A set of symmetrically segmented square prism Permanent Magnet (PM) halves in a 45-45-90 triangular prism and a rectangular square prism with predefined 45° stepped magnetizations are designed as Fine Elements (FEs), bringing finely adaptive mosaicking advantages for array arrangement. Optimized Hal
A set of symmetrically segmented square prism Permanent Magnet (PM) halves in a 45-45-90 triangular prism and a rectangular square prism with predefined 45° stepped magnetizations are designed as Fine Elements (FEs), bringing finely adaptive mosaicking advantages for array arrangement. Optimized Halbach effect FE PM pole modules in cuboidal and isosceles trapezoidal prism shapes are invented to provide an augmented one-side-operating field. Simulation data show that typical dual layer FE PM arrays generate high-fidelity sinusoidal waveforms within air-gaps with peak field strengths of up to 1.2 Tesla. Featuring a pole width-to-thickness ratio ranging from 1 to 6, FE PM motor tracks with a series of scale, format, and sectional features are constructed in lightweight ferrous and/or nonferrous structures, which energize OEM and/or FE current carrying winding coils to implement linear and curvilinear motors with high power/force/torque density and low force ripple.
대표청구항▼
1. A fine element (FE) magnet array configuration, comprising an arrangement of a set of predefined permanent magnet (PM) FEs; said predefined PM FEs set comprising two 3D shapes in a 45-45-90 triangular prism and a rectangular square prism that are symmetrically segmented geometries from a square p
1. A fine element (FE) magnet array configuration, comprising an arrangement of a set of predefined permanent magnet (PM) FEs; said predefined PM FEs set comprising two 3D shapes in a 45-45-90 triangular prism and a rectangular square prism that are symmetrically segmented geometries from a square prism reference;said PM FE prisms being magnetized with a series of magnetization orientations each rotating in substantial 45° quantized steps from an edge reference within a front face of said FE prism;said 45° quantized PM FE magnetizations generating eight (8) independent PM FEs, each having a distinctive FE pattern comprising a front face polygon of said FE prism with a magnetization vector inside;said set of eight (8) independent PM FEs comprising finely-arrangeable FE patterns and characterized geometric and magnetic interfaces; wherein Said finely-arrangeable FE patterns allow variable width FE arrays to be finely mosaicked with spatially-seamless patterns while simultaneously allowing magnetizations of each PM FE array finely organized to optimize magnetic field augmentation;Said characterized geometric and magnetic interfaces allow said PM FE array to be easily retained in static equilibrium with reduced retaining stress down to near zero; andsaid arrangement of a set of PM FEs comprising finely arranging said FEs into a series of PM FE arrays. 2. The FE magnet array configuration of claim 1, further comprising arranging a n-FE-composite (FEn; n=2, 3, 4, . . . ) into PM FE array; wherein said FEn is a single piece extended building block comprising n adjacent PM FEs arranged into a predetermined FEn magnetization pattern that can be physically made as assembled or glued or magnetized; andsaid FEn, including a type FEn that has a constant magnetization orientation, wherein said constant magnetization type FEn is equivalently made of either a FEn shaped single piece magnet or an assembled FEn because their resultant magnetizations and field distributions are essentially identical. 3. The FE magnet array configuration of claim 2 further comprises an FE2 called Magnet Assemblies Grouped with Angled Polarities (MAGAP), wherein said MAGAP comprises two adjacent 45-45-90 triangular prism FEs in a square prism shape with 3 optional angled magnetization patterns including: a MAGAP-90 comprising a special angled magnetization pattern with two magnetization vectors aligned along a 90° angled polyline reference that starts from said mid of an edge of said 1st FE, pointing to and bending at said mid of said joint border line of two FEs, then rotated 90° pointing to said mid of said edge of said other FE;a MAGAP-45EC comprising an angled magnetization pattern with two magnetization vectors aligned along a 45° angled polyline reference that starts from said mid of an edge of said first FE, pointing to and bending at said mid of said joint border of two FEs, then rotated 45° pointing to said right angle corner of said other FE;a MAGAP-45CE comprising a special angled magnetization pattern with its two magnetization vectors aligned along a 45° angled polyline that starts from said right angle corner of said first FE, pointing to and bending at said mid of said joint border line of two FEs, then rotated 45° pointing to said mid of an edge of said other FE; andsaid MAGAPs being pre-assembled to said FE magnetization patterns that simplify next level PM FE array configuration and smooth field waveforms of said active field. 