WO2003009311A1 - Electroceramic component - Google Patents

Abstract

The invention relates to an electric component with a reduced capacity, a base body with areas made from a first ceramic material (1) and areas made from a second ceramic material (5), whereby the second ceramic material has a reduced dielectric constant compared to the first ceramic material. Two contact layers (10 and 15) are arranged on the surface of the base body. The first ceramic material contacts both contact layers, defines current path between both contact layers and determines the electric properties of the components, other than the capacities.

Description

description

Electro ceramic component

The present invention relates to an electro-ceramic component with a low capacitance and at least two contact layers provided on the surface of a ceramic base body.

Components of the type mentioned initially include e.g. Varistors. The basic body of such known components is often made from a mixture of different metal oxides, for example based on zinc oxide. Varistors have a non-linear voltage-dependent change in resistance that is used to protect an electrical circuit from overvoltage. The resistance value of varistors decreases with increasing voltage.

However, multi-layer varistors have not been used for overvoltage protection of high-frequency circuits, such as high-frequency input circuits for antenna inputs. This is due to the fact that the laminar structure of the multilayer varistors and the grain boundary effect of the varistor ceramic cause the capacitors to be too high. The result of this is that the high-frequency signal is generally disadvantageously attenuated by the high capacitance of the varistor.

From document DE 199 31 056 AI it is known to reduce the capacitance of varistors by arranging several layers of non-overlapping internal electrodes in the varistor base. The electrodes contact only one contact layer in such a way that they are at a certain distance from the other electrodes which are connected to the second contact layer and do not overlap them. The possibility is also disclosed of applying an electrically insulating passive layer to the varistor base body, to reduce capacity. The disadvantage of this method is that the capacitance-increasing effect of the base body of the varistor is still present. For example, a varistor ceramic based on zinc oxide has a dielectric constant in the range from 400 to 800. Therefore, this method can only be used to implement varistors that have a capacitance in the range of approximately 1.5 to 10 pF. However, varistors with a lower capacitance are often sought for the overvoltage protection of high-frequency circuits.

The object of the present invention is to provide an electro-ceramic component which avoids the disadvantages mentioned.

This object is achieved according to the invention by an electrical component according to claim 1. Advantageous configurations of the component are the subject of further claims.

The invention describes an electrical component with a base body, consisting of at least a first and a second ceramic material and at least two contact surfaces applied to the surface of the base body. The capacitance of the component is reduced in that the second ceramic material has a lower dielectric constant than the first ceramic material. The second ceramic material primarily serves to reduce the capacitance of the entire electrical component, while the first ceramic material, apart from the capacitance, defines the electrical properties of the component. In order to be able to exert a capacity-reducing influence on the entire component, the second ceramic material should be arranged at least partially between the contact layers, but need not necessarily contact them.

The electrical component according to the invention can be used, for example, as a varistor. In this case includes the first ceramic is a varistor ceramic, for example based on zinc oxide. In order to define the electrical properties of the component, at least some regions of the first ceramic material advantageously contact both contact layers and define a current path between these contact layers.

The advantages of the invention compared to conventional varistors, the base body of which is made up of only a single ceramic material, consist in the fact that the second material enables a sometimes considerable reduction in capacitance without impairing the varistor properties of the component. This enables the use of the varistors according to the invention in highly sensitive high-frequency circuits.

The second material is advantageously a ceramic based on spinels with the general formula AB2O4, where A is divalent metals and B is trivalent or tetravalent metals, for example ZnMn2Ü4. The A and B positions can advantageously be filled with the elements magnesium, manganese, selenium, cobalt, nickel, zinc, aluminum or iron. The zinc manganese spinel, for example, has a dielectric constant in the range of approximately 10 to 20 and is therefore considerably below the dielectric constant of the varistor material (approximately 400 to 800). It is also possible to use phase mixtures, for example based on zinc oxide and bismuth oxide as the second ceramic material. Optionally, sintering aids such as bismuth oxide or a glass melting at a suitable temperature can be added to the second material. The advantages of the materials mentioned are also that the first and second ceramic materials can be sintered together, so that the manufacture of the electrical component is greatly simplified. In the following, the invention and some of its configurations will be explained in more detail with reference to figures and an exemplary embodiment.

Figure 1 shows a conventional varistor.

FIG. 2 shows a varistor according to the invention with two ceramic materials.

FIG. 3 shows a varistor according to the invention with two ceramic materials, the second ceramic material not contacting the contact layers.

FIG. 4 shows a varistor according to the invention, which is constructed from alternating layers of the first and the second ceramic material lying one above the other.

FIG. 5 shows a varistor according to the invention with internal electrodes which intermesh like a comb.

