DE202023106056U1 - Power converter arrangement - Google Patents

Abstract

Power converter arrangement, comprising:
a body part (2);
an electrical power converter including a DC voltage terminal and configured to convert electrical energy from one form to another, the electrical power converter comprising at least one power converter element (4);
a direct current circuit which is electrically connected to the direct voltage connection of the electric power converter in the operating mode of the power converter arrangement, the direct current circuit comprising at least one capacitor (6) which is designed to slow down voltage fluctuations in the direct current circuit;
a first wall (11), which is designed to be in the operating position in the operating mode of the power converter arrangement, the first wall (11) protecting at least one capacitor (6), characterized in that the power converter arrangement comprises a first hinge, by means of which the first wall (11) is designed to pivot with respect to the body part (2) about a first axis of rotation (pivl) between the operating position and a first mounting position, and at least one capacitor (6) is so attached to the first wall (11). that at least one capacitor (6) is designed to pivot together with the first wall (11).

Description

Background of the invention

The invention relates to a power converter arrangement according to the preamble of independent claim 1.

A problem with a known power converter arrangement is that replacing at least one capacitor in the DC circuit is complex.

Brief description of the invention

It is an aim of the invention to develop a power converter arrangement with which the aforementioned task can be solved. The object of the invention is achieved by a power converter arrangement characterized by what is disclosed in the independent claim. Preferred embodiments of the invention are disclosed in the dependent claims.

The invention is based on providing the power converter assembly with a first hinge by means of which a first wall is formed to pivot with respect to the body part about a first axis of rotation between an operating position and a first mounting position, and at least one capacitor is thus mounted on the first wall that at least one capacitor is designed to pivot with the first wall.

The advantage of the power converter arrangement according to the invention is that the ability to pivot the first wall to the first installation position makes it easier to reach the capacitors of the DC circuit.

In one embodiment, the first hinge of the power converter assembly includes a first hinge pin that is designed to be releasable such that releasing the first hinge pin allows the first wall to be released from the body part. This embodiment allows the at least one capacitor and associated components to be easily detached from the body part as a single unit.

Brief description of the drawings

• 1 eine Stromrichteranordnung gemäß einer Ausführungsform der Erfindung in einem Betriebsmodus zeigt;
• 2 die Stromrichteranordnung von 1 in einem ersten Wartungsmodus zeigt; und
• 3 die Stromrichteranordnung von 1 in einem zweiten Wartungsmodus zeigt.

The invention will now be described in further detail in connection with preferred embodiments and with reference to the accompanying drawings, in which:

• 1 shows a power converter arrangement according to an embodiment of the invention in an operating mode;
• 2 the power converter arrangement of 1 in a first maintenance mode; and
• 3 the power converter arrangement of 1 in a second maintenance mode.

Detailed description of the invention

1 shows a power converter assembly that includes a body part 2, an electrical power converter, a DC circuit, an AC filter, a first wall 11, a second wall 12 and a third wall 13. The electrical power converter has a DC voltage connection and a first AC voltage connection. The electrical power converter is designed to convert electrical energy from one form to another. In 1 the power converter arrangement is in operating mode.

The first wall 11 is designed to pivot by means of the first hinge with respect to the body part 2 about a first axis of rotation piv1 between the operating position and the first mounting position. The second wall 12 is pivotally attached to the body part 2 by a second hinge, and the third wall 13 is pivotally connected to the second wall 12 by a third hinge. The axis of rotation piv2 of the second hinge and the axis of rotation piv3 of the third hinge are parallel to the first axis of rotation piv1. A first body part wall 21 of the body part 2 is a flat wall that extends in a plane defined by the first axis of rotation piv1 and the axis of rotation piv2 of the second hinge.

In 1 are the first wall 11, the second wall 12 and the third wall 13 each in their own operating positions. The second wall 12 and the third wall 13 are flat walls with an angle of 90° between them in their operating positions.

2 shows the power converter arrangement of 1 in the first maintenance mode, where the first wall 11 is in the first mounting position, the second wall 12 is at an angle of 90 ° with respect to its operating position with respect to the body part 2, and the third wall 13 in the same plane with the second wall 12 is. The pivot angle between the operating position of the first wall 11 and the first mounting position is 90° with respect to the body part 2.

In an alternative embodiment, the pivot angle of the first wall between the operating position and the first mounting position is greater than or equal to 70°. In a further alternative embodiment, the second wall is designed to pivot at least 80° with respect to the body part, and the third wall is designed to pivot at least 80° with respect to the body part to pivot at least 80° in relation to the second wall.

