The invention relates to a method according to the main claim and to a corresponding product.
Because of supply risks and high prices for the rare earths, new, rare-earth-free solutions are being sought for the production of permanent magnets. Rare earths are used especially for the production of permanent magnets. Conventional rare-earth-free permanent magnet materials exhibit an energy density which is too low for high-tech applications—using iron, cobalt, nickel, or ferrites, for example—and/or are too expensive from an economic aspect, as is the case for FePt, for example.
The permanent-magnetic properties of magnetic materials are critically determined, in addition to the alloy composition, by the microstructure. In accordance with the theory of micro-magnetics, and also on the basis of experimental findings, it is known that a microstructural construction comprising single-domain, nanoscale structures can be used to obtain high coercive field strengths. This allows the construction of a rare-earth-free, high-performance magnet from nanoscale magnet building blocks. New nanotechnological synthesis methods are enabling the production of monocrystalline, single-domain, magnetic nanoparticles featuring a combination of shape anisotropy and crystalline anisotropy. For the construction of a macroscopic magnet, the magnetic nanoparticles must be embedded in organic or inorganic insulating matrices, in order not only to protect them from environmental effects and resultant corrosion processes but also to produce permanent magnets having appropriate mechanical, electrical, and thermal properties. In particular, a high electrical resistance is advantageous in order to reduce eddy currents. The resultant high-performance magnets can be put to use advantageously in high-efficiency drives and generators.
For production of these magnetically and electrically optimized volume magnets, there are a host of criteria that must be met.
Conventional permanent magnets are produced, for example, by means of a sintering technique (1) or by plastics binding (2).
The conventional method of the sintering technique allows production of anisotropic magnets by alignment of powder particles in the magnetic field ahead of a pressing and sintering process. For the rare-earth-based magnets produced accordingly, the coercive field strength is limited because of the microcrystalline particle size, which is in the range of a few μm, and must be compensated by the addition to the alloy of very expensive and scarce heavy rare earth metals such as Dy or Tb. Owing to the unfavorable temperature coefficient of the coercive field, this fraction must additionally be increased in line with increasing operating temperature. The heating of the magnet as a consequence of eddy current losses, accordingly, requires the use of a substantial fraction of expensive heavy rare earth metals. Alternatively to this so-called sintered magnet, plastics-bound magnets as well are conventionally produced. For this purpose, magnetic particles based on rare earths and with a size of several tens to several hundreds of micrometers are embedded into a thermoset or thermoplastic matrix. The mixture generated in this procedure, which may also be called a compound, is composed of a maximally high fraction of magnetic particles and the matrix. The mixture is subsequently processed to a volume magnet by injection molding, allowing a magnetic fraction of up to 60 vol %, or by compression molding, allowing up to an 80 vol % magnetic fraction. In comparison to the above-described sintered magnets, the magnetic energy density of plastics-bound magnets is reduced as a result of the dilution effect of the matrix used.
For the production of nanocomposite formulations, which may also be termed compounds, by the embedding of nanoparticles into a matrix, the degrees of filling conventionally required are not high. On account of the difficulty in processing, on the contrary, the conventional attempt is to achieve the maximum effect with the minimum amount of nanoparticles. Conventionally, for example, a degree of filling of up to 15 vol% is achieved for carbon nanotubes or SiO2 nanoparticles in an organic matrix. Given that high-performance permanent magnets require high degrees of filling, the use of such conventional standard methods is not conducive for nanoparticle-based magnets.
WO 2013/010173 A1 discloses a nanostructured magnetic alloy composition which is used for producing magnetic nanocomposite material for permanent magnets for electromechanical and electronic devices, and features an iron-nickel alloy.
CN 102610346A discloses a rare-earth-free, nanocomposite permanent-magnetic material that features a permanent-magnetic phase generating alloys with manganese, aluminum, bismuth, and aluminum, and an alpha-iron-generating soft-magnetic phase.
