DE1281581B - Electrolytic capacitor - Google Patents

Description

Electrolytic capacitor The invention relates to an electrolytic capacitor with a cathode cup that accommodates the anode and the electrolyte and is passed through a disk-shaped sealing washer penetrated by the anode connection Maintaining a cavity opposite the electrolyte is complete.

In the known capacitors of this type is to hold a Insulating washer and a sealing washer, a bead running all around in the cathode can necessary. This bead has the disadvantage that it makes it impossible to use the anode body to be installed at the smallest possible distance from the inner wall of the beaker, unless that the bead is only embossed after the anode body has been installed, which is, however, from a manufacturing point of view is inexpedient because attaching a bead and flanging the edge of the cup usually takes place in two production steps. In addition, the known electrolytic capacitor the anode body is not supported in the axial and radial directions.

The invention is based on the object of an electrolytic capacitor of the known design mentioned at the outset so that it makes optimal use of it the inside of the cup to achieve the highest possible capacity while at the same time high shake resistance guaranteed.

The solution to the problem is that the anode body between a base-side centering support known per se and a preferably funnel-shaped, the spacer carrying the sealing washer is supported radially and axially and that sealing linings of the disc, the inner wall of the cup and the lead out anode connection are fused to form a cohesive sealing layer.

Due to the lack of a bead in the cup according to the invention In addition, the type of sealing is inevitable regardless of any over time decreasing compressive forces.

In the electrolytic capacitor according to the invention, the anode connection is in the area of the passage through the sealing washer with a coating of sealing compound Mistake. The inner wall of the cup is also in the area of contact with the circumference the sealing washer equipped with a band-shaped covering made of sealing compound.

The sealing body preferably consists of at least two discs, between which there is sealant.

The preferably porous anode and the spacer can be made of tantalum or niobium, with the electrolyte having an excess of silver ions or Has copper ions beyond the amount that can be dissolved in it.

To produce the electrolytic capacitor according to the invention, proceed in such a way that the anode connection from a point slightly above the Anode face from up to a point above the edge of the seal body with a coating of adhesive, water- and electrolyte-repellent sealing compound, preferably at an elevated temperature, is provided that thereon the spacer is placed on the anode that the inner wall of the cathode can in the area the contact with the periphery of the sealing body with a band-shaped layer is provided from the same sealing compound that the multi-layer design Sealing body provided with the same sealing compound in its intermediate layers is placed on the spacer that after filling a certain amount of electrolyte the anode carrying the spacer and the sealing body into the cathode can is introduced, against the bottom of which it is supported with the anode support, and that finally by the action of pressure and / or heat the sealants to mutual confluence are brought, whereupon in a known manner the protruding edge of the cathode cup to hold the sealing body and the parts supporting against it is flanged.

The figures explain the invention using an exemplary embodiment. It represents F i g. 1 shows a condenser in axial section before compression of the sealing washers, FIG. 2 the finished capacitor, FIG. 3 the individual Parts of the capacitor, separated from one another in the direction of the longitudinal axis.

The anode body 12, which is secured axially and radially by a centering support 13 , is located in the cathode cup 11. The cathode connection 15 is soldered to the bottom 14 of the cup 11 using the solder 16. The electrolyte 17, the level of which extends approximately to the upper edge of the anode 12, is located in the cup. The upper end of the cup 11, from which the anode connection 18 is led out, is closed off by a sealing body 20 which seals with sealing compound 19 both against the cup and against the connection 18. This is fixed in its position opposite the anode 12 by a preferably funnel-shaped spacer 21, so that there is a free space above the electrolyte which prevents the electrolyte from expanding due to higher temperatures and the vapor or gas formed during operation of the capacitor Permitted to include the threat to the seal. The spacer 21 can be of relatively small thickness so that it takes up little space. It is preferably made of the same material as the anode, so that it also has a relatively high mechanical strength.

The seal is made by means of two plastic disks 20 a and 20 b and an inert, sufficiently elastic, adhesive mass 19, which has three functions, namely that of firm adhesion to the aforementioned electrical metal parts, and also that of elastic compensation while maintaining the seal of the through Changes in temperature caused mutual relative movement of the parts in question and finally summarized the sealing of the capacitor with regard to its electrolyte content and the resulting amounts of steam or gas. If it is considered necessary, for example with regard to the mechanical strength of the connecting line 18, then the space created by the flanging of the cathode cup edge can also be potted with casting resin 22, whereby the already very good seal is additionally secured.

The anode 12, which is made of valve metal such as tantalum or niobium, is held in the cup 11 in an axial and radial relationship so that it is shockproof and shake-proof. For this purpose, a preferably three-armed anode support 13 made of plastic and provided with a centering point is used (see USA patent 2758259).

