POWER MAGNETIC COMPONENT

Abstract

A magnetic component having a core of a high-permittivity material with one or more apertures extending between two opposite faces of the core and filled with a thermal conductors of a non-magnetic insulator material. Preferably, the apertures extending between a flat side of the core in contact with a metallic housing and the space where the windings are laid, providing a short and direct path for heat transfer. The thermal conductors may be alumina or any suitable material.

Description

REFERENCE DATA

The present application claims priority of European patent application EP22165533 of Mar. 30, 2022, the content whereof are entirely incorporated.

TECHNICAL DOMAIN

The present invention concerns a power magnetic component with improvements related to the cooling, and its uses. Embodiments of the invention relate to a ferrite-core transformer for a power converter or a battery charger as well as to an onboard battery charger for an electric or hybrid vehicle.

RELATED ART

Magnetic components are key elements of power electronics and are found in a wide range of applications in all industrial sectors. Inductors are used, among others, in filter, voltage converters and in power factor compensation.

Besides their electrical characteristics, magnetic components must also fulfil specifications for dimensions, heat dissipation, heat resistance, immunity to vibrations, and many other parameters. As a result, magnetic components are complex products that are difficult to design and customize to all the possible applications. In automotive applications, where magnetic components are increasingly common, these specifications are especially stringent.

A state-of the art magnetic component is the result of a trade-off between the desired nominal inductance value, the size, weight, and footprint dictated by the desired application, the choice of material, layout, and cooling.

All magnetic devices exhibit energy losses in the winding and in the magnetic circuit. Such losses may be caused by the winding's resistance, by hysteresis in the core, by eddy currents, or by any other form of inefficiency. In high-power applications, loss-generated heat must be evacuated from the magnetic assembly lest it impairs the performances of the inductor. The lower the thermal resistance between the inductor and the available heat sinks, the higher will be power rating and power density.

Applications to the automotive sector, as well as in other demanding areas, require superior manufacturability, reliability, resistance to mechanical shocks and vibrations in an extended temperature range, together with a precise control of the tolerances and low thermal drifts.

It is known to encapsulate magnetic components in a metallic housing filled with a curable potting compound. Potting protects the device from water, moisture and corrosion, adds resistance to shocks and vibration and, in some measure, improves the transmission of the heat generated in the device to the housing. Sometimes, in automotive applications, the housing has a flat bottom that is screwed on a cooled plate.

Biela, J., & Kolar, J. W. (2007). Cooling Concepts for High Power Density Magnetic Devices. Power Conversion Conference. Nagoya (doi: 10.1109/PCCON.2007.372915) discloses a theoretical comparison of several cooling methods.

Some known magnetic components use special thermal conductors to improve power dissipation. Thermal conductors may take the form of metallic elements, which are excellent conductors, but may be the seat of eddy currents which contribute to losses. U.S. Pat. No. 4,081,776 A discloses a laminated core with a sleeve of thermally conductive ceramic close to the windings. Thermally conductive ceramic materials are disclosed also in U.S. Pat. No. 4,897,626 A in association with magnetic toroids, in CN 107516581 A, mounted on a winding support, and in CN 20857027 U1 in the form of a ceramic element between two ferrite semi-cores.

U.S. Pat. No. 7,212,406 B2 discloses a magnetic component with non-magnetic passageways in the core that allow the flow or a fluid cooling medium, while US 2016/0064134 A1 discloses a transformer with stacked windings and, between primary and secondary, a heat-dissipating metallic panel.

Conductive ceramics are rather expensive to produce in custom shapes; moreover, in known solutions, the heath path between the source of the losses and the heat sink is rather long, and the thermal resistance is undesirably high.

SHORT DISCLOSURE OF THE INVENTION

An aim of the present invention is the provision of a power magnetic component that uses thermally conductive insulator elements in a new and more effective way. Compared to known devices, the magnetic components of the invention run at lower temperature and are more economical to produce.

According to the invention, these aims are attained by the object of the attached claims, and especially by a magnetic component having a magnetic core of a high-permittivity material forming a magnetic circuit, wherein the core has at least one aperture extending between two opposite faces of the core and the aperture is filled with a thermal conductors of a non-magnetic insulator material.

