EP4109476A1 - Device for filtering common mode interference and differential mode interference - Google Patents

Abstract

The invention relates to a device for filtering common mode interference and differential mode interference. The device comprises several electrical conductors (1). the electrical conductors (1) are each individually surrounded by a first core (2) in a section, the electrical conductors (1) and the first cores (2) being surrounded together by a second core (3) in this section wherein the first cores (2) each have a first magnetic permeability and the second core (3) has a second magnetic permeability, and wherein the second magnetic permeability is greater than each of the first magnetic permeabilities

Description

The invention relates to a device for filtering common mode interference and differential mode interference.

In the case of electronic devices, for example with clocked semiconductor switches, electrical interference signals occur during operation. The electrical interference signals can be divided into common mode interference and differential mode interference. For common-mode interference, the English term common-mode interference is also used, and for differential-mode interference, the English term differential-mode interference is used.

According to the prior art, common-mode interference and differential-mode interference are filtered using wound toroidal cores. Particularly in the case of higher currents, two or more toroidal cores connected in series are provided. One toroidal core is supposed to handle common-mode interference and the other toroidal core should Filter differential mode interference. However, such a structure requires a large amount of space. In addition, wound toroidal cores are complex to manufacture.

The German patent application DE 10 2010 050 828 A1 proposes a current-compensated choke comprising a core with two windings for filtering common-mode noise and differential-mode noise. For this purpose, the core has a complicated shape. A comparatively large amount of space remains.

The object of the present invention is to eliminate the disadvantages of the prior art. In particular, a compact device for filtering common mode interference and differential mode interference on electrical conductors is to be specified.

According to the invention, this object is achieved by a device according to the subject matter of claim 1 and by a motor vehicle according to the subject matter of claim 15. Advantageous refinements of the invention are specified in the dependent claims.

According to the invention, the device for filtering common mode interference and differential mode interference for a plurality of electrical conductors. The electrical conductors are each individually surrounded in one section by a first core. The first cores are preferably designed as first ring cores. The features described below for the first cores can therefore also apply to first toroidal cores. The first cores are preferably closed. In this case, the first cores preferably completely surround the electrical conductors. In this section, the electrical conductors and the first cores are jointly surrounded by a second core, preferably by exactly one second core. The second core is preferably second Ring core designed. The features described below for the second core can therefore also apply to the second toroidal core. The second core is preferably closed. In this case, the second core preferably completely surrounds the electrical conductors and the first cores in this section. The first cores each have a first magnetic permeability. The first magnetic permeabilities of the respective first cores are preferably the same, alternatively they can differ at least in part. The second core has a second magnetic permeability. The second magnetic permeability is greater than each of the first magnetic permeabilities.

In the present patent application, the term “permeabilities” is used in the plural, contrary to common usage. This is intended to make it clear that each first core has a first magnetic permeability and the “first magnetic permeabilities” can differ. “First magnetic permeabilities” can therefore be understood to mean “values of the respective first magnetic permeability” or more precisely “values of the first magnetic permeability of the respective first cores”. These expressions seem too cumbersome here. Therefore, in favor of a simpler language, the term "permeabilities" is used in the plural instead.

Differing first magnetic permeabilities are preferably provided for asymmetrically occurring currents. In this case, for example, a first core with a lower first magnetic permeability and thus a higher saturation strength is provided where higher currents occur due to a load.

Surprisingly, it has been shown that both common-mode interference and differential-mode interference can be filtered with the device according to the invention. in particular without the need for coils or magnetic cores arranged one behind the other or in series on the conductors. The first cores and the second core are arranged on the electrical conductors in a common plane. The first cores and the second cores are preferably arranged in a plane transverse to the electrical conductors, in particular in alignment with one another.

The first cores and the second core are advantageously arranged one above the other, one could also say arranged essentially concentrically to one another. This represents a departure from the prior art, in which multiple cores are often arranged in series to filter common-mode interference and differential-mode interference. The device according to the invention is particularly compact and thus enables considerable space savings. Furthermore, the device according to the invention is comparatively simple to manufacture.

Common-mode interference is understood to mean electromagnetic interference signals that propagate in the same direction on connecting lines. So, for example, propagate on the outgoing line and on the return line, each with the same phase position and/or current direction.

Push-pull interference or differential mode interference is understood to mean electromagnetic interference signals which propagate in opposite directions on connecting lines, ie propagate with different phase angles and/or current directions.

