DE102020210516A1 - Conductor arrangement designed as a filter capacitor - Google Patents

Abstract

A conductor arrangement (10) for forming an electrically conductive connection between at least one energy source (110) and electronics (120), having at least one first line (21) for a positive potential and at least one second line (22) for a negative potential , wherein the at least one first line (21) is spaced from the at least one second line (22) by at least one insulator (23), which eliminates the need for an intermediate circuit capacitor, it is proposed that the at least one first line (21), the at least one second line (22) and the insulator (23) are formed at least in regions as a capacitor

Description

The invention relates to a conductor arrangement for forming an electrically conductive connection between at least one energy source and electronics, having at least one first line for a positive potential and at least one second line for a negative potential, the at least one first line being separated from the at least a second line is spaced. Furthermore, the invention relates to a system for transforming a DC voltage from at least one energy source to an AC voltage using power electronics.

Electric motors are usually used to drive electric vehicles. The direct voltage provided by the energy source of the electric vehicle is transformed into an alternating voltage by power electronics in order to feed an electric motor. The use of filter capacitors or so-called intermediate circuit capacitors is necessary to smooth the ripple generated in this way on the DC voltage side of the power electronics and to decouple the energy source from the power electronics.

The intermediate circuit capacitor is dimensioned according to the operating voltage of the power electronics and is arranged at the electrical input on the DC voltage side of the power electronics. For example, the intermediate circuit capacitor can be designed for an operating voltage of 400 V or 800 V. Due to disturbances and resonances, the voltage present at the intermediate circuit capacitor can exceed the voltage provided by the energy source. A targeted oversizing of the intermediate circuit capacitor is therefore necessary.

The problem with such an intermediate circuit capacitor is that as the dielectric strength of the intermediate circuit capacitor increases, the requirements on the construction and the materials increase. An intermediate circuit capacitor suitable for use in electric vehicles therefore requires a large amount of installation space and has a disadvantageous effect on the cost efficiency of the electrical system of the electric vehicle.

The invention is based on the object of creating a system and a conductor arrangement which eliminate the disadvantages mentioned above and the need for an intermediate circuit capacitor. This object is achieved by the features specified in claim 1. Further advantageous configurations of the invention are described in the dependent claims.

According to one aspect of the invention, a conductor arrangement is provided for forming an electrically conductive connection between at least one energy source and electronics.

The conductor arrangement has at least one first line for a positive potential, at least one second line for a negative potential and at least one insulator. The at least one first line is preferably spaced apart from the second line by the at least one insulator.

According to the invention, the at least one first line, the at least one second line and the insulator are shaped as a capacitor at least in regions.

In particular, the first line, the second line and the insulator can be wound up perpendicularly or transversely to a current-carrying direction in order to form an electric field. Depending on the design, the at least one insulator can be designed in the form of an electrolyte or as a solid body or solid insulator.

According to a further aspect of the invention, a system for transforming a DC voltage of at least one energy source into an AC voltage is provided by power electronics. The at least one energy source and the power electronics can be connected at least in regions by a conductor arrangement according to the invention.

By connecting the energy source to the power electronics, a direct current flows through the conductor arrangement with the first line and the second line. The corresponding potential between the first line and the second line induces an electrical charge in the at least one insulator which is opposite to the respective charge of the first line and the second line. As a result of this measure, the conductor arrangement can fulfill the function of a capacitor in addition to the function of energy transmission. As a result, the electrical connecting lines between the energy source and the power electronics and the intermediate circuit capacitor can be combined with one another. The provision of an external intermediate circuit capacitor can thus be omitted.

Depending on the number of windings and the dimensions of the first line, the second line and the insulator, different capacitances can be formed by the conductor arrangement.

The conductor arrangement can be formed with a particularly high capacitance if the at least one first line, the insulator and the at least one second line as foils or layers are formed. A material thickness of the foils can be varied depending on the operating voltage and the operating current. The first line, the insulator and the second line can be designed in the form of foils over an entire length of the conductor arrangement, which extends from the energy source to the power electronics, or over part of the overall length. This enables the capacitance provided by the conductor arrangement to be set precisely.

According to a further exemplary embodiment, the at least one first line, the insulator and the at least one second line are wound symmetrically to form an electric field orthogonally to a current-carrying direction or wound asymmetrically to form a capacitor. For example, the insulator, the first line and the second line can be designed in the form of flexible plates or foils running parallel to one another. Such an arrangement can be made more compact if the respective wires and the insulator are wound into a roll. The current-carrying direction preferably runs parallel to the winding-up direction of the conductor arrangement.

