CN205069260U - One shot forming's halbach array permanent magnetism radially encircles - Google Patents
One shot forming's halbach array permanent magnetism radially encircles Download PDFInfo
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- CN205069260U CN205069260U CN201520803002.4U CN201520803002U CN205069260U CN 205069260 U CN205069260 U CN 205069260U CN 201520803002 U CN201520803002 U CN 201520803002U CN 205069260 U CN205069260 U CN 205069260U
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- 230000005389 magnetism Effects 0.000 title claims abstract description 26
- 230000015572 biosynthetic process Effects 0.000 claims description 5
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- 238000005245 sintering Methods 0.000 abstract description 16
- 238000000034 method Methods 0.000 abstract description 13
- 230000008569 process Effects 0.000 abstract description 13
- 238000004519 manufacturing process Methods 0.000 abstract description 2
- 239000000758 substrate Substances 0.000 description 38
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- 229910045601 alloy Inorganic materials 0.000 description 28
- 239000000843 powder Substances 0.000 description 21
- 238000002360 preparation method Methods 0.000 description 18
- 239000002245 particle Substances 0.000 description 15
- 239000000203 mixture Substances 0.000 description 11
- 238000012360 testing method Methods 0.000 description 11
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- 238000007747 plating Methods 0.000 description 10
- 229910052733 gallium Inorganic materials 0.000 description 8
- 230000005415 magnetization Effects 0.000 description 8
- 239000006247 magnetic powder Substances 0.000 description 5
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- 230000005405 multipole Effects 0.000 description 2
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- 229910000521 B alloy Inorganic materials 0.000 description 1
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- 230000008901 benefit Effects 0.000 description 1
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Abstract
The utility model discloses an one shot forming's halbach array permanent magnetism radially encircles, including whole fashioned ring magnets, ring magnets observes along the axial, and the magnetic field direction of at least ring magnets subregion in radial cross section is according to halbach array orientation. The utility model discloses a radial ring forms through the one shot forming sintering, need not loaded down with trivial details assembly process, and production is convenient, stable in structure, and the magnetic field stability is good, and the range of application is wide, the facilitate promotion.
Description
Technical field
The utility model relates to the magnetization of a kind of halbach array, particularly a kind of one-time formed halbach array permanent magnetism radial loop.
Background technology
In 1973, American scholar Mallianson found a kind of peculiar permanent magnet structure when carrying out assembled experiment to permanent magnet structure, and it is called 〝 MagneticCuriosity 〞.He did not perceive the using value of this structure at that time.1979, American scholar KlausHalbach recycled magnetic field that various permanent magnet structure produces when doing Accelerating electron experiment, has found this special permanent magnet structure, and this structure of gradual perfection, has finally defined so-called " Halbach " magnet.Halbach magnet ring magnet radial and run-in index is arranged to combine, if ignore end effect, and the permeability of the permeability magnetic material of surrounding is regarded as infinity, so above-mentioned magnet structure finally forms monolateral magnetic field (one-sidedfield), Halbach feature shown that Here it is.
Halbach magnet structure is the approximate of engineering coideal structure, and target produces the strongest magnetic field with minimum magnet.Utilize the arrangement of special magnet unit, strengthen the magnetic field on unit direction.For engineering there being very important meaning.But current halbach structure permanent magnetic radial ring all adopts the magnet of the single different direction of magnetization to carry out assembling and obtaining.The halbach structure permanent magnetic radial ring of assembling has following shortcoming: 1, the single magnet processing cost of the different direction of magnetization is high, and the process-cycle is long.2, the single magnet of the different direction of magnetization is when assembling, and due to the repulsive force between same polarity, the assembling of halbach ring bothers and easily causes dimensional accuracy not high.3, the magnet ring of assembling adopts glue bonding, and mechanical property is unreliable.