The electrical conductors, which are designed as busbars, for example, can advantageously be led out parallel to one another, for example horizontally, out of the device or out of a component having the device. As a result, the electrical conductors can be contacted particularly easily. the The device can be installed in a device in a particularly simple and particularly space-saving manner.

According to an advantageous embodiment of the invention, the device comprises two, three or four electrical conductors.

The electrical conductors preferably form a power supply line. The power supply line is preferably a single-phase or three-phase power supply line. In the case of a single-phase power supply line, two electrical conductors are provided, preferably one electrical conductor for the phase and one neutral conductor. In the case of a three-phase power supply line, three electrical conductors can be provided, preferably one electrical conductor for each of the three phases. As an alternative to this, four electrical conductors can be provided in a three-phase power supply line, preferably one electrical conductor for each of the three phases and an additional neutral conductor. A single-phase and/or a three-phase power supply line should preferably be operated with alternating current. As an alternative to this, the device according to the invention can also be provided for direct current. The device preferably comprises two electrical conductors, that is to say preferably an electrical conductor for the current flowing in and an electrical conductor for the current flowing out.

According to a further advantageous embodiment of the invention, the electrical conductors are busbars or current-carrying bolts. Alternatively, the electrical conductors may each be tape, each braid, each cable, or each wire. However, the electrical conductors can also be any combination of busbars, current-carrying bolts, straps, braiding, cables and/or wires. For example, at a A total of three electrical conductors can be designed as two electrical conductors as busbars and one electrical conductor as a cable.

The electrical conductors are preferably formed from copper and/or aluminum. Busbars made of copper, which are also referred to below as copper busbars, are particularly preferred.

The electrical conductors preferably have a cross-sectional area of 10 to 1000 mm ² , particularly preferably a cross-sectional area of 50 to 200 mm ² . The electrical conductors can be, for example, two copper rails each with a cross section of 15 mm*3 mm. As a further example, the electrical conductors can be two strands with a cross-sectional area of 500 mm ² .

The first cores and the second core preferably surround the electrical conductors over a length of 5 to 100 mm, for example over a length of 20 mm.

The electrical conductors preferably run parallel or essentially parallel to one another. In particular, the electrical conductors run parallel to one another at least in the section in which the first cores and the second core are arranged. Preferably, the electrical conductors within the device are not connected to each other. In particular, the electrical conductors within the device are galvanically isolated from one another.

If the electrical conductors are designed as busbars, preferably as copper busbars, a press-in nut can be inserted into each busbar. As a result, the busbars are particularly easy to contact.

According to a further advantageous embodiment of the invention, the electrical conductors are designed for currents of 50 A, preferably for currents of 100 A, particularly preferably for currents in a range from 300 A to 5,000 A.

It goes without saying that such an electrical conductor is also suitable in particular for lower current intensities than those mentioned and can therefore be operated at lower current intensities. For example, the electrical conductor designed for currents of 50 A is also particularly suitable for currents below 50 A and can also be operated at currents below 50 A.

According to a further advantageous embodiment of the invention, the first cores are each made from a soft magnetic material, preferably from a powder composite material. The powder composite material can be an NiFe powder, iron powder, carbonyl iron powder, ferrite powder and/or FeAl powder. The latter is also known as Sendust. Alternatively, the first cores may each be made of ferrite (e.g. manganese zinc ferrite (MnZn) or nickel zinc ferrite (NiZn)) and each have at least one air gap. Furthermore, the first cores can each be made from nanocrystalline or amorphous core material, with the first cores preferably each having at least one air gap.

According to a further advantageous embodiment of the invention, the second core is made of a soft-magnetic material such as ferrite (eg manganese-zinc ferrite (MnZn) or nickel-zinc ferrite (NiZn)), NiFe, SiFe, nanocrystalline or amorphous core material. Alternatively, the second core can be made of powder composite material. The powder composite material can be an NiFe powder, iron powder, carbonyl iron powder, ferrite powder and/or FeAl powder.

According to a further advantageous embodiment of the invention, the first magnetic permeabilities are each in a range from 5 to 500, preferably each in a range from 10 to 100. According to a further advantageous embodiment of the invention, the second magnetic permeability is in a range from 500 to 150,000 , preferably in a range from 1,000 to 100,000, particularly preferably in a range from 4,000 to 50,000.

