially-outer slot portion; and, a permanent magnet in said first slot portion. 17. An electric machine rotor assembly as claimed in claim 16, further comprising: said second radially-outer slot portion is an empty-space flux barrier; and, said permanent magnet generates flux saturating said bridge to create high resistance for further magnetic flux in said bridge and reduce magnetic conductivity of said bridge so as to extend the effect of said magnetic flux barrier to a total region of a longitudinal axis of said at least one salient pole. 18. An electric machine rotor assembly as claimed in claim 16, further comprising: said second radially-outer slot portion has a second permanent magnet therein. 19. An electric machine rotor assembly as claimed in claim 16, further comprising: said curved outermost transition region's profile shape that is at least approximately in form of a curve of second order includes a profile shape selected from the group consisting of an elliptical profile, a parabolic profile, and a higher- order polynomial profile. 20. An electric machine rotor assembly as claimed in claim 16, further comprising: said first slot portion having a respective curved outer transition region, said curved outer transition region of said first slot portion having profile shape at least approximating a respective ellipse perimeter, said respective ellipse perimeter of said curved outer transition region formed by a respective ellipse having a respective major diameter of length greater than said slot width by a range of 40-60% and having a respective minor diameter length smaller by a range of 70-80% than said slot width. 21. The electric machine rotor assembly as claimed in claim 20, wherein: said respective minor diameter of said respective ellipse perimeter of said curved outer transition region of said first slot portion is smaller than said minor diameter of said curved innermost transition region's ellipse perimeter. 22. An electric machine rotor assembly as claimed in claim 20, further comprising: said second slot portion having a respective curved inner transition region, said curved inner transition region of said second slot portion having profile shape at least approximating a respective ellipse perimeter, said respective ellipse perimeter of said curved inner transition region formed by a respective ellipse having a respective major diameter of length greater than said slot width by a range of 40- 60% and having a respective minor diameter length smaller by a range of 70-80% than said slot width. 23. The electric machine rotor assembly as claimed in claim 22, wherein: said respective minor diameter of said respective ellipse perimeter of said curved outer transition region of said first slot portion is smaller than said minor diameter of said curved innermost transition region's ellipse perimeter; and, said respective minor diameter of said respective ellipse perimeter of said curved inner transition region of said second slot portion is smaller than said minor diameter of said curved innermost transition region's ellipse perimeter. 24. An electric machine rotor assembly as claimed in claim 16, further comprising: said radially-outermost edge section of said radially-extending longitudinal slot having a radially-maximal extent spaced in the range of 0.6 - 0.7 mm from an outer periphery of said at least one salient pole. 25. An electric machine rotor assembly as claimed in claim 16, further comprising: said rotor piece being produced from an iron-cobalt alloy. 26. An electric machine rotor assembly comprising: a rotor piece, said rotor piece having at least one salient pole, said at least one salient pole having a shank, said shank having a radial shank axis, and said at least one salient pole having a shoe; a radially-extending longitudinal slot in said at least one salient pole, said radially-extending longitudinal slot having a central slot axis coincident with said shank axis, said radially-extending longitudinal slot having a first lateral side surface, said radially-extending longitudinal slot having a second lateral side surface, the distance between said first and second lateral side surfaces defining a slot width; a radially-outermost edge section of said radially-extending longitudinal slot, said radially-outermost edge section located at a radially outer end of said radially- extending longitudinal slot; said radially-outermost edge section including a curved outermost transition region, said curved outermost transition region having profile shape at least approximately in form of a curve of second order; a radially-innermost edge section of said radially-extending longitudinal slot, said radially- innermost edge section located at a radially inner end of said radially- extending longitudinal slot; said radially-innermost edge section including a curved innermost transition region, said curved innermost transition region having profile shape at least approximately in form of a curve of second order; a bridge spanning the slot width and connected to said first and said second lateral side surfaces, said bridge dividing said radially-extending longitudinal slot into a first radially-inner slot portion and a second radially-outer slot portion; said first slot portion having a respective curved outer transition region, said curved outer transition region of said first slot portion having profile shape at least approximately in form of a curve of second order; said second slot portion having a respective curved inner transition region, said curved inner transition region of said second slot portion having profile shape at least at least approximately in form of a curve of second order; and, a permanent magnet in said first slot portion. 27. An electric machine rotor assembly as claimed in claim 26, further comprising: said second radially-outer slot portion is an empty-space flux barrier; and, said permanent magnet generates flux saturating said bridge to create high resistance for further magnetic flux in said bridge and reduce magnetic conductivity of said bridge so as to extend the effect of said magnetic flux barrier to a total region of a longitudinal axis of said at least one salient pole. 28. An electric machine rotor assembly as claimed in claim 26, further comprising: said curved outermost transition region's profile shape that is at least approximately in form of a curve of second order, and said curved innermost transition region's profile shape that is at least approximately in form of a curve of second order, and said curved outer transition region's profile shape that is at least approximately in form of a curve of second order, and said curved inner transition region's profile shape that is at least approximately in form of a curve of second order, each includes a respective profile shape selected from the group consisting of an elliptical profile, a parabolic profile, and a higher-order polynomial profile. 29. An electric machine rotor assembly as claimed in claim 26, further comprising: said radially-outermost edge section of said radially-extending longitudinal slot having a radially-maximal extent spaced in the range of 0.6 - 0.7 mm from an outer periphery of said at least one salient pole. 30. An electric machine rotor assembly as claimed in claim 26, further comprising: said rotor piece being produced from an iron-cobalt alloy. 31 . An electric machine rotor assembly as claimed in claim 26, further comprising: said second radially-outer slot portion has a second permanent magnet therein. 32. An electric machine rotor assembly comprising: a rotor piece, said rotor piece having a central axis, said rotor piece having a radial extent from said central axis; a first magnet pocket recess disposed in said rotor piece and transversely to a radius of said rotor piece, said magnet pocket recess having a major axis coinciding with a chord segment of a rotor circle delineated by said radial extent; said magnet pocket recess having a radially-outer top wall; said magnet pocket recess having a radially-inner bottom wall; said magnet pocket recess having a first end closing between said radially-outer top wall and said radially-inner bottom wall, and said magnet pocket recess having a second end closing between said radially-outer top wall and said radially-inner bottom wall; a first flux barrier recess located proximate to said first end, said first flux barrier recess separated from said first end by a first oblique crosspiece lying obliquely at an angle in the range of 10°-50° relative to a radius of said rotor piece that passes through a center of said magnet pocket recess, said first flux barrier recess having a respective upper wall, and said first flux barrier recess having a respective lower wall; a second flux barrier recess located proximate to said second end, said second flux barrier recess separated from said second end by a second oblique crosspiece lying obliquely at an angle in the range of 10°-50° relative to a radius of said rotor piece that passes through a center of said magnet pocket recess, said second flux barrier recess having a respective upper wall, and said second flux barrier recess having a respective lower wall; a pocket recess first outer transition region between said radially-outer top wall and said first end, a pocket recess first inner transition region between said radially- inner bottom wall and said first end, a pocket recess second outer transition region between said radially-outer top wall and said second end, a pocket recess second inner transition region between said radially-inner bottom wall and said second end, a first flux barrier upper transition region between said first flux barrier respective upper wall and said first oblique crosspiece, a first flux barrier lower transition region between said first flux barrier respective lower wall and said first oblique crosspiece, a second flux barrier upper transition region between said second flux barrier respective upper wall and said second oblique crosspiece, a second flux barrier lower transition region between said second flux barrier respective lower wall and said second oblique crosspiece, each of said transition regions having a respective profile shape at least approximately in a respective form of a respective curve of second order. 