Laminated round busbar for capacitor mounting, suitable for high-frequency applications

DE602021056096T2Active Publication Date: 2026-06-24TDK ELECTRONICS AG

Patent Information

Authority / Receiving Office
DE · DE
Patent Type
Patents
Current Assignee / Owner
TDK ELECTRONICS AG
Filing Date
2021-11-17
Publication Date
2026-06-24

AI Technical Summary

Technical Problem

Conventional capacitors with flat band connections face limitations in high frequency applications due to high equivalent series inductance (ESL), high and frequency-unstable equivalent series resistance (ESR), and non-homogeneous internal current distribution, leading to restricted operation bandwidth and internal resonances.

Method used

A laminated, overlapped bus bar with insulated layers is integrated within the capacitor, featuring a round shape and extending along the outer side of winding elements, providing a short and equilibrated electric connection, reducing parasitic inductances and resistances, and ensuring homogeneous current distribution.

Benefits of technology

The laminated bus bar design achieves low ESL, frequency-stable ESR, and homogeneous current distribution, enhancing electrical performance and avoiding internal resonances, while maintaining compact dimensions suitable for high frequency applications.

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Description

[0001] The present invention relates to a bus bar for a capacitor. Moreover, the present invention relates to a capacitor comprising the bus bar.

[0002] In high frequency applications, a capacitor has to fulfill the requirements defined in table 1 inside the operation bandwidth. Table 1: requirements for a capacitor in high frequency applicationsRequirementsALow Equivalent Series Resistance (ESR)BFrequency-stable ESRCLow Equivalent Series Inductance (ESL)DHomogeneous internal current distributionEInternal resonance avoidance

[0003] Overlapped bus bars are used for high frequency applications where a low equivalent series inductance (ESL), low and frequency stable equivalent series resistance (ESR) and a homogeneous internal current distribution are needed. The overlapped bus bar contributes as well to the avoiding of internal resonances between elements.

[0004] Capacitors with round construction are normally divided internally by windings placed axially connected in parallel. The internal construction (round windings and connection elements) are packed in a round case. The round shape of the capacitor makes the use of an internal overlapped bus bar especially complicated from the mechanical point of view.

[0005] Conventionally, the capacitor windings are connected by means of flat bands or wires without any overlapping. This construction has the following disadvantages when good performance at high frequency is requested: the operation bandwidth is limited to low frequencies (f < 10kHz); the DC-Link capacitor is divided in several independent capacitors connected in parallel by an external bus bar but if the space is limited and the only dimension of the capacitor that can be increased is the height, the problem cannot be solved with an efficient mechanical solution.

[0006] Document CN 204 407 189 U refers to a metallized film filter capacitor with low-inductance low equivalent series resistance properties. The metallized film filter capacitor comprises a plurality of cores coaxially stacked from top to bottom and connected to a laminated bus bar through connecting copper plates.

[0007] Document CN 111 048 304 A refers to a capacitor comprising a bus bar assembly which includes lead-out arc electrodes including a planar portion and an arc portion. The first element arc electrode includes a first flat portion and a first arc portion, the first flat portion is attached to the upper end surface of the capacitor element. The second element arc electrode includes a second flat portion and a second arc portion, the second flat portion being attached to the lower end surface of the capacitor element.

[0008] It is an object of the present disclosure to solve the above mentioned problems. This object is solved according to the invention by a capacitor according to claim 1. Embodiments of the invention are set forth with the appended claims.

[0009] According to a first aspect of the present disclosure, a bus bar is provided. The bus bar is configured to be used in a capacitor. The bus bar is adapted to be integrated in a capacitor, in particular a round capacitor. The bus bar is adapted and arranged for high frequency applications. The bus bar is laminated. In other words, the bus bar is at least partly overlapped. The bus bar is designed such that it comprises a larger width / larger extension perpendicular to a longitudinal axis of the capacitor / larger azimuthal extension than conventional bus bars.

[0010] The bus bar comprises a round shape. For example, the bus bar comprises the shape of a part of a cylinder shell. The bus bar is adapted to an outer shape of the capacitor into which the bus bar is to be integrated. In particular, the bus bar is adapted to the winding shape of the capacitor.

[0011] By means of the laminated bus bar parasitic inductances and resistances (ESRi, Rp, Rp2, ESLi, Lp, Lp2) can be strongly reduced. This makes the bus bar particularly suitable for high frequency applications.