There can be a factor of 5 to 20,000 between the first magnetic permeability and the second magnetic permeability. In particular, combinations of low values of the respective first magnetic permeability with high values of the second magnetic permeability or of low values of the second magnetic permeability with high values of the respective first magnetic permeability are also possible.

As already explained above, the first cores can be configured as first toroidal cores and/or the second core can be configured as a second toroidal core. According to a further advantageous embodiment of the invention, the cross section of the first cores each form an oval, round or rectangular area, in particular an annular area, or combinations thereof in sections. According to a further advantageous embodiment of the invention, the cross section of the second core forms an oval, round or rectangular area, in particular an annular area, or a combination thereof in sections.

According to a further advantageous embodiment of the invention, the first cores are each formed in one piece or in several pieces. According to a further advantageous embodiment of the invention, the second core is designed in one piece or in several pieces.

In a one-piece construction, the first cores and/or the second core are preferably pressed as a tube. The first cores and/or the second core can be pushed from the front onto the electrical conductors, which are preferably designed as busbars or bolts. In this case, in particular, the entirety of the first cores and the second core can be pushed onto electrical conductors.

In the case of a multi-piece design, the first cores and/or the second core are preferably each slipped on around the electrical conductors, which are preferably in the form of busbars or bolts. The first cores are preferably each attached individually around one of the electrical conductors. The second core is then preferably fitted around the first cores surrounding the respective electrical conductors. In the case of a multi-part design, the first cores and/or the second core are preferably each formed as two U-cores, as two E-cores and/or as a combination of a U-core or E-core with an I-core. The two U-cores or the combination of the U-core with the I-core are put together in such a way that an axial hole is formed in which an electrical conductor or the first cores surrounding the respective electrical conductors can be accommodated. Two E-cores or the combination of an E-core with an I-core have two axial holes. The formation of a first core as two E-cores or as a combination of an E-core with an I-core therefore enables two electrical conductors to be accommodated, with one electrical conductor running through each of the two holes. Thus, the number of first cores can be reduced by one. In a device with a total of two electrical conductors, exactly one first core configured as two E cores or as a combination of an E core and an I core can surround the two electrical conductors. This configuration is also covered by the invention. Generally speaking, two can or several first cores can be formed integrally, for example in one piece in the form of an 8 or in several pieces in the form of two E-cores. According to the invention, the electrical conductors are each individually surrounded by a first core in this configuration as well.

As an alternative or in addition to this, the first cores and/or the second core can be made in several pieces in the axial direction. In this case, the first cores and/or the second core can, for example, each be composed of a plurality of pieces pressed as tubes. For example, first cores, which each surround the electrical conductors over a length of 30 mm, can be composed of three pieces each 10 mm long. A second core surrounding the electrical conductors over a length of 30 mm can be composed of three pieces each 10 mm long. These pieces can be pushed from the front onto the electrical conductors, which are preferably designed as busbars or bolts. Furthermore, the first cores and/or the second core can be formed, for example, from a plurality of pairs of U cores, from a plurality of pairs of E cores, from a plurality of U-I cores and/or from a plurality of E-I cores. The pairs can be fitted around the electrical conductors and/or around the first cores surrounding the respective electrical conductors.

Preferably, with a second magnetic permeability in a range from 500 to 2,000, the second core is configured as two U-cores, as two E-cores, as a combination of a U-core with an I-core and/or as a combination of an E- Core formed with an I core.

According to a further advantageous embodiment of the invention, the first cores form a receptacle for the second core. The receptacle can be formed by one or more indentations provided in the lateral surfaces of the first cores be. Alternatively or additionally, the receptacle can be formed by one or more elevations provided in the lateral surfaces of the first cores. The indentation, the indentations, the elevation and/or the elevations can run in the circumferential direction of the lateral surfaces of the first cores.

According to a further advantageous embodiment of the invention, the second core is applied to the first cores in a form-fitting manner. The second core is preferably attached to the first cores in a form-fitting manner.

According to a further advantageous embodiment of the invention, the second core is pushed onto the first cores in the axial direction. The axial direction preferably runs parallel to the electrical conductors.

According to a further advantageous embodiment of the invention, the device contains an insulating material between the first cores and the second core. Alternatively or additionally, the first cores and/or the second core have an insulating material on a surface.