The electrical power converter includes a control unit 909 and three power converter elements 4. The control unit 909 is designed to control the power converter elements 4. Each power converter element 4 includes several controllable semiconductor switches that are connected in a bridge connection.

The direct current circuit includes eighteen capacitors 6, which are designed to slow down voltage fluctuations in the direct voltage circuit in the operating mode of the power converter arrangement. In addition, the direct current circuit includes a plurality of leakage resistors 76, which are designed for an electrical connection to the capacitors 6.

The capacitors 6 and the bleeder resistors 76 are connected to the first wall 11 such that the capacitors 6 and the bleeder resistors 76 are designed to rotate together with the first wall 11. The capacitors 6 are attached to the first wall 11 via capacitor holders.

The AC filter consists of three inductors 8. In the operating mode of the power converter arrangement, the AC filter is electrically connected to a first AC connection of the electrical power converter.

Each capacitor 6 is a cylindrical electrolytic capacitor with a capacity of 4000 µF. In alternative embodiments, the DC circuit includes at least one capacitor with a capacity greater than or equal to 500 µF.

The first wall 11 comprises a first wall section 111 and a second wall section 112, which are at a wall angle to one another. The wall angle is defined around an axis parallel to the first axis of rotation piv1. The wall angle is 90°. In an alternative embodiment, the wall angle is greater than or equal to 60° and less than or equal to 120°.

The first wall section 111 and the second wall section 112 are flat wall sections. The first hinge is arranged between the body part 2 and the first wall section 111. When the first wall 11, the second wall 12 and the third wall 13 are in their operating positions, the second wall portion 112 and the third wall 13 are arranged in the same plane so that they are bounded by each other.

1 and 2 show that the first wall 11 is designed in its operating position to protect the capacitors 6 so that the first wall 11 surrounds the capacitors 6 on two sides. The central axes of the capacitors 6 are perpendicular to the second wall section 112. Show additionally 1 and 2 that the power converter elements 4 and the inductors 8 are arranged in the operating mode of the power converter arrangement between the first axis of rotation piv1 and the axis of rotation piv2 of the second hinge. In other words, in the operating mode of the power converter arrangement, projections of the power converter elements 4 and the inductors 8 are arranged in a plane defined by the first axis of rotation piv1 and the axis of rotation piv2 of the second hinge between the first axis of rotation piv1 and the axis of rotation piv2 of the second hinge.

In the in 2 In the first maintenance mode shown, the first wall 11 allows access to the capacitors 6. In addition, in the first maintenance mode, the second wall 12 and the third wall 13 allow access to the control unit 909 and to the inductors 8.

3 shows the power converter arrangement of 1 in a second maintenance mode. The second maintenance mode is different from that in 2 shown first maintenance mode in that the first wall 11 was pivoted further by 90 ° with respect to the body part 2, so that the first wall 11 is in a second assembly position.

In the operating mode of the power converter arrangement, the capacitors 6 are electrically connected to the power converter elements 4 via a positive DC busbar 91 and a negative DC busbar 92, so that the positive DC busbar 91 is electrically connected between the positive terminals of the capacitors 6 and the positive terminals of the power converter elements 4, and the negative DC bus bar 92 is electrically connected between the negative terminals of the capacitors 6 and the negative terminals of the power converter elements 4. In the operating mode of the power converter arrangement, the positive DC bus bar 91 is in contact with the positive terminals of the capacitors 6, and the negative DC bus bar 92 is in contact with the negative terminals of the capacitors 6.

3 shows that the planes defined by the positive DC bus bar 91 and the negative DC bus bar 92 are parallel to each other as well as to the second wall section 112. The capacitors 6 are arranged between the second wall section 112 and the negative DC bus bar 92. The positive DC bus bar 91 and the negative DC bus bar 92 are so ver with the first wall 11 tied in that the positive DC bus bar 91 and the negative DC bus bar 92 are designed to pivot together with the first wall 11.

The positive DC bus bar 91 and the negative DC bus bar 92 are connected to the first wall 11 via the capacitors 6 and the bus bar clips. The leakage resistors 76 are connected to the positive DC busbar 91 and the negative DC busbar 92 via leakage resistor fasteners.

The first hinge includes the first hinge pin, which is designed to be detachable, so that releasing the first hinge pin allows the first wall 11 to be detached from the body part 2. Together with the first wall 11, the capacitors 6, the leakage resistors 76, the positive DC bus bar 91 and the negative DC bus bar 92 are designed to be released.