Dependent claims relate to features that, while being important and useful, are not essential, such as the winding or windings concatenated with the magnetic circuit, or the shape of the core that may be a pot core with a flat side and a concavity for lodging the winding, the apertures extending between the flat side and a bottom side of the concavity, and the flat side abuts against a metallic housing. The openings and the thermal conductor can be arranged in the core to run along a contour of the winding or windings concatenated with the magnetic circuit.

Other desirable features include that the thermal conductors may extend above the bottom side of the concavity into the space filled by potting compound to increase the thermal contact with the windings, and optionally provide a mechanical support to the winding themselves. In some variants, the thermal conductors may be completed by additional elements to provide a coil former or a bobbin on which the winding(s) are wound.

The core may be a ferrite core or powdered metal core, and the thermal conductivity of the inserts should be above that of the high-permeability material, for example above 5 W/m·K, preferably above 10 W/m·K or better above 20 W/m·K. Such values can be obtained using pure sintered alumina (Al₂O₃) or Al₂O₃-rich ceramic materials, for example. In addition, the thermal conductivity of the inserts should be above that of a potting compound that can be used for potting the magnetic component in a housing.

Other materials with high thermal conductivity exist and may be applied to the invention, pure or mixed to other components, possibly in the form of sintered ceramic. Beside alumina, these materials include boron nitride, aluminium nitride, silicon carbide, beryllium oxide and exotic materials like diamond and graphene. The list is not exhaustive.

The thermal conductor could also be a composite including particles of a high-conductivity material, for example one of the above, dispersed in a suitable matrix. The matrix could be an organic polymer, a thermoplastic, a thermoset, a silicon polymer, or any suitable organic or inorganic binder.

With respect to what is known in the art, the invention provides a superior evacuation of the heat losses and is particularly suitable to installations on a cooled plate, where the heat conductors of the invention are strategically placed to conduct the heat toward the cooled plate along the shortest possible path. It can be applied to transformers, inductors, chokes and multiphase components alike. An important use case of the invention is in onboard chargers for electric and hybrid vehicles, but many other applications are possible.

SHORT DESCRIPTION OF THE DRAWINGS

Exemplar embodiments of the invention are disclosed in the description and illustrated by the drawings in which:

FIGS. 1a-1c illustrates schematically a magnetic component of known type with a ceramic plate providing a heat path around the magnetic core.

FIGS. 2a-2d show a possible realization of the inventive magnetic component.

FIG. 3 shows a variant of the inventive component with thermal conductors extending above the core into the potting compound.

FIG. 4 shows a variant of the invention involving a core of a different shape

EXAMPLES OF EMBODIMENTS OF THE PRESENT INVENTION

FIG. 1a represents a magnetic transformer with a gapped core, suitable for use in certain classes of DC-DC converters and battery chargers. The transformer is represented with the components exploded, omitting the potting compound that is poured in the housing in a final assembly step.

The transformer represented in the figures can be used, for example in a power converter or in a battery charger. On-board battery chargers for electric and hybrid vehicles are an important use case of the present invention, but not the only one. The invention can be applied also to filters, power factor converters, and any application of magnetic components where high power density is desired.

The transformer is mounted in a metallic housing 25, for example a cast aluminium element. The housing has a receptacle that is configured to contain the transformer and a flat base designed to be fastened to a flat plate. The plate may be cooled by water, forced air or natural air convection.

The winding or windings 61, 62 are inserted in the magnetic core 32 around the central leg and the magnetic circuit is completed by the lid 33. A heat-conducting ceramic plate 50 adds a thermal path that improves the transmission of heat from the windings to the bottom of the housing and thence to the cooled plate. FIGS. 1b and 1c show the same assembly from above and in section, the windings 61, 62 and the potting having been omitted for simplicity. The core 32 can comprise any suitable magnetic material such as a ferrite or powdered iron. Ferrites are the material of choice in high-performance power converters operating at carrier frequencies of hundreds of kHz or more. Ferrites suitable to use in the present invention can be obtained commercially by the company “Ferroxcube” under the denomination “3C92” among others, but many other producers and grades are available.

