DE3147032C2 - Electric capacitor - Google Patents

Abstract

The invention relates to an electrical capacitor which is made up of several ceramic layers (11) which are alternately printed with metal layers (21, 22). The ceramic layers (11) printed with metal layers (21, 22) are arranged between a thicker base layer (12) and a thicker cover layer (13) and are densely sintered. In order to be able to realize extremely small designs or even higher capacitance values per unit volume, the metal layers (21, 22) cover the ceramic layers (11), with the exception of an area around the edges (14, 15), the cuboid ceramic body (1 ) Completely. Thin outer metallizations (2) around these edges (14, 15) protrude from a glaze layer (3) covering the ceramic body (1) or its outer surface and are electrically connected to known contact metallizations (4).

Description

The invention relates to an electrical capacitor according to the preamble of claim 1.

Such a capacitor is known from GB-PS 13 80 662.

In the case of known capacitors, they are preferably rectangular in shape and are one on top of the other arranged ceramic layers and printed metal layers are also rectangular and conformal and provided with a metal-free strip towards the outer contours. This metal-free strip must be off For reasons of problem-free manufacturability of such capacitors have a certain width, which in the Of the order of 0.4 mm and more. Particularly in the case of very small designs, they are cuboid Multi-layer capacitors, this width of the metal-free strips limits the minimum structural size to values around 1 mm x 2 mm.

DE-OS 29 21 409 discloses an electrical filter having a ceramic multilayer capacitor known. There each metal layer of the capacitor located on a ceramic layer has it two connecting surfaces protruding on two diametrically opposite edges of the capacitor body, which are twisted against each other for metal layers arranged one above the other. Even with this well-known Capacitors are the metal layers with the exception of the terminal surfaces on all sides of the front surfaces of the jacket of the capacitor body spaced apart by a metal-free strip.

A multi-layer capacitor, the metal layers of which are applied to the ceramic layers S-shaped, metal-free, running through the center of the surface of a ceramic layer Have strips is known from DE-AS 25 09 669. This known capacitor is also suitable not suitable for the smallest designs in the order of 1 mm x 1 mm.

GB-PS 5 71798 is an electrical one Capacitor known for relatively high performance, which consists of self-supporting metal sheets, with between the metal sheets and laterally surrounding them an insulating material forming the dielectric is available.

From DE-OS 2119 040 it is known multi-layer To process or grind capacitors in drum mills to remove the metal layers of the ceramic To expose layers on the surface of the cuboid ceramic body.

The outer surfaces of a ceramic body of a multilayer capacitor after sintering with grind off with a sandblasting blower in order to grind off any glaze residues that may have formed during the sinter firing, is known from DE-AS 17 64 214.

The present invention has for its object to provide an electrical capacitor of the im

The preamble of claim 1 mentioned type to the effect that even smaller than that known structural sizes of ceramic multilayer capacitors can be made available.

This object is solved by the features of the characterizing part of claim 1. Preferred developments of the OF ^INVENTION: dung are characterized in the subclaims

The advantages achieved with the invention are in particular that the production of even the smallest designs of 1 mm - 1 mm and smaller is easily possible because each metal layer covers the entire surface of a ceramic layer with the exception of a small defined area, so that cutting through one a plurality of capacitors containing stack is unproblematic. Such small capacitor designs are of particular importance in the course of the miniaturization of electronic circuits, if one considers that integrated circuits on silicon wafers on the order of a few mm ² with a large number of electrical functions are possible and that such circuits are usually larger in terms of dimensions with peripherally surrounding chip capacitors with only one function are.

The invention is shown in the drawing using an exemplary embodiment and comparing it with a known one Multi-layer capacitor explained in more detail. It shows

1 shows a known multilayer capacitor in plan view,

F i g. 2 shows an embodiment of a multilayer capacitor according to the invention in plan view,

F i g. 3 is a schematic, spatial representation of the internal structure of a capacitor Fig. 2,

4 shows a three-dimensional representation of the ceramic body a multilayer capacitor,

Fig.5 is a plan view of a glazed and an cube-shaped ceramic bodies rubbed off at its corners, and

F i g. 6 shows a three-dimensional representation of a multilayer capacitor.

F i g. 1 shows a top view of a ceramic layer 11 of a capacitor body 1, which is printed with a metal layer 21, which is shown hatched. as shown in dashed lines. The cross-hatched, overlapping surface area of the alternating metal layers 21 and 22, which determines the capacitance of the electrical capacitor, is smaller by the widths d \ and c / _2? the base area of the cuboid ceramic body 1. With a structural size of 1 mm · 2 mm and a width of the metal-free strips d \ - J ₂ = 0.4 mm, the overlap area is 0.2 mm · 1.2 mm = 0.24 mm ² with exactly aligned projection of the metal surfaces 21 and 22.

