DE2200582B2 - Low inductance capacitor for high frequencies - Google Patents

Description

The invention relates to a capacitor of low inductance for high frequencies, consisting of a of anode foils and cathode foils with an insulating layer in between, the Anode foils on one side and the cathode foils on the other side extend beyond the insulating layer and are electrically connected to each other.

Electrolytic capacitors for high frequencies, which have high capacitance and low dielectric strength, make it possible to filter at low frequencies and still have a high switching speed S to have. Electrolytic capacitors, which can operate at high frequencies, require low effective capacitors Series resistances and low effective series inductances, so as to reduce the amount consumed within the capacitor To reduce performance and thus the destructive

reduce the effects of overheating. The US-PS 35 18 500 and 32 75916 show for high frequencies usable electrolytic capacitors. However, the upper frequency limit should be increased even further and the manufacturing costs even further

is gen than it is with those in these patents capacitors shown is the case

The object of the present invention is therefore to produce an electrolytic capacitor in which the Series resistance and the series inductance of the capacitor is lowered even further over the known capacitors, and also significantly cheaper to manufacture.

According to the invention the object is achieved in that an anode plate and a cathode plate of approximately the same size due to an intervening insulating layer that electrically separates the two plates from each other insulated with the unit in rolled and flattened form with the plates electrical and is mechanically connected in such a way. that the anode plate with the anode foils and the cathode plate with the Cathode foils are bonded together at opposite ends of the unit.

The arrangement advantageously partially shortens the supply lines to the individual electrode foils compared to the known capacitors and thus reduces series inductance and series resistance, at the same time the manufacturing process is also simplified and thus cheaper.
A particularly favorable manufacturing process results from the fact that, according to a further development of the invention, the anode plate has an L-shape, with a central part encompassing the wing part of the L, that the cathode plate has an L-shape with a central part encompassing the wing part of the L, that the wing part of the cathode plate lies directly opposite the wing part of the anode plate, that the flattened winding is trimmed at all four corners in such a way that a number of the anode foils extend from one side of the unit and are connected to the wing part of the anode plate, that a number of the cathode foils are connected extends from the other side of the unit and is connected to the wing part of the cathode plate and that at least one further unit is fixed on the other side of the plate arrangement in a corresponding manner. This arrangement allows the capacitance of the capacitor to be doubled without also doubling the series inductance and the series resistance.
The capacitance of the capacitor can be increased even further without a proportional increase in series inductance or series resistance if, according to a further embodiment of the invention, three coils are arranged on each side of the plate arrangement in piggyback fashion and connected to the plate arrangement in this way that the anode foils of all windings electrically and mechanically with one another and with the anode plate and that the cathode foils of all windings are electrically

22 OO 582

trically and mechanically with each other and with the Kaöodenplatte are connected.

The space requirement of the capacitor is reduced if according to a further embodiment of the invention The anode and cathode plates are part of a film Metal consists that the anode and the cathode foüen consist of a film-bonded metal that the anode foil is normalized with a certain voltage and that the dielectric spacer material is impregnated with an electrolyte

Further advantages and possible applications of the invention emerge from the attached illustration of an exemplary embodiment and from the following description. It shows

F i g. 1 is a perspective view of a capacitor winding;

Fig. 2 is a perspective view of the coil of FIG. 1 after flattening,

F i g. 3 is a perspective view of the coil of FIG. 2 after cutting and bending,

F i g. 4 is a perspective view of three welded together Wrap,

Fig. 5 is a perspective view of a strip line arrangement;

6 shows a cross section of the stripline of F i g. 5 along line 6-6 with a wrap placed on each side.

F i g. 7 is a perspective view of a condenser container used to illustrate the contained therein Wrap has been opened and

F i g. 8 is a perspective view of a stacked Electrolytic capacitor.

The wound electrolytic capacitor pack of the invention is manufactured by first winding anode foils, dielectric: spacer papers and cathode foils in such an overlapping manner that anode foils and cathode foils flank the central part of the capacitor winding which contains alternating layers of anode foil, dielectric spacer paper and cathode foil is in Fig. 1 with the anode foil U extending on one side to the middle of the roll, spacer paper 12 in the middle, and cathode foil 13 extending from the dashed line 14 in the middle to the outer edge on the other side of the roll extends, wherein the spacer paper is arranged between alternating layers of cathode foil and anode foil. This coil is then flattened (FIG. 2) and, if necessary, on all four edges 15a. 156, 15c and i5d so as to be the ones shown in FIG. 3 to produce the construction shown, the anode foils 11 extending to one side and the cathode foils 13 extending to the other side of the winding. This shape facilitates any later bending of the foils.