The insulating material preferably forms an insulating layer with a thickness of 0.1 to 2 mm, particularly preferably a thickness of 0.7 to 1.0 mm, for example 0.8 mm.

The first cores and/or the second core can be completely or partially covered with insulating material.

The first cores can each be surrounded by a shrink tube or an insulating tube, for example. The shrink tubing can be formed from radiation-crosslinking polyolefin, for example. The insulating tube can, for example, a Glass fabric tubing, silicone tubing, PVC tubing, or Teflon tubing.

The second core can be embedded in plastic, in particular in epoxy resin, polyurethane resin, acrylic resin and/or silicone. The second core can be coated with one or more of these materials. The second core is preferably encased in a fluidized bed layer made of plastic, in particular epoxy resin, polyurethane resin, acrylic resin and/or silicone. Furthermore, the second core can be accommodated in a cup, preferably in a plastic cup. The plastic cup can be made of PA6.6 or PVC, for example, and/or can be made by means of plastic injection moulding. Furthermore, the second core can be placed on a pipe or hose. The tube can be formed from plastic or from glass fibers impregnated with plastic, in particular with epoxy resin. As an example, the tube may be made of FR4. The tube can be a fabric tube, preferably a glass fabric tube. The glass fabric tube can be impregnated, for example, with acrylic resin, polyurethane resin, epoxy resin, silicone and/or Teflon. The insulating material may also include resin-impregnated paper (e.g. Nomex), resin-impregnated cardboard, glass and/or tar.

If the second core is completely or partially encased with insulating material, the first cores can remain without additional insulating material if there is a sufficient distance from one another.

The first cores and the second core can be cast and/or encapsulated together with an insulating material. The first cores and the second core can be cast together, for example with silicone, PUR or epoxy resin, and/or overmoulded with plastic, for example PVC. These are the first cores and the second core is preferably fixed to one another during casting, overmolding and/or curing. The encapsulation is carried out, for example, by means of mold encapsulation.

A groove can be introduced into the insulating material surrounding the second core, preferably into the plastic cup accommodating the second core, with which a circuit board can be fixed in a defined manner. The circuit board preferably houses a capacitor assembly. The connection between the printed circuit board and the electrical conductors, preferably the busbars, particularly preferably the copper bars, can be made with low inductance by means of additional bolts, additional copper bars, additional copper strips or additional copper braids. This enables a defined, precisely positioned and reproducible assembly. This is particularly advantageous in the case of interference frequencies in the MHz range.

According to a further advantageous embodiment of the invention, the electrical conductors are each individually surrounded by a first core in a further section or in a plurality of further sections. The first cores are preferably designed as first ring cores. The features described below for the first cores can therefore also apply to first toroidal cores. The first cores are preferably closed. In this case, the first cores preferably completely surround the electrical conductors. The electrical conductors and the first cores are surrounded in one further section by a second core, preferably by exactly one second core, or in each of the several further sections by a second core, preferably by exactly one second core. surround. The second core and/or the second cores are preferably each configured as a second toroidal core. The features described below for the second core and/or the second cores can therefore also apply to the second toroidal core and/or the second toroidal cores. The second core and/or the second cores are preferably each closed. The electrical conductors and the first cores are preferably completely surrounded in one further section by a second core, preferably by exactly one second core, or in each of the several further sections are preferably completely surrounded by a second core each, preferably by exactly one each second core, surrounded.

The first cores also each have a first magnetic permeability in the further section or in the plurality of further sections. The first magnetic permeabilities of the respective first cores in the respective sections are preferably the same, but can alternatively differ at least in part. The second core and/or the second cores each have a second magnetic permeability. The second magnetic permeability in each section is preferably greater than each of the first magnetic permeabilities in the same section. Preferably, each of the second magnetic permeabilities of the entire device is greater than each of the first magnetic permeabilities.

As explained above for the "first magnetic permeabilities", the expression "second magnetic permeabilities" is also used in the plural in this context to simplify the language.

The device can therefore be configured in one or more stages. The device is preferably configured in one stage, in two stages, in three stages or in multiple stages. In a single-stage configuration, first cores and a second core are provided in only one section. In a two-stage configuration, first cores and a second core are provided in two sections. In a three-stage Configuration are each provided first cores and a second core in three sections. In particular, the two or three or more sections on the electrical conductors are arranged one behind the other or in series with one another.