33. The electric machine rotor assembly as claimed in claim 32, wherein: each transition region's profile shape includes a respective profile shape selected from the group consisting of an elliptical profile, a parabolic profile, and a higher-order polynomial profile. 34. The electric machine rotor assembly as claimed in claim 32, wherein: each transition region's profile shape is a respective elliptical profile. 35. An electric machine rotor assembly as claimed in claim 32, further comprising: said rotor piece being produced from an iron-cobalt alloy. 36. An electric machine rotor assembly as claimed in claim 32, further comprising: an outer magnet pocket recess disposed in said rotor piece and transversely to a radius of said rotor piece, said outer magnet pocket recess having a respective major axis parallel to the major axis of said first magnet pocket recess that coincides with a chord segment of a rotor circle delineated by said radial extent; said outer magnet pocket recess having a respective radially-outer top wall; said outer magnet pocket recess having a respective radially-inner bottom wall; said outer magnet pocket recess having a respective first end closing between its respective radially-outer top wall and its respective radially-inner bottom wall, and said outer magnet pocket recess having a second end closing between its respective radially-outer top wall and its respective radially-inner bottom wall; a first radially outwardly lying recess located proximate to said outer magnet pocket's first end, said first radially outwardly lying recess having a ham-like or kidney-like contour; and, a second radially outwardly lying recess located proximate to said outer magnet pocket's second end, said second radially outwardly lying recess having a ham-like or kidney-like contour. An electric machine rotor assembly as claimed in claim 36, further comprising: an outer magnet pocket recess first outer transition region between said outer magnet pocket recess radially-outer top wall and said outer magnet pocket recess first end, an outer magnet pocket recess first inner transition region between said outer magnet pocket recess radially-inner bottom wall and said outer magnet pocket recess first end, an outer magnet pocket recess second outer transition region between said outer magnet pocket's radially-outer top wall and said outer magnet pocket's second end, an outer magnet pocket recess second inner transition region between said outer magnet pocket's radially-inner bottom wall and said outer magnet pocket's second end, each of said outer magnet pocket's transition regions having a respective profile shape at least approximately in a respective form of a respective curve of second order. 38. The electric machine rotor assembly as claimed in claim 37, wherein: each respective transition region of said outer magnet pocket's transition regions includes a respective profile shape selected from the group consisting of an elliptical profile, a parabolic profile, and a higher-order polynomial profile. 39. The electric machine rotor assembly as claimed in claim 37, wherein: each transition region's respective profile shape is a respective elliptical profile. |
[0001 ] This application claims benefit of priority to prior U.S. provisional application no. 61/363,199 filed on July 9, 2010, and as a non-provisional thereof; this application also claims benefit of priority to prior European application no. EP101691 15 filed on July 9, 2010; the entirety of European application no. EP101691 15 and of U.S. application no. 61/363,199 are expressly incorporated herein by reference in their entirety, for all intents and purposes, as if identically set forth herein.
FIELD OF THE INVENTION
[0002] The present invention relates to a laminated rotor for a rotating electric machine, in particular for a highly stressed hybrid synchronous motor (HSM) of vehicle drives. The invention relates to a special configuration of the geometry of rotor plates in electric motors, in particular for the drive of an electric car.
PRIOR ART [0003] An electric machine is known from WO-0148890-A1 , in which the stator or the rotor has radial tooth modules/poles which are separated from each other. In order to increase the reluctance, each tooth module/pole is provided with a reluctance barrier which is constructed as a radial and axially extended gap in the pole shoe.
[0004] As is known, the electric motors in the main drive of electric cars or hybrid cars often operate up to rotation speeds of approximately 12000 rpm. These high rotation speeds bring about very great centrifugal forces on the periphery. By way of example, reference is to be made to current-excited synchronous motors (CSM). Originally, such current-excited synchronous motors or generators were used for large motors or generating plants, where the rotation speeds are a fraction of the above-mentioned value. The current-excited synchronous motor differs from the other types of motor used hitherto in an electric car (e.g. asynchronous and permanent magnet synchronous motors) substantially by a wound and current-excited rotor. [0005] Owing to the very high centrifugal forces which act on the pole caps and are produced not least by the weight of the copper windings, in the new application for electric cars the poles/pole shoes or plate stacks of the rotor in the CSM are particularly highly stressed. Owing to the high centrifugal forces, which are produced inter alia, by the winding and act with leverage force on the pole caps, high notch stresses occur in the region of slots acting as a flux barrier, namely at the geometric transitions from the horizontal into the vertical. Also with the configuration of conventional roundings (circular in shape), enormous stress peaks also occur, and namely at the transitions from the circular rounding to the straight line. Nowadays, these stress peaks restrict the possibility for further development of the rotor geometry in a CSM or prevent high rotation speeds. Conventional methods, such as for example the application of Kevlar cages, welded or screw constructions or suchlike which are intended to increase the stability of the rotor, however, have a performance-reducing effect.
[0006] Similar effects also occur, however, in known hybrid synchronous motors (HSM) for the main drive in the automobile field, in which recesses are provided for buried magnets and/or punched-out flux barriers.
[0007] Another problem in the rotor geometry of the conventional current-excited synchronous machines lies in that the plate stacks of the rotor likewise under the rotation speed-induced centrifugal forces with identical dimensioning lift themselves earlier from the shaft than in comparable electric motors with closed rotor plate stacks. The effect of the lifting from the shaft therefore likewise limits the possible rotation speed. The lifting effect is less in machines with a closed pole structure (e.g. HSM), but it is also considerable.
[0008] Therefore, an improved lifting behaviour, i.e. less easy releasing of the plate stack from the shaft, is also desirable. The lifting behaviour of the rotor plates could theoretically be influenced by a greater interference fit between shaft and rotor plate. However, the stress on the plate geometry would be additionally increased in the region of the radial slits, which is not desirable for the reasons previously mentioned. Therefore, the effects of lifting and notch stresses or respectively increased contact pressure between rotor plate stack and shaft, and increased notch stress play against each other in a disadvantageous manner.
[0009] It could be defined as a superordinate objective, to find a rotor structure which has no centrifugal force-induced problems at high rotation speeds (e.g. approximately 12000 rpm). [0010] US-2007096578-A1 discloses a rotor for electric machines. However, this solution deals expressly only with the edge paths of the recesses of the rotor plate immediately adjoined by the outer rotor periphery, wherein exclusively the curved end part of the recess is configured circularly or, if applicable, elliptically.