Utility model content
For solving the problem, the utility model discloses a kind of one-time formed halbach array permanent magnetism radial loop, being formed by one-shot forming sintering, without the need to loaded down with trivial details assembling process, convenient for production, Stability Analysis of Structures, magnetic field stability is good, applied range, is convenient to promote.
One-time formed halbach array permanent magnetism radial loop disclosed in the utility model, comprise the toroidal magnet of global formation, toroidal magnet is observed vertically, and at least toroidal magnet is orientated according to halbach array at the magnetic direction in territory, radial section internal zone dividing.Namely magnet ring can be orientated according to halbach array the subregion in radial section; Also can be orientated according to halbach array in entire scope.
The one of one-time formed halbach array permanent magnetism radial loop disclosed in the utility model is improved, and the enhancing magnetic field that the halbach array orientation of toroidal magnet is formed is at the inner surface of toroidal magnet or outer surface.
The one of one-time formed halbach array permanent magnetism radial loop disclosed in the utility model is improved, the alloy composition of toroidal magnet is (mass percent) Nd (27.9-34) %M (65-71) %B surplus, and wherein M is for be jointly made up of Fe, Al, Ga, Cu, Co.
The one of one-time formed halbach array permanent magnetism radial loop disclosed in the utility model is improved, and in the composition of alloy, the composition of M meets Fe
(1-x-y-m-n)al
xga
ycu
mco
n, wherein 0<x≤0.011,0<y≤0.0046,0<m≤0.011,0<n≤0.046, and x, y, m, n sum is less than 1.
The one of one-time formed halbach array permanent magnetism radial loop disclosed in the utility model is improved, and alloy obtains anisotropic magnetic through melting, fragmentation, grinding.
The one of one-time formed halbach array permanent magnetism radial loop disclosed in the utility model is improved, and the average grain diameter of magnetic is 2-10 micron.
Halbach array ring of the present utility model is the permanent-magnetic clamp adopting one-shot forming sintering.Be different from the magnet ring that common halbach array ring obtains by adopting the magnet of the single different direction of magnetization to carry out assembling, magnet ring of the present utility model is in the sintered magnet oriented moulding stage, the direction of magnetization of the basic magnetic powder particle (micron order) of composition magnet arranged according to the arrangement mode of halbach array, the pressed compact then arranged by basic granules obtains after carrying out sintering.Because the elementary cell of the arrangement of the halbach array of magnet ring of the present utility model is by common single magnet (Centimeter Level, magnet after shaping is assembled, there is obvious physical boundary and magnetic field boundary) replace with the basic magnetic powder particle (micron order forming magnet, halbach array is directly formed by micromorphologic magnetic magnetization, become the structure of magnet ring itself, magnetic field good integrity), magnetic field between the elementary cell of the different direction of magnetization turns to more continuously smooth, more can give full play to the magnetic polarization of each basic magnetic powder particle; And the metallic bond by producing after sintering between each basic magnetic powder particle is combined together to form an entirety, has the mechanical properties such as higher intensity.Halbach array ring of the present utility model is that one-shot forming sintering forms, without the need to loaded down with trivial details assembling process, after carrying out overall dimensions processing according to dimensional requirement, and use of can magnetizing.
Melted Nd Fe B alloys is carried out hydrogen break and after airflow milling, obtain the anisotropic magnet powder of particle mean size 2-5 micron.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the magnetic field of 1-2T in mould, and the magnetic line of force in magnetic field distributes at die space according to halbach array.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up.The magnetic suppressed is carried out vacuum-sintering annealing in process, halbach array magnet ring base substrate can be obtained.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Use identical anisotropic magnet powder, according to different product size, halbach array magnet ring of the present utility model is owing to there being halbach array effect, and every pole table magnetic exceeds 20%-80% than common multi-pole magnet-ring.Use the motor of halbach array ring of the present utility model through test, motor overall efficiency exceeds 5%-10% than common subsides magnetic shoe motor, exceeds 20%-50% than common multi-pole magnet-ring, has extremely significantly advantage and economic worth.