Depending on the configuration, an elastic or bendable conductor arrangement can be advantageous. For this purpose, an asymmetrical winding can enable the required elasticity of the conductor arrangement. For example, the first line, the second line and the insulator can be spirally wound in order to be able to guide the conductor arrangement past components of an electric vehicle.

The conductor arrangement can be designed in a technically particularly simple manner if the at least one first line and the at least one second line are designed as individual wires which are each sheathed by an insulator. Thin individual wires can be provided with insulation layers for this purpose. Both potentials of the first line and the second line are then intertwined to form a conductor arrangement. The capacitance of such a conductor arrangement results from the surfaces of the respective individual wires.

According to a further embodiment, the at least one first line designed as individual wires and the at least one second line are braided symmetrically or asymmetrically to form an electric field. This measure makes it possible to realize different shapes and properties of the conductor arrangement. In addition to the electrical properties, mechanical properties of the conductor arrangement can also be adjusted by the type of braiding of the individual wires.

The capacitance of the conductor arrangement can be defined in advance if the at least one first line, the insulator and the at least one second line are formed into a capacitor over an entire length of the conductor arrangement or along a section of the entire length. A total area of the lines is adjustable based on a length of the first line formed into a capacitor, the second line, and the insulator. The capacitance of the capacitor depends on this total area of the electrical lines formed into the capacitor and the insulator, so that the capacitance of the conductor arrangement can be directly influenced.

According to a further exemplary embodiment, the at least one first line and the at least one second line have a plurality of mutually parallel connection points for electrical contacting, which are arranged at the end of the overall length of the conductor arrangement, the respective connection points being electrically insulated from one another by the insulator. As a result, the conductor arrangement can be hermetically sealed by the at least one insulator. Liquid or gaseous insulators can also be used in such a conductor arrangement. To avoid short circuits between the first line and the second line, spacers or additional insulators arranged between the first line and the second line can be used.

• 1 eine schematische Darstellung eines Systems mit einer erfindungsgemäßen Leiteranordnung,
• 2 eine Schnittdarstellung einer Leiteranordnung gemäß einer ersten Ausführungsform,
• 3 eine schematische Darstellung der in 2 gezeigten Leiteranordnung in einem abgewickelten Zustand,
• 4 eine perspektivische Darstellung einer Leiteranordnung gemäß einer zweiten Ausführungsform, und
• 5 eine perspektivische Darstellung einer Leiteranordnung gemäß einer dritten Ausführungsform.

Exemplary embodiments of the invention are explained in more detail below with reference to the drawings. Show it:

• 1 a schematic representation of a system with a conductor arrangement according to the invention,
• 2 a sectional view of a conductor arrangement according to a first embodiment,
• 3 a schematic representation of the in 2 shown conductor arrangement in an unwound state,
• 4 a perspective view of a conductor arrangement according to a second embodiment, and
• 5 a perspective view of a conductor arrangement according to a third embodiment.

In the figures, the same structural elements each have the same reference numbers.

In the 1 a schematic representation of a system 100 with a conductor arrangement 10 according to the invention is shown. The system can, for example, in an electric, not shown vehicle are used to provide a drive power. For this purpose, the system 100 has an energy source 110 , power electronics 120 and an electric motor 130 .

The energy source 110 is in the form of a battery or a fuel cell, for example, and provides electrical energy in the form of a DC voltage.

The DC voltage provided by the energy source 110 is transformed by the power electronics 120 into an AC voltage suitable for the electric motor 130 . For example, the power electronics 120 can be configured as a DC/AC converter.

In order to avoid an intermediate circuit capacitor, the energy source 110 is connected to the power electronics 120 via a conductor arrangement 10 .

In this case, the conductor arrangement 10 functions both as an electrical line and as a capacitor for filtering AC voltage components on the DC voltage side of the power electronics 120.

the 2 shows a sectional view of a conductor arrangement 10 according to a first embodiment. In this case, the conductor arrangement 10 is wound symmetrically into a roll.

The respective layers of the conductor arrangement 10 include a first line 21 for a positive potential, a second line 22 for a negative potential and at least one insulator 23 which spaces the first line 21 from the second line 22 .

