The invention relates to a capacitor, particularly an intermediate circuit capacitor for a multi-phase system, having a plurality of capacitor elements of identical design, which are mutually connected in parallel and/or in series and, in combination, constitute the capacitor, wherein at least one interspace is constituted between the capacitor elements.
In power electronics, a plurality of electrical networks are energetically bonded to a common DC voltage level by means of electrical capacitors in an intermediate circuit of converters. As a result of the repeated execution of switching operations, high frequency-related power losses are associated with the alternating phase currents.
Intermediate circuit capacitors comprise a plurality of capacitor elements which are connected in parallel and which, in combination, constitute the intermediate circuit capacitor. In intermediate circuit capacitors for drive system inverters, foil capacitors in the form of “flat windings” are currently employed, as intermediate circuit capacitors based upon flat windings are significantly simpler and more cost-effective to produce than capacitors produced, for example, by stitching technology, in which cuboid capacitor elements are employed.
According to the invention, a capacitor, particularly an intermediate circuit capacitor for a multi-phase system, is proposed. The capacitor comprises a plurality of capacitor elements of identical design. The capacitor elements of identical design are mutually connected in parallel and/or in series and, in combination, constitute the capacitor. At least one interspace is constituted between the capacitor elements. According to the invention, at least one intermediate capacitor element is arranged in the interspace, which is connected in parallel with the capacitor elements and thus, in combination with the capacitor elements, constitutes the capacitor.
The employment of flat windings as capacitor elements for intermediate circuit capacitors is associated with a disadvantage, in that available structural space for intermediate circuit capacitors is not optimally exploited, on the grounds that vacant interspaces are present between the individual flat windings in the intermediate circuit capacitor, dictated by the geometrical arrangement thereof. In comparison with the prior art, the capacitor according to the invention provides an advantage, in that available structural space for the capacitor can be optimally exploited and, with minimum structural space, a maximum capacitance density of the capacitor can be achieved. It is thus further permitted that, in the available structural space, loss resistance, and thus the losses generated, are minimized. Moreover, the maximum winding temperature is reduced accordingly, thus permitting an increased current-carrying capacity at an equal winding temperature. The EMC performance of the drive system is further improved by the present invention.
According to one advantageous exemplary embodiment, it is provided that the at least one intermediate capacitor element assumes a smaller volume than each of the capacitor elements. An intermediate capacitor element thus configured can, to some extent, advantageously occupy the resulting interspaces between the capacitor elements, and thus advantageously increase the overall capacitance of the capacitor.
According to one advantageous exemplary embodiment, it is provided that the capacitor elements are in mutual contact. The capacitor elements, for example, are packed in a compact arrangement and engage in mutual contact at various points. For example, the capacitor elements can be stacked and/or arranged next to one another.
According to one advantageous exemplary embodiment, it is provided that the capacitor elements are configured in the form of foil capacitors, and particularly as flat windings. Foil capacitors comprise thin metal foils, which are separated by insulating foils the form of a dielectric material. The foils are wound, as a result of which high capacitance values are achieved in limited structural volumes. By the winding of foils, the foil capacitor assumes the form of a winding. Foils are thus wound cylindrically about a winding axis, such that a round cylindrical winding is produced. If the round winding is compressed, to some extent, in the radial direction, a “flat winding” is produced. A capacitor element which is described as a round winding assumes a circular cross section, perpendicularly to the winding axis about which the foils are wound. A capacitor element which is described as a flat winding assumes an oval-shaped cross section, or a cross section in the shape of a quadrilateral with rounded corners, perpendicularly to the winding axis about which the foils are wound.
According to an advantageous exemplary embodiment, it is provided that the intermediate capacitor element is configured in the form of a foil capacitor, particularly as a round winding. If the capacitor elements are configured as flat windings, and the latter are of an identical design and are tightly packed, an intermediate capacitor element which is configured in the form of a round winding can be adapted, in an advantageously simple manner, to an interspace between mutually adjoining capacitor elements, for example to an interspace between four capacitor elements.
According to an advantageous exemplary embodiment, it is provided that, between the plurality of capacitor elements, a plurality of interspaces are configured, wherein an intermediate capacitor element is arranged in each of the interspaces. Accordingly, all the interspaces between the capacitor elements are employed, thereby increasing the capacitance of the capacitor with an equal overall structural space for said capacitor.
According to an advantageous exemplary embodiment, it is provided that an interspace is arranged between four capacitor elements respectively, wherein an intermediate capacitor element is arranged between said four capacitor elements. If the capacitor elements, particularly capacitor elements of identical design, for example in the form of flat windings, are tightly packed, such that a plurality of rows, each comprised of a plurality of capacitor elements, are arranged one above another, thereby resulting in a compact packing of capacitor elements, one interspace is constituted respectively between each four capacitor elements, as a result of the non-cuboid shape of the capacitor elements, which are configured in the form of foil capacitors. If the capacitor elements are arranged in this manner, and the interspaces are occupied by intermediate capacitor elements, this results overall in a particularly compact packing of the capacitor elements and intermediate capacitor elements in the capacitor.