One embodiment provides a method for producing a permanent magnet (PM), comprising the steps of synthesizing rare-earth-free ferromagnetic anisotropic nanoparticles; coating the synthesized nanoparticles with a matrix via physical or physicochemical deposition, and generating a matrix coating of the nanoparticles; introducing the matrix-coated nanoparticles into a mold, and applying an external force field to orient and shape the matrix-coated nanoparticles.
In a further embodiment, the deposition takes place by means of physical vapor deposition, chemical vapor deposition, or thermal spraying, more particularly ion beam-assisted deposition or sputtering, molecular beam epitaxy, electron beam evaporation, atomic layer deposition, or laser ablation.
In a further embodiment, the matrix consists of organic material, more particularly of a plastic.
In a further embodiment, the plastic is a thermoplastic or a thermoset.
In a further embodiment, the plastic is polyphenyl sulfide or polyamide or epoxide.
In a further embodiment, the method includes synthesizing of ferromagnetic anisotropic nanoparticles.
In a further embodiment, the nanoparticles have a core or a core-shell construction, the shell completely or partly covering the core.
In a further embodiment, the nanoparticles have a protective casing.
In a further embodiment, during the coating of the synthesized nanoparticles, they are distributed spatially by means of a distributing device, more particularly a fluidized bed.
In a further embodiment, after they have been coated, the synthesized nanoparticles are in powder form.
In a further embodiment, the orienting and shaping are performed simultaneously.
In a further embodiment, the matrix coating solidifies or cures during or after shaping.
In a further embodiment, the solidifying or curing is activated, more particularly thermally activated.
In a further embodiment, the nanoparticles contain Co, Fe, Ni, or Mn and/or are synthesized wet-chemically.
In a further embodiment, the core consists of a soft-magnetic material and the shell of a hard-magnetic material or the construction is the other way round.
In a further embodiment, the protective casing consists of carbon and has been generated by storage of the nanoparticles for a period of several hours and temperatures in the region of around 250° C. to 350° C. in an organic liquid.
In a further embodiment, the protective casing consists of silicon dioxide and has been generated by hydrolysis and polycondensation of silane compounds in a polar solvent.
Another embodiment provides a permanent magnet formed by any of the methods disclosed above.
Embodiments of the invention are described in more detail below with reference to the figures, in which:
Embodiments of the invention can produce, reliably and simply, highly active permanent magnets having a nanocrystalline structure. The intention in particular is to be able to produce magnetically and electrically optimized volume magnets which meet in particular the following criteria: a high degree of filling, homogeneous particle distribution with parallel alignment along the magnetic axis, positionally fixed binding of the magnetic particles after alignment, and also magnetic and electrical decoupling. A production regime is intended in particular to overcome a high surface-to-volume ratio on the part of nanoparticles.
According to a first aspect, a method is proposed for producing a permanent magnet, comprising the following steps: synthesizing rare-earth-free ferromagnetic anisotropic nanoparticles; coating the synthesized nanoparticles, implemented by means of physical or physicochemical deposition, with a matrix; orienting and shaping the matrix-coated nanoparticles introduced into an external magnetic field and into a mold.
According to a second aspect, a permanent magnet is claimed which has been generated by means of a method according to the main claim.
Ferromagnetic means, in particular, exhibiting a very high permeability number and a positive magnetic susceptibility, and considerably strengthening a magnetic field.
Anisotropic means, in particular, having a directionally dependent property, more particularly a magnetic property.
Nanoparticles have dimensions which are nanoscale and here in particular compel a single-domain behavior, and are mono-crystalline.