2 shows a metal layer 22 of a capacitor body 1, which extends into the vicinity of the edge 14, as well as a metal layer 21 underneath, which is delimited by the dashed line in the area of the edge 14. With the same structural size of the capacitor as that in FIG. ^{1, a cross-hatched area of 1 mm 2} , that is to say the area, results with a size of a coating-free triangular area of 1 mm side length

The capacitance value of such a capacitor is approx. 70% greater than that with otherwise the same parameter values of a conventional multilayer capacitor. Of particular importance, however, is that even smaller Bai'formen are realizable. Connecting layers 2 at the edges 14, 15 connect the inner ones Metal layers 21 and 22 and connect them in parallel to one of the two coverings. These connecting metal layers 2 must be so narrow that they do not bridge the metal-free, triangular areas, because this would mean a short circuit of the capacitor. One consisting of a layer of glaze Cover 3 covers the side surfaces of the capacitor body 1 or its entire surface with the exception of the corners 5 of the body 1. The targeted removal of the glaze layer at the corners 5 of the Condenser body 1 is made by scrubbing in a drum mill or by grinding. So that this The base layer and the top layer are not removed down to the metal layers 21 and 22 Ceramic body 1 preferably thicker than ceramic layers 11 which determine the capacitance value or several ceramic layers are arranged one above the other without metal layers, which the Close the condenser body 1 at the top and bottom. Through the defined removal of the glaze layer the connecting metal layers 2 are exposed on the surface of the capacitor body 1 and can are connected to the contact metal layers 4 known per se.

Fig. 3 shows the internal structure of a capacitor body 1, from which the shape of the metal layers 21 and 22 applied to ceramic layers 11 recognize is. The top metal layer 22 and the bottom metal layer 21 are thicker in this figure drawn to the alternating arrangement of the successive metal layers 21 and 22 around the Edges 14 and 15 of the capacitor body 1 to better illustrate. From this figure it can also be seen that the base layer 12 and the cover layer 13 are thicker than the capacitance value of the capacitor determining ceramic layers 11, on which the metal layers 21 or 22 are printed, with With the exception of a triangular area around the edges 14 and 15 on all four side surfaces of the Condenser body 1 protrude.

FIG. 4 shows a capacitor body 1 made up of several ceramic layers 11, the closed up and down by a thick base layer 12 and a thick cover layer 13 is. The metal layers 21 extend as far as the edge 15 and are at a distance from the edge 14. Conversely, the metal layers 22 extend as far as the edge 14 and are spaced apart from the edge 15. Interconnecting metal layers 2 in the area around the edges 14 and 15, the metal layers 21 and 22 respectively close in parallel to the two toppings together.

Fig. 5 shows a capacitor body 1, which with the exception of its corners 5 with a glaze layer is covered. The glaze is abraded from the corners 5, so that the connecting metal layers 2 at the corners 5 of the edges 14, 15 rake freely on the surface.

F i g. 6 shows the two protruding from the glaze at the rounded corners 5 of the capacitor body 1 Connection metal layers 2, which are electrically conductive with contact metal layers 4 known per se are connected.

For this purpose 2 sheets of drawings

Claims (9)

Patent claims: 1. Electrical capacitor, which consists of a ceramic base layer, a number of ceramic layers arranged one above the other, on the main surfaces of which the metal layers forming the two coverings are applied, and a ceramic top layer in which these ceramic layers are sintered together to form a dense, cuboid ceramic body which the n> metal layers of adjacent ceramic layers alternately exposed to contact on two edges formed by side surfaces of the ceramic body and are connected here with connecting metal layers applied to the ceramic body to form a coating, characterized in that the metallic layers (21, 22) forming the coatings the ceramic layers (11) with the exception of a surface area around one of the adjacent or diametrically opposite edges (14) or (15) covered with a connecting metal layer (2) completely cover that an electrically insulating sheath (3) surrounds at least the side surfaces of the cuboid ceramic body (1) and - 'covers the connecting metal layers (2) so that the casing (3) at least at the corners (5) of the ceramic body (1) closing the edges (14, 15) is removed so that the two connection metal layers (2) are exposed there so that they can be contacted, and jo that an outer contact metal layer (4) is electrically conductively connected to each connection metal layer (2) exposed at the corners (5). 2. Electric capacitor according to claim 1, characterized in that the metal-free areas on the surface and edges (14) and (15) are formed triangular or quarter circle. 3. Electrical capacitor according to claim 1 or 2, characterized in that the two Connection metal layers (2) the edges (14, 15) and areas of the side surfaces of the near them Cover the ceramic body (1). 4. Electrical capacitor according to one of claims 1 to 3, characterized in that the ⁴ ^ two connecting metal layers (2) also cover the areas of the two main surfaces of the ceramic body (1) close to the two edges (14, 15). 5. Electrical capacitor according to one of claims 1 to 4, characterized in that the ^M ceramic base layer (12) and the ceramic cover layer (13) of the ceramic body (1) is several times thicker than that with metal layers (21,22) covered ceramic layers (11). 6. Electrical capacitor according to one of claims 1 to 5, characterized in that the the connecting metal layers (2) and the contact metal layers (4) assigned to them in each case spatially separating electrically insulating sheath (3) a glaze or a layer of the Material of the ceramic layers (11) is that only the side surfaces of the ceramic body (1) or the ceramic body (1) on its entire surface covered. 7. Electrical capacitor according to one of the * " Claims 1 to 6, characterized in that the casing (3) at the corners (5) of the cuboid Ceramic body (1) is only removed in the area of the base layer (12) and the cover layer (13) 8. Electrical capacitor according to one of claims 1 to 7, characterized in that the two contact metal layers (4) opposite end faces and areas of the close to them covered ceramic body (1). 9. Electrical capacitor according to one of claims 1 to 8, characterized in that the Ceramic body (1) has a rectangular or square base.