[001 1] None of the two indicated known technologies satisfactorily solves the problem which is posed.
[0012] According to US-2010045121 -A1 , a cobalt alloy was used for the magnet circuits, to increase the magnetic saturation in electric motor construction. SUMMARY OF THE INVENTION
[0013] The invention is based on solving the problem of creating an improved rotor geometry, by which the above-mentioned disadvantages of the prior art are reduced or eliminated, i.e. by which on the one hand the stress peaks, in particular the notch stresses in the rotor - despite high centrifugal forces - can be significantly reduced. On the other hand, through the invention also the lifespan and the torque of the rotor or of the electric motor are to be increased, and therefore also the lifting behaviour is to be positively influenced, or reduced.
[0014] The problem which is posed is solved by the features of the appended
independent claims.
[0015] Advantageous further developments of the solution according to the invention are indicated in the dependent claims.
[0016] To solve the problem which is posed, one proceeds from a laminated rotor for rotating electric machines, in particular for a hybrid synchronous motor of vehicle drives, the rotor plates of which have one or several recesses as flux barrier or magnet pocket. The radially innermost and outermost edge sections of these recesses (rounded transition regions) comprise edge sections lying therebetween, wherein at least one of these transition regions is configured in a circular or ellipse shape. According to the invention, each of the rounded transition regions is shaped at least approximately respectively according to a part of a curve of second order, on the other hand between the adjacent recesses in each case an oblique cross-piece is provided, the centre line of which lies obliquely to a pole axis and forms here with the pole axis preferably an angle of approximately 20° - 50°, in particular 30°. [0017] The term "curve of second order" is to be understood in this application to mean, both in the description and also in the claims, a geometric figure of a curve which can be designated as a conic section, and which is configured elliptically, parabolically or hyperbolically (i.e., not circularly or angularly).
[0018] This rotor plate geometry is suitable in particular for a fast-running HSM or CSM.
[0019] In the CSM, the rotor comprises at least two rotor poles, each with an exciter winding and in each rotor pole at least one magnetic flux barrier in the form of a radial slit. In the HSM, per rotor pole at least one magnet is housed in a magnet pocket and the lamination also has at least one flux barrier.
[0020] Our calculations [by means of the Finite Element Method (FEM)] and tests confirmed that the shape of an ellipse in the recess transition region involves the least stresses. In the opinion of the inventors, this is attributable to the continuous alteration of the distance from the intersection of the main axis of the ellipse. (This corresponds to a continuous alteration of the radius). By systematic determination of height and width, the ellipse can be optimized geometrically with respect to as minimal a notch stress as possible. As the use of two cooperating circular roundings with different radii represents a good approximation to the ellipse, thereby a distinct improvement compared to a pure circular rounding can already be achieved. Through the elliptical configuration of the transition regions of the recesses, the lifespan of the rotor is increased and the risk of fracture induced by centrifugal force is reduced.
[0021] Through the invention, evidently an effective deflection of the flux of force takes place in the transition region or respectively a reduction of the notch effect, which does not even allow stress peaks to occur in the dangerous zone at all. Through the use of the ellipse shape with its continuous distance increase, this takes place in a particularly harmonious manner. (The term "distance" is to be understood in each case to mean a distance from the intersection of the main axis of the ellipse.) The condition for fulfilling the function of the continuous distance increase could also be designated as "distance gradient". This continuous distance increase as a condition could, however, in addition to the ellipse, also be fulfilled according to the invention by parabola (quadratic function), polynomials of higher order, or as an approximation to the ellipse by two radii continuing tangentially into each other, with a different value.
[0022] This part of the invention is therefore basically to be used advantageously in all electric motors with radial slits, magnet pockets and/or other recesses, in which notch stresses occur. In this respect, the invention is not restricted to CSM or HSM, but rather it can be used expediently in any rotor geometry having recesses.
[0023] In the preferred example version, alternatively to iron-silicon plates, at least the rotor plates, to increase the rotor torque which is able to be achieved, are produced from an iron-cobalt alloy, preferably with a proportion of 50% cobalt and 50% iron. Through this measure, the torque e.g. of a HSM can therefore be further increased and hence the power density can be increased significantly.
[0024] In an example version of a CSM, the radial slot is divided - in its longitudinal axis - by a transversely arranged bridge into two or several regions, wherein the radially inner first slit part is configured as a first flux barrier, if applicable to receive a permanent magnet, and the radially outer second slit part is configured as a second flux barrier, if applicable also to receive a permanent magnet. Through the permanent magnet, the rotor iron of the rotor plates - at the bridges or respectively at the remaining connection sites - is saturated, so that these regions for the magnetic flux act as a division of the pole. Thereby, the effect of the magnetic field lines can be optimized in the rotor pole.
[0025] In an expedient version, at least the radially inner end of the two slit parts for the continuous distance increase is configured elliptically and/or parabolically and/or with two radii continuing into each other tangentially. The radially outer end of the first slit part can also be configured elliptically and/or parabolically and/or with two radii continuing into each other tangentially as an approximation to an ellipse.
[0026] If applicable - alternatively or additionally - the radially outer slit part may also receive a permanent magnet.
[0027] In preferred exemplary versions of the invention, the curves of second order in the transition regions in all recesses and contour sections of the rotor plate may be configured elliptically or approximately to an ellipse. In additional preferred exemplary versions, there is a rotor piece having at least one salient pole that has a shank, said shank having a radial shank axis, and said at least one salient pole having a shoe. There is a radially-extending longitudinal slot in said at least one salient pole, said radially- extending longitudinal slot having a central slot axis coincident with said shank axis, said radially-extending longitudinal slot having first and a second lateral side surfaces, the distance between said first and second lateral side surfaces defining a slot width.
Furthermore, there is a radially-outermost edge section of said radially-extending longitudinal slot, said radially-outermost edge section located at a radially outer end of said radially-extending longitudinal slot. This radially-outermost edge section includes a curved outermost transition region having profile shape at least approximately in form of a curve of second order. A radially-innermost edge section of said radially-extending longitudinal slot is located at a radially inner end of said radially-extending longitudinal slot. This radially-innermost edge section includes a curved innermost transition region having profile shape at least approximately in form of a curve of second order. A bridge spanning the slot width and connected to said first and said second lateral side surfaces divides said radially-extending longitudinal slot into a first radially-inner slot portion and a second radially-outer slot portion; said first slot portion having a respective curved outer transition region having profile shape at least approximately in form of a curve of second order. The second slot portion has a respective curved inner transition region having profile shape at least at least approximately in form of a curve of second order, and a permanent magnet is in said first slot portion. This permanent magnet generates flux saturating said bridge to create high resistance for further magnetic flux in said bridge and to reduce magnetic conductivity of said bridge, so as to extend the effect of said magnetic flux barrier to a total region of a longitudinal axis of said at least one salient pole. The second radially-outer slot portion is preferably an empty (vacant) space flux barrier, or may have a second permanent magnet therein.