Accompanying drawing explanation
The basic magnetic powder particle halbach array arrangement figure of a kind of embodiment of one-time formed halbach array permanent magnetism radial loop disclosed in Fig. 1, the utility model;
The field waveform figure of a kind of embodiment of one-time formed halbach array permanent magnetism radial loop disclosed in Fig. 2, the utility model.Reference numerals list:
1, toroidal magnet.
Embodiment
Below in conjunction with the drawings and specific embodiments, illustrate the utility model further, following embodiment should be understood and be only not used in restriction scope of the present utility model for illustration of the utility model.It should be noted that, the word "front", "rear" of use is described below, "left", "right", "up" and "down" refer to direction in accompanying drawing, word " interior " and " outward " refer to the direction towards or away from particular elements geometric center respectively.
Constructive embodiment 1
As shown in Figure 1, the halbach array permanent magnetism radial loop of the present embodiment, comprise the toroidal magnet 1 of global formation, toroidal magnet is observed vertically, and the magnetic direction of toroidal magnet entirety in radial section is orientated according to halbach array.
Constructive embodiment 2
The halbach array permanent magnetism radial loop of the present embodiment, comprise the toroidal magnet of global formation, toroidal magnet is observed vertically, the magnetic direction of toroidal magnet magnetized area in radial section is orientated according to halbach array and forms magnetized area, wherein magnetized area and unmagnetized region concentrically annular (comprise the two-layer sandwich construction above that magnetized area and unmagnetized region are formed; When for time two-layer, the outside of the ring that the ring that magnetized area is formed is formed in unmagnetized region, or the inner side of ring that the ring that formed of magnetized area is formed in unmagnetized region; When for more than two-layer time, the ring that magnetized area is formed or the ring that unmagnetized region is formed all can be greater than one deck, and the ring that magnetized area is formed or the ring that unmagnetized region is formed can be adjacent or alternate; Also can be magnetized area and the unmagnetized region structure in the combination of axis; Also can for have concurrently axially with radial structure).
Constructive embodiment 3
The halbach array permanent magnetism radial loop of the present embodiment, comprise the toroidal magnet of global formation, toroidal magnet is observed vertically, the magnetic direction of toroidal magnet in territory, radial section internal zone dividing is orientated according to halbach array and forms magnetized area, wherein this subregion can for the subregion (being free of attachment to the outer surface of toroidal magnet and be connected with inner surface) inside toroidal magnet or the subregion outside toroidal magnet (being free of attachment to the inner surface of toroidal magnet and be connected with outer surface) or in the subregion (being connected to outer surface and the inner surface of toroidal magnet) of toroidal magnet radial direction.It should be noted that the selection of Ben Chu subregion can also can for irregular form for the form of rule simultaneously.
Alloy embodiment 1
The alloy that in the present embodiment, the preparation of halbach array permanent magnetism radial loop adopts is (mass percent) Nd32%M67%B1%, and wherein M is for be jointly made up of Fe, Al, Ga, Cu, Co, and the composition of M meets Fe
surplusal
0.011ga
0.0046cu
0.011co
0.046, in M formula, numerical value all represents the mass fraction in M.
Alloy embodiment 2
The alloy that in the present embodiment, the preparation of halbach array permanent magnetism radial loop adopts is (mass percent) Nd30%M69%B1%, and wherein M is for be jointly made up of Fe, Al, Ga, Cu, Co, and the composition of M meets Fe
surplusal
0.011ga
0.0046cu
0.011co
0.046, in M formula, numerical value all represents the mass fraction in M.
Alloy embodiment 3
The alloy that in the present embodiment, the preparation of halbach array permanent magnetism radial loop adopts is (mass percent) Nd33.5%M65.5%B1%, and wherein M is for be jointly made up of Fe, Al, Ga, Cu, Co, and the composition of M meets Fe
surplusal
0.011ga
0.0046cu
0.011co
0.046, in M formula, numerical value all represents the mass fraction in M.
