DE20001632U1 - Low induction electrolytic capacitor - Google Patents

Description

Low induction electrolytic capacitor

The invention relates to a low-induction electrolytic capacitor with a winding arranged in a cup, which has metal foils that function as cathode and anode. The cup is closed with an electrically insulating cover plate. This has a plus and a minus leadthrough, which are connected to the electrode foils of the winding in the cup via electrically conductive strips and provide connections to the outside for external contact.

In the case of fast switching processes, which can correspond to switching frequencies of more than 1 MHz in the frequency range, the self-inductance of electrolytic capacitors is a disadvantage. It delays the smoothing function for voltages and therefore impairs its function of reducing voltage surges in corresponding circuits and leads to a reduced usability of the capacitor.

Numerous efforts have already been made to keep the self-inductance of an electrolytic capacitor and thus the delays in its smoothing function as low as possible (see, for example, DE 297 18 066 Ul). Many of these efforts aim to reduce individual inductances that contribute to the overall inductance of an electrolytic capacitor.

0 An important point that contributes to increasing the self-inductance of an electrolytic capacitor is the minimum distance between the two bushings in the end plate required for safe wiring. This also essentially determines the so-called ribbon spacing of the winding.

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kels, i.e. the distance between the contact points of the ribbons on the winding.

Furthermore, for electrolytic capacitors, a threaded hole in the feedthrough with sufficient depth to connect the feedthrough with a screw is required for secure contact. Since the ribbons for electrical contact with the winding also have to be passed through and secured below the feedthrough, more space is required, i.e. a greater distance between the feedthrough and the winding. The current must bridge a path on the way from the contact points on the winding via the ribbons and the feedthrough, and the inductance of the electrolytic capacitor increases as the length increases. In general, the inductance is almost proportional to the distance between the winding and the plane within which the contact to the outside is made.

Known measures to reduce the distances 0 mentioned so far require a high technical effort, which is reflected in higher manufacturing costs for the capacitor.

The object of the present invention is therefore to provide a low-induction electrolytic capacitor in which the self-inductance is reduced by simple and cost-effective measures.

This object is achieved with an electrolytic capacitor according to claim 1. Further embodiments of the invention can be found in the subclaims.

For a low-induction electrolytic capacitor, the invention proposes that the connecting strips, which connect the winding to the bushings in the end plate, are connected to the bushings from the inside 5, i.e. from the direction of the winding center.

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This frees up the space between the bushing and the winding, so that the corresponding distance between the winding and the bushing can be reduced and, for example, set to almost zero. Since this distance essentially determines the inductance of the capacitor, this is thereby reduced.

In order to guide the connecting ribbons from the contact points on the winding to their connections on the bushings in such a way that ribbons with different polarities do not come into contact with one another, different folds of the ribbons are always required, which take up a certain amount of space within the cup. In known solutions, the folds are made below the bushings. In the invention, the necessary folds are advantageously made in the space between the bushings. This also reduces the required distance between the connecting ribbons with different polarities and thus reduces the self-inductance of the capacitor.

In a further advantageous embodiment of the invention, the connecting strips are not connected directly to the feedthroughs, but to a connecting element that protrudes laterally over the feedthroughs. This can be designed in such a way that it offers a connection option for the connecting strips. However, it is also possible to design the connecting element in such a way that it offers several connection options for different strips. Since the contacting of the strips takes place from the direction of the winding center according to the invention, the connecting elements protrude over the feedthroughs at least towards the center of the winding.

A possible connection element is a connection plate, which can be attached to the bushings, or which together with the bushings forms a one-piece, particularly metallic,

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cal molded part. Preferably, the connection plate is integrated into the end plate. Such an integrated connection plate has the further advantage that it can be easily inserted into the end plate as a closure and also provides sufficient surface area for contacting the connection strips.

As a further possible connection element, a tab can be arranged at the lower end of the bushings.

In the following, the invention is explained in more detail using embodiments and the associated figures.

Figure 1 shows an electrolytic capacitor with conventional contacting in schematic cross section

Figure 2 shows a capacitor according to the invention in schematic cross section

0 Figure 3 shows a capacitor according to the invention with connection element in schematic cross section

Figure 4 shows a capacitor with connection plate in schematic plan view

Figure 5 shows a capacitor with a separate contact plate

Figure 6 shows a capacitor with a lower contact level

Figure 7 shows a capacitor where the negative leadthrough is connected to the cup

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Figure 8 shows a capacitor with a tab-shaped connection element and

Figure 9 shows another connection option for connecting ribbons.

Figure 1 shows a known electrolytic capacitor with a winding W consisting of mutually insulated, wound electrode foils serving as cathode and anode. The winding is placed in a cup (not shown in the figure) filled with electrolytic fluid. The cup containing the capacitor is closed by an electrically insulating end plate AP in which two metal bushings D are embedded. The winding is electrically connected to the bushings D via connecting strips B which are attached to various electrode foils of the winding W. The strips B are guided to the bushing from below, with any necessary folds in the strips also being located below the bushings D. While practically no self-inductance is generated within the winding area WB, the entire remaining current path between the winding and the contact level in which the external connection is made is decisive for the inductance. The ribbon spacing BA between differently polarized connecting ribbons B makes a significant contribution to this. The distance BB between the upper end of the winding W and the bushing D, within which the current flows through the ribbons including their folds, also contributes significantly to the self-inductance of the capacitor.

0 The feedthrough area and its height are also crucial for the inductance. The height of the feedthrough area is determined by the internal thread, which can be used to attach external connections to the feedthroughs.

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Figure 2 shows a simple embodiment of the invention in a schematic cross-section. In contrast to known electrolytic capacitors, the area BB is minimized. In the case shown, the bushings D are placed practically directly on the winding W. The ribbons and any folds required for them are arranged in the area between the two differently polarized bushings D. This also minimizes the ribbon spacing BA.