A capacitor assembly, for example, can be provided between two such sections. According to a further advantageous embodiment of the invention, a capacitor assembly is provided between two consecutive sections. In particular, a capacitor assembly can be provided between successive sections. The capacitor assembly expands the device into a so-called passive L/C filter. The filter effect of the device can be further improved via the capacitor assembly; the edge steepness of the interference signals can preferably be improved by the filter.

The capacitor assembly preferably comprises one capacitor to ten capacitors, particularly preferably two or three capacitors. The capacitors can be arranged as X-capacitors between two electrical conductors, preferably between two phases. Alternatively, the capacitors can be connected with a first side to the respective electrical conductor, preferably to the respective phase, and be interconnected with a second side to form a star point. Furthermore, several capacitors can be connected in parallel.

The capacitor assembly is preferably accommodated on a printed circuit board. The printed circuit board is preferably fixed in a defined manner on the second cores provided in two consecutive sections. For this purpose, the two second cores involved preferably each have a receptacle. The circuit board shows preferably two holding devices, one holding device corresponding to one receptacle. The receptacle is preferably provided in each case in the insulating material surrounding the second core, particularly preferably in each case in the plastic cup accommodating the second core. The receptacle is preferably designed as a groove. The holding device can in each case be designed as a spring which engages in the groove. The connection between the printed circuit board and the electrical conductors, preferably the busbars, particularly preferably the copper bars, can be made with low inductance by means of additional bolts, additional copper bars, additional copper strips or additional copper braids. This enables a defined, precisely positioned and reproducible assembly. This is particularly advantageous in the case of interference frequencies in the MHz range.

The device can include such a printed circuit board with a capacitor assembly or a plurality of such printed circuit boards, each with a capacitor assembly. Preferably, a printed circuit board with a capacitor assembly can be provided between each pair of consecutive sections.

The second cores preferably each have two receptacles in order to be able to accommodate both a circuit board connecting to the preceding section and a circuit board connecting to the following section.

The first and/or second cores in the further section or in the plurality of further sections preferably each have one or more of the features discussed generally above. Individual first cores may differ or be the same in these features. The respective second cores can differ in these features or be the same.

According to a further advantageous embodiment of the invention, the first magnetic permeabilities of first cores assigned to one of the electrical conductors in different sections are the same or they differ. Alternatively or additionally, the second magnetic permeabilities of second cores provided in different sections are the same or different.

Furthermore, at least one of the first cores assigned to one of the electrical conductors in different sections can have a different first magnetic permeability, while the first magnetic permeabilities of the remaining first cores assigned to one of the electrical conductors in different sections correspond in each case. Furthermore, at least one of the second cores provided in different sections can have a different second magnetic permeability, while the second magnetic permeabilities of the remaining second cores correspond to each other.

According to the invention, a motor vehicle is also provided which includes an electric traction motor and a traction battery as well as a power converter or inverter and a device according to the invention. The traction battery can be rechargeable. The electrical conductors connect the traction motor to the power converter or inverter and this in turn to the traction battery. The motor vehicle is preferably a passenger car, in particular an electric car, a truck, a bus, a ship, a submarine, a diesel-electric locomotive or a construction machine, in particular an excavator. In the ship or submarine, for example, a ship's propulsion system or a plurality of ship's propulsion systems can comprise the device according to the invention.

Fig. 1

eine Vorderansicht, Draufsicht und perspektivische Ansicht einer ersten erfindungsgemäßen Vorrichtung mit zwei elektrischen Leitern, und

Fig. 2

eine Vorderansicht, Draufsicht und perspektivische Ansicht einer zweiten erfindungsgemäßen Vorrichtung mit drei elektrischen Leitern, und

Fig. 3

verschiedene Ansichten einer zwei Abschnitte umfassenden dritten erfindungsgemäßen Vorrichtung mit drei elektrischen Leitern.

The invention will now be explained in more detail using exemplary embodiments. Show it:

1

a front view, plan view and perspective view of a first device according to the invention with two electrical conductors, and

2

a front view, plan view and perspective view of a second device according to the invention with three electrical conductors, and

3

different views of a two-section third device according to the invention with three electrical conductors.

The figures show different exemplary embodiments of the invention. Components with the same effect are provided with the same reference symbols. The exemplary embodiments shown should not be understood as limiting, but rather serve to explain specific configurations of the invention. It is clear to the person skilled in the art that he can modify advantageous features of the described configurations within the scope of the invention defined by the claims or combine them with one another in order to arrive at further exemplary embodiments of the invention.