Alloy embodiment 4
The alloy that in the present embodiment, the preparation of halbach array permanent magnetism radial loop adopts is (mass percent) Nd34%M65%B1%, and wherein M is for be jointly made up of Fe, Al, Ga, Cu, Co, and the composition of M meets Fe
surplusal
0.011ga
0.0046cu
0.011co
0.046, in M formula, numerical value all represents the mass fraction in M.
Alloy embodiment 5
The alloy that in the present embodiment, the preparation of halbach array permanent magnetism radial loop adopts is (mass percent) Nd31%M68%B1%, and wherein M is for be jointly made up of Fe, Al, Ga, Cu, Co, and the composition of M meets Fe
surplusal
0.011ga
0.0046cu
0.011co
0.046, in M formula, numerical value all represents the mass fraction in M.
Alloy embodiment 6
The alloy that in the present embodiment, the preparation of halbach array permanent magnetism radial loop adopts is (mass percent) Nd29.1%M70%B0.9%, and wherein M is for be jointly made up of Fe, Al, Ga, Cu, Co, and the composition of M meets Fe
surplusal
0.011ga
0.0046cu
0.011co
0.046, in M formula, numerical value all represents the mass fraction in M.
Alloy embodiment 7
The alloy that in the present embodiment, the preparation of halbach array permanent magnetism radial loop adopts is (mass percent) Nd27.9%M71%B1.1%, and wherein M is for be jointly made up of Fe, Al, Ga, Cu, Co, and the composition of M meets Fe
surplusal
0.011ga
0.0046cu
0.011co
0.046, in M formula, numerical value all represents the mass fraction in M.
Distinguish with above-described embodiment, in above-described embodiment, the value of x, y, m, n can also be the arbitrary of following state: 0.005,0.001,0.007,0.01; 0.007,0.002,0.001,0.011; 0.0015,0.0015,0.002,0.022; 0.0032,0.0027,0.01,0.037; 0.0026,0.0013,0.006,0.001; 0.0013,0.0029,0.005,0.015; 0.0062,0.0007,0.0028,0.021; 0.0048,0.0022,0.0023,0.043, above data of often organizing correspond to x, y, m, n in turn.
Preparation embodiment 1
In the present embodiment, alloy is broken through hydrogen and after airflow milling, obtains the anisotropic magnet powder of particle mean size 2 microns.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the alignment magnetic field of 1-2T (as 1T) in mould, and the magnetic line of force of alignment magnetic field distributes at die space according to halbach array in needs region.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up, obtain the radial magnetic ring base substrate with halbach as shown in Figure 1.The base substrate suppressed is carried out vacuum-sintering annealing in process, just can obtain halbach array magnet ring base substrate.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Preparation embodiment 2
In the present embodiment, alloy is broken through hydrogen and after airflow milling, obtains the anisotropic magnet powder of particle mean size 3 microns.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the alignment magnetic field of 1-2T (as 2T) in mould, and the magnetic line of force of alignment magnetic field distributes at die space according to halbach array in needs region.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up, obtain the radial magnetic ring base substrate with halbach as shown in Figure 1.The base substrate suppressed is carried out vacuum-sintering annealing in process, just can obtain halbach array magnet ring base substrate.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Preparation embodiment 3
In the present embodiment, alloy is broken through hydrogen and after airflow milling, obtains the anisotropic magnet powder of particle mean size 4 microns.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the alignment magnetic field of 1-2T (as 1.5T) in mould, and the magnetic line of force of alignment magnetic field distributes at die space according to halbach array in needs region.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up, obtain the radial magnetic ring base substrate with halbach as shown in Figure 1.The base substrate suppressed is carried out vacuum-sintering annealing in process, just can obtain halbach array magnet ring base substrate.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Preparation embodiment 4
In the present embodiment, alloy is broken through hydrogen and after airflow milling, obtains the anisotropic magnet powder of particle mean size 5 microns.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the alignment magnetic field of 1-2T (as 1.7T) in mould, and the magnetic line of force of alignment magnetic field distributes at die space according to halbach array in needs region.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up, obtain the radial magnetic ring base substrate with halbach as shown in Figure 1.The base substrate suppressed is carried out vacuum-sintering annealing in process, just can obtain halbach array magnet ring base substrate.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Preparation embodiment 5