The invention involves the construction of a rare-earth-free permanent magnet whose magnetic properties, as for example the magnetization, the coercive force, and the energy product, exceed the properties of conventional rare-earth-free permanent magnets. The improvement of the magnetic properties of the rare-earth-free magnets proposed herewith allows the replacement of conventionally used, rare-earth-based permanent magnets in electric motors and generators. For this purpose, the magnet is constructed from nanoscale, single-domain particles, which may also be referred to as nanoparticles. This magnetically optimized microstructure maximizes the attainable coercive field and also allows great magnetization by means of a suitable selection of material. An advantageously thin matrix layer is deposited on the magnetic nanoparticles. The thickness of the matrix layer is located more particularly in the nanometer range.
Further embodiments are claimed in connection with the dependent claims.
According to one embodiment, the deposition of a matrix may take place by means of laser ablation, atomic layer deposition, chemical vapor deposition, ion beam-assisted deposition, molecular beam epitaxy, or electron beam evaporation, as for example by deposition by means of physical vapor deposition, more particularly laser ablation, ion beam-assisted deposition (also sputtering), molecular beam epitaxy, electron beam evaporation, chemical vapor deposition, more particularly atomic layer deposition, plasma-assisted deposition, at atmospheric pressure or low pressure, or thermal spraying.
According to another embodiment, the matrix may consist of organic material, more particularly of a plastic.
According to another embodiment, the plastic may be a thermoplastic or a thermoset.
According to another embodiment, the plastic may be polyphenyl sulfide, a polyamide, or an epoxide.
According to another embodiment, ferromagnetic anisotropic nanoparticles can easily be industrially synthesized. Anisotropy is relative in particular to the shape or to the crystal structure.
According to another embodiment, the nanoparticles may have a core or a core/shell construction and optionally cumulatively a protective casing. The shell may be soft-magnetic. The extremely thin protective casing, extending in particular in the nanometer range, protects the nanoparticles from corrosion and oxidation. The casing also reduces the agglomeration of the individual particles, thereby on the one hand reducing inter-particle contact which is unfavorable for the coercive field, and on the other hand increasing the anisotropy achievable by the volume magnet. The protective casing may consist, for example, of C and/or SiO2.
According to another embodiment, during the coating of the synthesized nanoparticles, they can be distributed spatially by means of a distributing device, more particularly a fluidized bed.
According to another embodiment, the synthesized nanoparticles, after having been coated, may be in powder form.
According to another embodiment, the orienting and shaping may be performed simultaneously.
According to another embodiment, the matrix coatings may solidify or cure, or form a crosslinked or polymerized matrix coating, during or after shaping.
According to another embodiment, the solidifying or curing may be activated, more particularly thermally activated.
Chemical activation using catalysts is also possible.
According to another embodiment, the nanoparticles may contain Co, Fe, Ni, or Mn. The nanoparticles may be synthesized wet-chemically, from the gas phase, or by means of milling.
According to another embodiment, the core may consist of a soft-magnetic material and the shell of a hard-magnetic material, or may be formed the other way round.
According to another embodiment, the protective layer may consist of carbon and may have been generated by storage of the nanoparticles for a period of several hours and temperatures in the region of about 250° C. to 350° C. in an organic liquid.
According to another embodiment, the protective layer may consist of silicon dioxide and may have been generated by hydrolysis and polycondensation of silane compounds in a polar solvent.
According to other embodiments, the scope of protection of this application embraces all permanent magnets generated by means of a method in accordance with the present invention.
The invention relates to a method for producing a permanent magnet PM, by coating of synthesized nanoparticles 1 with a plastics-bound matrix 3, implemented by means of physical or physicochemical deposition A, and by orienting and shaping of the matrix-coated nanoparticles 5 introduced into an external magnetic field M and into a mold. High degrees of filling can be obtained in this way.
Number | Date | Country | Kind |
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10 2013 213 646.3 | Jul 2013 | DE | national |
This application is a U.S. National Stage Application of International Application No. PCT/EP2014/060778 filed May 26, 2014, which designates the United States of America, and claims priority to DE Application No. 10 2013 213 646.3 filed Jul. 12, 2013, the contents of which are hereby incorporated by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/060778 | 5/26/2014 | WO | 00 |