Electromagnetic induction device configured as a multiple magnetic circuit

An electromagnetic induction device comprises a closed magnetic circuit, without air gap, of which at least one first part is substantially rectilinear and surrounded by a sleeve, the sleeve being surrounded by an electrical conductor which comprises at least one metal sheet electrically insulated on at least one of its faces, wherein at least the first part of the magnetic circuit has a section of circular form.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a National Stage of International patent application PCT/EP2016/052926, filed on Feb. 11, 2016, which claims priority to foreign French patent application No. FR 1500283, filed on Feb. 13, 2015, the disclosures of which are incorporated by reference in their entirety.

FIELD OF THE INVENTION

Background

The present invention relates to the field of electromagnetic inductors and electrical transformers. This type of device is for example used to produce a filter at the output of an alternating/direct electrical current converter. These inductors make it possible to reduce the residual current and/or voltage variations at the output of such a converter. This type of electromagnetic inductor, called coil, can also be implemented to produce a transformer. In this case, it is necessary to couple several coils wound around one and the same magnetic circuit.

In the aeronautical field, the weight and the noise of the embedded components are important parameters for which reductions are sought. To this end, it is possible to use electrical conductors made of aluminum, lighter than copper, for a use of the electrical component at a given power. The ductility of aluminum is much lower than that of copper. Consequently, aluminum in sheet form is often used, that is wound to produce coils.

The coils are wound around closed magnetic circuits to best guide the magnetic flux. Magnetic circuits produced in two parts are commonly used. The coil or coils are produced outside of the magnetic circuit, then placed therein. Once this operation is completed, the two parts of the magnetic circuit are assembled to close the circuit. The junction between the two parts forms an air gap. It is difficult to make the two surfaces forming the air gap strictly parallel: there remains a low deviation between the two parts that is difficult to eliminate. The surfaces of the two parts intended to come into contact can be ground in order to improve the surface condition at the junction. It is also possible to band the magnetic circuit by means of a strip surrounding it to close it. The banding force contributes to further reducing the air gap.

Nevertheless, the electrical current circulating in the coils can generate mechanical vibrations in the device. These vibrations tend to separate the two parts of the magnetic circuit to reform an air gap. The vibrations can also tend to loosen the mechanical securing of the different parts of the magnetic circuit, which tends to allow the amplitude of the vibrations to increase throughout the life of the coil. At the same time, the induction device heats up during its use. The temperature difference of the induction device between use and rest can lead to an expansion of the magnetic circuit and the appearance of a deviation in the air gap.

Moreover, the vibrations described previously tend also to generate noise which can be a nuisance. The constructors, for example in aeronautics, demand increasingly lower sound nuisance levels.

To mitigate this problem, there are electromagnetic induction devices and transformers in which the magnetic circuit does not have an air gap. The electrically conductive coil must be wound around the magnetic circuit: a device for this winding is described in the patent FR 2939559. This device uses a sleeve, also called duct, of circular internal section, assembled from two parts around the magnetic circuit. The electrical conductor is first of all attached to this sleeve. A driving means then rotates this sleeve, via a sleeve engaging means. The sheet or sheets of electrical conductor are then wound around the sleeve.

Another known technical problem with induction devices lies in the occurrence of eddy currents in the magnetic circuit, leading to a loss of energy due to the electrical resistance of the magnetic material, if the material is an electrical conductor. This problem is conventionally mitigated by the production of a layered laminated magnetic circuit: flat plates of magnetic material, electrically insulated from one another by an electrically insulating material, such as lacquer or certain types of glue, are superposed one on top of the other. This super positioning can also be obtained by winding a plate. Each layer of the winding is then separated by an electrically insulating material.

The magnetic material used in the magnetic circuit is often a soft magnetic material, to avoid the losses of energy by hysteresis upon the imposition of variable magnetic fluxes. The circuit obtained makes it possible to limit the occurrence of the eddy currents, but the section of the magnetic circuit obtained, by using this production method, is rectangular.

The difference in form between the circular section of the sleeve and the rectangular section of the magnetic circuit limits the efficiency of the energy coupling between the coil and the magnetic circuit and leads to losses in the use of the transformer.

Another limitation of the device is linked to the losses by Joules' effect. They can reach high temperatures (typically above 100° C.) on the device and thus limit its use. Different cooling means are generally used to reduce the temperature of the electromagnetic induction devices: by liquid contact or by solid contact with a cold reservoir.

The invention aims to overcome at least one of the abovementioned drawbacks of the prior art.