The anode foil attachments 11 and the cathode foil attachments 13 are bent downward into the positions shown at 11a and 13a, respectively. The outermost parts of this Approaches are bent to the side for subsequent assembly and welding. Then there will be three such units rolled, cut and bent accordingly and placed on top of each other in a kind of piggyback fashion, wherein the anode foils on the one hand and the cathode foils on the other hand with one another cursing. These three units are then welded to form a capacitor pack 10, as shown in FIG. 4 shown. The cathode foils 13 are cut so that the pack after welding at the points 16 has a substantially flat bottom. The anode foils 11 on the other side of the pack are cut and differentiated in the same way However, fewer cuts can be made in the wrap to make similar ones, though also to form less favorable units. The flattened wraps can namely also without prior Cuts get bent, but bending problems and electrical flaws at the bends make it

ίο more advantageous to make a few cuts on the flattened corners to undertake.

This type of structure retains the low resistance and inductance values created by a stacked Structure are available, but also has the

is advantage of large savings in manufacturing costs, because these rolls can be made at a very high speed. The anode and cathode foils of the capacitor shown here are made of high purity aluminum (99% or higher), which means Corrosion problems are excluded and the formation of high quality aluminum oxide films is ensured. As an alternative, the anodes and cathode foils could also be made from another film forming a film Metal, such as B. tantalum or niobium can be produced. The anode foils 11 are required for the Tensile strengths produced using known processes. The cathode foils can also be shaped so that a non-polar capacitor is obtained. The anode and cathode foils have a thickness on the order of 0.05 to 0.076 mm Although FIG. 4 three coiled and Flattened wraps are welded together to form a package, but can of course also be more or less Wraps can be used per package, depending on the case.

which capacity properties are desired. The spacer paper 12 can be 0.0127 to 0.1 mm thick Be it Kraft or Benares paper that is normally used for electrolytic capacitors. The foil approaches can with With the help of a tungsten inert gas welding process (TIG) are welded together.

The stripline structure 20 shown in FIG. 5 is made up of an anodized aluminum plate 21 and a partially overlapping anodized aluminum cathode plate 23. which are separated from one another by an insulating layer 22. These units are laminated together. Terminals are formed at 28 and 29. Each plate has an L-like shape. As another option the anode and kithode plates can be made of another anodizable metal, such as e.g. B. tantalum or niobium. Both the anode plate 21 and the cathode plate 23 are the same Size and shape. After they are arranged in the strip line 20, an aluminum plate becomes slipped over so as to form a symmetrical T-structure, which is shown in FIG. 5 is shown. Here is the central part of the anode plate is essentially identical to the central portion of the cathode plate, but is the wing portion the anode plate is the mirror image of the cathode plate and directly opposite to the cathode plate The thickness of the cathode and anode plates 21 and 23 and that of the insulating layer 22 are aligned have been exaggerated in the drawing to better show the structure of the stripline. The anode and cathode plates of the preferred embodiment are typically 1.6 mm thick, but can can also be made thinner or thicker, depending on the respective requirements on the condensate

gate. The insulating layer 22 would be made of polyethylene terephthalate having a thickness in the range of 0.025 to 0.25 mm exist, although other insulating materials, such as. B. epoxy-coated fabric or polytetrafluoroethylene could be used for this. The wing part of the anode and cathode plates 21 and 23 is provided to facilitate the welding of the wraps of anode and cathode foils, as along the line 6-6 in F i g. 5 is shown. Although this particular geometric shape is special for the stripline seems to be cheap, other sizes and shapes of stripline are possible.

Two packages, each made of three flattened, cut, bent and welded wraps of foil and spacer paper are then connected to the stripline assembly using the TIG process welded (Fig. 7), with a wrap on each side on the outer edge of the wing part of the respective Plate is welded on. In Fig.6 are the cathode foils 13 of the electrode packs with the wing parts of the cathode plate 23 and the anode foils 11 with welded to the wing part of the anode plate 21. The two circuit boards in the stripline are electrical and mechanically separated by an insulating layer 22, while the foils are separated from one another by spacer paper 12 are separated. An anode terminal 28 and a cathode terminal 29 are located on the extended part of the Stripline. The capacitor 10 is provided with a standard electrolyte, e.g. B. glycol borate, impregnated and closed in a housing 31 with a cover 27 (FIG. 7).