[0028] Preferably, the recesses in the rotor poles are configured as radial slots, wherein the curve of second order is arranged as an ellipse in the radial slit tangentially and symmetrically. Here, a main axis of the tangential ellipse, which defines the rounding, can preferably be configured greater by 40-60% than a width of the radial slit, and a secondary axis of the ellipse can preferably be configured smaller by 70-80% than the width of the slit.
[0029] If applicable, however, the curves in the transition regions may be configured parabolically, hyperbolically, therefore according to a polynomial of higher order (third or higher order), or with two radii continuing tangentially into each other with a different value - as an approximation to the ellipse -, in order to achieve an improvement compared with conventional pure radii in the transition regions. Thus, in the
aforementioned additional preferred exemplary versions, said curved outermost transition region's profile shape, and said curved innermost transition region's profile shape, and said curved outer transition region's profile shape, and said curved inner transition region's profile shape, each may include a respective profile shape selected from the group consisting of an elliptical profile, a parabolic profile, and a higher-order polynomial profile. [0030] In yet additional preferred exemplary versions of the invention, there is a rotor piece having at least one salient pole that has a shank, said shank having a radial shank axis, and said at least one salient pole having a shoe. A radially-extending longitudinal slot in said at least one salient pole has a central slot axis coincident with said shank axis. This radially-extending longitudinal slot has first and second lateral side surfaces, the distance between said first and second lateral side surfaces defining a slot width. A radially-outermost edge section of said radially-extending longitudinal slot is located at a radially outer end of said radially-extending longitudinal slot, and said radially-outermost edge section includes a curved outermost transition region having profile shape at least approximately in form of a curve of second order. Furthermore, a radially-innermost edge section of said radially-extending longitudinal slot is located at a radially inner end of said radially-extending longitudinal slot. This radially-innermost edge section includes a curved innermost transition region having profile shape at least approximating an ellipse perimeter formed by an ellipse having major diameter of length greater than said slot width by a range of 40-60% and having minor diameter length smaller by a range of 70-80% than said slot width. There is a bridge spanning the slot width and connected to said first and said second lateral side surfaces, this bridge dividing said radially- extending longitudinal slot into a first radially-inner slot portion and a second radially- outer slot portion. A permanent magnet is located in said first slot portion. It is further advantageous if permanent magnet generates flux saturating said bridge to create high resistance for further magnetic flux in said bridge and reduce magnetic conductivity of said bridge so as to extend the effect of said magnetic flux barrier to a total region of a longitudinal axis of said at least one salient pole. In turn, the second radially-outer slot portion is either preferably an empty-space flux barrier, or may have a second permanent magnet therein.
[0031 ] In variations of these additional preferred exemplary versions of the invention, it may be additionally advantageous configure said curved outermost transition region's profile shape to include a profile shape selected from the group consisting of an elliptical profile, a parabolic profile, and a higher-order polynomial profile. Or, to configure said first slot portion to have a respective curved outer transition region having profile shape at least approximating a respective ellipse perimeter formed by a respective ellipse having a respective major diameter of length greater than said slot width by a range of 40-60% and having a respective minor diameter length smaller by a range of 70-80% than said slot width. Or, to configure said second slot portion to have a respective curved inner transition region having profile shape at least approximating a respective ellipse perimeter formed by a respective ellipse having a respective major diameter of length greater than said slot width by a range of 40-60% and having a respective minor diameter length smaller by a range of 70-80% than said slot width. In additional variations, it may be afford advantage to configure the respective minor diameter of said respective ellipse perimeter of said curved outer transition region of said first slot portion to be smaller than said minor diameter of said curved innermost transition region's ellipse perimeter, or additionally, to configure said respective minor diameter of said respective ellipse perimeter of said curved inner transition region of said second slot portion to be smaller than said minor diameter of said curved innermost transition region's ellipse perimeter.
[0032] In these examplary versions, it may be further advantageous to locate an outermost point of the radial slit arranged at a radial distance from the outer shell of the rotor pole, the value of which preferably lies between 0.6-0.7 mm ( in order to bear the 12000 rpm with this rotor size). This arrangement may be stated alternatively by indicating that said radially-outermost edge section of said radially-extending longitudinal slot has a radially-maximal extent spaced in the range of 0.6 - 0.7 mm from an outer periphery of said at least one salient pole.
[0033] Further according to the invention, therefore in each case an oblique cross-piece is provided between adjacent recesses (e.g. between magnet pockets and flux barriers). Thereby, the cross-pieces with the greatest stresses are stressed more strongly to tension and less to bending. This results in a reduced notch stress, whereby the risk of fracture of the cross-pieces is significantly reduced. It is additionally expedient if the oblique cross-pieces are configured to be as narrow as possible, in order to thereby at the same time make possible a magnetic saturation thereof more quickly, which in turn increases the performance of the motor, as the magnet mass which is used can be utilized more effectively.
[0034] Thus, in further developments, the invention may advantageously include a rotor piece having a central axis, and having a radial extent from said central axis. A first magnet pocket recess is disposed in said rotor piece and transversely to a radius of said rotor piece. This magnet pocket recess has a major axis coinciding with a chord segment of a rotor circle delineated by said radial extent. The magnet pocket recess has a radially-outer top wall and a radially-inner bottom wall. It also has a first end closing between said radially-outer top wall and said radially-inner bottom wall, as well as a second end closing between said radially-outer top wall and said radially-inner bottom wall. A first flux barrier recess is located proximate to said first end and is separated from said first end by a first oblique crosspiece lying obliquely at an angle in the range of 10°- 50° relative to a radius of said rotor piece that passes through a center of said magnet pocket recess, said first flux barrier recess having a respective upper wall and a respective lower wall. A second flux barrier recess is located proximate to said second end and is separated from said second end by a second oblique crosspiece lying obliquely at an angle in the range of 10°-50° relative to a radius of said rotor piece that passes through a center of said magnet pocket recess. This second flux barrier recess has a respective upper wall and a respective lower wall. A pocket recess first outer transition region lies between said radially-outer top wall and said first end. A pocket recess first inner transition region lies between said radially-inner bottom wall and said first end. A pocket recess second outer transition region lies between said radially-outer top wall and said second end. A pocket recess second inner transition region lies between said radially-inner bottom wall and said second end. A first flux barrier upper transition region lies between said first flux barrier respective upper wall and said first oblique crosspiece. A first flux barrier lower transition region lies between said first flux barrier respective lower wall and said first oblique crosspiece. A second flux barrier upper transition region lies between said second flux barrier respective upper wall and said second oblique crosspiece. A second flux barrier lower transition region lies between said second flux barrier respective lower wall and said second oblique crosspiece. Each of said transition regions preferably has a respective profile shape at least approximately in a respective form of a respective curve of second order. As a variation, each transition region's profile shape may include a respective profile shape selected from the group consisting of an elliptical profile, a parabolic profile, and a higher-order polynomial profile; or, each transition region's profile shape is a respective elliptical profile. Within these developments of the invention as well, it should again be understood, as previously referred to, that the rotor piece may advantageously be produced from an iron-cobalt alloy.