[0012] According to one embodiment, the bus bar comprises a first layer or pole. The bus bar further comprises a second layer or pole. The layers may comprise copper, for example. The layers of the bus bar are adapted and arranged to be connected to poles of a capacitor, in particular to poles of winding elements of the capacitor. The bus bar and, in particular, the layers comprises an overlap area. In the overlap area, the layers of the bus bar overlap one another. In this way, a short and very equilibrated electric connection is facilitated.

[0013] According to one embodiment, an insulation layer is arranged between the first and second layer. The insulation layer may comprise a polymer, for example. The insulation layer is provided at least in the overlap area. In this way, a short circuit between the two layers of the bus bar can be efficiently avoided.

[0014] According to one embodiment, the first layer comprises a plurality of first connection areas. The second layer comprises a plurality of second connection areas. The overlap area of the first layer and the respective first connection area merge into one another. In other words, the first layer and the first connection areas are integrally formed. The overlap area of the second layer and the respective second connection area merge into one another, i.e. the second layer and the second connection areas are integrally formed. Error-prone connections between the overlap area and the connection areas are thus eliminated.

[0015] According to a further aspect, a capacitor is provided. The capacitor is adapted for high frequency applications. The capacitor comprises a plurality of winding elements, e.g. two, three, four or more winding elements. The winding elements are axially arranged, i.e. they are arranged along a main longitudinal axis of the capacitor.

[0016] The capacitor further comprises at least one bus bar. Preferably, the capacitor comprises exactly one bus bar. The bus bar may be the previously described bus bar. Thus, all features described in connection with the bus bar apply for the capacitor as well.

[0017] The capacitor comprises a round shape. The capacitor may comprise the shape of a cylinder. Accordingly, the respective winding element comprises the shape of a cylinder, as well. The laminated / overlapped bus bar is adapted and arranged to connect the winding elements in parallel.

[0018] The laminated bus bar provides a shorter and more equilibrated electric connection of the capacitor and, hence, an improvement of the electrical performance of the capacitor as compared to conventional capacitors. Parasitic inductances and resistances can be strongly reduced, independently of the width of the metallized film of the capacitor. Moreover, considering C homogenous, the impedance (Z) from terminals of the capacitor to each independent winding element is homogenous in all the bandwidth.

[0019] According to the invention, the bus bar is arranged inside a case of the capacitor. Accordingly, the bus bar is an internal bus bar. Preferably, the bus bar is arranged on an outer side of the winding elements. Preferably, the bus bar covers between 20 to 50 % of the outer side of the winding elements. The laminated bus bar is very space-saving. In particular, capacitors with the laminated bus bar described above can keep similar dimensions as the one with standard connections (copper bands). Due to the fact that the standard dimensions of the capacitor diameters are kept, a good integration in the power converter is enabled.

[0020] According to the invention, the bus bar comprises a first layer or pole. The bus bar further comprises a second layer or pole. The first and second layers are electrically insulated from one another. In particular, the layers are electrically insulated by means of the insulation layer described above.

[0021] The layers of the bus bar extend at least partly along an outer side of the respective winding element. In other words, the bus bar extends on the outer side of the winding elements along the longitudinal axis.

[0022] The bus bar comprises an overlap area. In the overlap area, the layers / poles of the bus bar overlap one another. As the bus bar extends along the longitudinal axis of the capacitor, the bus bar is a laterally overlapped bus bar.

[0023] Preferably, the overlap area of the bus bar covers between 5% and 40% of the outer side of the winding elements. In other words, an extension of the bus bar in longitudinal and azimuthal direction is such that the region where the two layers overlap occupies up to 40% of the outer surface of the winding elements. Thereby, the greater the overlap, the better the compensation of parasitic inductances and resistances. The size of the overlap area depends on the size of the capacitor as well as on the number of windings.

[0024] According to one embodiment, the bus bar has a shape adapted to a diameter of the respective winding element. In particular, the bus bar comprises a round shape, e.g. the shape of a part of a cylinder shell. The bus bar can be used with any numbers of windings. In other words, a length and / or azimuthal extension of the bus bar can be adapted to the size and number of winding elements. Hence, provision of a very flexibly usable bus bar is provided.

[0025] According to one embodiment, the bus bar comprises a plurality of connection areas. In particular, the first layer comprises a plurality of first connection areas. The second layer comprises a plurality of second connection areas.

