The present disclosure relates to aligned magnetic cores and fixtures and methods for making the same.
Electric machines convert energy through electromagnetic interactions, such as electricity to electricity (transformer), electricity to mechanical power (motor), or mechanical power to electricity (generator). A factor that influences the energy conversion is the magnetic core materials, which are generally formed from laminations of electric steels (also called silicon steel). In addition to electric machines, magnetic cores in inductors also play a role in their performance. However, core loss (also called iron loss) in the magnetic core occurs due to the AC magnetic field inside the materials, especially during high frequency operation. Core loss generally includes three components: hysteresis loss, eddy current loss and excess loss (or anomalous loss). Hysteresis loss is frequency independent, while both eddy-current and excess losses are frequency dependent.
As fuel economy is an important factor in electric vehicles (EVs), such as hybrid electric vehicles (HEVs), plug-in hybrid EVs (PHEVs), and battery EVs (BEVs), reducing core loss and increasing induction (flux density) in the magnetic cores (such as rotor and stator cores) of electric machines and power electronics (such as inductor cores) may be a goal. Conventional core forming processes generally reduce losses by sacrificing other magnetic properties or enhance magnetic properties such as flux density but sacrifice loss performance.
One common way to reduce core loss in a magnetic core is to reduce the lamination thickness of the electric steel through mechanical rolling, including hot and cold rolling. Magnetic cores with thinner laminations have significantly lower eddy-current loss, and therefore lower core loss, than thicker laminations. Another way to reduce core loss is to control the chemical composition in electric steels, e.g., Si and Al content. Since Si and Al increase resistivity in electric steels, they are generally controlled during manufacturing in order to reduce the eddy-current loss. Usually 2-3% Si is used in non-oriented electric steel and about 6% in grain-oriented electric steel. Although core loss is significantly reduced by these two approaches, it may still be problematic, especially for high frequency applications. Another approach to reduce core loss is to produce magnetic powders that are sintered into a bulk core directly, with or without an insulating coating on the magnetic particles. A similar approach is to mix magnetic powders with a binder and then press them into near-shape devices. However, the use of a binder may reduce the flux density and permeability of the core.
In at least one embodiment, a magnetic core is provided comprising a magnetic body including magnetic grains and a magnetic flux path, the magnetic grains aligned in a plurality of distinct directional alignments to conform to the magnetic flux path. Each alignment may be a major alignment with respect to the magnetic body. In one embodiment, the magnetic body has an inner cavity. The plurality of directional alignments may extend around a perimeter of the inner cavity.
In one embodiment, the magnetic core is an inductor core. In another embodiment, the magnetic core is a stator core including a plurality of stator teeth and a plurality of stator slots between the stator teeth. The plurality of directional alignments may include a plurality of arc-shaped alignments from one stator tooth to another stator tooth around a stator slot. In another embodiment, the magnetic core is a rotor core including a plurality of permanent magnets disposed therein. The plurality of directional alignments may include a plurality of alignments extending between the permanent magnets and an outer perimeter of the rotor core.
In at least one embodiment, a fixture for aligning grains in a magnetic core is provided. The fixture may include one or more inner magnets configured to be located in an interior of the core, the inner magnets configured to generate a magnetic field in the magnetic core and align the grains in a plurality of directional alignments.
The inner magnets may be configured to generate a magnetic field in the magnetic core that mimics a magnetic flux path of the magnetic core. Each inner magnet may have a north (N) side and a south (S) side. The fixture may include a plurality of inner magnets and a plurality of outer magnets configured to be located exterior to the core and each inner magnet may form a magnet pair with an outer magnet. Each magnet pair may either have the N sides facing each other or the S sides facing each other and adjacent magnet pairs may have opposite N and S side configurations.
In one embodiment, the magnetic core is a stator core having a plurality of stator teeth and a plurality of stator slots between the stator teeth. The inner magnets may be configured to generate a magnetic field in the stator core and align the grains in a plurality of arc-shaped alignments from one stator tooth to another stator tooth around a stator slot. The inner magnets may be configured to be located at tips of the stator teeth or in the stator slots. In another embodiment, the magnetic core is a rotor core and the inner magnets are rotor permanent magnets that remain in the rotor core after consolidation.
