DE3612290A1 - Solid-electrolyte capacitor - Google Patents

Abstract

A cut-off safety device which is suitable for a solid-electrolyte capacitor consists of two metallic side surfaces (4, 5) and a thin metal layer (2) which is deposited on the surface of an insulator (1). That part (3) of the metal layer (2) which is arranged between the side surfaces (4, 5) is used as a safety path, which can possibly be covered by varnish (6). <IMAGE>

Description

The invention relates to a solid electrolytic capacitor with a sintered anode made of a valve metal, one on arranged oxide layer serving as dielectric, a semiconducting electrolyte as cathode, a catho denkontaktierung, an anode and cathode connection and a shutdown protection.

Such capacitors are from DE-A1-33 19 371 be knows, the cut-off protection in the supply line of Cathode connection integrated as a narrowed section and is designed as a fuse.

In the solid electrolytic capacitors mentioned in general tantalum as valve metal for the manufacture of Sintered anode used, and the one serving as a dielectric Then oxide layer by an electrochemical Forming process generated on the anode. Serves as the cathode mainly semiconducting manganese dioxide, on which one Contacting layer is attached, which is preferably of a graphite layer and one arranged thereon Silver layer exists.

Such capacitors have a short circuit or with incorrect polarity over no current limitation, so that There is a risk that the short-circuit current will damage the capacitor heated so much that the anode body begins to glow.  

There are a number of ways to address these difficulties Fuse elements have been proposed. In addition to the one The above-mentioned shutdown protection is also from the DE-A1-29 47 185 a fuse element known from one arranged in a cavity of an insulating body Fusible wire fuse exists. The well-known backup however, elements require a complex manufacturing technology nik.

Furthermore, from DE-A1-29 23 623 is one with insulation particle-permeated conductor layer as a possible security known. In this embodiment, it is difficult to achieve reproducible switch-off results aim.

Finally, DE-C3-25 31 438 is a switch-off device cherung known, in which a space between the Cathode connection and the cathode contact by ei ne metal alloy is bridged, which as a fuse tion serves. The difficulties with this execution Form can occur, are that for the An speak of the fuse heating the capacitor body pers is required.

The object of the invention is to provide a shutdown protection for specify a solid electrolytic capacitor, which at a Short circuit or incorrect polarity an excessive current prevented from rising, thereby excessive heating of the Ano prevented the body, is economically producible and has defined shutdown properties.

This object is achieved in that the shutdown protection from two metallic side surfaces exists between which a thin conductor layer of egg  an electrically conductive material on the surface Nes insulator is arranged in electrical contact with the metallic sides.

The conductor layer, which is preferably made of nickel or Copper is used in an electrolyte bath deposited without current or applied by lamination.

Further expedient configurations of a solid electrolyte capacitors with cut-off protection are in the lower sayings.

The shutdown protection according to the invention has the advantage on that it is economical to manufacture and define has shutdown properties. Another advantage is that after the fuse has responded, the ohmic resistance of the fuse element in the range of 10 kΩ is due to the fact that decomposed insulation material frees it up Carbon is formed.

This resistance is high enough to withstand the short circuit current limit so that it is no longer used to glow the anode body leads. On the other hand, this resistance is small Comparison to that of an intact capacitor (<10 MΩ). Capacitors that have a short circuit and their Fuse has responded, even if it is in Printed circuit boards are easily soldered through Resistance measurement can be determined.

The shutdown protection according to the invention has the advantage of small geometric dimensions (e.g. 1 mm × 1 mm × 1 mm), as well as the hassle-free way of electrical values the fuse (ohmic resistance, switch-off current) by varying the conductor layer thickness. Derar  Term shutdown safeguards, for example, have a resistance level of <0.1 Ω and switch-off depending on the layer thickness currents from 3 to 5 A. After the fuse has responded The resistance is 5 to 50 kΩ.

Appropriate configurations of the shutdown protection will be described in the following embodiments.

Show in the accompanying drawing

Fig. 1 shows an embodiment with enhanced Anschlußbe rich,

Fig. 2 shows an embodiment with metallic covering surfaces,

FIGS. 3 and 4 embodiments, with butt welded connection elements,

Fig 5 locking elements. An embodiment with flat welded An,

Fig. 6 is a cut-out fuse capacitor during an axial cup,

Fig. 7 is a switch-off protection in a radially wirte th plastic cup capacitor and

Fig. 8 is a cut-off protection in a plastic th chip capacitor.

In Fig. 1, the embodiment of a switch-off is shown, in which on an insulating body, preferably made of epoxy resin, an approximately 5 microns thick metallic Ka is arranged. The middle part of this Kaschie tion 2 remains unreinforced and serves as a backup route 3rd Two side areas 4 , 5 of the lamination 2 are either galvanically or reinforced by soldering a sheet and bil the connection areas for contacting the connection elements. The middle part, which serves as a securing section 3 , can optionally be covered by a lacquer 6 .