[0026] A number of first connection areas corresponds to a number of winding elements. Moreover, a number of second connection areas corresponds to the number of winding elements.

[0027] The connection areas are adapted and arranged to be electrically and mechanically connected to poles of the winding elements. The connection areas may be soldered to the poles of the winding elements. Accordingly, the first layer may be connected to a first pole of a respective winding element. The second layer may be connected to a second pole of the respective winding element. Hence, a short and very equilibrated electric connection between the bus bar and the poles is enabled. In this way, the electrical performance of the capacitor is increased.

[0028] Further features, refinements and expediencies become apparent from the following description of the exemplary embodiments in connection with the figures. Figure 1 schematically shows a simplified electrical model of a capacitance unit according to the state of the art, Figure 2 schematically shows a simplified electrical model of a DC-Link capacitor according to the state of the art, Figures 3a and 3b schematically show a perspective view of a capacitor according to the state of the art, Figures 4a and 4a schematically show a perspective view of parts of a capacitor, Figures 5a and 5b schematically show a sectional view of a part of a capacitor, Figure 6 schematically shows a sectional view of a part of a capacitor, Figure 7 schematically shows a perspective view of a part of a capacitor, Figure 8 schematically shows a perspective view of the capacitor according to Figure 7, Figures 9a to 9c schematically show a perspective view of parts of the capacitor according to Figures 7 and 8, Figure 10 schematically shows a comparative ESR measurement between a capacitor according to the state of the art and the capacitor according to the present disclosure.

[0029] Figures 1, 2, 3a and 3b are related to a capacitor according to the state of the art. In particular, Figures 3a and 3b show a conventional capacitor 100 from a first side (Figure 3a) and from the opposite side (Figure 3b). The capacitor 100 is divided into units Ci (see Figures 1 and 2) which are connected in parallel by flat copper bands 102. Each capacitance unit Ci contains a capacitance element (winding element 101) and its connections to the copper band 102.

[0030] The winding elements 101 are connected in parallel by the copper bands 102 without any overlap of the copper bands 102. The copper bands 102 electrically connect terminals / poles 103 of the winding elements 101. The respective copper band 102 is secured to the respective terminal 103 by means of a screw 104. The respective copper band 102 extends along an outer side of the capacitor 100 and, in particular, outside a case of the capacitor 100 (external bus bar). In other words, one copper band 102 extends on the first outer side of the capacitor 100 and another copper band 102 extends on the second (opposite) outer side of the capacitor 100.

[0031] In this context, Figure 1 shows a simplified electrical model of the capacitance unit Ci (winding element 101 and its connection to the copper band 102). Thereby, ESRi denotes the parasitic ESR of the capacitance unit Ci and ESLi denotes the parasitic ESL of the capacitance unit Ci.

[0032] A simplified electrical model of a complete DC-Link capacitor (with a plurality of capacitance units Ci) is shown in Figure 2, where Ci: capacitance unit - capacitance value, ESRi: capacitance unit - parasitic ESR, ESLi: capacitance unit - parasitic ESL, Cp: connectors between capacitance units - parasitic capacitance, Rp, Rp2: connectors between capacitance units - parasitic resistance, Lp, Lp2: connectors between capacitance units - parasitic inductance, Rt: terminal - parasitic resistance, Lt: terminal - parasitic inductance.

[0033] The electrical requirements achieved with this solution are summarized in table 2. Table 2: requirements for a capacitor in high frequency applications as achieved by capacitors according to the state of the art.RequirementsAchieved by state of the artALow Equivalent Series Resistance (ESR)NoBFrequency-stable ESRNoCLow Equivalent Series Inductance (ESL)NoDHomogeneous internal current distributionNoEInternal resonance avoidanceNo

[0034] Figures 4 to 9 schematically show a capacitor 1 according to the present invention. The capacitor 1 has a round construction. In other words, the capacitor 1 has a round outer shape. In particular, the capacitor 1 comprises the outer shape of a cylinder (see, in particular, Figures 4a, 4b, 8 and 9a to 9c). The capacitor 1 is especially adapted to be used in high frequency applications.