In at least one embodiment, a fixture for aligning grains in a magnetic core is provided. The fixture may include one or more inner wires configured to be located in an interior of the core and to carry electric current in a first direction and one or more outer wires configured to be located exterior to the core and to carry electric current in a second direction, opposite the first. The inner and outer wires may be configured to generate a magnetic field in the magnetic core.
In one embodiment, the inner and outer wires are configured to generate a magnetic field in the magnetic core and align the grains in a plurality of directional alignments that mimic a magnetic flux path of the magnetic core. The fixture may include a plurality of inner wires and a plurality of outer wires and each inner wire may form a wire pair with an outer wire.
As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.
As described in the background, conventional magnetic core processing generally requires a choice between good magnetic properties and good loss performance (i.e., low loss). The present disclosure provides methods and fixtures for forming magnet cores having both good magnetic properties and low loss, or less sacrifice of one property compared to another, relative to conventional magnetic cores. In at least one embodiment, magnetic cores are formed having a grain orientation along a specified predetermined or preferred direction or path. The grain orientation may be provided by applying a specified magnetic field to the magnetic core during processing. The magnetic field may be complex and/or multidirectional (e.g., not in a single, straight line). The magnetic field direction/path (and corresponding grain alignment) may conform, approximate, or correspond to the magnetic flux direction that will occur in the core during use. The degree of grain orientation in the magnetic cores produced by this method may be high, but may be moderate or low as well, depending on factors such as the magnetic powders, magnetic field strength, pressing condition, binders and others. The degree of grain orientation may be adjusted based on the required or desired properties of the magnetic cores.
The magnet cores may be formed using any suitable process, including sintering and bonding of magnetic powder. The magnetic powder may include any magnetic material that is able to be sintered or bonded to make a powder core, such as ferrite particles. The magnetic field may be applied during the forming of the cores using any suitable method, including fixtures having electrical circuits with one or more current-carrying wires and/or arranged permanent magnets. The properties of magnetic cores formed of any suitable magnetic material may be improved, including electric steels (e.g., by heat-treatment under magnetic fields). The disclosed magnetic cores may be suitable for numerous applications where improved directional permeability and flux density are beneficial. For example, the disclosed magnetic cores may be used in inductors, transformers, generators, stators, rotors, or any other devices which prefer better properties in certain directions.
With reference to
At step 14, the powder may be mixed with or coated with an insulating material. The high resistance of the insulating material reduces eddy current losses in the magnet core. In one embodiment, the magnetic powder may be mixed with an insulating material, which may be any suitable dielectric or high-resistance material. Non-limiting examples of insulating materials may include silica, ferrite, phosphate binders, Teflon (PTFE) binders, and others. Alternatively, the magnetic powder may be coated with an insulating material such that each particle has a core/shell configuration with the magnetic material as the core and the insulating material as the shell. The magnetic powder may be coated using any suitable method, such as chemical solution, vapor deposition, sputter coating, or others. The magnetic powder may also be oxidized through a controlled oxidation process in order to form an insulating layer on the particles. The above insulating methods may be used individually, or any combination thereof may be used to increase the resistance of the magnet core.
At step 16, the magnetic powder may be consolidated and aligned. Conventional pressing may lead to non-uniform density in the green compact, which in turn may lead to significant shape changes after sintering. In one embodiment, a tapping or agitation process may be applied during consolidation to provide more uniform compacts and reduce or eliminate shape changes after sintering. The tapping process may include air-tapping, mechanical tapping, ultrasonic tapping, or other methods of tapping or agitating the powder. In addition, any combination of the tapping processes may be performed, either sequentially or simultaneously. Air tapping may include applying air pressure to the powder and/or mold by controlling pressure, air flow load, speed and time. Mechanical tapping may include tapping the powder and/or mold using physical contact using either manual or automatic methods. Ultrasonic tapping may include tapping/vibrating the powder and/or mold using ultrasonic waves by controlling ultrasonic power, frequency and time.