FIG. 2a shows a magnetic component according to the invention. The core 32 has openings 35 that traverse a thickness of the core and connect one flat face 37 of the core with an inner face, adjacent to the windings 61, 62. The openings 35 are filled by plugs 55 of a thermally conducting non-magnetic material. Preferably, the thermal conductivity of the material chosen for the plugs 55 is sensibly more than the thermal conductivity of the magnetic material composing the main part of the core 32, for example heat conducting ceramic with a thermal conductivity higher than 5 W/m·K, preferably 10 W/m·K or higher. Al₂O₃ with thermal conductivities better than 20 W/m·K is available and suitable for the present invention. Al₂O₃ also provides the advantage that it is inexpensive, available on the market and is electrically insulating. Other technical materials that could be used for this purpose include Silicon Carbide, Boron Nitride and diamond.

Ceramic materials are attractive choices for the thermal plugs 55 because they resist to very high temperatures and their coefficient of thermal expansion is quite small; nevertheless, they are not the only choice possible. The thermal plugs 55 could be made out of any suitable insulator with a thermal conductivity higher than that of the surrounding ferrite. This includes, among others, composite materials with a thermally conductive phase in a matrix. The matrix could be a silicone polymer, or an organic polymer or any other suitable binder. Thermally conductive composites and thermally conductive plastics are inexpensive and easy to manufacture in complex shapes.

Preferably, the openings 35 and the thermal plugs 55 inserted into the openings 35 are not arranged randomly in the core 32, but run along the contour, or outline, of the overlying windings 61, 62. This means that the heat generated by the windings 61, 62 can be dissipated very efficiently, as the thermal path is relatively short due to this arrangement. This solution is simple and a complex structure for thermally connecting the windings 61, 62 to its environment can be omitted. More preferably, the openings 35 and the thermal plugs 35 run along the entire contour of the windings 61, 62 to optimise the heat transfer and avoid hot spots.

FIG. 2b shows the magnetic device of the invention from the top. FIG. 2c is a cross section that shows the core 32 alone with the openings 35 in the bottom of the receptacle that is designed to receive the windings 61, 62. In the finished product, the lower flat side 37 of the core 32 will sit directly on the bottom of the aluminium casing 25 that is fastened on a cooled plate, as in FIGS. 1a-1c. The plugs 55 provide a direct and short path to dissipate the heat generated by the losses, particularly the losses in the windings.

The aluminium casing 25 can be filled with the potting compound (not illustrated) in a final assembly step. The potting compound can have, when solidified, a thermal conductivity of 0.7 W/m·K, 1.0 W/m·K or 1.6 W/m·K but in any case lower than 2.0 W/m·K. The potting compound may be constituted of an semi-elastic material, such as silicone or urethane; or a resin material, such as acrylonitrile-butadiene-styrene, polybutylene-terephthalate, or polyphenylene sulfide.

As one can notice, the potting compound's thermal conductivity is typically far lower than the thermal conductivity of the thermal plugs 55. In return, the thermal conductivity of the thermal plugs 55 are at least two times higher than the thermal conductivity of potting compound.

In a non-illustrated example, the plugs 55 may protrude from the openings 35, so that protruding ends form a spacer between the lower flat side 37 of the core 32 and the bottom of the aluminium casing 25 when potted. The resulting distance between the lower flat side 37 of the core 32 and the bottom of the aluminium casing can reduce eddy currents in the material of the casing 25. The protruding ends, however, can still be in contact with the bottom of the aluminium casing 25 for thermal exchange.

FIG. 2d shows the core 32 from above, with a recess configured to accept the windings, which are not drawn in this figure, around a central column. The openings 35 lie on the bottom of the recess and provide a direct path to the flat underlying face. This disposition is advantageous because, on one side, the length of the heat path is limited and, on the other side, the effects of the apertures on the reluctance and the maximum flux density of the magnetic circuit are moderate.

