DE3032819A1 - CAPACITOR WITH TAPE CONNECTIONS - Google Patents

Description

PHA 20 918 * 12-8-1980

-A-

"Capacitor with ribbon cable connections."

The invention relates to a capacitor with a housing located in a housing closed by a cover Capacitor winding, of which both an anode foil and a cathode foil by a number on the length of the Foils distributed inner connection strips with at least two external connections are electrically connected.

In a known capacitor of the type mentioned at the beginning (manufactured by Philips, type 2222 106 3 according to FIG Description in "Philips Technical Information" from 22.

September 1975 ₇ p. 5) the connections connected to the anode foil are located on one side and the connection strips connected to the cathode foil are located on the other side of the capacitor winding and are connected to the anode foil at equal distances from one another, to those on the on the other side of the capacitor winding, which are connected in parallel with the cathode foil at equal distances from one another (measured in the longitudinal direction of the foils), a capacitor is obtained whose so-called equivalent series impedance is relatively low.

A disadvantage of the known capacitor is that it is equivalent in high-frequency applications Series impedance is still higher than desired. this causes essentially the component of the equivalent series impedance created by the equivalent series inductance is formed.

The invention is based on the object of creating a capacitor whose series inductance is equivalent - So the equivalent series impedance only increases relatively slowly even at high frequencies. This object is achieved with the inventive Capacitor solved by the fact that the two inner connection

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strip containing electrical tape lines that go through each two electrically conductive strips are formed, which are separated from each other by an electrical insulating strip are, where of the electrical assigned to a ribbon line trisch conductive pair of strips each one with the anode foil of the capacitor winding and the other with the cathode foil of the capacitor winding is connected at a point that corresponds to the connection point of the respective ribbon cable borders with the anode foil.

It should be noted that from U.S. Patent 3,654,524 and 3 611 051 capacitors with one in the form of a ribbon cable Connection is known. Such a capacitor is compressed by stacking a number Capacitor winding formed. Between two of the capacitor windings The long legs of two L-shaped metal profiles are inserted into the stack, which are connected by an electrical Isolation layer are separated from each other. These L-shaped profiles are welded to each capacitor coil connected and form a connection in the form of a ribbon cable. Since the two L-shaped profiles in the stack of Capacitor winding must be welded to the anode foil or to the cathode foil, it is necessary that Relationship between the film widths and their overlap very large to choose. The consequence of this is that only a relatively small volume of the capacitor winding stack works capacity-building. The capacity per unit volume is therefore in such a capacitor relatively low.

In a capacitor according to the invention can on the other hand, the overlap between anode foil and cathode foil should theoretically be maximal. In practice you give way from this somewhat in order to minimize the possibility of short circuits on the end faces of the capacitor winding.

Embodiments of the invention are described below explained in more detail on the drawing. Show it

Fig. T is a side view of a first embodiment a capacitor according to the invention,

FIG. 2 is a plan view of the capacitor according to FIG.

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3 shows a section along the plane III-III in FIG. 2 on an enlarged scale;

FIG. H shows a section along the plane IV-IV in FIG. 1 on an enlarged scale, FIG. 5 shows, partly in view and partly in longitudinal section, a second embodiment of a capacitor according to the invention,

6 shows a section along the plane "VT-VI in Fig. 5,

¹ ^ Fig. 7 schematically shows the ribbon lines in one

In accordance with the invention capacitor,

Figure 8 is a graph of the equivalent series impedance and equivalent series resistance as a function of the frequency for a capacitor according to FIG. 1,

Fig. 9 is a graph of the equivalent Series impedance and the equivalent series resistance as a function of frequency for a capacitor of the type according to Fig. 1, but with two connections on the anode foil and two connections on the cathode foil,

Fig. 10 is a graph of the equivalent Series impedance and the equivalent series resistance as a function of frequency for a comparable one known capacitor with two terminals of a known type on the anode foil and two terminals of a known type on the cathode foil,

Figure 11 is a graph of the equivalent series impedance and equivalent series resistance as a function of frequency for a capacitor according to FIG. 5.

The first illustrated with FIGS. 1 ... 4 Contains embodiment of a capacitor according to the invention one arranged in a cylindrical aluminum housing 1 Capacitor winding 3 of a type known per se. Such a capacitor winding can, for example, from an anode foil formed from aluminum, a first separator foil made of paper, an aluminum cathode foil and be constructed of a second insulating separator film. the

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first separator foil can be in an electrolyte liquid be soaked. Although the invention is based on an electrolytic capacitor is not limited to this and is in fact to all so-called wound capacitors applicable. The housing 1 is provided with a cover 5 made of an electrically insulating material such as a hard type of rubber closed. The capacitor winding 3 is in the usual way fastened in the housing 1 by a circumferential groove 7. Both the anode foil 9 and the cathode foil 11 of the capacitor winding 3 (see Fig. 3) are through four flexible metal connection strips I3 and 15 with an L-shaped Metal profile 17 or with an L-shaped metal profile 19 electrically connected (external connections). In each of the four pairs of connection strips (13> 15) the two strips are through a strip 14 of electrically insulating Material separated from one another and together with this strip 14 form a so-called ribbon line with a relatively low inductance. These four ribbon lines extend between the L-shaped profiles I7 and

2D and the capacitor winding 3 · As can be seen from FIG the connection strips are only nearby the L-shaped profiles 17 and 19 and the capacitor winding 3 separated from each other. The connecting strips belonging to the same pair are almost opposite each other (border to each other) in the unrolled state of the roll. The connection are strips of the anode or cathode foil Evenly distributed over the length of the film in question, i.e. the points where the connection strips with the corresponding foils are connected, lie in almost equal distance from each other. The L_shaped profiles 17 and 19 are supported by a plate 21 made of electrically insulating Material isolated from each other and together form a T-shaped unit, which in itself also forms a ribbon cable with a contains low inductance. The latter ribbon line is made of mutually opposite and electrical from each other separate legs of the L-shaped profiles 17 and 19 are formed.