4. The FE magnet array configuration of claim 1, further comprising an arrangement of a group of selected PM FEs into said one-sided-operating pole modules; wherein said one-sided-operating pole modules comprise South pole and North pole modules each with a symmetrically configured FE mosaic pattern that arranges FE magnetization orientations that augments the magnetic field on said operating side of said FE PM pole module while diminishing said field on said back of said operating side;said one-sided-operating North and South pole modules comprise arranging 5 segments of FE patterns [El],[Ml],[C], [Mr], [Er] into one of a group consisting of symmetrically sandwiched magnetization patterns structured and symbolized as:{[El], [Ml], [C], [Mr], [Er]}, {[Ml], [C], [Mr]}, {[El], [C], [Er]}, and {[Ml], [Mr]},and said arrangement of said North and South pole module comprises orienting a bundle of magnetization vectors into a predetermined pointing pattern, wherein: for said North pole module, said orientations of said center, mid, and edge magnetization vectors are organized as all pointing convergently toward said referencing active North pole center;for said South pole module, said orientations of said bundle of center, mid, and edge magnetization vectors are organized all pointing divergently apart from said referencing active South pole center;said referencing active North pole center is a reference point located at said midpoint of said active North Pole surface of said center magnet of said North pole module; andsaid active South pole center is a reference point located at said midpoint of said active South Pole surface of said center magnet of said South pole module. 5. The FE magnet array configuration of claim 4, further comprising an arrangement of a FE pole module called Magnet Assembly Grouped with T-shaped Polarity (MAGTP), wherein: said MAGTP is modularized as a cuboidal shaped black box type magnetic pole module;said volume of said MAGTP array normal magnetized segment substantially equals to said volume of said entire array tangential magnetization segments;said plurality of periodically paired alternating MAGTP South/North pole modules makes a MAGTP array;said MAGTP array augments one-sided magnetic field on said active side of said FE PM array while diminishing the field on the other side to near zero;said MAGTP array being easy to assemble as said MAGTP South/North pole modules magnetically attract each other on their sides;said MAGTP array not having to use a soft ferromagnetic back providing a lightweight design, wherein said MAGTP array can be more flexibly retained in high-strength, and lightweight structures using metal alloy, carbon fiber, and polycarbonate materials; andsaid MAGTP array has periodic gaps between adjacent MAGTP modules filled with air or structural materials. 6. The FE magnet array configurations of claim 5, further comprising arrangements of Type-I MAGTPs by assigning: said square prism FE2 as said array-normal magnetized center magnet [C];a pair of said rectangle prism FEs as said array-tangential magnetized edge magnets {[El],[Er]}; anda pair of said adaptive width FE/FEn or nil as said wedge magnetized mid segments {[Ml],[Mr]} to form different modules including:2H width Type-I MAGTP South and North modules having no said mid segment; and4H width Type-I MAGTP South and North having a pair of said square prism shaped FE2 magnet for a pair of mid magnet segments {[Ml],[Mr]}. 