Figure 3 shows a further embodiment of the invention in which the connection of the ribbons B to the bushings D is made easier. The ribbons B are attached to a contact plate KP, which lies in the plane of the connection plate AP and is in contact with the bushings D. The great advantage of this arrangement is that the ribbons B can be guided upwards to the contact plate KP and attached there with almost no folding. The contact plate KP can be a separate part, but in a preferred embodiment of the invention it is manufactured together with the bushings as a one-piece element. With the help of a center piece MS it can be inserted into the end plate AP as an integral component. This figure also shows a section of a cup wall BW, which forms the outer housing for the capacitor.

Figure 4 shows the arrangement shown in Figure 3 in a schematic plan view. The bushings D and the contact plate KP can be one or two pieces, whereby the two bushings and the associated contact plates KP are electrically separated from each other. With the help of an electrically insulating middle piece MS, both contact plates can be connected and thus facilitate handling as one piece for insertion into the end plate AP.

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Figure 5 shows a further embodiment of the invention, in which a contact plate KP is provided as the connection element, which is arranged as a separate element below the connection plate AP. Here too, the ribbons B are connected to the contact plate KP.

Figure 6 shows a further possibility of reducing the self-inductance of the capacitor according to the invention by moving the contact level of the external connections downwards. Since the height of the bushings is determined by the internal thread IG, the contact level can only be lowered by additional measures. In the embodiment shown, a contact rail KS is arranged above the end plate but below the upper edge of the bushings D and is fixed with the aid of a screw via a pressure ring DR. The reduced distance between the contact level (= level of the contact rail KS) and the upper edge of the winding W also reduces the self-inductance of the capacitor.

Figure 7 shows a further embodiment in which the inductance of the capacitor is reduced by opening up new current paths via the cup wall. For this purpose, the negative feedthrough D" connected to the cathode is electrically connected to the cup wall BW. This can be done via a connection plate AS which rests on the connection plate and is in contact with the negative feedthrough D". The positive feedthrough D ⁺ is electrically insulated from the connection plate AS. However, further electrically conductive connections of the negative feedthrough D" to the cup wall BW are possible, which are not listed in detail.

Figure 8 shows a possibility to reduce the folding effort of the ribbons, to connect the ribbons to the feedthroughs between them and at the same time to reduce the

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between the end plate AP and the upper surface of the winding W. For this purpose, the bushings D are designed with connection elements in the form of inwardly bent connection lugs AL. These connection lugs have at least one eyelet-shaped opening through which the ribbons B can be guided. The opening of the lugs is preferably positioned such that a ribbon can be guided horizontally, i.e. parallel to the end plate. This design has the advantage that it allows the ribbons to be connected easily. In addition, the connection lug AL can be guided in a simple manner to the corresponding contact point or contact points of the ribbons B, so that the entire current path is further reduced with minimal ribbon spacing.

Figure 9 shows another way of connecting the ribbons to the feedthroughs. To do this, the ribbons B are folded as required between the two feedthroughs D and the ribbons are then placed so that they run parallel to the upper edge of the coil, stacked on top of each other 0. In this form, they are attached to the feedthroughs below them. In this way, the ribbon area BB is also reduced compared to the known design shown in Figure 1. Bifilamentary currents can form via the stacked and electrically contacted ribbons in the ribbon stack, which generate particularly little inductance.

Comparative inductance measurements with the different embodiments of the invention show that all embodiments reduce the inductance value of the electrolytic capacitor. While 17.7nH is measured for a known solution shown in Figure 1, this value can be reduced to 10.8nH by providing a contact plate such as in Figure 5. Even better values are obtained if additional current paths are provided for the cathode via the cup

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wall, as is provided in Figure 4. An inductance of 7.65 nH is measured for such an arrangement, which is more than half the known original value. None of the embodiments according to the invention requires excessive construction effort; in some cases the contacting effort is even reduced compared to the known solution. The invention is also not limited to the embodiments shown, which merely represent possible configurations. Further variations are conceivable within the scope of the claims.

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Claims (12)

1. Low induction electrolytic capacitor 1. with a winding arranged in a cup, which has metal foils acting as cathode and anode 2. with an electrically insulating cover plate on the cup, 3. with a plus and a minus leadthrough for the power connections in the cover plate, 4. with metallic connecting strips that electrically connect the anode and cathode of the winding to the corresponding bushing via contact points on the surface of the winding 5. The connecting strips are brought to the bushings in such a way that contact with the bushings is made from the direction of the winding center. 2. Capacitor according to claim 1, wherein all required folds of the connecting ribbons are arranged in the space between the feedthroughs. 3. Capacitor according to claim 1 or 2, wherein the feedthroughs extend directly to the surface of the winding. 4. Capacitor according to one of claims 1-3, in which the connecting strips are connected to a connecting element projecting laterally beyond the bushings. 5. A capacitor according to claim 4, wherein the connection element is a connection plate. 6. Capacitor according to claim 4, wherein the connection element is a tab arranged at the lower end of the bushings and bendable in the direction of the winding axis. 7. Capacitor according to claim 6, wherein the tab has a horizontally opened passage for a connecting ribbon. 8. Capacitor according to claim 5, wherein the connection plate is integrated into the cover plate. 9. Capacitor according to one of claims 1-8, wherein the feedthroughs have an externally accessible internal thread for connection to external terminals. 10. Capacitor according to one of claims 1-9, wherein the negative feedthrough is connected to the electrically conductive can. 11. Capacitor according to claim 10, wherein the negative feedthrough is connected to the can via a contact disk. 12. Capacitor according to claim 9, wherein a connection possibility for the external connections is provided which is located lower than the upper edge of the feedthrough.