[0035] In a preferred example version, the radially outwardly lying recesses have a ham- or kidney-like contour for an increased deflection or respectively a concentration of magnetic flux lines in radial direction.
[0036] In further developments, the invention may advantageously include an outer magnet pocket recess disposed in said rotor piece and transversely to a radius of said rotor piece, this outer magnet pocket recess having a respective major axis parallel to the major axis of the first magnet pocket recess. This outer magnet pocket recess has a respective radially-outer top wall and a respective radially-inner bottom wall. It also has a respective first end closing between its respective radially-outer top wall and its respective radially-inner bottom wall, as well as a second end closing between its respective radially-outer top wall and its respective radially-inner bottom wall. A first radially outwardly lying recess is located proximate to said first end, this first radially outwardly lying recess having a ham-like or kidney-like contour. A second radially outwardly lying recess is located proximate to said second end this second radially outwardly lying recess has a ham-like or kidney-like contour. As will be readily understandable, in advantageous variations, there is: an outer magnet pocket recess first outer transition region between said outer magnet pocket recess radially-outer top wall and said outer magnet pocket recess first end; an outer magnet pocket recess first inner transition region between said outer magnet pocket recess radially-inner bottom wall and said outer magnet pocket recess first end; an outer magnet pocket recess second outer transition region between said outer magnet pocket's radially-outer top wall and said outer magnet pocket's second end; and, an outer magnet pocket recess second inner transition region between said outer magnet pocket's radially-inner bottom wall and said outer magnet pocket's second end. Each of these outer magnet pocket's transition regions may advantageously have a respective profile shape at least approximately in a respective form of a respective curve of second order. As shall be further readily understandable, in variants, each respective transition region of said outer magnet pocket's transition regions may advantageously include a respective profile shape selected from the group consisting of an elliptical profile, a parabolic profile, and a higher-order polynomial profile. Or, as a variant, each transition region's respective profile shape may be a respective elliptical profile.
[0037] A HSM (or CSM) with the rotor 1 according to the invention of plates of a cobalt/iron alloy with flux barriers which are rounded in the notches elliptically or approximately elliptically or respectively according to a curve of second order, therefore creates a surprising improvement in power density per space or per weight, which is an important criterion in electric car construction for vehicle drives.
BRIEF DESCRIPTION OF THE DRAWINGS [0038] The invention is explained in further detail below by way of example with the aid of the enclosed drawings, which illustrate preferred example versions of the rotor geometry according to the invention of one CSM and two HSM laminations, in which are shown:
· Fig. 1 a view of a first example embodiment of the rotor geometry according to the invention;
• Fig. 2 a view of a part II in Fig. 1 on an enlarged scale;
• Fig. 3 a view of a part III in Fig. 2 on a proportionally enlarged scale;
• Fig. 4 a partial view of the second embodiment of the rotor geometry according to the invention (60° sector);
• Fig. 5 a third preferred embodiment of the rotor geometry according to the
invention for a HSM; in this case with six rotor poles
• Fig. 6. a partial view VI in Fig. 5 on a proportionally enlarged scale;
• Fig. 7 a partial view VII in Fig. 6 on a proportionally enlarged scale;
· Fig. 8 a further partial view in Fig. 6 on a proportionally enlarged scale.
DESCRIPTION OF EXEMPLARY VERSIONS OF THE INVENTION
[0039] Fig. 1 shows diagrammatically the view of an example version of the rotor 1 (without rotor shaft) according to the invention, which is provided for a current-excited synchronous motor (CSM) e.g. suitable for vehicle drives. In this example version, the rotor 1 has a 6-pole embodiment, however, if applicable, 2-pole, 4-pole, 8-pole etc. rotor geometries also lie within the scope of the invention. The rotor poles are designated in Fig. 1 by 2.
[0040] The rotor 1 is illustrated in Fig. 1 as a salient pole rotor, wherein each of the rotor poles 2 has a pole shank 3 and a pole shoe 4. Each rotor pole 2 is provided in a manner known per se with an exciter winding 5, which is arranged around the pole shank 3. The cross-section of the exciter winding 5 is illustrated only diagrammatically and hatched in Fig. 1 .
[0041] The rotor 1 in this case consists of a stack (bundle) of uniform rotor plates 6, which are combined in a manner known per se, e.g. glued, welded or connected by a positive fit (not illustrated). [0042] In Fig. 1 it can be seen that the lamination changes here from a closed ring element - technically designated as hub 7 - to six rotor poles 2 connected externally thereon, which are respectively wound around with the wire (e.g. copper wire) of the exciter windings 5. A central opening of the rotor 1 to receive the rotor shaft (not illustrated) is designated by 8.
[0043] In each rotor pole 2, a radial recess acting as a flux barrier is provided, i.e. a slit 9 along a pole axis 10. The recesses or slits 9 are configured here in the rotor poles 2 as central longitudinal openings with substantially parallel edges or side faces 1 1 (Figures 1 and 2).
[0044] The dimensions and the relative arrangement of the slit 9 in a rotor pole, or respectively the rotor poles 2 of this example version itself are to be seen in Fig. 1 and 2. Through the present invention, a novel rotor geometry is indicated. [Substantially the construction by Arno Mathoy in DE 10 2007 040 750 A1 (magnetic constitution of the flux barrier in the CSM), (also published as US- 20100308686-A1 ) incorporated herein by reference in its entirety for all intents and purposes, is now also optimized mechanically].
[0045] The present invention makes provision to configure the radial slit 9 in the rotor plate 6 elliptically at least at its origin, i.e. at the radially inner end 12 of the slit 9 in its transition region 13, i.e. with a continuous increase of the distances 14a...14g from an intersection O of a main axis 16 and a secondary axis 17 of an ellipse 15, in order to reduce the notch stresses - as greatly as is practically possible - in these transition regions 13 (Fig. 3). The ellipse 15 therefore lies with its main axis 16 ideally arranged tangentially to the high radial stresses, which occur both with high pressure, necessary for torque transmission at high rotation speeds, and also with high centrifugal forces, because both forces attempt to widen the rotor radially outwardly. The ellipse 15 therefore lies approximately transversely to the pole axis 10. In Fig. 3, the recess or slit part 9A has three transition regions 13: from the left-hand side face 1 1 (edge) over the radially deepest point P up to the right-hand side face 1 1 (edge).
[0046] In this version of the invention, the continuous increase of distances 14a - 14g is configured as part of the ellipse 15 (Fig. 3). The full ellipse 15 is only illustrated by dot- and-dash lines in Fig. 3. In the inner end 12 (front face) of the radial slit 9, the ellipse 15 is therefore arranged tangentially, i.e. with its main axis 16 perpendicularly to the pole axis 10 (Fig. 2).
[0047] In the illustrated example version, the main axis 16 of the ellipse 15 is preferably longer by 40-60% than the width 18 of the slit 9. The secondary axis 17 of the ellipse 15 is preferably shorter by 70-80% than the width 18 of the slit 9. In the example version according to Fig. 3, the width 18 of the slit 9 is selected at approximately 2.5 mm, the main axis 16 at approximately 3.6 mm and the secondary axis 17 of the ellipse 15 at approximately 1 .4 mm.