7. The FE magnet array configurations of claim 5, further comprising special arrangements of Type-II MAGTP modules by assigning: said square prism FE2 magnet as said array-normal magnetized center magnet [C];said MAGAP-45EC and MAGAP-45CE assemblies as said combination of said array tangential magnetized edge magnets and outer part of said wedge magnetized mid magnets in said arrangement of {[El],[Ml−, −Mr], [Er]}; andsaid adaptively width FE/FEn or nothing as a pair of said inner part of said wedge magnetized mid magnet segments in format of {−Ml],[Mr−} to form different width Type-II modules, including preferred:3H width Type-II MAGTP South and North modules comprising none of said additional inner part of said mid segment;4H width Type-II MAGTP South and North comprising a pair of said special rectangle FE magnets as two inner parts of said wedge magnetized mid segments {−Mll],[Mr−]}; and5H width Type-II MAGTP South and North comprising a pair of square prism shaped FE2 magnets as 2 inner sandwiched wedge magnetized mid segments {−Ml], [Mr−]},hereinbefore {[El], [Ml], [C], [Mr], [Er]}=[El], {[Ml−+−Ml],[C], [Mr−+−Mr], [Er]}. 8. The FE magnet array configurations of claim 5, further comprising special arrangements of Type-III MAGTP modules by assigning: said 45-45-90 triangle prism shaped FE2 magnet with its hypotenuse face orientated toward said active side of said MAGTP as array-normal magnetized center magnet [C];a pair of special 45-45-90 triangle prism FE magnets with their hypotenuse faces orientated parallel to a pair of said leg faces of said 45-45-90 triangle prism shaped center magnet as a pair of said array tangential magnetized edge magnets {[E1], [Er] }; anda pair of various width FE/FEn magnet(s) or nothing as said wedge magnetized mid segments {[Mll],[Mr]} to form various width modules, including preferred:2H width Type-III MAGTP South and North comprising none of said mid segment;4H width Type-III MAGTP South and North comprising a pair of parallelogram front face shaped FE2 mosaiced by two adjacent special 45-45-90 triangle prism FE magnets as a pair of wedge magnetized mid magnet segments {[Ml],[Mr]}; and5H width Type-III MAGTP South and North comprising a pair of parallelogram front face shaped FE3, each consisting of a rectangle shaped FE sandwiched by 2 special 45-45-90 triangle prism FEs, as said wedge magnetized mid magnet segments {[Ml], [Mr]}. 9. The FE magnet array configurations of claim 5, further comprising special arrangements of Type-VI MAGTP modules by assigning: said 2H width 45-45-90 triangle prism shaped FE2 magnet with its hypotenuse faces orientated toward said none-active back side of said MAGTP as said array-normal magnetized center magnet [C];a pair of said special 45-45-90 triangle prism FEs or a pair of said special rectangular FEs as said array tangential magnetized edge segments {[El], [Er]}; andvarious width and shape FE/FEn as an optional pair of said wedge magnetized mid segments {[Ml],[Mr]} to form various width modules, including preferred:4H width Type-IV MAGTP South and North comprising a pair of said special 45-45-90 triangle prism FE2 magnets with its hypotenuse faces orientated toward said active side of said MAGTP as a pair of mid magnetized segments; and a pair of said special 45-45-90 triangle prism FEs with their one of leg faces orientated parallel to said array normal as a pair of edge magnet segments; and 5H width Type-IV MAGTP South and North comprising a pair of trapezoid shaped FE3 mid magnetized segments, each consisting of said special 45-45-90 triangle prism FE magnet and one of said square prism FE2 magnet as said wedge magnetized mid segments; and a pair of said special rectangular FE magnets as a pair of said array tangential magnetized edge segments. 10. The FE magnet array configurations of claim 5, further comprising special arrangements of Type-V MAGTP modules by assigning a sole symmetrical pair of various width FE/FEn magnet(s) in a rectangular outer shape to a pair of wedge magnetized mid segments {[Ml], [Mr]} without using said center and edge segments, including preferred: 1H width Type-V MAGTP South and North each consisting of a pair of said rectangular prism shaped FE magnets that are wedge magnetized as {[Ml], [Mr]}; and2H width Type-V MAGTP South and North each having a pair of said square prism shaped FE2 magnets that are wedge magnetized as {[Ml], [Mr]}. 11. The FE magnet array configuration of claim 4 further comprising: an arrangement of a FE pole module called a Magnet Assembly Grouped with Y-characteristic Polarity (MAGYP); said MAGYP being modularized as either a trapezoid or rectangular prism shaped, black box type FE pole module; said MAGYP comprises a main pole in said front to provide active field and two linkage poles on two side faces along with a back pole to provide said side flux linking and back flux returning respectively;said a plurality of periodically paired alternating MAGYP South/North pole modules make a MAGYP array;said magnetization pattern of said MAGYP array augments said active magnet field in said front operating side;said MAGYP array allows periodic gaps between adjacent MAGYP modules filled with air or PM or structural materials;said MAGYP array being easy to assemble as said MAGYP South/North pole modules magnetically attract each other on their sides; andsaid MAGYP being sectional and having a length extendable for constructing flexibly shaped linear/curvilinear FE PM arrays. 