On each of the L-shaped profiles 17 and

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of the capacitor shown in Figs. 1 ... 4 are two screw-threaded connection sockets 23 resp. attached (external connections). The connection sockets 23 and 25 have a symmetrical position against the plate 21 (see Fig. 2), in which the connection sockets 23 with the Anode foil and the connection sockets 25 with the cathode foil are connected. Since the L-shaped profiles 17 and 19 are completely in the housing 1 of the capacitor, the connection sockets 23 and 25 protrude through the cover 5 through.

As will be explained in more detail with reference to FIGS. 8 ... 10, the capacitor described has not only one ratio moderately low equivalent series resistance, but in combination with it also a relatively low equivalent series inductance, which makes the capacitor makes it particularly suitable for high frequency applications.

In the second embodiment of a capacitor according to the invention shown in FIGS. 5 and 6 the T-shaped unit by the structure of the L-shaped profiles

ZO and the insulating plate is formed at a different location than in the capacitor according to FIGS. 1 ... 4. Because the capacitor 5 and 6 has great resemblance to the capacitor according to FIGS. 1 ... 4, are the latter Reference numerals corresponding to the figures are used for the capacitor according to FIGS. The T-shaped unit of the capacitor 5 and 6 is located partially inside and outside of the housing 1 because the legs of the L-shaped profiles 17 and 19 protrude through the cover 5. At the bottom (see Fig. 5) the L-shaped Profiles are each two connection sockets 23 and 25 attached. This allows the top of the T-shaped unit to be mounted directly on conductor strips. in the The rest of the capacitors of FIGS. 1 and 5 are structurally same.

As further explained with reference to FIGS. 10 and 11 the capacitor of FIGS. 5 and 6 has not just a relatively low equivalent Series resistance, but also in combination with it

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a relatively low equivalent series inductivity, ■ which makes the capacitor particularly suitable for high frequency applications.

The characteristics of the capacitors according to FIGS. 8, 9, 10 and 11 are as follows: 8

- Capacitor of the type of Figs. 1, 2, 3 and k.

- Capacity 27000 mF

- Operating voltage 20 V

- Operating temperature 25 ° C

- inductance 1.82 nH

- Number of pairs of connecting strips (13, 15): four Fig. 9

- Capacitor of the type of Figs. 1, 2, 3 and h - Capacitance 27000 mF

- Operating voltage 20 V

- Operating temperature 25 ° C

- inductance 2.54 nH

- Number of pairs of connecting strips (i3j 15) * two Fig. 10

- Known capacitor of the type as in Fig. 1, 2, 3 and h, but without ribbon cables between the capacitor winding and L-shaped profiles

- Capacity 9000 mF

- Operating voltage 20 V

- Operating temperature 25 ° C

- inductance 25.32 nH

- Number of pairs of connection strips: two Fig. 11

- Capacitor of the type according to Fig. 5 and

- Capacity 10,000 mF

- Operating voltage 6 V

- Operating temperature 25 ° C

- Inductance 2.00 nH

- Number of pairs of connecting strips (13, 15): four.

For those in the graphical representations of the Fig. 8 ... 11 specified equivalent series impedance Z as a function of the Freqifi nz, the following relationship applies

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Z = ESR + ESC + ESL,
where ESR is the equivalent series resistance, ESC is the equivalent series capacitance and ESL is the equivalent series inductance.

Since in Fig. 8, 9 »10 and 11 both the Z curve and also indicated the ESR curve and the contribution of the equivalent Series capacitance ESC to the Z curve for frequencies higher than the resonance frequency is negligible (included in Minimum in the Z curve), the difference between the Z curve and the ESR curve for any frequency can be above the Resonance frequency as the contribution of the equivalent series inductance ESL considered to be the equivalent series impedance Z. will.

From the comparison of FIGS. 8 and 9 with FIG.

10 it can be concluded that with a Capacitor the Z-curve and thus the equivalent series inductance over the resonance frequency significantly less rises steeply through the ribbon cables between the capacitor winding and the L-shaped profiles. Fig. 8 and 9 clearly show that halving the number of connection pairs of stripes to increase the equivalent Series resistance ESR leads. A comparison of FIG. 11 with FIG. 10 results in a similar filling with regard to of the capacitor shown in Figs. 5 and 6 according to the invention.

It will be clear that the described low inductance Ribbon line connections are not limited to the electrolytic wound capacitors, but can also be used advantageously with non-electrolytic (dry) wound capacitors.

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Claims (2)

PHA ZO 918 £ T 12-8-1980 PATENT CLAIMS: Capacitor with in a closed by a lid Housing located capacitor winding, of which both an anode foil and a cathode foil by a number of inner connection strips distributed over the length of the foils with at least two external ones Connections are electrically connected, characterized in that the inner connections meet electrical ribbon cables included, which are formed by two electrically conductive strips that are separated from each other by a electrical insulating strips are separated, from which an electrically conductive pair of strips assigned to a ribbon line, one each with the anode foil of the capacitor winding and the other is connected to the cathode foil of the capacitor coil at a point which is adjacent to the connecting parts the strip line concerned is adjacent to the anode foil. 2. Capacitor according to claim 1, characterized in that said external connections are two of Contain an insulating layer separated from each other, L-shaped metal profiles, which over the aforementioned ribbon lines are connected to the capacitor winding. 130012/0811