In the present embodiment, alloy is broken through hydrogen and after airflow milling, obtains the anisotropic magnet powder of particle mean size 2.5 microns.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the alignment magnetic field of 1-2T (as 1.3T) in mould, and the magnetic line of force of alignment magnetic field distributes at die space according to halbach array in needs region.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up, obtain the radial magnetic ring base substrate with halbach as shown in Figure 1.The base substrate suppressed is carried out vacuum-sintering annealing in process, just can obtain halbach array magnet ring base substrate.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Preparation embodiment 6
In the present embodiment, alloy is broken through hydrogen and after airflow milling, obtains the anisotropic magnet powder of particle mean size 10 microns.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the alignment magnetic field of 1-2T (as 1.3T) in mould, and the magnetic line of force of alignment magnetic field distributes at die space according to halbach array in needs region.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up, obtain the radial magnetic ring base substrate with halbach as shown in Figure 1.The base substrate suppressed is carried out vacuum-sintering annealing in process, just can obtain halbach array magnet ring base substrate.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Preparation embodiment 7
In the present embodiment, alloy is broken through hydrogen and after airflow milling, obtains the anisotropic magnet powder of particle mean size 8 microns.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the alignment magnetic field of 1-2T (as 1.3T) in mould, and the magnetic line of force of alignment magnetic field distributes at die space according to halbach array in needs region.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up, obtain the radial magnetic ring base substrate with halbach as shown in Figure 1.The base substrate suppressed is carried out vacuum-sintering annealing in process, just can obtain halbach array magnet ring base substrate.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Preparation embodiment 8
In the present embodiment, alloy is broken through hydrogen and after airflow milling, obtains the anisotropic magnet powder of particle mean size 7.6 microns.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the alignment magnetic field of 1-2T (as 1.3T) in mould, and the magnetic line of force of alignment magnetic field distributes at die space according to halbach array in needs region.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up, obtain the radial magnetic ring base substrate with halbach as shown in Figure 1.The base substrate suppressed is carried out vacuum-sintering annealing in process, just can obtain halbach array magnet ring base substrate.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Preparation embodiment 9
In the present embodiment, alloy is broken through hydrogen and after airflow milling, obtains the anisotropic magnet powder of particle mean size 6 microns.Anisotropic magnet powder is loaded mould and carry out orientation compacting.Produce the alignment magnetic field of 1-2T (as 1.3T) in mould, and the magnetic line of force of alignment magnetic field distributes at die space according to halbach array in needs region.Anisotropy magnetic is arranged along the magnetic line of force in magnetic field, then by magnetic compacting, the halbach of magnetic is arranged and is fixed up, obtain the radial magnetic ring base substrate with halbach as shown in Figure 1.The base substrate suppressed is carried out vacuum-sintering annealing in process, just can obtain halbach array magnet ring base substrate.After machining plating is carried out to base substrate, operational halbach array magnet ring can be obtained.Magnet ring is magnetized, the Surface field waveform of test magnet ring, magnetic field have good sinuso sine protractor and each pole table magnetic variation is different is less than 3%.
Choose the alloy adopting alloy embodiment 1 to state, there is according to the preparation of preparation embodiment 1 the halbach array permanent magnetism radial loop of constructive embodiment 1 statement, the Distribution of Magnetic Field of the radial loop obtained as shown in Figure 1, its field waveform as shown in Figure 2 simultaneously, and the magnetic field of visible radial loop has field strength distribution and the magnet structure of stable and uniform.