The alignment process includes applying a magnetic field to the powder while it is in the mold (e.g., unconsolidated), such that the grains of the powder are aligned along the magnetic field (e.g., along their easy axes). The magnetic field may be applied in the shape or the path of the flux direction in the magnet core, thereby increasing the permeability and flux density in the flux direction of the finished core. Additional description of the fixtures and methods of producing the magnetic field is included later in the disclosure. The magnetic field may be applied while a tapping process is being performed. The tapping/agitation produced during the tapping process may allow the magnetic powder to rotate and orient themselves easier such that their easy axes are aligned with the magnetic field. In addition, if the particles have a single or only several grains per particle, as described above, the alignment in the magnetic field is further facilitated. To further facilitate and promote the rotation of the magnetic particles during the alignment process, a lubricant may be added to the powder during this step. Non-limiting examples of suitable lubricants may include surfactants, calcium stearate, polyethylene glycols, sorbitol, glycerol monostearate, or others, as well as mixtures thereof.
At step 18, an optional pressing process may be performed. Any suitable pressing method may be performed to increase the density of the magnet core, such as uniaxial pressing. A magnetic field may be applied during the pressing step 18 in order to maintain or further align the particles in the mold. The magnetic field may be the same one applied in step 16. As a result of the tapping process in step 16, the resulting green compact from the pressing may be substantially uniform in density.
At step 20, the magnetic powder may be sintered to consolidate the powder and form a finished magnet core. The sintering temperature may be any suitable temperature to consolidate the powder, for example, from 600° C. to 1,500° C. The sintering time may be any suitable time to consolidate the powder, for example, from 10 minutes to tens of hours. In general, higher temperatures will require shorter sintering times, and vice versa. A magnetic field may be applied during the sintering step 20 in order to maintain or further align the particles in the mold. The magnetic field may be the same one applied in steps 16 and/or 18. As a result of the tapping process in step 16, the resulting green compact from the pressing may be substantially uniform in density. After sintering, a finished magnet core is formed having aligned grains with increased permeability and flux density along the path of the aligned grains, which were formed using a predetermined, customized magnetic field applied during the consolidating step 16 and optionally the pressing step 18 and/or sintering step 20.
Furthermore, in some embodiments, magnetic powders (or solid samples) may be heated while an external magnetic field is applied prior to sintering. In one or more embodiments, where a magnetic field is applied during the heating step, the magnetic field may be an external magnetic field. The powder may be tapped while the external magnetic field is applied, as in the tapping process of step 16, to further align the magnet powder. In at least one embodiment, an electric current is applied to the magnetic powder after it is aligned and dense to generate heat (i.e., Joule heating). In at least one embodiment, the electric current is about 5 to 150 A, in other embodiments, about 10 to 125 A, and in yet other embodiments, about 15 to 100 A. The electric current, in some embodiments, heats a container to generate heat in the magnetic powder. The container may be used as heating media during the annealing step. The container may be any suitable conductive material, such as, but not limited to, graphite. In certain embodiments, at least the bottom of the container includes insulating materials, such as, but not limited to ceramic. In other embodiments, the bottom and top of the container are conductive, while the side of the container is an insulating material. In another embodiment, the magnet powder can be heated by placing the powder assembly into a coil carrying a high-frequency electric current (i.e., induction heating). In at least one embodiment, the high-frequency is about 5 to 500 kHz, in other embodiments, about 10 to 450 kHz, and in yet other embodiments, about 15 to 400 kHz. In certain embodiments, the current is is about 5 to 150 A, in other embodiments, about 10 to 125 A, and in yet other embodiments, about 15 to 100 A. An alternating magnetic field generates an eddy current in the magnet powder assembly because of the high-frequency current in the coil, which in turns generates heat in the magnet powder assembly. In some embodiments, to maintain the magnet powder alignment, a DC current component may be added to the current in the coil.