[0035] The capacitor 1 comprises a plurality of winding elements 2. In this embodiment, the capacitor 1 comprises three winding elements 2 (Figure 4a). Of course, the capacitor 1 can comprise more than three winding elements 2, e.g. four, five or six winding elements 2. The capacitor 1 can also comprise less than three winding elements 2, e.g. two winding elements 2. In particular, the number of winding elements 2 is freely selectable. In other words, the construction described in the following can be implemented with any number of winding elements 2. An insulation 9 is arranged between succeeding winding elements 2 as can be seen from Figure 8. The insulation 9 may comprise a polymer, for example.

[0036] The winding elements 2 are axially arranged, i.e. they are arranged along a main longitudinal axis 18 of the capacitor 1. The winding elements 2 are electrically connected in parallel. For this purpose, a laminated bus bar 3 is provided (Figure 4b). In this context, the term "laminated" means that the bus bar 3 comprises several layers (4a, 4b, 5; see, for example, Figure 6). The said layers, which are explained later on in detail, overlap one another at least partly along an outer side of the winding elements 2. In other words, the bus bar 3 is a (lateral) overlapping bus bar.

[0037] As can be seen from Figure 4b, the bus bar 3 extends along the outer side of the winding elements 2 (lateral bus bar). The bus bar 3 extends along the outer side of the winding elements 2 from a first end side 10 towards a second end side 11 of the capacitor 1 (see Figure 8). The bus bar 3 covers the outer side of the respective winding element 2 at least partly. Altogether, the whole bus bar 3 covers between 20% and 50% of the outer side of the winding elements 2. The bus bar 3 is an internal bus bar. In other words, the bus bar 3 is arranged inside a case 16 of the capacitor 1 (see Figure 9c).

[0038] The bus bar 3 has a round shape which can be taken particularly well from Figure 5a. The bus bar 3 comprises the shape of an (incomplete) cylinder shell. The bus bar 3 has a shape which is adapted to an outer shape and / or a diameter of the respective winding element 2 and the case 16 of the capacitor 1. The bus bar 3 can be used with any number of windings. A length (axial extension, i.e. extension along the main longitudinal axis 18 of the capacitor 1) of the bus bar 3 is adapted to the number of winding elements 2.

[0039] The bus bar 3 comprises the previously mentioned layers. In particular, the bus bar 3 comprises a first layer (first pole) 4a and a second layer (second pole) 4b, which can be gathered from Figures 5b and 6, for example. The layers 4a, 4b comprise copper. The layers 4a, 4b comprise a thickness between 0.3 mm and 1.5 mm, preferably 0.5 mm.

[0040] The layers 4a, 4b overlap at least partly. In particular, in a subarea of the bus bar 3 (overlap area 6), the first layer 4a and the second layer 4b are stacked in a radial direction of the capacitor 1. A size of the overlap area 6 (axial and azimuthal extension) is such that the overlap area 6 covers between 5% and 40% of the outer side of the winding elements 2. Preferably, the overlap area 6 covers 30% of the outer side of the winding elements 2.

[0041] The layers 4a, 4b are electrically insulated from one another by means of an insulation layer 5. The insulation layer 5 comprises a polymer. A thickness of the insulation layer 5 is between 0.2 mm and 2.5 mm. Preferably, the thickness of the insulation layer 5 amounts to 0.5 mm.

[0042] The insulation layer 5 is arranged between the first layer 4a and the second layer 4a at least in the overlap area 6 of the two layers 4a, 4b. In fact, the insulation layer 5 extends beyond the overlap area 6 in an azimuthal and / or axial direction as can be seen from Figure 5b, for example. In other words, the azimuthal and / or longitudinal extension of the whole bus bar 3 including the layers 4a, 4b and the insulation layer 5 is larger than the azimuthal extension of the overlap area 6 (see for example Figures 7 and 8).

[0043] The first layer 4a is connected to a first pole 17a (e.g. the negative pole) of the respective winding element 2 (Figure 7). The second layer 4b is connected to a second pole 17b (e.g. the positive pole) of the respective winding element 2.

[0044] For this purpose, the first layer 4a comprises a plurality of first connection areas 7a. The second layer 4b comprises a plurality of second connection areas 7b. In this embodiment, the respective layer 4a, 4b comprises three respective connection areas 7a, 7b. The number of respective connection areas 7a, 7b corresponds to the number of winding elements 2.