12. The FE magnet array configurations of claim 11, further comprising arrangements of Type-I MAGYP modules into said three segment sandwiched magnetizations {[Ml],[C], [Mr]}, wherein said special array-normal magnetized center magnet [C] is assigned as said square prism FE2 magnet (or its isosceles trapezoid prism shaped equivalent); and a pair of said wedge magnetized magnet segments {[Ml], [Mr]} are a symmetrical pair of various width said FE/FEn magnet(s) in a rectangular prism outer shape with various width, including preferred: 3H width Type-I MAGYP South and North, wherein a pair of said square prism FE2 shaped wedge magnetized magnet are selected for said wedge segments {[Ml], [Mr]}; and4H width Type-I MAGYP South and North, wherein a pair of said rectangular prism outer shaped FE3 and wedge magnetized magnet segments, each consisting of a square prism FE2 and an adjacent FE, are selected for said wedge segments {[Ml], [Mr]}. 13. The FE magnet array configurations of claim 11, further comprising special arrangements of Type-II MAGYP modules by assigning: said FE4 cuboidal format magnet (or its isosceles trapezoidal prism shaped equivalent) as array normal magnetized center segment [C], said MAGAP-45EC and MAGAP-45CE assemblies as a pair of said combination of said outer part of wedge and said array tangential magnetized segments denoted as {[El],[Ml−; −Mr], [Er]}); and said adaptively width FE/FEn or nothing as a pair of said inner part of said mid wedge magnetized segments {−Ml], [Mr−} to form a series of different width modules, including preferred: 4H width Type II MAGYP South and North comprising none of said additional inner part of said mid magnet segments;5H width Type II MAGYP South and North comprising a pair of said special rectangle FE magnets as two inner mid wedge magnetized magnet segments {−Ml], [Mr−]}; and6H width Type II MAGYP South and North comprising a pair of said square prism FE2 magnets as two inner sandwiched mid wedge magnetized magnet segments {−Ml], [Mr−]},Hereinbefore, [Ml−+−Ml]=[Ml]; and [Mr−+−Mr]=[Mr]. 14. The FE magnet array configurations of claim 11, further comprising special arrangements of Type-III MAGYP modules into said three segments of said sandwiched magnetization structure {[Ml],[C], [Mr]} by assigning a symmetrical pair of FE2 shaped wedge magnetized magnets for {[Ml],[Mr]} parts that sandwich a 2H width specially magnetized FE4 (or its isosceles trapezoid prism shaped equivalent) in the center, including preferred modules of: 4H width Type-IIIa MAGYP South and North, utilizing said rectangular prism FE4 (or its isosceles trapezoid prism shaped equivalent) as normal magnetized [C] segment; and4H width Type-IIIb MAGYP South and North, each consisting of a 45-45-90 triangular prism FE2 magnet (with its hypotenuse faces orientated toward said active field side) as said array normal magnetized center magnet [C] sandwiched by a pair of said FE3 magnets as a pair of wedge magnetized segments. 15. The FE magnet array configurations of claim 11, further comprising arrangements of Type-IV MAGYP modules by assigning: said isosceles trapezoid prism shaped FE4 magnet as said array normal magnetized center magnet piece [C] with its short parallel edge arranged as said active side; a pair of said FE magnets as a pair of said array tangential magnetized edge magnet segments {[Ell],[Er]}; a pair of said FEn magnets as a pair of said wedge magnetized mid magnet segments {[Ml], [Mr]} for various width modules, including said preferred modules of: 5H width Type-IV MAGYP South and North, each comprising a symmetrical pair of said 45-45-90 FE2 magnet as said wedge magnetized mid segments; and a symmetrical pair of said special 45-45-90 triangle prism FEs as said tangential magnetized edge segments; and6H width Type-IV MAGYP South and North modules each comprising a symmetrical pair of FE3 magnets each comprising a square prism FE2 magnet and a 45-45-90 FE as said wedge magnetized mid segments; and a symmetrical pair of said rectangular prism FE magnets as said array tangential magnetized edge magnets. 