In another embodiment, the stripline could be arranged so that the terminals meet extend to opposite ends of the capacitor case or package. These capacitors can be provided with two or four connections. In the illustrated embodiment each roll used to form a pekete has a film length of 152 cm. this applies for anode and cathode foils. Since six wraps are used and each wrap measures six inches, is the total length of the anode per capacitor 912 cm. Six capacitors of this construction have one average resistance of 0.00153 ohms. The resistance increases with the number of approaches or with a larger number of wraps providing a larger number of lugs. The for Connection of the cathode foil and plate previously described method for a stripline capacitor drastically reduce the foil and connection resistances and thus contribute to a low one Series impedance of the capacitor and make it useful for filtering at low impedance and for circuits suitable for high frequencies.

Many different embodiments are natural possible. For example, similar, albeit somewhat less favorable, results could be obtained with a rectangular stacked execution can be achieved, which is shown in FIG. 8 is shown. In this alternative embodiment are the overlapping layers of anode foils 41, spacer papers 42 and cathode foils 43 so on top of one another stacked that the cathode foils 43 reach only up to the perforated line 44, while the anode foils extend to an equal point on the other side of the central portion of the stack. Of this At this point the units can be machined in the same way as described for the flat wraps became. The protruding anode sets 41 and cathode lugs 43 can be bent and placed on others Units are mounted and welded in piggyback fashion. These packages can then be sent with the Strip line arrangement 20 are welded, as shown in FIG. 5, an anode plate 21 of anodized Aluminum separated from a cathode plate 23 made of the same material by an insulating layer 22 is. The strip line arrangement is laminated to one another.

The inductance of the capacitor according to the invention is much lower than it is with the help of a wound one Prior art arrangements achievable with multiple approaches is one of the greatest Advantages of the strip line cone described here capacitors is the cheap production that was discovered in connection with the flat coils. The misery agile work for the units was shown by approximately 70% versus the stacked sheet units the prior art, while even lower impedances and inductances are achieved could.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Low inductance capacitor for high frequencies, consisting of an anode foil and cathode foils with an insulating layer therebetween, the anode foils on one side and the cathode foils on the other side extend beyond the insulating layer and are electrically connected to one another, characterized by an anode plate (21) and a cathode plate (23) of approximately the same size, through an intervening insulating layer (22), which electrically isolates the two plates (21, 23) from one another, the unit (10) in rolled and flattened form is electrically and mechanically connected to the plates in such a way that the anode plate (21) with the anode foils (13) and the cathode plate with the cathode foils (11) are interconnected at opposite ends of the unit. 2. Capacitor according to claim 1, characterized in that the anode plate (21) has a Has an L-shape, with a central part encompassing the handle part of the L, that the cathode plate (23) has an L-shape, with a wing part of the L-comprehensive central part that the wing part the cathode plate (23) is aligned directly opposite the wing part of the anode plate (21) that the flattened winding (FIG. 2) is trimmed at all four corners in such a way that a number of the anode foils (13) extends from one side of the unit and is connected to the wing part of the anode plate (21) is. that a number of the cathode foils (11) extend from the other side of the unit and mil the wing part of the cathode plate (23) is connected and that at least one further unit on the other side of the plate assembly (20) is attached in a corresponding manner. 3. Capacitor according to claim 2, characterized in that that on each side of the plate assembly (20) three coils in piggyback fashion arranged one above the other and connected to the plate arrangement (20) in such a way that the anode foils (13) of all coils electrically and mechanically with one another and with the anode plate (21) and that the cathode foil (11) of all windings electrically and are mechanically connected to one another and to the cathode plate (23). 4. Capacitor according to claim 2, characterized in that that the anode (21) and the cathode plate (23) consist of a film-forming metal, that the anode (13) and the cathode foils (11) consist of a film-forming metal, that the anode foil (Ii) is formed with a certain voltage and that the dielectric distance measure material is soaked with an electrolyte.