The generated heat melts the rare earth-rich grain boundary phase, similar to a sintering furnace, for forming the soft magnetic core. The external magnetic field may be applied until the magnet powder temperature reaches the Curie temperature of the main phase of the magnet powder to ensure the magnetic particles are aligned after sintering. The Curie temperature may or may not be higher than the melting point of the boundary phase of the main phase of the magnet powder. The powder assembly may be a soft ferrite, pure iron, iron-silicon, or other suitable soft magnetic core materials. However, as an example for materials with Curie temperatures relative to melting points, rare earth examples are discussed herein (e.g., neodymium magnets where the Curie temperature of Nd2Fe14B is lower than the melting point of the rare-earth rich phase). In some embodiments, the Curie temperature is higher than the melting point of the boundary phase. For example, in SmCo magnets, the Curie temperature of SmCo is higher than the melting point of the rare-earth rich grain boundary phase. As such, in the example for SmCo magnets, the external field is held at a temperature higher than the SmCo phase, around about 800° C. After the magnetic powders reach the Curie temperature of the main phase, the magnetic powders become paramagnetic and the self-demagnetizing force is eliminated. Therefore, the external magnetic field may be removed to reduce energy consumption. For example, the external magnetic field need not be applied during sintering, as in other embodiments.
The sintering step 20 in some embodiments, after heating with an external magnetic field, may be conducted at a heating temperature higher than the melting point of the rare-earth rich phase. The melting point may be, but is not limited to, about 500 to 900° C. The sintering step melts the rare-earth rich phase around the grain boundaries melts such that the powders are adhered together in a solid compact. As the sintering temperature further increases, the density of the compact increases, and grains begin to grow. The grain size may be optimized by time and temperature selections during sintering to achieve the desired magnetic properties in the final magnets. After sintering, the magnets are cooled and have an improved alignment since the magnetic powder can be heated while being exposed to an external magnetic field.
With reference to
To prepare a bonded core, rather than a sintered core, a binder may be used to consolidate and secure the magnetic powder (and any insulating or lubricating material that is present). Any suitable binder may be used, such as thermosets, thermoplastics, elastomers, inorganic ceramic binders, high-temperature ceramic binders, or others. A non-limiting example of a thermoset that may be used as a binder is an epoxy, which may be phenolic or novalac. A non-limiting example of a thermoplastic that may be used as a binder is a polyamide, such as polyphenylene sulfide (PPS). Non-liming examples of elastomers that may be used as a binder include nitrile rubber, polyethylene, and vinyl.
At step 36, the magnetic powder may be aligned using a magnetic field. The mixture of magnetic powder and binder (plus any lubricant or insulating material) may be introduced into a mold while the binder is in a liquid or uncured state (e.g., unconsolidated). While the binder is in the liquid or uncured state, a magnetic field may be applied to the mixture and/or mold in order to align the magnetic particles in a preferred pattern or direction. Since the binder is not yet cured, the particles are more easily aligned by the magnetic field since they are free to rotate, which may allow the magnetic powder to orient themselves easier such that their easy axes are aligned/parallel with the magnetic field. As described above, the rotation may be further facilitated by using particles that have one or few grains. The magnetic field may be applied in the shape or the path of the flux direction in the magnet core, thereby increasing the permeability and flux density in the flux direction of the finished core. Additional description of the fixtures and methods of producing the magnetic field is included later in the disclosure. While not required, a tapping process, similar to described in step 16 may be applied to the binder and powder mixture during the alignment process.
At step 38, an optional pressing process may be performed. Any suitable pressing method may be performed to increase the density of the magnet core, such as compression (e.g., uniaxial pressing), extrusion, or injection molding. In one embodiment, when compression is performed, the binder used may be a thermoset. In another embodiment, when extrusion is performed, the binder may be an elastomer or a thermoplastic. In another embodiment, when injection molding is performed, the binder may be a thermoplastic. A magnetic field may be applied during the pressing step 38 in order to maintain or further align the particles in the mold. The magnetic field may be the same one applied in step 36.
At step 40, the magnetic powder and binder mixture may be cured. The curing time and temperature may vary, depending on the type of binder used. Some binders may not require the application of heat and may cure at room or ambient temperature. A magnetic field may be applied during the curing step 40 in order to maintain or further align the particles in the mold. The magnetic field may be the same one applied in steps 36 and/or 38. After curing, a finished magnet core is formed having aligned grains with increased permeability and flux density along the path of the aligned grains, which were formed using a predetermined, customized magnetic field applied during the aligning step 36 and optionally the pressing step 38 and/or curing step 40.