[0048] According to the calculations and considerations carried out by the inventor, through this configuration an effective, harmonious deflection of the stresses takes place in the transition regions 13. This continuous increase in distance as a condition could, however, also be fulfilled according to the invention - as had already been mentioned above - in addition to the ellipse 15, by means of parabolae (quadratic function), hyperbolically, as polynomials of higher order or by two or more radii, continuing into each other tangentially, of circles of different diameter (approximation to the ellipse).
[0049] Such approximations to the ellipse can be seen e.g. in Figure 6 and namely in the radially outer roundings of the flux barriers, which according to Fig. 6 are composed of three circles in each case with different radii, while the comparable roundings according to Fig. 4 are circular or can be configured purely elliptically. It is evidently crucial that the transition does not take place angularly or in the form of a single circle (with constant radius), but rather with a continuous increase of the distances 14a...14g from the point O.
[0050] Through the configuration according to the invention also according to other curves of second order by definition as according to an ellipse (hyberbola or parabola), a requirement of a "distance gradient" is also specified, i.e. the requirement of a continuous change of the distances 14a...14g of the individual ellipse points from the ellipse centre point O (Fig. 3).
[0051] As can be seen in Fig. 1 -3, in this version the radial slit 9 - viewed in its longitudinal axis (which coincides here with the pole axis 10) - is divided into two parts by a bridge or cross-piece 19, wherein the radially inner first slit part 9A is configured to receive a permanent magnet 30 as additional flux barrier (see also Fig. 1 ), and the radially outer second slit part 9B as reinforced air gap-flux barrier.
[0052] Using the teaching according to the invention, preferably the following parts can be configured elliptically and/or parabolically:
• the radially inner end 12 of the slit 9, or respectively of the first slit part 9A,
• the respectively inner end 12 or respectively 20 of both slit parts 9A and 9B,
• the radially outer end 21 of the first slit part 9A or of the slit parts 9A and 9B; • likewise, an ellipse is also conceivable and used expediently at an outermost point 26 of the second slit part 9B.
[0053] In the preferred example version, not only these ends 12, 20, 21 of the slit parts 9A and 9B of rotor poles 2, but at all transitions of the rotor geometry of opening or respectively recesses to the full material are configured with a distance gradient, in particular elliptically, in order to further reduce the centrifugal force-induced stresses in the rotor plate.
[0054] In the version according to Fig. 2 a width of the bridge 19 was designated by 22. The value of the width 22 of the bridge 19 is selected here at approximately 1 .2 mm, and a length 23 of the inner first slit part 9A at approximately 15.5 mm, and a length 24 of the radially outer second slit part 9B at approximately 12.5 mm.
[0055] The region of an outer end 25 of the second slit part 9B is widened here circularly with a radius R1 (Fig. 2), the value of which here is about 2.6 mm. The outermost point 26 of the slit part 9B is arranged from an outer shell 27 of the pole shoe 4 at a radial distance 28, the value of which in this case is approximately 0.7 mm. In this example version, the maximum rotor radius R was selected with 82 mm (Fig. 1 ) and the diameter of the opening 8 of the rotor 1 was selected with 85 mm.
[0056] In Fig. 2 it can also be seen that as a rounding or curve in the transition regions 13, the same ellipse 15' is used at the outer end 21 of the first slit part 9A and at the inner end 20 of the second slit part 9B, the secondary axis 17' of which, however, is smaller (only approximately 1 .0 mm) than the secondary axis 17 of the ellipse 15 at the inner end 12 of the first slit part 9A. The ellipses 15' have the same main axis 16 as the ellipse 15.
[0057] In Fig. 2 and 3, the ellipses 15 or respectively 15' are connected with the side faces 1 1 (edges) of the slit 9 by a radius 29, the value of which was selected here at approximately 5.0 mm. In Fig. 1 a radial distance between the opening 8 and an innermost point P (see also Fig. 3) of the slit 9 was designated by 31 . The distance 31 in this case has a value of 10.0mm.
[0058] The rotor geometry according to the invention opens up new possibilities for the motor designers, which are based on the following findings:
[0059] As the prior art offers no basic principles for a motor type of the current-excited synchronous motor in this structural and output size, extensive tests, calculations and modelling were carried out by the inventor for the realization of the above concepts. In the first step, the cylinder press fit between rotor shaft and plate stack of the rotor was tested. Particularly in the upper rotation speed range - 8000 to 12000 rpm - a distinct difference in operating behaviour was able to be established here - compared with plate stacks hitherto, as in the hybrid synchronous motor or in an IPM (motor excited by interior permanent magnets).
[0060] In the comparison of these two laminations - with regard to the joining pressure - a reduction of about 70% was able to be established at the maximum rotation speed. As the widening of the hub 7 with respect to the shaft - owing to the greater median diameter and the greater centrifugal force connected therewith - increases more rapidly, with an increasing rotation speed the interference fit, and hence the joining pressure, decreases. Therefore, according to the invention with the geometry of the current-excited synchronous motor an increase of the interference fit is definitively preferred, in order to thereby prevent a lifting of the rotor hub - even at high rotation speeds. This lifting must be prevented in order to ensure the torque transmission between rotor shaft and plate stack in all operating situations. For this reason here according to the invention the identical joining pressure between rotor shaft and hub is to be aimed for as in closed laminations according to the prior art known per se - similar to Fig. 4.
[0061] Based on these findings according to the invention, the geometry of the rotor plate 6 was able to be dimensioned more objectively with regard to stability according to the invention. In order to prevent a failure of the final rotor stack in operation, the necessary components were tested with regard to stresses and were successfully adapted geometrically.
[0062] The geometry of the proposed rotor plate 6 also influences very positively the lifting behaviour of the rotor 1 from the shaft. With a maximum rotation speed of 12000 rpm a minimum joining pressure of 6122 MPa and a maximum joining pressure of 14862 MPa - according to tolerance position - were measured in the prototype according to the invention for the lifting of the rotor hub from the rotor shaft by means of the rotor geometry according to the invention. The significant increase of the rotation speed lower limit for the lifting of the rotor hub from the machine shaft constitutes an original and very advantageous technical effect, which for this reason is therefore to be regarded as inventive.
[0063] The dimensioning of the lamination (by means of the Finite Element Method) takes place through an analysis on the model of the 60° segment, which was already used for the calculations of the cylinder press fit. The recess (the radial slit 9) is situated in the pole axis, which serves to increase the reluctance moment of the available torque without exciting current. This characteristic is of crucial importance for the CSM for obtaining the emergency operating characteristics (in vehicle drives) in the case of fault.
[0064] Viewed physically, this flux barrier separates from each other the two magnetic flux lines, with run in opposite directions, and prevents too great a phase shift between the current axis and the field axis. Therefore, the torque which is produced can also nevertheless be kept at the nominal torque without a current supply of the rotor winding (e.g. also in an emergency operation).