FIG. 6 shows a varistor according to the invention with internal electrodes which are at a distance from one another.

FIG. 2 shows a varistor according to the invention, the base body of which consists of regions 1 of a first ceramic material and regions 5 of a second ceramic material. In this case, the two contacting layers 10 and 15 contact the two ceramic materials. In comparison to the prior art (FIG. 1), part of the varistor base body is therefore replaced by a second ceramic which has a lower dielectric constant. Since the capacity-reducing influence of the second ceramic material on the varistor is also possible if the second ceramic material does not contact the contact surfaces 10 and 15, an embodiment shown in FIG. 3 is also possible. The second ceramic material is on the first ceramic material, the varistor ceramic, applied without contacting the contact layers.

A construction from alternating layers of the first and second ceramic material lying one above the other is also possible, as shown in FIG.

In an alternative embodiment of the component, multilayer varistors can also be realized with inner electrodes 25, in which each inner electrode only contacts one contact layer 10 or 15, so that electrode stacks 30, 35 are formed, which are each connected to only one contact layer. These electrodes are advantageously only arranged in the first ceramic material, the varistor ceramic, and not in the second ceramic material.

FIG. 6 shows an alternative embodiment in which the inner electrodes do not intermesh like a comb, but in which comb-like electrode stacks face each other at a distance, the area 40 between the electrode stacks 30, 35 consisting of the ceramic material 1.

Comparative capacitance measurements between a varistor according to the invention, constructed according to FIG. 6, and a conventional varistor with internal electrodes, in which the base body is constructed from only one material, showed that at approximately 1 MHz the capacitance of a varistor according to the invention is approximately 0.3 pF im Compared to a capacitance of 1.5 pF with conventional varistors. The varistor voltage was approximately 370 V. The first ceramic material used for both varistor types was a varistor ceramic based on zinc oxide, while ZnMn2θ ₄ was additionally used as the second material for the varistor according to the invention.

With the help of varistors according to the invention, low capacitances of approximately 0.1 pF can be achieved. Experiments have shown that up to 2/3 of the base body of the varistor comes from the second ceramic material can be produced without adversely affecting the varistor properties of the component.

The invention is not restricted to the specifically described exemplary embodiments. Of course, there are further variations within the scope of the invention, in particular with regard to the design of the electrical component, the number and arrangement of the ceramic materials used, and the type and properties of the second ceramic material.

Claims

claims

1. Electrical component with reduced electrical capacity, - with a base body which comprises areas of at least a first ceramic material (1) and areas of a second ceramic material (5), in which the second ceramic material (5) has a lower dielectric constant than the first ceramic material - rial (1), in which at least a first (10) and a second (15) contact layer are provided on the surface of the base body, in which the second ceramic material is at least partially arranged between the first and second contact layers, - in which the first Ceramic material (1), apart from the capacity, defines the electrical properties of the component.

2. The electrical component as claimed in claim 1, in which the regions of the second ceramic material (5) are applied to at least parts of the surface of the first ceramic material (1) which is free from the contact layers (10, 15).

3. The component according to claim 1, in which the base body is constructed from alternating, superimposed layers of the first (1) and the second ceramic material (5).

4. Electrical component according to claim 1, in which in the base body a plurality of electrically conductive electrode layers (25) are provided, one above the other in the regions of the first ceramic material (1) and separated by a row (20) of the first ceramic material, each with one of the contact layers (10, 15) are electrically conductively connected, so that two electrode stacks (30, 35) are arranged, each contacting a contact layer, in which an area (40) consisting of the first ceramic material is located between the two electrode stacks (30, 35) (1) is present

5. Electrical component according to one of claims 1 or 2, - in which several in the first ceramic material (1) of the base body one above the other by regions (20) of the first ceramic material separated from each other electrically conductive electrode layers (25) are present, which alternate with one of the two contact layers (10, 15) are electrically connected, in which the electrode layers (25), which are each contacted by the same contact layer (10 or 15), form an electrode stack (30, 35).

6. Electrical component according to one of the preceding claims, wherein the first ceramic material comprises a varistor ceramic.

7. Electrical component according to one of the preceding claims, wherein the composition of the second ceramic is selected so that it can be sintered together with the first ceramic material.

8. Electrical component according to one of the preceding claims, wherein the second ceramic material comprises a spinel ceramic of the composition AB2O4.

9. The electrical component according to claim 8, wherein the second ceramic material is ZnMn2Ü4.

10.Electrical component according to one of claims 1 to 4,

- In which the second ceramic material comprises a phase mixture.

11.Electrical component according to the preceding claim,

- in which the phase mixture is ZnO / Bi2θ ₃ .