Detaching the first wall 11 from the body part 2 requires disconnecting the electrical connection between the capacitors 6 and the power converter elements 4. This is done by opening at least one electrical connection between the capacitors and the power converter elements. In one embodiment, at least one electrical connection between the capacitors and the power converter elements is designed to be opened manually, with the first wall being in the first installation position. In an alternative embodiment, at least one electrical connection between the capacitors and the power converter elements is designed to open automatically when the first wall is pivoted from the operating position into the first mounting position. In this alternative embodiment, at least one electrical connection between the capacitors and the power converter elements is additionally designed to close automatically when the first wall 11 is pivoted from the first mounting position into the operating position.

The electrical converter of the converter arrangement of 1 includes a frequency converter. In alternative embodiments, the electrical power converter of the power converter arrangement comprises an inverter, a rectifier or a DC-DC converter.

It will be apparent to those skilled in the art that the basic idea of the invention can be implemented in many different ways. The invention and its embodiments are therefore not limited to the examples described above, but may vary within the scope of the claims.

Claims (10)

Power converter arrangement comprising: a body part (2); an electrical power converter including a DC voltage terminal and configured to convert electrical energy from one form to another, the electrical power converter comprising at least one power converter element (4); a direct current circuit which is electrically connected to the direct voltage connection of the electric power converter in the operating mode of the power converter arrangement, the direct current circuit comprising at least one capacitor (6) which is designed to slow down voltage fluctuations in the direct current circuit; a first wall (11), which is designed to be in the operating position in the operating mode of the power converter arrangement, the first wall (11) protecting at least one capacitor (6), characterized in that the power converter arrangement comprises a first hinge, by means of which the first wall (11) is designed to pivot with respect to the body part (2) about a first axis of rotation (pivl) between the operating position and a first mounting position, and at least one capacitor (6) is so attached to the first wall (11). that at least one capacitor (6) is designed to pivot together with the first wall (11). Power converter arrangement according to Claim 1 , wherein the power converter arrangement comprises: a positive DC busbar (91), which in the operating mode of the power converter arrangement is designed to be electrically connected between a positive terminal of at least one capacitor (6) and a positive terminal of at least one power converter element (4); a negative DC busbar (92), which in the operating mode of the power converter arrangement is designed to be electrically connected between a negative connection of at least one capacitor (6) and a negative connection of at least one power converter element (4); wherein the positive DC busbar (91) and the negative DC busbar (92) are connected to the first wall (11) such that the positive DC busbar (91) and the negative DC busbar (92) are formed together with the first wall (11) to pivot. Power converter arrangement according to Claim 1 or 2 , whereby the power converter arrangement is at least a bleeder resistor (76) which is designed to be electrically connectable to at least one capacitor (6), at least one bleeder resistor (76) is connected to the first wall (11) in such a way that at least one bleeder resistor (76) is formed, together with the to pivot the first wall (11). A power converter assembly according to any one of the preceding claims, wherein the first hinge comprises a first hinge pin which is designed to be releasable such that release of the first hinge pin allows the first wall (11) to be released from the body part (2). Power converter arrangement according to any one of the preceding claims, wherein a capacitance of at least one capacitor (6) of the direct current circuit is greater than or equal to 500 µF. Power converter arrangement according to any one of the preceding claims, wherein a pivot angle between the operating position and the first mounting position is greater than or equal to 70°. Power converter arrangement according to any one of the preceding claims, wherein the first wall (11) comprises a first wall section (111) and a second wall section (112) at a wall angle with respect to one another, the wall angle being defined about an axis parallel to the first axis of rotation (pivl). and the wall angle is greater than or equal to 60° and less than or equal to 120°. A power converter assembly according to any one of the preceding claims, wherein the power converter assembly comprises a second wall (12) pivotally attached to the body portion (2) by a second hinge, and a third wall (13) pivotally attached to the second by a third hinge Wall (12) is attached, the axis of rotation (piv2) of the second hinge and the axis of rotation (piv3) of the third hinge being parallel to the first axis of rotation (pivl). Power converter arrangement according to Claim 8 , wherein the second wall (12) is configured to pivot at least 80° with respect to the body part (2), and the third wall (13) is configured to pivot at least 80° with respect to the second wall (12). sway. Power converter arrangement according to Claim 8 or 9 , wherein the electric power converter has a first AC voltage connection, and the power converter arrangement comprises an AC voltage filter which is electrically connected to the first AC voltage connection of the electric power converter in the operating mode of the power converter arrangement, wherein the AC voltage filter comprises at least one inductor (8), wherein at least one power converter element (4 ) and at least one inductor (8) are arranged between the first axis of rotation (pivl) and the axis of rotation (piv2) of the second hinge.

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