SUMMARY OF THE INVENTION

One object of the invention making it possible to achieve this aim is an electromagnetic induction device comprising a closed magnetic circuit, without air gap, of which at least one first part is substantially rectilinear and surrounded by a sleeve, said sleeve being surrounded by an electrical conductor which comprises at least one metal sheet electrically insulated on at least one of its faces, characterized in that at least said or each said first part of said magnetic circuit has a section of circular form, and in that said magnetic circuit is laminated with several layers of magnetic material separated by an electrical insulator, and that at least one said sleeve comprises an inner face of which the form of a section is circular and closely fits the form of said magnetic circuit, and an outer face comprising curved parts and planar parts.

Advantageously, said magnetic circuit comprises at least one second part which has at least one planar surface.

Advantageously, said electromagnetic induction device comprises a local heat exchanger in contact with said magnetic circuit outside of said first part or parts.

Advantageously, said local heat exchanger comprises at least one surface closely fitting the form of said magnetic circuit and at least one planar surface.

Advantageously, a section of said magnetic circuit is of circular form along the contact with at least one said local heat exchanger.

Advantageously, several surfaces chosen from at least one said planar surface of said magnetic circuit and at least one said planar surface of said local heat exchanger or exchangers, are coplanar and adapted to be placed in contact with at least one planar heat exchanger.

Advantageously, said magnetic circuit comprises at least one sheet of magnetic material electrically insulated on at least one of its faces and wound over at least one element chosen from at least one other said sheet of magnetic material and itself.

Advantageously, each said sleeve comprises several parts adapted to cooperate to surround said magnetic circuit.

Advantageously, at least one said sleeve comprises at least one engaging means adapted to transmit a drive to allow the rotation of each said sleeve about each said longitudinal axis of each said first part, in order to wind and order at least one said electrical conductor in sheet form around each said sleeve.

Advantageously, said electromagnetic induction device comprises two planar electrical conductors in electrical contact with one said electrical conductor and arranged so as to form the terminals of said electrical conductor.

DETAILED DESCRIPTION

The following description presents a number of exemplary embodiments of the device of the invention: these examples are nonlimiting on the scope of the invention. These exemplary embodiments show both the essential features of the invention and additional features associated with the embodiments considered. For clarity, the same elements will bear the same references in the different figures.

FIG. 1presents a perspective schematic view of an electromagnetic conduction device1. The magnetic circuit2is closed and without air gap. In this particular embodiment of the invention, it has a section of circular form along all of the circuit2. It is surrounded by a sleeve3over a rectilinear part of the magnetic circuit, called first part11. The sleeve3, in a particular embodiment of the invention, can be produced in an insulating material, for example by the compact vacuum insulation method (U.S. Pat. No. 5,157,893 A). The magnetic circuit2has at least one part that is rectilinear, or at the very least, that can be likened to a rectilinear part given the length of the sleeve3.

An electrical conductor4in sheet form is wound around the sleeve3. In a particular embodiment of the invention, the sheet can be made of aluminum. The sheet must be electrically insulated on at least one of its faces to keep the properties of an electromagnetic coil. In a particular embodiment of the invention, oxidation of the surface of the electrical conductor4, lacquer or glue, or a mixture of lacquer and glue are used to electrically insulate layerings of the sheet of electrical conductor4.

FIG. 2presents a perspective schematic view of a magnetic circuit2and of a planar heat exchanger14. The magnetic circuit2represented in this particular embodiment of the invention has several distinct parts: first parts11, defined previously and parts each having at least one planar surface of said magnetic circuit13, called second parts12. In a particular embodiment of the invention, some of these planar surfaces can be coplanar and adapted to be placed in contact with a planar heat exchanger14. This configuration makes it possible to control or limit the temperature of the device during use at high power. In the example ofFIG. 2, the two planar surfaces13are coplanar and adapted to be placed in contact with a planar heat exchanger14. For clarity of the representation, the planar heat exchanger14is placed in contact with two other planar surfaces13that are coplanar and not referenced by the figure.

FIG. 3is a perspective schematic view of a part of the magnetic circuit2and of a local heat exchanger15, also called cradle. The local heat exchanger15is in contact with a portion of the magnetic circuit2other than a first part11. The local heat exchanger15has a face which closely fits the form of the magnetic circuit2to maximize the contact surface and thus favor the heat transfer, for a given form of magnetic circuit2. Furthermore, the local heat exchanger15has at least one planar surface22. InFIG. 3, the local heat exchanger15has several planar surfaces22, one of which coincides with a planar surface13. In the particular embodiment of the invention represented inFIG. 3, the portion of magnetic circuit2has a section of circular form along the contact with the local heat exchanger15.

FIG. 4Apresents a perspective schematic view of a sleeve3.FIG. 4Bpresents a part of a sleeve6. In this particular embodiment of the invention, the sleeve3presented is made up of two parts of sleeve6. A part of sleeve6alone cannot surround the magnetic circuit2. On the other hand, it is possible to securely assemble different parts of sleeves6in cooperation to surround the magnetic circuit2and form a sleeve3. Such cooperation is presented inFIGS. 4A and 4B.