Preferably, the first line 21 and the insulator 23 and the second line 22 and the insulator 23 have body contact in order to induce electrical charges in the insulator 23 . As a result of this measure, the conductor arrangement 10 is formed at least in regions as a capacitor.

In the 3 is a schematic representation of the in 2 illustrated conductor assembly 10 shown in an unwound state. In particular, a construction of an exemplary layer with a foil-shaped first line 21 , a foil-shaped second line 22 and an insulator 23 arranged between the first line 21 and the second line 22 is shown.

The electrical energy from the energy source 110 can be routed through the conductor arrangement 10 along a current-carrying direction S. In the exemplary embodiment shown, the current-carrying direction S runs parallel to an axis of rotation of the conductor arrangement 10 wound up to form a roll.

A plurality of connection points 31, 32 arranged parallel to one another are provided to simplify electrical contacting between the energy source and the conductor arrangement and between the power electronics and the conductor arrangement. The respective connection points 31, 32 can be arranged at the ends of an overall length L of the conductor arrangement 10. In the exemplary embodiment shown, the section 11 of the conductor arrangement 10 formed into a capacitor extends over the entire length L of the conductor arrangement 10.

Connection points 31 of the first line 21 and connection points 32 of the second line 22 are spaced apart from one another by the insulator 23 .

the 4 shows a perspective view of a conductor arrangement 10 according to a second embodiment. In contrast to the first exemplary embodiment, the conductor arrangement 10 according to the second exemplary embodiment has a first line 21, a second line 22 and an insulator 23, which are wound asymmetrically in the form of a spiral to form a capacitor.

According to a third embodiment of the conductor assembly 10, which in the 5 is illustrated in a perspective view, the at least one first line 21 and the at least one second line 22 are designed as individual wires, which are each sheathed by an insulator 23 .

The insulator 23 for encasing the first line 21, which is designed as individual wires, and the second line 22 can consist of a plastic or of a lacquer.

In order to increase a surface area between the first line 21 and the insulator 23 and between the second line 22 and the insulator 23 and thus to adjust a capacitance of the conductor arrangement 10, a plurality of first lines 21 and second lines 22 are provided. For the sake of clarity, only a first line 21 and a second line 22 are shown.

reference list

100

system

110

energy source

120

power electronics

130

electric motor

10

conductor arrangement

11

section of the conductor arrangement formed into a capacitor

21

first line

22

second line

23

insulator

31

Connection point of the first line

32

Connection point of the second line

L

Total length of the ladder assembly

S

direction of current conduction

Claims (8)

Conductor arrangement (10) for forming an electrically conductive connection between at least one energy source (110) and electronics (120), having at least one first line (21) for a positive potential and at least one second line (22) for a negative potential, wherein the at least one first line (21) is spaced apart from the at least one second line (22) by at least one insulator (23), characterized in that the at least one first line (21), the at least one second line (22) and the Insulator (23) are at least partially formed as a capacitor. arrangement of conductors claim 1 , wherein the at least one first line (21), the insulator (23) and the at least one second line (22) are formed as foils or layers. arrangement of conductors claim 1 or 2 , wherein the at least one first line (21), the insulator (23) and the at least one second line (22) are wound symmetrically to form an electric field orthogonally to a current-carrying direction (S) or are wound asymmetrically at least in regions to form a capacitor. Conductor arrangement according to one of Claims 1 until 3 , wherein, wherein the at least one first line (21) and the at least one second line (22) are designed as individual wires, which are each sheathed by an insulator (23). arrangement of conductors claim 4 , wherein the at least one first line (21) designed as individual wires and the at least one second line (22) are braided symmetrically or asymmetrically to form an electric field. Conductor arrangement according to one of Claims 1 until 5 , wherein the at least one first line (21), the insulator (23) and the at least one second line (22) over a total length (L) of the conductor arrangement (10) or along a section (11) of the total length (L) into one Capacitor are shaped. Conductor arrangement according to one of Claims 1 until 6 , wherein the at least one first line (21) and the at least one second line (22) have a plurality of connection points (31, 32) arranged parallel to one another for electrical contacting, which are arranged at the end of the overall length (L), the respective connection points (31 , 32) are electrically insulated from one another by the insulator (23). System (100) for transforming a DC voltage from at least one energy source (110) to an AC voltage using power electronics (120), the at least one energy source (110) and the power electronics (120) being at least partially connected by a conductor arrangement (10) according to one of the preceding claims can be linked.

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