[0045] The first connection areas 7a and the first layer 4a are integrally formed. The second connection areas 7b and the second layer 4b are integrally formed. The respective connection area 7a, 7b is bar shaped. The respective connection area 7a, 7b extends parallel to the layers 4a, 4b along the outer surface of the respective winding element 2. In an intermediate section 19a, 19b (see Figures 7 and 8), the respective layer 4a, 4b passes over into the respective connection area 7a, 7b. The intermediate section 19a, 19b extends perpendicularly to the connection areas 7a, 7b.

[0046] The respective connection area 7a, 7b is electrically and mechanically connected to the respective pole 17a, 17b of a winding element 2 for connecting the winding elements 2 in parallel. The connection areas 7a, 7b are connected to the poles 17a, 17b by means of a connection element 8, e.g. a metal strip (Figures 7 and 8). The connection areas 7a, 7b may be soldered to the poles 17a, 17.

[0047] For electrically and mechanically connecting the bus bar 3 to terminals 13a, 13b of the capacitor 1, the capacitor 1 further comprises first and second connecting members 12a, 12b (Figures 8 and 9a). The connecting members 12a, 12b are arranged in the first end region 10 of the capacitor 1. The connecting members 12a, 12b comprise metal strips, for example. The connecting members 12a, 12b are bent to connect the bus bar 3 arranged on the side surface of the winding elements 2 with the terminals 13a, 13b which are arranged on the first end side 10 of the capacitor 1. A terminating member 20 is arranged at the first end side 10 between the winding element 2 and the connecting members 12a, 12b (Figure 8). The terminating member 20 comprises an insulating material, e.g. a polymer.

[0048] In a first end section, the first connecting member 12a is connected to the first layer 4a of the bus bar 3, e.g. by means of soldering (Figure 8 and 9a). Likewise, in a first end section, the second connecting member 12b is connected to the second layer 4b of the bus bar 3, e.g. by means of soldering (Figure 8 and 9a).

[0049] In a second or opposite end section, the first connecting member 12a is connected to the first terminal 13a, e.g. by means of a screw or soldering (Figure 9a). Likewise, in a second or opposite end section, the second connecting member 12b is connected to the second terminal 13b, e.g. by means of a screw or soldering (Figure 9a).

[0050] An external insulation 14 is arranged on top of the connecting members 12a, 12b on the side surface of the winding elements 2 (Figure 9b). The external insulation 14 comprises a strip-like shape. The external insulation 14 comprises a round shape and extends partly around the outer surface of the winding element 2 arranged close to the first end side 10 of the capacitor 1. The external insulation 14 electrically insulates the connecting members 12a, 12b from the case 16 of the capacitor 1 which case 16 is arranged on the external insulation 14 and completely covers the winding elements 2 and the bus bar 3 (Figure 9c).

[0051] Moreover, on the first end side 10 a cover 15 is arranged on the connecting members 12a, 12b (Figures 9b and 9c). The cover 15 comprises two cut-outs. The cut-outs are adapted and arranged to receive the terminals 13a, 13b. The terminals 13a, 13b project from the cut-outs in an axial direction. In this way, an electrical connection of the capacitor 1 is enabled. The cover 15 acts as a terminating element of the first end side 10 of the capacitor 1. A corresponding cover without cut-outs is arranged on the second side face 11 of the capacitor 1 (not explicitly shown).

[0052] By means of the construction as described above parasitic inductances and resistances (ESRi, Rp, Rp2, ESLi, Lp, Lp2) can be strongly reduced, independently of the width of the metallized film of the capacitor. Moreover, considering C to be homogenous, the impedance from the terminals 13a, 13b to each independent winding is homogenous in all the bandwidth. Therefore, the requirements summarized in table 3 can be achieved. Table 3: requirements for a capacitor in high frequency applications as achieved by capacitors according to the state of the art in comparison to the capacitor according to the present invention.RequirementsAchieved by state of the artAchieved by present inventionALow Equivalent Series Resistance (ESR)NoYesBFrequency-stable ESRNoYesCLow Equivalent Series Inductance (ESL)NoYesDHomogeneous internal current distributionNoYesEInternal resonance avoidanceNoYes

[0053] Figure 10 schematically shows a comparative ESR measurement between the capacitor 100 according to the state of the art (Figures 3a, 3b) and the capacitor 1 according to the present disclosure (Figures 4 to 9). It can be observed that in the state of the art, the ESR is less frequency-stable than the ESR of the capacitor according to the present invention. This is due to higher skin effect, non-homogenous internal current distribution and internal resonances in the capacitor design based on the state of the art.