In view of the utility model Solution Embodiments is numerous, each embodiment experimental data is huge numerous, be not suitable for particularize explanation herein, but the content of the required checking of each embodiment is all close with the final conclusion obtained, so do not illustrate one by one the checking content of each embodiment, only with above-described embodiment, the excellent part of the utility model application is representatively described herein.
This place embodiment to the claimed technical scope midrange non-limit part of the utility model and in embodiment technical scheme to the new technical scheme that the equal replacement of single or multiple technical characteristic is formed, equally all in the scope that the utility model is claimed; Simultaneously in all embodiments enumerated or do not enumerate of the utility model scheme, parameters in the same embodiment only represents an example (i.e. a kind of feasible scheme) of its technical scheme, and between parameters, there is not strict cooperation and qualified relation, wherein each parameter can be replaced, except special declaration mutually when stating ask without prejudice to axiom and the utility model.
Technological means disclosed in the utility model scheme is not limited only to the technological means disclosed in above-mentioned technological means, also comprises the technical scheme be made up of above technical characteristic combination in any.The above is embodiment of the present utility model; it should be pointed out that for those skilled in the art, under the prerequisite not departing from the utility model principle; can also make some improvements and modifications, these improvements and modifications are also considered as protection range of the present utility model.
Claims (2)
1. an one-time formed halbach array permanent magnetism radial loop, comprises the toroidal magnet of global formation, it is characterized in that: described toroidal magnet is observed vertically, and at least toroidal magnet is orientated according to halbach array at the magnetic direction in territory, radial section internal zone dividing.
2. one-time formed halbach array permanent magnetism radial loop according to claim 1, is characterized in that: the enhancing magnetic field that the halbach array orientation of described toroidal magnet is formed is at the inner surface of toroidal magnet or outer surface.
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| Application Number | Priority Date | Filing Date | Title |
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| CN201520803002.4U CN205069260U (en) | 2015-10-16 | 2015-10-16 | One shot forming's halbach array permanent magnetism radially encircles |
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|---|---|---|---|
| CN201520803002.4U CN205069260U (en) | 2015-10-16 | 2015-10-16 | One shot forming's halbach array permanent magnetism radially encircles |
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105304263A (en) * | 2015-10-16 | 2016-02-03 | 宁波鑫丰磁业有限公司 | One-step molding halbach array permanent magnet radial ring |
| CN107256791A (en) * | 2017-05-13 | 2017-10-17 | 安徽大地熊新材料股份有限公司 | A kind of preparation method of special-shaped magnetic circuit magnet |
| CN116111790A (en) * | 2023-02-06 | 2023-05-12 | 浙江中科磁业股份有限公司 | Manufacturing device and method for magnetic shoe for high-torque driving motor |
-
2015
- 2015-10-16 CN CN201520803002.4U patent/CN205069260U/en not_active Expired - Fee Related
Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105304263A (en) * | 2015-10-16 | 2016-02-03 | 宁波鑫丰磁业有限公司 | One-step molding halbach array permanent magnet radial ring |
| CN107256791A (en) * | 2017-05-13 | 2017-10-17 | 安徽大地熊新材料股份有限公司 | A kind of preparation method of special-shaped magnetic circuit magnet |
| CN107256791B (en) * | 2017-05-13 | 2019-02-15 | 安徽大地熊新材料股份有限公司 | A kind of preparation method of abnormity magnetic circuit magnet |
| CN116111790A (en) * | 2023-02-06 | 2023-05-12 | 浙江中科磁业股份有限公司 | Manufacturing device and method for magnetic shoe for high-torque driving motor |
| CN116111790B (en) * | 2023-02-06 | 2023-10-03 | 浙江中科磁业股份有限公司 | Manufacturing device and method for magnetic shoe for high-torque driving motor |
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