阅读说明：本技术 用于能电运行的机动车的共模-差模扼流圈 (Common-mode differential-mode choke for an electrically operated motor vehicle ) 是由 E.古迪诺卡里萨莱斯 于 2018-11-23 设计创作，主要内容包括：本发明涉及一种用于能电运行的机动车的共模-差模扼流圈(1),所述共模-差模扼流圈具有芯(4)、共模电感线圈(L1)和差模电感线圈(L2),其中所述芯具有至少两个平行地并且彼此间隔地取向的腿(6、8),其中所述两个电感线圈(L1、L2)分别围绕所述两个腿(6、8)之一卷绕。其规定：在所述两个电感线圈(L1、L2)的面向彼此的绕组区段之间的间距相应于所述电感线圈(L1、L2)其中至少之一的在相应的所述腿(6、8)的两侧的绕组区段彼此间的间距。(The invention relates to a common-mode differential-mode choke (1) for an electrically operable motor vehicle, comprising a core (4), a common-mode inductor (L1) and a differential-mode inductor (L2), wherein the core has at least two legs (6, 8) which are oriented parallel to one another and spaced apart from one another, wherein the two inductors (L1, L2) are each wound around one of the two legs (6, 8), wherein the spacing between the winding sections of the two inductors (L1, L2) which face one another corresponds to the spacing between the winding sections of at least one of the inductors (L1, L2) on both sides of the respective leg (6, 8).)

1. Common-mode differential-mode choke (1) for an electrically operable motor vehicle, having a core (4), a common-mode inductor (L1) and a differential-mode inductor (L2), wherein the core has at least two legs (6, 8) which are oriented parallel and at a distance from one another, wherein the two inductors (L1, L2) are each wound around one of the two legs (6, 8), characterized in that the spacing between the winding sections of the two inductors (L1, L2) which face one another corresponds to the spacing between the winding sections of at least one of the inductors (L1, L2) on both sides of the respective leg (6, 8).

2. A choke according to claim 1, characterized in that the core (4) has a central leg (7), wherein the central leg (7) is arranged between and spaced apart from and oriented parallel to the two legs (6, 8).

3. A choke according to one of the preceding claims, characterized in, that the three legs (6, 7, 8) have the same width (bs).

4. A choke according to one of the preceding claims, characterized in, that the three legs (6, 7, 8) are connected to each other at the ends by a first trunk leg (10).

5. A choke according to one of the preceding claims, characterized in, that the core (4) is configured in EI-shape.

6. A choke according to one of the preceding claims, characterized in, that the core (4) is configured in a UI-shape, EE-shape or UU-shape.

7. A choke according to one of the preceding claims, characterized in, that the central leg (7) ends spaced apart from the second trunk leg (10), so that an air gap (I) exists between the central leg (7) and the second trunk leg (10)_ag）。

8. Transformer having a circuit arrangement which is arranged between a high-voltage side and a low-voltage side, wherein a common-mode differential-mode choke (1) according to one of claims 1 to 7 is arranged or connected on at least one of the sides of the transformer.

Technical Field

The invention relates to a common-mode differential-mode choke for an electrically operated motor vehicle, comprising a core, a common-mode inductor and a differential-mode inductor, wherein the core has at least two legs which are oriented parallel to one another and spaced apart from one another, wherein the two inductors are each wound around one of the two legs.

The invention also relates to a transformer having a circuit arrangement which is arranged between a high-voltage side and a low-voltage side of the transformer, wherein a common-mode differential-mode choke is arranged or connected on at least one of the sides of the transformer.

Background

Common-mode differential-mode chokes of the type mentioned at the outset are already known from the prior art. Thus, for example, EP 2814151 a2 discloses an inverter with an integrated common-mode differential-mode choke having a common-mode inductor and a differential-mode inductor. The two inductors are wound on a common choke core.

In the case of electrically powered motor vehicles, i.e. in particular electric or hybrid vehicles, energy is transmitted from a high-voltage network or a high-voltage battery pack into a low-voltage network, which typically has a maximum voltage of 12 volts. This is usually achieved using a single-phase dc voltage converter. The single-phase transformer converts the primary voltage (high-voltage) to the secondary side (low-voltage) and ensures the necessary electrical separation between the two voltage networks, in order to ensure personal protection in particular. The alternating voltage on the secondary side is then rectified by means of a rectifier diode or by means of a synchronous rectifier. In order to reduce the ripple of the output voltage, it is furthermore known: a smoothing choke and a smoothing capacitor are used.