[0065] For this reason, the dimensioning of this flux barrier is accorded increased attention. Ideally, the pole should be completely separated through in the vertical axis. As this is not possible, however, for mechanical reasons, the flux barrier becomes as large as possible and the remaining mechanical connections, which are designated as
"magnetic bridges", are preferably saturated magnetically by a permanent magnet or by the basically present magnetic flux. As soon as the bridges are saturated, they act as flux barriers. In this way, a complete separation of the two regions is achieved with regard to the magnetic flux.
[0066] The applicant's tests showed that without the present invention with a standard dimensioning, at 12000 rpm in the rotor plate stress peaks are reached with respect to the comparison stress according to MISES of over 870 MPa.
[0067] The parameters, influencing each other reciprocally, formed a vicious circle which is only broken by the invention. Through the invention, it becomes possible for the first time to offer CSMs in the same overall size as IPMs with at least the same performance and with an identical rotation speed range.
[0068] In the region of the flux barrier (of the radial slit 9), enormous notch stresses occurred at the geometric transitions from the horizontal into the vertical. With
conventional roundings, in addition stress peaks occurred at the tangential transitions. Through the invention, and factually confirmed by variational calculus, the stresses were able to be reduced to a minimum by geometric alterations, wherein the shape of an ellipse ultimately produced the transition with the least stresses. This is evidently to be attributed to the continuous increase of the distance towards the notch.
[0069] The ellipse 15 is therefore (Figures 1 -3) to be configured "recumbent", i.e. the main axis 16 perpendicular to the slit 9 or respectively tangentially at the end of the radial slit 9. By definition, notch stresses are a concentration of stresses as a result of force deflections on notches and projections. According to the invention, the force deflection can be configured more "harmoniously", which is an important advantage of the invention. The stresses in the lamination are dominated by the radial stresses in the peripheral direction and these undergo a deflection in the region of the recess (slit 9). Through the ellipse 15 with its continuous distance increase, this force deflection takes place particularly harmoniously.
[0070] In Fig. 4 a partial view is illustrated of the second version of the geometry according to the invention of a rotor plate 6 of a rotor 1 for a HSM. Here, the rotor plate 6 is provided with recesses 9 as flux barriers, wherein a first group of the recesses 9 is configured, with respect to the diameter, as approximately radial slits, another group of the recesses 9, however, is configured as tangential slits (magnet pockets) with in each case a permanent magnet 30. In this version, mechanically highly stressed transition regions 13 of all recesses 9 are configured elliptically.
[0071] Between the adjacent recesses 9 in each case a cross-piece 32 is provided, the width of which is to be configured as narrow as possible for saturation purposes and is to withstand the centrifugal forces mechanically. As can be seen from Fig. 4, in this version the cross-pieces 32 have a parallel position to the pole axis 10. A centre line of the cross-piece 32 is designated in Fig.4 by reference number 34.
[0072] In Figures 5-8 a third and preferred version is illustrated of the geometry according to the invention of a rotor plate 6 of a rotor 1 for a HSM, wherein Fig. 5 is a complete view of the rotor plate 6, Fig. 6 a partial view VI in Fig. 5 on a proportionally enlarged scale, and Figures 7 and 8 is/are each a partial view in Fig. 6 on a
proportionally likewise enlarged scale.
[0073] The plate geometry for the HSM according to Figures 5-8 differs from the version according to Fig. 4 substantially in that here the centre lines 34 of the cross-pieces 32 between the adjacent recesses 9 in the rotor plate 6 are configured obliquely to the pole axis 10, preferably at an angle 33 of approximately 10-50°, in particular 30°.
[0074] The reason for the inclination of the cross-pieces 32 according to the invention is as follows:
• At high rotation speeds, powerful centrifugal forces impinge and draw the cross- pieces 32 in the direction of the pole axis 10, because in radial direction of the pole axis, owing to the material accumulation by permanent magnets and the additional pole iron between the permanent magnets the greatest centrifugal forces occur in this direction; through the inclination according to the invention it is achieved that with the greatest stresses, the cross-pieces 32 are mostly stressed in longitudinal direction to tension and are stressed as minimally as possible to bending stress, in order to thus prevent signs of material fatigue in the cross- pieces 32 and hence to reduce the risk of fracture;
• The local notch effect at the force deflection sites is reduced by the use of the ellipses 15;
· The stresses in the cross-pieces 32 can be reduced continuously with an
increasing inclination.
• Through the inclination of the cross-pieces 32, in connection with the improved embodiments of the transitions (ellipses), a symbiotic effect is produced, which reduces the notch effect still further.
[0075] Through the present invention therefore, through the oblique cross-pieces 32 and the special, in particular elliptical transitions of the recesses 9, a significant reduction of the mechanical stresses is achieved in the rotor plate 6.
[0076] Through this stress reduction, inter alia the following conclusions result:
• the oblique cross-pieces 32 can be configured distinctly narrower, which is
connected with a saving on material with regard to magnet material and hence with a certain saving on weight, or
• the oblique cross-pieces 32 can be configured distinctly narrower and with an unchanging magnet mass the performance of the machine increases with regard to torque and output, or
· the security of the rotor 1 or respectively of the machine (with regard to the
maximum rotation speed) can be distinctly increased.
[0077] Figure 8 illustrates a further partial view in Fig. 6, wherein the special ham- or kidney-like shape of the two radially outermost recesses 9 of the rotor plate 6 (alongside the smallest magnets) can be seen in a proportionally enlarged scale. All the curve shapes of all radially outwardly lying recesses 9 consist here of either a part of an ellipse 15 lying flat and approximately tangential to the periphery of the rotor (the full ellipse 15 is only illustrated in dot-and-dash lines in Fig. 8), or of at least two radii, running into each other, with different sizes, so that practically an ellipse is approximated. Therefore, e.g. to the right and left, two smaller radii could be used and in the centre - pointing radially outwards - one larger radius could be used.
[0078] In Fig. 8 it can also be seen that here a radius R2 or respectively R3 is connected in each case to the ellipse 15 on both sides, which radii are connected with each other by the lower radius R4. As has been described more extensively above, the cross-pieces 32 also alongside the smallest magnets 30 have a special oblique arrangement in this version, i.e. the centre line 34 of the cross-pieces 32 between the adjacent recesses 9 in the rotor plate 6 stands at an angle 33 obliquely to the pole axis 10, the value of which is approximately 10-50°, in particular 15-30°.
[0079] Through the curve shape according to the invention (ham- or kidney-like shape with elliptical end regions) of the recesses 9 (Fig. 8) - apart from the advantageous stress reduction against fracture - it is achieved that they form a "magnetic lens" (focussing lens on magnetic flux lines M), and they bundle or respectively deflect the magnetic flux lines M also from the radially outermost small magnet approximately in radial direction (Fig. 8). On the other hand, the oblique cross-piece shape reduces the extremely high notch stress, because the force deflection is reduced.
[0080] As a result, the HSM according to the invention with e.g. reduced magnet mass is lighter, more stable with regard to mechanical stress and has a greater torque, owing to the magnetic lens in the outer region. (The structure according to Fig. 4 is less preferred in this respect owing to these differences.)