The electrolyte 17 can be in a liquid state or in an immobile state Find form use; it can contain a suitable depolarizing substance, to the greatest possible extent any gas formation during operation of the electrolytic capacitor to prevent. If the electrolyte is to be used in immobile form, then a gel-forming agent is added to the initially liquid material, which in Connection with this does not result in any harmful reactions, e.g. B. silica gel.

The anode connection 18 is preferably made of the same material as the anode and is firmly connected to it. In order to be able to solder the capacitor into a circuit later, a solderable, preferably a tin-plated nickel wire 23 is welded to the anode connection 18. The sealant is provided as a coating 19a on the anode terminal 18 in the required width through the two plastic discs 20 a and 20 b provided also. The spacer 21 is arranged in such a way that it encloses the connection 18 and covers as little as possible of its surface at its contact point on the anode 12. On the inner surface of the cup at the level of the intended seal there is a sealing compound 19 b applied in approximately the same width and thickness; it extends so far in the axial direction that it still protrudes sufficiently on both sides compared to the later finished seal. The acid-resistant plastic disk 20 a rests directly on the sufficiently stable spacer 21. Between the two plastic washers 20a and 20b is provided from a sealant layer 19 c, which first touched neither the anode terminal 18, the edge of the two discs.

Since the z. B. funnel-shaped spacer 21 only a little over 1 / 1o mm thick, very little material is needed for it, and still its mechanical strength is relatively high. That way do not need how it has heretofore been customary to use relatively thick plugs, so that in this regard, the height of the capacitor can be kept optimally small and also its operating properties, including its tightness behavior, are improved will.

Since the adhesive sealant is water- and electrolyte-repellent is, the sealing surface is already wetting during the assembly of the capacitor practically prevented. As a sealing compound, such a use is found with the electrolyte, e.g. B. sulfuric acid, which does not react in the one for the condenser The effectiveness of the temperature range in question is not damaged and those on materials such as silver and tantalum or its oxide, firmly and tightly adhesive adheres. Such a mass is, for example, polyisobutylene; for the intended For the sealing purpose, a polyisobutylene with a high degree of polymerisation is selected, that at the highest, for the. Capacitor occurring temperatures not yet flows, but it is sufficiently plastic. Instead of polyisobutylene you can however, other masses can also be used. However, they must have the following properties have: 1. Form an electrolyte-repellent surface and are inert to the various be eligible electrolytes, 2. have a sufficiently high adhesive strength, 3. easy to handle, 4. over a wide temperature range (from -55 to -I-125 ° C) be applicable without flowing, 5.have high electrical strength, 6. have a low permeability for water vapor.

The rigid seal discs 20a and 20 b are made z. B. from a fluorine-containing plastic, such as polytetrafluoroethylene or Polytriftuorchloräthylen, which are specially pretreated so that they give a particularly high adhesive strength for the aforementioned sealing compounds. To achieve a particularly high mechanical strength, the disc 20 b made of plastic reinforced with glass, for. B. epoxy resin exist.

F i g. 2 differs from FIG. 1 only in that the seal is in its final form. The rigid plastic disks 20 a and 20 b are tightly adhered to one another and connected to the capacitor electrodes by the sealing surfaces 19 a, 19 b and 19 c. This state was achieved by applying pressure, preferably with a heated tool, to the upper pane 20b, as a result of which the sealing compound could flow together at the various points to form a cohesive layer. Then the upper edge of the cup 11 is then shaped in accordance with FIG. 2 flanged, the discs 20 a and 20 b lying on top of one another in the axial direction, the spacer 21, the anode 12 and its centering bracket 13 being immovably firmly pressed together in support against the cup base 14. The casting resin 22 is then introduced into the trough formed by the beading of the cup rim and then cured. Since the anode connection 18 is bare in this area, there is a good, ie mechanically strong and tight bond with the casting resin 22, in particular epoxy resin. The closure with cast resin is used to give the anode connection wire a mechanically secure hold.

The F i g. 3 shows the parts of the capacitor moved apart in the axial direction and explains how the assembly is to be carried out. First, the cathode cup 11 (made of silver or another suitable metal) is thoroughly cleaned so that there are no traces of an oil film or other contamination on the surface. The cathode connecting wire 15 is preferably soldered to the cup.