Since the transformer only transmits an alternating voltage, the high-voltage direct voltage must first be converted into an alternating voltage or a voltage that varies in time. Usually, high-voltage switches, in particular semiconductor switches, take on this task. The high-voltage switch, in particular the semiconductor switch, is controlled in such a way that, during the conduction phase, a total input voltage is applied to the primary winding of the transformer and a secondary voltage is induced. After the conduction phase, the switch is opened and the voltage on the primary winding is 0 volts. After the down time, two other switches are actuated in this way: the total input voltage is now applied to the primary inductance, but with the opposite polarity. Thus, the transformer is operated with an alternating voltage. The transformer may also be operated with pulsed dc voltage. In this case, it must be ensured that: the transformer is demagnetized and no saturation of the magnetic material occurs. To achieve high efficiency, the switch is brought very quickly from the blocking state to the conducting state and vice versa. By switching quickly, the switching losses of the switch are minimized and the speed of voltage and current changes is increased. Such faster voltage and current changes, in combination with parasitic electrical components, electrical components and mechanical configurations of the circuit board, result in higher power-related interference and electromagnetic interference emissions. The maximum value of the power-related disturbances fed into the high-voltage network and the low-voltage network by the dc voltage converter is specified and must not be exceeded. By using a filter (EMF filter) that is suitable for electromagnetic compatibility, this interference can be reduced to such an extent that the device meets all specification requirements. Line-related interference is subdivided into common mode interference and differential mode interference. Common Mode inductance or Common-Mode inductance (CMC) or Common Mode inductor reduces Common Mode interference, while differential Mode inductance (DMC) or differential Mode inductor reduces differential Mode interference. Typically, EMF direction filters require both inductance types, as both interference modes occur in common. In practice, the two inductors are usually used as two physically separate distinct devices. However, it is already known from the above-mentioned publications: these two inductances are combined in the device.

Disclosure of Invention

The common mode-differential mode choke coil according to the invention has the following advantages: these inductances, which are arranged on the same choke core and function without affecting the electrical or magnetic properties of the common-mode and differential-mode inductors, can be adjusted precisely. By integrating the two inductors, the installation space is reduced and the choke and in particular the transformer with the choke are thus made compact. In addition, manufacturing costs are reduced and manufacturing steps are reduced. By precisely adapting the two inductances, the EMV characteristic of the choke and thus of the circuit with the choke is also improved. According to the invention, provision is made for: the distance between the winding sections of the two inductor coils facing each other corresponds to the distance between the winding sections of at least one of the inductor coils on both sides of the respective leg. The choke according to the invention therefore has a defined distance of the two coils from one another at their winding sections facing one another. In this case, the distance corresponds to the distance between the winding sections of the same inductor winding on both sides of the assigned leg that face away from each other and thus to the inner diameter of the respective inductor winding. By advantageously selecting this distance, it is possible to particularly precisely adjust the inductances of the two inductors and thus to ensure optimized operation of the circuit with the choke or of the common-mode differential-mode choke.

According to a preferred embodiment of the invention, it is provided that the core has a central leg which is arranged between the two legs already mentioned. The three legs preferably lie side by side in the same plane, wherein the third leg is also oriented/arranged at a distance from the other two legs, in particular parallel. The third leg thus projects at least in sections through the space between the two inductors. The magnetic field guidance and thus the effect of the choke are improved by the third leg.

Particularly preferably, the three legs have the same width or the same cross section. This results in a particularly advantageous design of the common-mode differential-mode choke. The aforementioned advantageous spacing of the inductors from one another is automatically achieved by the central leg also being as wide as the outer leg. It has hitherto been customary to make the central leg, in the case of comparable chokes, at least twice as wide as the two outer legs, and to make the central leg narrower, i.e. exactly as wide as the outer legs, in this case, so that an advantageous adjustment of the inductance results.

Furthermore, it is preferably provided that: the three legs are connected to each other at the ends by a first trunk leg. This results in a core with an E-shaped configuration having a favorable magnetic flux.

Furthermore, it is preferably provided that: at least the outer legs are connected to one another at the other end by a second trunk leg, which in particular forms an I-shaped core. In this way, a free space is provided between the two main legs, which free space serves to accommodate the winding sections of the inductor winding facing one another. The third leg or the central leg, which extends for example up to the second trunk leg, also projects into the free space, so that the free space is subdivided by the central leg into two free spaces. The core is generally formed by the second trunk leg, in particular EI-shaped here.

Alternatively, the core is preferably constructed in a UI-shape, EE-shape or UU-shape, depending on whether the core has three legs or only two legs. This results in further areas of application for advantageous chokes.

According to a preferred embodiment, the central leg terminates spaced apart from the second trunk leg, so that an air gap is present between the central leg and the second trunk leg. The size of the air gap determines the size of the inductor. By shortening the central leg, it is thus possible in a simple manner to adapt the inductance to different application situations. In one extreme, the central leg extends up to the second trunk leg, and in the other extreme, the leg length of the central leg is equal to zero, thereby turning the E-shaped core into a U-shaped core. These inductances obtain their own maximum if the air gap is bridged completely by the central leg up to the second main leg, i.e. the size of the air gap is equal to zero. These inductances obtain their own minimum if the air gap between the central leg and the second backbone leg is at a maximum. In the latter case, the leakage inductance depends mainly on the geometric arrangement of the windings with respect to each other.