[0054] In the figures, elements of the same structure and / or functionality may be referenced by the same reference numerals. It is to be understood that the embodiments shown in the figures are illustrative representations and are not necessarily drawn to scale.Reference numerals

[0055] 1Capacitor 2Winding element 3Bus bar 4aFirst layer 4bSecond layer 5Insulation layer 6Overlap area 7aFirst connection area 7bSecond connection area 8Connection element 9Insulation 10First end side of capacitor 11Second end side of capacitor 12aFirst connecting member 12bSecond connecting member 13aFirst terminal 13bSecond terminal 14Insulating element 15Cover 16Case 17aFirst pole 17bSecond pole 18Main longitudinal axis 19aFirst intermediate section 19bSecond intermediate section 20Terminating element 100Capacitor 101Winding element 102Copper band 103Terminal 104Screw CiCapacitance unit - capacitance value ESRiCapacitance unit - parasitic ESR ESLiCapacitance unit - parasitic ESL CpConnectors between capacitance units - parasitic capacitance Rp, Rp2Connectors between capacitance units - parasitic resistance Lp, Lp2Connectors between capacitance units - parasitic inductance RtTerminal - parasitic resistance LtTerminal - parasitic inductance

Claims

1. Capacitor (1) comprising - a round shape, - a plurality of winding elements (2), - a bus bar (3) adapted and arranged to connect the winding elements (2) in parallel, wherein the bus bar (3) is laminated and comprises a round shape, characterized in that the bus bar (3) is a single overlapped bus bar and wherein all winding elements (2) are connected to the single overlapped bus bar (3).

2. Capacitor (1) according to claim 1, wherein the bus bar (3) is arranged inside a case (16) of the capacitor (1).

3. Capacitor (1) according to claim 1 or claim 2, wherein the bus bar (3) comprises a first layer (4a) and a second layer (4b) extending at least partly along an outer side of the respective winding element (2), wherein the bus bar (3) comprises an overlap area (6) in which the layers (4a, 4b) overlap one another.

4. Capacitor (1) according to claim 3, wherein the first layer (4a) is connected to a first pole (17a) of a respective winding element (2) and wherein the second layer (4b) is connected to a second pole (17b) of a respective winding element (2).

5. Capacitor (1) according to claim 3 or claim 4, wherein an insulation layer (5) is arranged between the first and second layer (4a, 4b) at least in the overlap area (6).

6. Capacitor (1) according to any one of the previous claims, wherein the bus bar (3) has a shape adapted to a diameter of the respective winding element (2).

7. Capacitor (1) according to any one of the previous claims, wherein the bus bar (3) comprises a plurality of connection areas (7a, 7b) adapted and arranged to be electrically and mechanically connected to poles (17a, 17b) of the winding elements (2).

8. Capacitor (1) according to claim 7, wherein the respective connection area (7a, 7b) is soldered to the respective pole (17a, 17b) of a winding element (2).

9. Capacitor (1) according to any one of claims 3 to 8, wherein the first layer (4a) comprises a plurality of first connection areas (7a) and the second layer (4b) comprises a plurality of second connection areas (7b), wherein the overlap area (6) of the first layer (4a) and the respective first connection area (7a) merge into one another, and wherein the overlap area (6) of the second layer (4b) and the respective second connection area (7b) merge into one another.

10. Capacitor (1) according to claim 9, wherein the number of first connection areas (7a) corresponds to a number of winding elements (2) and wherein the number of second connection areas (7b) corresponds to the number of winding elements (2).

11. Capacitor (1) according to any one of the previous claims, wherein the bus bar (3) is adapted and arranged for high frequency applications.

12. Capacitor (1) according to any one of the previous claims, wherein an extension of the bus bar (3) along a main longitudinal axis (18) of the capacitor (1) is adapted to a number of winding elements (2).

13. Capacitor (1) according to any one of the previous claims, wherein the bus bar (3) extends along an outer side of the winding elements (2) from a first end side (10) towards a second end side (11) of the capacitor (1).

14. Capacitor (1) according to any one of claims 7 to 13, wherein the connection areas (7a, 7b) are connected to the poles (17a, 17b) by means of a connection element (8).

15. Capacitor (1) according to claim 14, wherein the connection element (8) comprises a metal strip.

16. Use of a capacitor (1) according to any one of the previous claims in high frequency applications.