[0081] It is also to be mentioned that at least the rotor plates 6 according to the present invention - if applicable, however, also the stator plates - are preferably constructed from an iron-cobalt alloy. Thereby, further increase in performance and insensitivity to temperature, and less lost heat of the electric motor can be achieved. With this alloy, preferably approximately 50% cobalt with approximately 50% iron can be alloyed.
[0082] With such a "cobalt plate", surprisingly even about 40% more torque is produced with otherwise identical machine design of a HSM (compared with a HSM with conventional iron plates). An ideal structure is therefore found especially for electric high performance racing engines. This measure is therefore also to be regarded as inventively significant.
[0083] If applicable, these iron-cobalt plates can also be configured permanent- magnetically, which achieves the effect that the magnetic fields produced by the permanent magnet (HSM) or by the electromagnet (CSM) lead to a magnetization of the rotor plate 6. This does not play an essential role in the HSM. In the CSM, on the other hand, this brings it about that also after the switching off (failure) of the exciting current, nevertheless a rotor magnetic field is present, which can be used for torque generation. In the stator, where the magnetic polarity changes, on the other hand, preferably no permanently magnetic plates come into use. [0084] As mentioned, the measure according to the invention, the use and broadening of the ellipse (or other curves of second order) to other laminations, and preferably to all transition regions of the recesses 9 is extremely important in practice. According to the invention the notch stresses in the rotor plate 6 in the HSM were even able to be reduced by 25%, which is likewise a surprising effect of the invention.
[0085] The laminations of electric motors are definitely very varied. In principle at least all transitions of the recesses 9 lying close to the shaft (close to the inner geometry) (transitions stressed with high stresses) can be configured in this manner according to the invention. This geometry could also even be used to reduce bending stresses.
[0086] It is also emphasized, that the systematic reduction of notch stresses preferably by ellipses in the transition regions 13 in the outer region, in addition to mechanical advantages also brings magnetic advantages, and therefore a somewhat increased efficiency, because thereby the magnetic short-circuits can be significantly reduced in the outer region. The above reduction of the magnetic short-circuit face (owing to the ellipses 15) in the outer region of the rotor 1 and hence an increase in the efficiency also belong to the overall aim of the increase in performance with, at the same time, an improved stability of the motor.
[0087] The rotor plate construction according to the invention, with the ellipses 15 at the transition regions 13, in combination with the oblique cross-pieces 32, makes possible significant reduction of the stresses in the sites which are at risk of fracture (i.e. at transitions of the cross-pieces 32 to the solid material of the rotor plate 6). Tests confirmed that through the proposed oblique cross-pieces 32, the cause of stress can be significantly mitigated and through the ellipse 15 the stress effect can be effectively reduced; that through both measures therefore symbiotically an improvement of the rotor is produced in terms of the objective.
[0088] Although the proposed rotor geometry is connected with a slightly increased production expenditure with regard to tools, the use of an ellipse or parabola in the transition regions 13 of the recesses is nevertheless categorically advisable in cases of application where high demands are made with regard to stability.
[0089] It is also to be noted that the proposed oblique cross-pieces 32 are relatively longer. Therefore, with an oblique cross-piece 32 the magnetic path is also somewhat longer and therefore its disrupting, flux-deviating effect is somewhat reduced. The proposed oblique cross-pieces 32 therefore offer a greater resistance to the magnetic field and in such a way also act more quickly in a saturated manner, i.e. "non- magnetically" for a further flux.
[0090] An even more important aspect, from a practical point of view, of the use of the proposed oblique cross-pieces 32 is seen in that the mechanical stresses decrease by 30% with the inclination, and thereby:
• the oblique cross-pieces 32 can be configured distinctly narrower, which is
connected with a saving on material with regard to magnet material and hence with a certain saving on weight, or
• the oblique cross-pieces 32 can be configured distinctly narrower and with
unchanging magnet mass the performance of the machine increases with regard to torque and output, or
• the security of the rotor or respectively of the machine (with regard to the
maximum rotation speed) can be distinctly increased.
[0091] Through the use of the present invention and its subsequent analysis by means of the Finite Element Method with the ANSYS programme, based on the model of a 60° segment, which was also used for testing the cylinder press fit, it is found that the slit can be provided without disadvantage, and serves there to increase the reluctance moment - of the available torque in the absence of exciting current.
[0092] This characteristic is of crucial importance for the CSM for obtaining the emergency operating characteristics in the case of fault, and is to be preferred for an electric car equipped according to the invention. If, in addition, a permanent-magnetic rotor plate were to be selected, this effect is further intensified.
[0093] This flux barrier separates from each other the two magnetic flux lines, which run in opposite directions, and prevents too great a phase shift between the current axis and the field axis. Therefore, the torque which is produced can nevertheless be kept at the nominal torque without current supply of the rotor winding, which plays a very important role in electric cars without regard to functional security.
[0094] Through the invention, the entire rotor stack changes, and therefore the Hybrid Synchronous Motor (HSM) (and if applicable - according to the use of the invention - also the current-excited synchronous motor CSM). The invention therefore offers an improved lamination which handles the high forces in the rotor plate better than in the prior art, because due to the high centrifugal forces with high angular speeds - in particular at revolutions of about 12000 rpm - in operation the laminations are intensively stressed.
[0095] Further embodiments, variants of the present invention - and also combinations thereof - are also conceivable within the framework of the scope of protection according to the enclosed claims, to which however - in the knowledge of the present disclosure of the invention - an artisan in this art after receiving the teaching according to the invention needs no further technical information.
[0096] LIST OF REFERENCE NUMBERS
1 - rotor
2 - rotor pole
3 - pole shank
4 - pole shoe
5 - exciter winding (cross-section)
6 - rotor plate
7 - hub
8 - central opening (joint diameter)
9 - recess/slit, or contour section
9A - first slit part
9B - second slit part
10 - pole axis
1 1 - side face/edges (recess/ slit 9)
12 - inner end (of slit or of first slit part 9A)
13 - transition region
14a, ...,14g - distance from intersection of the main- and secondary axis 15 and 15' - curve of second or higher order, preferably ellipse
16 - main axis (of ellipse)
17 and 1 T- secondary axis (of ellipse 15 or 15')
18 - width (of slit)
19 - bridge
20 - inner end (of second slit part 9B)
21 - outer end (of first slit part 9A)
22 - width (of bridge 19)
23 - length (of first slit part 9A)
24 - length (of second slit part 9B)
25 - outer end (of second slit part 9B)
26 - outermost point (of second slit part 9B)
27 - outer shell (contour section of rotor pole)
28 - radial distance 29 - radius
30 - permanent magnet
31 - distance
32 - cross-piece
33 - angle
34 - centre line (of cross-piece)
M - magnetic flux lines
O - intersection (of main and secondary axis of ellipse) P - radially innermost point of recess/slit
R - rotor radius
R1 - radius (of second slit part 9B)
R2 - radius
R3 - radius
R4 - radius
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