16. A FE PM servomotor assembly, comprising: An FE PM array track assembly comprising a plurality of South/North alternating MAGTP or MAGTP pole modules retained in a linear or curvilinear format to provide an alternating magnetic field in said active front of said FE PM track;an FE PM array matching three-phase current-carrying coil forcer guided by a bearing device to be sliding along said active front of said linear or curvilinear FE magnetic track wherein said curvilinear FE magnetic track is matched by an FG FE arc motor coil embodiment, consisting of three phases of said finely shaped and finely arranged oval-ring winding coils sliding along a predetermined arc track line of said curvilinear FE PM magnetic track device; andan OEM servomotor drive sub-system with an integrated OEM encoder energizing said coil forcer in said closed loop controlled mode to operate said coil forcer and a secured payload along said linear or curvilinear FE PM track. 17. The FE PM servomotor assembly of claim 16 wherein said FE PM track assembly comprises a lightweight material fixture for retaining an FE MAGTP or MAGYP pole module array, said retaining fixture comprises: a pair of upper and lower U-shape structured push-on-trim-channels each made of non-magnetic lightweight high-strength structural materials including carbon fiber, aluminum alloy, polycarbonate, and non-magnetic stainless steel materials;a thin layer of soft ferromagnetic back sheet inserted into said U-shaped structural channels and retained on non-operating side of said FE pole module array; andperiodic inter pole module spacers being made of ferromagnetic or non-ferromagnetic materials;said various number of FE alternating pole modules separated by said inter module spacers being pushed into a pair of said U-shape structured channels, on to said periodic retaining positions with a soft ferromagnetic sheet on said array back for constructing a low cost FE magnetic track assembly. 18. The FE PM servomotor assembly of claim 16, wherein said magnetic track assembly further comprises a DL fixture that retained FE MAGTP or MAGYP array magnetic track, wherein said operating sides of said dual layers of FE arrays facing each other to form an air-gap;each upper and lower part of said dual layers comprises a plurality of said alternating FE MAGTP or MAGYP pole modules arranged as each center of said South poles on said lower layer is aligned substantially underneath each center of said North poles on said upper layer so that said active magnetic fields between said dual layers are constructively superimposed within said air-gap; andsaid magnetic track dual layer assembly further comprises a pair of soft ferromagnetic end pieces that redirect said magnetic field of said linkage ports of MAGTP or MAGYP at two ends of said track assembly for enhancing said FE magnet array performance and mechanically retaining said dual layers with a fixed air-gap. 19. The DL FE MAGYP array magnetic track of claim 18, further comprising a preferred arc shaped FE PM magnetic track assembly that retains periodic isosceles trapezoid prism shaped 4H width Type-II MAGYP South and North modules, wherein said optional inter-module spacers are tangential magnetized PMs with each of their magnetization vectors arranged pointing from its adjacent MAGYP South module to an adjacent MAGYP North module. 20. The FE PM magnetic track assembly of claim 19 wherein said center magnets of said 4H width Type-II MAGYP are isosceles trapezoid prism shaped with a 12° wedge angle, said unit width (1H) of MAGYP is 0.25 inches, said magnet pitch is twenty-four degrees (24°), and said arc shaped array retaining fixture of said MAGYP motor assembly has a predetermined outer radius approximately 6.29 inches (160 mm) or 7.1 inches (180 mm). 21. The FE PM servomotor assembly of claim 16, wherein said FG FE arc motor coil forcer, is an interacting part to an arc shaped FE PM magnetic track assembly, comprising three fine oval-ring shaped winding coils, each comprising two straight, fixed-width-sections that are fanned out from the arc center with a predetermined wedge angle; wherein said wedge angle of two straight sections of said oval ring is of said angle between said two symmetric center lines of two adjacent oral-ring coils.
Bang, Deok Je; Kim, Bong Jun; Ferreira, Jan Abraham; Polinder, Henk, Direct-drive electric machine configured with a plural-module combination structure.
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