FIGS. 4A and 4Balso present engaging means17of the sleeves3, which, depending on the embodiments, can be holes, notches, protuberances, tenons or mortices. These engaging means17are useful during the production of the device1. Once a conductive metal sheet is attached outside the sleeve3, a rod can be pressed into each engaging means17then transmit a motor torque allowing a rotation of the sleeve3about the longitudinal axis of a first part11of magnetic circuit2. This rotation makes it possible to wind the metal sheet around the sleeve3and thus form a winding of electrical conductor4around the magnetic circuit2.

FIGS. 4A and 4Bpresent a sleeve whose inner face7has a circular section. This attribute is essential to be able to perform a rotation of the sleeve3around the magnetic circuit2on the longitudinal axis of a first part11, during the production of the device. On the other hand, the outer face8, that is to say the lateral face of the sleeve, comprises a curved part19and a planar part20. It is also possible to define the outer face8as an axial face: this is a surface which can be defined by a set of straight lines parallel to the main axis of the sleeve. On the outer face8, the production of the device requires the absence of any excessively pronounced angle which could induce the breaking or the tearing of the sheet of electrical conductor4during the winding around the sleeve3. The alternation presented inFIGS. 4A and 4Bbetween curved part19and planar part20makes it possible to mitigate this problem while keeping a planar part20, useful to the electrical connections of the device1. The planar part8of the sleeve brings about, upon a winding, the arrangement of a planar part of a metal sheet surrounding the sleeve3, located on the planar part8. A planar contact between the metalized sheet and another element can thus be produced, allowing for example for a transfer of heat from the electromagnetic induction device to this element. This feature can make it possible to cool the electromagnetic induction device.

FIG. 5is a perspective schematic view of a part of the magnetic circuit2, of a sleeve3and of an electrical conductor4. It presents the electrical conductor4in a sheet wound around the sleeve3, itself assembled around a first part11of magnetic circuit2of circular section. The presence of a curved part19and of a planar part20on the outer face of the sleeve8is reflected in the form of the winding:FIG. 5presents a winding of electrical conductor4whose outer part also has a curved part and a planar part. This attribute too is also useful to the electrical connections of the device1.

FIGS. 6A and 6Bare perspective schematic views of details of a first part11of the electromagnetic induction device1. In a particular embodiment of the invention, two planar electrical conductors16are in mechanical and electrical contact with the electrical conductor4wound around the duct. These two planar electrical conductors16are arranged in such a way as to form the terminals of the electrical conductor4. InFIG. 6A, the planar electrical conductor16is in contact with the electrical conductor4at the start of the winding. InFIG. 6B, the planar electrical conductor16is in contact with the electrical conductor4at the end of the winding.

In this particular embodiment of the invention, the planar electrical conductors16can be placed on the planar part20of the outer face8of the sleeve3, and/or on the corresponding planar parts of the winding of electrical conductor4. This feature makes it possible to be able to fold the planar electrical conductors16. The folding of the conductors makes it possible to simplify the external electrical connection of the device1.

FIGS. 7A and 7Bare plan schematic views of two windings of magnetic material21.FIG. 7Adescribes a simple winding21of magnetic material: a single sheet of magnetic material18is wound on itself. This sheet18is covered on at least one of its faces by an electrical insulation. In particular embodiments of the invention, this insulation can be lacquer, or glue, or both.

This configuration provides the device with two distinct advantages. On the one hand, the magnetic circuit2formed by the simple winding21forms a succession of layers between magnetic material and electrical insulation. This configuration makes it possible to avoid the appearance of eddy currents by layering the magnetic circuit2. These currents, when they exist, lead to energy losses linked to the electrical resistivity of the magnetic material. Also, this type of winding makes it possible to create a magnetic circuit of round section. In effect, starting from a sheet of magnetic material18of a variable width, the width of this sheet18can, for a fixed point of the magnetic circuit2and on each turn of the winding, increase or decrease substantially. This width is not visible inFIGS. 7A and 7Bbecause the schematic representation is a plan view. Consequently, by starting from a sheet whose overall form is a rhomboid, it is possible to produce a magnetic circuit2whose section is circular. With this method, the greater the number of turns in the winding21, the more the section can exactly approximate a circle. In the interests of clarity of the explanation, there are few windings21inFIGS. 7A and 7B. In a particular embodiment of the invention, the number of windings can be between 20 and 600.

FIG. 7Bpresents a winding21of several sheets of magnetic material18to produce the magnetic circuit2. A first sheet of magnetic material18is wound around two sheets of magnetic material18, wound on themselves. This configuration makes it possible to multiply the branches of the magnetic circuit2in the case of applications such as voltage ratio selection in a transformer. In this case, a winding21can be produced by several sheets of magnetic material18with the width increasing for each of the sheets18.