The inverter according to the invention with the features of claim 8 is distinguished by a common-mode-differential-mode choke according to the invention. This yields the advantages already mentioned. Further advantages and preferred features and feature combinations result, in particular, from the content of the preceding description and from the claims.

Drawings

In the following, the invention shall be further elucidated on the basis of the drawings. For this purpose:

fig. 1 shows a circuit diagram of an integrated common-mode differential-mode choke; and

fig. 2A and B show an embodiment of a common mode choke.

Detailed Description

Fig. 1 shows a circuit diagram of a common-mode differential-mode choke 1, which is realized in components, in a simplified illustration, the choke 1 having inductors L1, L2 and L0 DM, wherein these inductors L1, L DM are connected in parallel with an inductor L2, a first voltage is dropped by a capacitor CX1 assigned to the high-voltage network and a voltage on the low-voltage side is dropped by two further capacitors CY, wherein a ground connection is located between the two further capacitors CY, the choke is connected here in particular to the circuit of a transformer, which is not further shown here, the coils L1 and L2 and L DM form a common-mode choke CMC, and the coils L1 and L DM form a differential-mode choke DMC.

Fig. 2A and 2B show an exemplary embodiment of a choke 1 in a simplified illustration, wherein fig. 2A shows the dimensioning and fig. 2B shows the magnetic stray field of the choke 1.

The construction of the choke 1 in planar technology is shown here. This configuration can also be applied to an inductor wound with a wire. The EI core shape of the core 3 of the choke coil 1 is shown in the figure. The core 3 thus has an E-shaped core 4 and an I-shaped core 5. The E-shaped core 4 has three legs 6, 7 and 8 which are oriented parallel and spaced apart from one another and project from a trunk leg 9, giving rise to the E-shape. The I-shaped core 5 is opposite the E-shaped core 4, so that the I-shaped core 5 is parallel to the trunk legs 4 and forms itself a second trunk leg 10, which lies on the end side on the outer legs 6 and 8, so that a touching contact is present between the legs 8, 9 and the trunk leg 10 or the I-shaped core 5.

The central leg 7 between the legs 6 and 8 is designed in a shortened manner, so that it follows thatAir gap l_ag. The air gap l_agHere according to the present embodiment, is smaller than the length IF of the legs 6, 8 located on the outside.

The legs 6, 7 and 8 each have the same width bs, so that the spacing of the winding sections of the coils L and L facing each other in the E-core 9 at their sides facing each other is exactly as large as the inner diameter of the coils on the respective legs 6, 8.

In operation, the fields or magnetic fluxes shown in fig. 2B are derived here, the main current flows through these windings, resulting in a main magnetic field H, to which, in addition, each inductor winding L1, L2 has its own stray field L1S or L2S, respectively, which does not flow through the other inductor windings, the main magnetic field H being generated by the main inductor L H and the stray fields being generated by the respective leakage inductancesAnd then generated.

By targeted adjustment of the air gap l_agThe inductance L DM and L CM is also changed by changing k, the inductance L DM and L H reaches its maximum value in the case of an air gap lag =0, whereas the inductances L DM and L H have their minimum value in the case of an air gap lag = IF, in this case, the central leg 7 disappears completely and the I core 4 has hitherto become a U core or U-shaped core, the leakage inductance in this case depends primarily on the geometric arrangement of the windings or inductors L, L with one another, depending on the core geometry and material, the value of L H changes by approximately 20% of the minimum value over the change in the total length of the air gap lag, on the contrary, the value of the inductance L DM changes by approximately 8000% of the total length of the air gap lag, in the case of very different values of the inductance under consideration, the maximum energy of the adjustment of the differential mode choke reaches a value of approximately equal value, the common mode inductance H is assumed to be constant, the common mode inductance H is also assumed to be able to be determined by taking into account the common mode inductance value H > 100 μSaturation of the magnetic material.

Choke 1 can also be realized with two E-cores or two U-cores or a combination of U1-the turns of inductors L1 and L2 are not wound around leg 7 in the center of the cores as is common, these turns are wound around outer legs 6, 8 respectively-which improves the leakage inductance of the common mode choke. In this configurationAnd the main inductance L h corresponds to the common mode inductance L CM, so L h = L CM applies.

In the case of high-voltage applications, a further advantage emerges, since the two windings or inductors L1, L2 are not stacked one on top of the other but are arranged side by side at a distance, since the insulation requirements can be met without difficulty.