FIG. 3 illustrates a variant of the magnetic component illustrated in FIGS. 2a-2d, in which the heat conductors 55 are not entirely contained in the thickness of the core 32 but directly extend in the space above, providing both a thermal contact and a mechanical support to the windings 61, 62. The thermal path between the windings 61, 62 and the aluminium casing 25 is improved by providing a path with higher thermal conductivity. As a result, heat generated by the windings 61, 62 is better evacuated. Furthermore the core 32 remains in connection with the heat conductors 55 and thereby also providing a thermal path for the heat generated by the core 32. In addition, the manufacturability of the magnetic component can be improved by the heat conductors 55 directly extending into the space above, as they can function as guiding means for optimally placing the windings 61, 62 in the concavity of the core 32.

Also in the present variant, the openings and the heat conductors 55 run along the contour of the windings 61, 62 providing a short thermal path.

The previous example shows a transformer with two coupled windings and an air gap in the magnetic circuit; nevertheless, the invention is not so limited, and may include plain inductors with a single winding, common-mode chokes with two coupled windings, conventional transformers without air gaps, power-factor correction impedances, multiphase devices with multiple windings and more.

While the examples represent a pot core of a special shape, magnetic cores come in a large variety of shapes, and the present invention applies to all shapes. The invention includes variants in which the core is made by two symmetrical halves, rather than a deep pot closed by a flat lid, and other shapes like “C” cores, “E” cores and many others. FIG. 4 represents a possible implementation of the invention in a ferrite core 31 with an “E” shape. In contrast with the example of FIGS. 2a-2d that had cylindrical conductors 55, the thermal inserts 56 of FIG. 3 are prismatic. According to the need, the thermal inserts could assume any suitable shape.

REFERENCE SYMBOLS IN THE FIGURES

• • 25 housing
  • 31 “E” core
  • 32 pot core, core
  • 33 core lid
  • 35 opening
  • 37 flat face
  • 50 thermal plate
  • 55 thermal conductor, cylindrical, plug
  • 56 thermal conductor, prismatic
  • 61 winding
  • 62 winding

Claims

1. A magnetic component having a core of a high-permittivity material forming a magnetic circuit, wherein the core has at least one aperture extending between two opposite faces of the core and filled with a thermal conductor of a non-magnetic insulator material.

2. The magnetic component of claim 1, comprising at least one winding concatenated with the magnetic circuit.

3. The magnetic component of claim 2, wherein the core is a pot core with a flat side and a concavity for lodging the winding therein, the at least one apertures extending between the flat side and a bottom side of the concavity, the core and the winding being potted in a metallic housing, the flat side abutting a flat bottom of the housing.

4. The magnetic component of claim 3, wherein the thermal conductors extends above the bottom side of the concavity and is partly surrounded by potting compound.

5. The magnetic component of claim 4, wherein the thermal conductors is in thermal contact with the winding and support mechanically the windings.

6. The magnetic component of claim 1, wherein the core is a ferrite core or powdered metal core, and the thermal conductors are one of: Alumina, a Al2O3 composite, ceramic, Boron Nitride, a BN composite, Silicon Carbide.

7. The magnetic component of claim 1, wherein a thermal conductivity of the thermal conductor is higher than a thermal conductivity of the high-permittivity material and a potting compound, preferably above 5 W/m·K, more preferably above 10 W/m·K, even more preferably above 20 W/m·K.

8. The magnetic component of claim 1 configured as a transformer with two magnetically coupled windings.

9. Use of the magnetic component of claim 1 in a power converter or in a battery charger.

10. The magnetic component of claim 4, comprising a plurality of apertures and thermal conductors, wherein the said apertures and thermal conductors are arranged along a contour of the winding lodged in the concavity.

11. The magnetic component of claim 5, comprising a plurality of apertures and thermal conductors, wherein the said apertures and thermal conductors are arranged along a contour of the winding lodged in the concavity.

12. The magnetic component of claim 6, wherein the said apertures and thermal conductors are distributed along the entire contour of the winding.

13. The magnetic component of claim 7, wherein the said apertures and thermal conductors are distributed along the entire contour of the winding.