1 12 shows a front view (a), a plan view (b) and a perspective view (c) of a first common-mode and differential-mode noise filtering device according to the invention. The device comprises two electrical conductors 1. The electrical conductors 1 are designed as copper busbars. More precisely, a section of the two electrical conductors 1 is shown. In this section, each of the two electrical conductors 1 is connected to a first one core 2 surrounded. The two electrical conductors 1 and the two first cores 2 are surrounded by a second core 3 in this section. The two first cores 2 are the same in this exemplary embodiment and each have an identical first magnetic permeability. The first magnetic permeability is 50, for example. The second core 3 has a second magnetic permeability. The second magnetic permeability is 20,000, for example. According to the invention, the second magnetic permeability is therefore greater than the first magnetic permeability.

The second core 3 is accommodated in a plastic cup 4 . In this exemplary embodiment, the plastic cup 4 is produced from PA6.6 by means of plastic injection molding. The plastic cup 4 forms an insulating layer with a thickness of 1.0 mm as insulating material. The second core 3 is electrically insulated from the first cores 2 and the electrical conductors 1 by the plastic cup 4 . The second cores 2 are at a sufficiently large distance from one another. An additional insulating material was therefore dispensed with in the first cores 2 in this exemplary embodiment. The first cores 2 are therefore each at potential with the respective electrical conductor 1.

2 12 shows a front view (a), a plan view (b) and a perspective view (c) of a second common-mode and differential-mode noise filtering device according to the invention. The device comprises three electrical conductors 1. The electrical conductors 1 are designed as copper busbars. More precisely, a section of the three electrical conductors 1 is shown. Each of the three electrical conductors 1 is surrounded by a first core 2 in this section. The three electrical conductors 1 and the three first cores 2 are surrounded by a second core 3 in this section. The first cores 2 are each the same in this exemplary embodiment and each have an identical first core magnetic permeability. The first magnetic permeability is 50, for example. The second core 3 has a second magnetic permeability. The second magnetic permeability is 20,000, for example. According to the invention, the second magnetic permeability is therefore greater than the first magnetic permeability.

In this exemplary embodiment, the second core 3 is encased in a fluidized-bed sinter layer 5 made of epoxy resin. As an insulating material, the fluidized bed layer 5 forms an insulating layer with a thickness in a range from 0.8 mm to 1.2 mm. The second core 3 is electrically insulated from the first cores 2 and the electrical conductors 1 by the fluidized bed sinter layer 5 . In this exemplary embodiment, too, the second cores 2 are at a sufficiently large distance from one another. An additional insulating material was therefore dispensed with in the first cores 2 . The first cores 2 are therefore each at potential with the respective electrical conductor 1.

The first cores 2 and the second core 3 are advantageously arranged essentially concentrically with one another. The device according to the invention is therefore particularly compact. This enables considerable space savings. Furthermore, the device according to the invention is comparatively simple to manufacture.

3 12 shows a bottom view (a), a side view (b), a front view (c) and a perspective view (d) of a third common-mode and differential-mode noise filtering device according to the invention. The third device according to the invention comprises three electrical conductors 1. The electrical conductors 1 are designed as copper busbars. Furthermore, the third device according to the invention comprises a first section 6 and a second Section 7. In each of the two sections 6, 7, each of the three electrical conductors 1 is surrounded by a first core 2, respectively. The three electrical conductors 1 and the three first cores 2 are surrounded by a second core 3 in each of the two sections. In this exemplary embodiment, the first cores 2 are each the same and each have an identical first magnetic permeability. The first magnetic permeability is 50, for example. The two second cores 3 are also identical in this exemplary embodiment and each have an identical second magnetic permeability. The second magnetic permeability is 20,000, for example. According to the invention, the second magnetic permeability is therefore greater than the first magnetic permeability.

The second cores 3 are each accommodated in a plastic cup 4 . As in the first device according to the invention, the plastic cup 4 is produced from PA6.6 by means of plastic injection molding and, as the insulating material, forms an insulating layer with a thickness of 1.0 mm.