In Fig. 2 a further embodiment of a circuit breaker is shown, in which an insulating body 7 between two metallic cover plates 8 , 9 , z. B. made of nickel. The cover plates 8 , 9 are used for contacting the connection elements. A thin, approx. 5 µm thick metal layer is electrolytically deposited on the entire fuse element. The metal layer on the insulating body 7 , which preferably consists of epoxy resin, serves as a securing section.

In Fig. 3, a possibility is shown how the shutdown protection shown in Fig. 2 can be arranged in a supply line of the solid electrolytic capacitor. The tantalum wire 10 anchored in the sintered anode and the anode-side connecting wire 11 , e.g. B. of nickel or copper, are butt welded to the flat sides of the metallic cover plates 8 , 9 , z. B. by resistance spot or percussion welding.

In Fig. 4 another possibility is shown to install the termination protection of FIG. 2 by a blunt Ver connection elements 10 , 11 on the end faces of the cover plates 8 , 9 in the anode lead of a solid electrolytic capacitor.

In Fig. 5 it is shown how the shutdown protection according to Fig. 1 te by means of flat welded connecting elements 10 , 11 is installed in the anode lead of a solid electrolytic capacitor.

In Fig. 6 the use of a cut-off fuse 15 is shown in a built in a metal cup 29 fixed electrolytic capacitor. The capacitor consists of the anode body 12 and the wire 10 arranged therein. Anode body 12 and wire 10 are made of the same material, preferably tantalum. The capacitor is fastened in the metal cup 29 by the soldering tin 13 , which simultaneously serves as the cathode contact. A connecting wire 30 on the cathode side is arranged on the outside of the cup 29 . The anode-side connecting wire 11 is insulated from the metal cup 29 by a pressure glass bushing 14 .

In Fig. 7 a further embodiment is shown in which a cut-off device 16 between cathode contact 17 and cathode-side connecting wire 18 is net angeord. The anode body 18 is arranged in a plastic cup 19 , which is filled with a potting compound 22 after installation. The anode contact 20 , e.g. B. a tantalum wire is welded to the anodensei term lead 21 .

In Fig. 8, the embodiment of a chip-solid electrolytic capacitor is shown, in which the cut-off device 25 is arranged between the anode contact 28 and the anode-side terminal 27 . The anode body 23 with the connection 24 on the cathode side is surrounded by a coating compound 26 .

Claims (9)

1. Solid electrolytic capacitor with a sintered anode made of a valve metal, an oxide layer arranged thereon, serving as dielectric, a semiconducting electrolyte as cathode, a cathode contact, an anode and cathode connection and a cut-off fuse, characterized in that the cut-off fuse ( 15 , 16 , 25 ) of two metallic side surfaces ( 4 , 5 ; 8 , 9 ), between which a thin conductor layer ( 2 ) made of an electrically conductive material is arranged on the surface of an insulator ( 1 , 7 ), which in electrical contact with the metallic side surfaces ( 4 , 5 ; 8 , 9 ). 2. Solid electrolytic capacitor according to claim 1, characterized in that the Lei terschicht ( 2 ) consists of nickel or copper. 3. Solid electrolytic capacitor according to claim 1 or 2, characterized in that the conductor layer ( 2 ) is produced by electroless deposition or ka. 4. Solid electrolytic capacitor according to one of claims 1 to 3, characterized in that the cut-off protection ( 15 , 16 , 25 ) consists of an insulating body ( 1 ), preferably made of epoxy resin, with an approximately 5 µm thick metallic lamination ( 2 ) is seen ver, and that the lateral areas of the lamination are either galvanically or by soldering a sheet metal ( 4 , 5 ) reinforced. 5. Solid electrolytic capacitor according to one of claims 1 to 3, characterized in that the cut-off protection ( 15 , 16 , 25 ) consists of two metallic cover plates ( 8 , 9 ), preferably made of nickel, between which an insulating body ( 7 ) is arranged, and that on the insulating body ( 7 ) a thin, by electroless galvanic deposition, about 5 microns thick metal layer is arranged. 6. Solid electrolytic capacitor according to claim 5, there characterized in that the Me Shoot the metal layer on the entire shutdown protection that is. 7. Solid electrolytic capacitor according to one of claims 1 to 6, characterized in that the connections ( 10 , 11 ) are butt-welded onto the metallic surfaces ( 8 , 9 ). 8. Solid electrolytic capacitor according to one of claims 1 to 6, characterized in that the connections ( 10 , 11 ) flat on the metallic surfaces ( 4 , 5 ) are welded. 9. Solid electrolytic capacitor according to one of claims 1 to 8, characterized in that the thin conductor layer ( 2 ) is covered with a varnish ( 6 ).