The anode support 13 is inserted into the cup. The anode connection 18 of the anode 12 is provided with a coating 19a made of an adhesive sealing compound. This coating extends from a point slightly above the anode face to a point above the sealing body consisting of the closure disks 20 a and 20 b. The coating is preferably applied at an elevated temperature in order to ensure a particularly good bond to the anode connection. The spacer 21 is placed on the anode after the anode connection has been introduced. A sufficiently wide strip is then attached to the inside of the cathode can 11 made of the same adhesive sealing compound in an area in which the sealing body consisting of the disks 20a and 20b will later be located protrudes. The sealing washers 20 a and 20 b are then pushed over the anode connection 18. A disk laminated with a layer of adhesive sealant can also be used; when using two separate disks 20 a and 20 b, a ring 19 c is made of sealing compound on one of the inner sides of the disks, but initially does not reach the outer edges of the disk or the edge of the central hole. The electrolyte (sulfuric acid H., SO4), which contains silver sulfate if the cathode cup 11 is made of silver, is now filled up to approximately the upper edge of the anode 12. The abovementioned depolarizer must be present in such an amount that the electrolyte (H, SO4) is saturated with it in considerable excess (see U.S. Patents 2,710,369 and 2,778,979). The anode is then carefully inserted into the cathode cup 11, so that the thin covering tape 19b of sealing compound is not damaged and that the anode 12 is exposed to the electrolyte for a sufficient period of time to fill it up to the greatest possible extent. The rigid sealing washers 20 a and 20 b, which are now on their periphery in contact with the sealing tape, are pressurized with a preferably heated tool so that the sealing layer 19 c between the two disks 20 a and 20 b melts and radially and is also pushed out axially through the feed-through opening for the anode connection 18. The sealant combined thereby with the sealant 19a at the anode terminal 18 and with the sealant 19 b on the inside wall of the cup 11. While the upper sealing washer is held in position takes place with a different tool, the changeover or crimping of the upper edge of the cup to fix the sealing washers in their final position.

To the anode terminal 18 is an extension 23, for. B. a tinned nickel wire, welded on. Finally, the trough created by the flanging of the upper edge of the cup is filled with casting resin 22 , which is then cured. The invention is primarily intended for use on tantalum and niobium capacitors. However, zirconium, titanium or aluminum can also be used as film-forming anode metals.

The capacitor according to the invention can be optimally small in dimensions perform, but this is not the only advantage of the invention.

Claims (9)

Claims: 1. Electrolytic capacitor with a cathode cup receiving the anode and the electrolyte, which is closed by a disk-shaped sealing washer penetrated by the anode connection while maintaining a cavity with respect to the electrolyte, characterized in that the anode body (12) is between a per se known centering support (13) on the bottom side and a preferably funnel-shaped spacer (21) carrying the sealing disk (20) is supported radially and axially, and that sealing linings (19 a to 19 c) of the disk (20), the inner wall of the cup and the anode connection (18 ) are fused to form a cohesive sealing layer. 2. Electrolytic capacitor according to claim 1, characterized in that the anode connection (18 ) is provided with a coating (19 a) made of sealing compound in the region of the passage through the sealing washer (20). 3. Electrolytic capacitor according to claim 1 or 2, characterized in that the cup inner wall in the area of contact with the periphery of the sealing washer (20) is provided with an approximately band-shaped covering (19 b) made of sealing compound. 4. Electrolytic capacitor according to Claims 1 to 3, characterized in that the sealing body consists of at least two discs (20 a, 20 b), between which there is sealing compound. 5. Electrolytic capacitor with a silver cathode according to claims 1 to 4, characterized in that the preferably porous anode and the spacer from a valve metal, like tantalum or niobium, and the electrolyte has an excess of silver ions over the amount soluble in it. 6. Electrolytic capacitor with a copper cathode according to Claims 1 to 4, characterized in that the preferably porous anode and the spacer made of tantalum or niobium and the electrolyte has an excess of copper ions over the amount that can be dissolved in it. 7. electrolytic capacitor according to claims 1 to 6, characterized in that the Sealant is adhesive on metals and non-metals and in a temperature range from -55 to + 125 ° C neither embrittles nor melts. B. Electrolytic capacitor Claims 1 to 7, characterized in that the sealing compound is water- and electrolyte-repellent is. 9. A method for producing an electrolytic capacitor according to claims 1 to 8, characterized in that the anode connection from a point slightly above the anode face up to a point above the edge of the sealing body with a coating of adhesive, water- and electrolyte-repellent sealing compound, preferably at elevated temperature, is provided that thereupon the spacer is placed on the anode that the inner wall of the cathode can in the area the contact with the periphery of the sealing body with a band-shaped layer is provided from the same sealing compound that the multi-layer design Sealing body provided with the same sealing compound in its intermediate layers is placed on the spacer that after filling a certain amount of electrolyte the anode carrying the spacer and the sealing body into the cathode can is introduced, against the bottom of which it is supported with the anode support, and that finally by the action of pressure and / or heat the sealants to mutual confluence are brought, whereupon in a known manner the protruding edge of the cathode cup to hold the sealing body and the parts supporting against it is flanged. Considered publications: German utility model No. 1820 906; Patent No. 26 713 of the Office for Invention and Patent system in East Berlin.