In addition, a groove (not shown) is made in each of the plastic cups 4 . A printed circuit board 8 is fixed in a defined manner between the first section 6 and the second section 7 with the aid of the respective groove. For this purpose, the printed circuit board 8 has a tongue (not shown) that engages in the corresponding groove. The circuit board 8 preferably accommodates a capacitor assembly with three capacitors 9 . In this case, for example, a capacitor 9 is connected between each two of the three electrical conductors 1 .

The connection between the printed circuit board 8 and the electrical conductors 1 is made with low inductance by means of three bolts 10. Each of the three electrical conductors 1 is connected to the printed circuit board 8 by a bolt 10 each.

The third device according to the invention advantageously provides a defined, precisely positioned and reproducible assembly of the capacitors 9 . This is particularly advantageous in the case of interference frequencies in the MHz range.

Reference List

1

electrical conductors

2

first cores

3

second core

4

plastic cup

5

fluidized bed layer

6

first section

7

second part

8th

circuit board

9

capacitor

10

bolt

Claims (15)

Device for filtering common-mode interference and differential-mode interference, the device comprising a plurality of electrical conductors (1), the electrical conductors (1) being individually surrounded in one section by a first core (2) each, the electrical conductors (1) and the first cores (2) in this section are collectively surrounded by a second core (3), the first cores (2) each having a first magnetic permeability and the second core (3) having a second magnetic permeability, and wherein the second magnetic permeability is greater than each of the first magnetic permeabilities. Device according to claim 1, wherein the device comprises two, three or four electrical conductors (1). Device according to Claim 1 or 2, in which the electrical conductors (1) are in each case bus bars or in each case current-carrying bolts. Device according to one of the preceding claims, wherein the electrical conductors (1) are designed for currents of 50 A, are preferably designed for currents of 100 A, particularly preferably for currents in a range from 300 A to 5,000 A are designed. Device according to one of the preceding claims, wherein the first cores (2) are each made of a soft magnetic material, preferably of powder composite material, and/or
wherein the second core (3) is made of a soft magnetic material such as ferrite, NiFe, SiFe, nanocrystalline or amorphous core material. Device according to one of the preceding claims, wherein the first magnetic permeabilities are each in a range of 5 to 500, preferably each in a range of 10 to 100, and/or
wherein the second magnetic permeability is in a range of 500 to 150,000, preferably in a range of 1,000 to 100,000, more preferably in a range of 4,000 to 50,000. Device according to one of the preceding claims, wherein the cross section of the first cores (2) each form an oval, round or rectangular area or combinations thereof in sections, and/or
wherein the second core (3) forms in cross-section an oval, round or rectangular surface or a combination thereof in sections Device according to one of the preceding claims, wherein the first cores (2) are each formed in one or more pieces, and / or
wherein the second core (3) is designed in one piece or in several pieces. Device according to one of the preceding claims, in which the first cores (2) form a receptacle for the second core (3). Device according to one of the preceding claims, wherein the second core (3) is applied to the first cores (2) in a form-fitting manner. Device according to one of the preceding claims, in which the second core (3) is pushed onto the first cores (2) in the axial direction. Device according to one of the preceding claims, wherein the device contains an insulating material between the first cores (2) and the second core (3), and/or
wherein the first cores (2) and/or the second core (3) have an insulating material on a surface. Device according to one of the preceding claims, in which the electrical conductors (1) are each individually surrounded by a first core (2) in a further section or in a plurality of further sections, the electrical conductors (1) and the first cores (2) in which one further section is jointly surrounded by a second core (3) or in each of the several further sections is jointly surrounded by a second core (3), in particular a capacitor assembly being provided between two consecutive sections, it being provided in particular that the capacitor assembly is preferably accommodated on a printed circuit board (8) which is fixed in a defined manner on the second cores provided in the two successive sections, the two second cores involved preferably each having a receptacle for this purpose and the Printed circuit board (8) preferably has two holding devices, each holding device corresponding to a respective recording. Device according to Claim 13, in which the first magnetic permeabilities of first cores (2) assigned to one of the electrical conductors (1) in different sections are the same or different, and/or
wherein the second magnetic permeabilities of second cores (3) provided in different sections are the same or different. Motor vehicle comprising an electric traction motor and a traction battery as well as a converter or inverter and a device according to one of the preceding claims, wherein the electrical conductors (1) connect the traction motor to the converter or inverter and this in turn to the traction battery, the motor vehicle preferably being a passenger car , truck, bus, ship, submarine, diesel-electric locomotive or construction machinery.

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