According to an advantageous exemplary embodiment, it is provided that the intermediate capacitor element engages in contact with each of the four capacitor elements in the interspace. It is thus ensured, firstly, that the interspace is occupied to the maximum possible extent and, secondly, that heat is distributed effectively and uniformly through the capacitor at the same time, by means of said contact.
According to an advantageous exemplary embodiment, it is provided that the capacitor elements, with respect to their longitudinal axes, are arranged in parallel with one another. The term “longitudinal axes” describes the axes along which the capacitor elements extend with a constant cross section. In the case of foil capacitors in the form of flat windings or round windings, the longitudinal axes are the winding axes about which the foils of the foil capacitor are wound. This results in a particularly dense packing of the capacitor elements, and thus a particularly high overall capacitance of the capacitor.
According to an advantageous exemplary embodiment, it is provided that the intermediate capacitor element, with respect to its longitudinal axis, is arranged parallel to the longitudinal axes of the capacitor elements. This results in a particularly dense packing of the capacitor elements and the intermediate capacitor elements, and thus a particularly high overall capacitance of the capacitor.
An exemplary embodiment of the invention is represented schematically in the drawing, and is described in greater detail in the following description. In the drawing:
In the context of the present application, a capacitor element 10 is understood as a structure which, in isolation, can constitute a capacitor. Various capacitor technologies such as, for example, stacked capacitors, round-wound capacitors or flat-wound capacitors can be employed as capacitor elements 10.
In the exemplary embodiments, the capacitor elements 10 are configured in the form of foil capacitors. Foil capacitors comprise thin metal foils, which are separated by insulating foils in the form of a dielectric material. The foils are wound, as a result of which high capacitance values are achieved in limited structural volumes. By the winding of foils, the foil capacitor assumes the form of a winding. Foils are thus wound cylindrically about a winding axis, such that a round cylindrical winding is produced. If the round winding is compressed, to some extent, in the radial direction, a “flat winding” is produced. A capacitor element which is described as a round winding assumes a circular cross section, perpendicularly to the winding axis about which the foils are wound. A capacitor element which is described as a flat winding assumes an oval-shaped cross section, or a cross section in the shape of a quadrilateral with rounded corners, perpendicularly to the winding axis about which the foils are wound. The capacitor elements 10 represented in the exemplary embodiments according to
As represented in
The capacitor elements 10 are arranged such that their longitudinal axes L are oriented parallel to one another. In
The capacitor elements 10 which, in combination, constitute the capacitor 1, are all mutually connected in parallel, such that the capacitances of the individual capacitor elements 10 are added together. For the electrical contact-connection of the capacitor elements 10, in the present exemplary embodiment, the capacitor elements 10 are contact-connected at one end face, in an electrically conductive manner, to a first voltage level 2 and, at the second end faces of the capacitor elements 10 which are arranged opposite the first end faces of the capacitor elements 10, are contact-connected to a second voltage level. The capacitor elements 10 are thus arranged, for example, between the first voltage level 2 and the second voltage level. The capacitor 1 can be electrically contact-connected to the first voltage level 2 by means of electric terminals, and electrically contact-connected to the second voltage level by means of electric terminals. The capacitor elements 10 can be referred to as “main” capacitor elements to distinguish them from the “intermediate” capacitor elements described below.
The intermediate capacitor elements 30, for example, are of an identical design, and one intermediate capacitor element 30 assumes a smaller volume than one capacitor element 10. Accordingly, one intermediate capacitor element 30 also assumes a lower capacitance than one capacitor element 10.
In this exemplary embodiment, the intermediate capacitor elements 30 are configured in the form of foil capacitors. The intermediate capacitor elements are preferably configured as round windings, as these can be inserted particularly effectively into the interspaces 20 between the capacitor elements 10.
If the capacitor 1 in the present exemplary embodiment is constituted of capacitor elements 10 in the form of flat windings, this produces interspaces 20 in which intermediate capacitor elements 30 of circular cross section can be particularly effectively inserted, and which occupy the interspace 20 in a particularly effective manner. Accordingly, a particularly high overall capacitance of the capacitor 1 can be achieved, with an equal structural space.
As represented in
The intermediate capacitor elements 30 are preferably configured in the form of foil capacitors, and particularly as round windings. The intermediate capacitor elements 30 thus assume a cylindrical shape, with a circular cross section.
The intermediate capacitor elements 30 are arranged such that their longitudinal axes Z are oriented in parallel with the longitudinal axes L of the capacitor elements 10. In
Naturally, further forms of embodiment and combined forms of the exemplary embodiments represented are also possible.
Number | Date | Country | Kind |
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10 2019 203 843.3 | Mar 2019 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/053527 | 2/12/2020 | WO | 00 |