The magnetic field applied in either the sintered or bonded magnet cores described above may provide a magnet core suitable for any application in which anisotropic or directional magnetic properties are desired, such as permeability, induction/flux density, coercivity, core loss, or others. Non-limiting applications that may benefit from the disclosed magnet cores include inductors, transformers, generators, and rotors and/or stators of electric motors (e.g., electric vehicle motors). To provide the anisotropic/directional properties described above, a predetermined, specific magnetic field may be applied while the core is being formed that corresponds to the flux path in the finished core when it is used in a certain application. Accordingly, the magnetic field being applied may be tailored to a specific magnet core application, such as a stator or an inductor core. By generating a magnetic field having a shape or path(s) that conforms, follows, mimics, or approximates the flux path(s) in the final application, permeability, flux density, and other properties may be significantly improved without sacrificing loss performance. For magnet cores having complex shapes or that experience complex flux paths, the magnetic field may also be complex, for example, including a plurality of distinct curved or non-linear directional alignments.
The magnetic field may be applied using any suitable method. In at least one embodiment, an alignment fixture may include one or more electric circuits, each including one or more wires carrying electric current to generate the magnetic field. By controlling the placement or configuration of the wire(s) and the level and/or direction of the current, a specific, custom magnetic field can be generated that mimics or corresponds to the flux direction in a magnet core during operation. The magnetic field may therefore align the magnetic grains in a plurality of directional alignments to conform to, mimic, or follow the magnetic flux direction. As used herein, directional alignments may refer to major alignments, or those that exist on a macro scale versus micro scale. Accordingly, small deviations in alignment from one grain to another or between several grains are not considered major alignments.
In at least another embodiment, an alignment fixture may include one or more magnets for providing the magnetic field during the alignment process. In one embodiment, the magnets are permanent magnets. By controlling the placement, configuration, size, shape, and/or strength of the magnet(s), a specific, custom magnetic field can be generated that mimics or corresponds to the flux direction in a magnet core during operation. While the Figures and the following descriptions describe fixtures in which electric circuits or magnets are used to generate the magnetic field, one of ordinary skill in the art will appreciate that any combination of the two approaches may also be utilized. In addition, any magnet field line or direction shown or described may also be a directional alignment of magnetic grains.
With reference to
In one embodiment, shown in
With reference to
As described previously, with respect to
While the arrangement of magnets 72 in
In addition to adjusting the number and/or placement of the magnets 72, one or more iron cores 80 may be included in the alignment fixture, as shown in
With reference to
With reference to
In one embodiment, shown in
While
Another embodiment of a fixture for providing a magnetic field 106 alignment in a stator core 100 is shown in
As described above with respect to
In another embodiment, shown in
With reference to
In at least one embodiment, the magnets 204 used in the fixture may be the same permanent magnets that are incorporated into the rotor core 200 in its final form (e.g., in a permanent magnet motor). Accordingly, the permanent magnets that are used in the rotor are also used to orient the grains/powder during the rotor core manufacturing process (e.g., alignment and optionally compaction and/or sintering/curing). The permanent magnets may be embedded in the powder core during the manufacturing process and may remain in the core after the processing is finished to form the final rotor core. Similar to the fixtures described above, the fixture for the rotor orientation may include an iron core 214 that surrounds (partially or completely) the rotor core 200 in order to assist in guiding the magnetic field 202.
The non-limiting examples of fixtures described in
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.
This application is a continuation-in-part of U.S. Ser. No. 15/962,268 filed Apr. 25, 2018, which is a division of U.S. application Ser. No. 14/535,807 filed Nov. 7, 2014, the disclosures of which are hereby incorporated in their entirety by reference herein.
Number | Date | Country | |
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Parent | 14535807 | Nov 2014 | US |
Child | 15962268 | US |
Number | Date | Country | |
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Parent | 15962268 | Apr 2018 | US |
Child | 16228874 | US |