DE2529281C2 - Non-linear resistor body made of zinc oxide (varistor) - Google Patents

Description

20th

The present invention relates to an electrically nonlinear resistance body made of doped Zinc oxide as specified in the preamble of claim 1

It is known to use varistors made of zinc oxide to protect electrical systems, and both for so-called high-voltage systems with voltages over 1000 volts and for low-voltage systems with voltages below 1000 volts such as B. the household networks. These varistors should be there with their non-linearity of the electrical resistance and their limiting voltage, especially semiconductor elements, such as B. diodes, for example in power supplies of devices, transistors and thyristors, z. Am Protect control circuits with phase control for motors, in dimmers and the like.

From DE-OS 18 02 452, as here, possible non-linear resistance bodies made of zinc oxide known which are doped with various metal oxides, such. B. with oxides of cobalt, manganese, indium, Antimony, titanium, boron, aluminum, tin, barium, nickel, molybdenum, tantalum, iron and chromium. In particular but contain all zinc oxide bodies of this publication, up to 10 mol%, bismuth oxide as mandatory component. Bismuth oxide is because of its strong evaporation and because of the In addition, the high toxicity of bismuth vapors is an additive that not only causes major problems in production which raises non-linear resistance bodies, special due to the associated necessary extremes Protective measures make the end product considerably more expensive

The following proportionality is used to evaluate a varistor:

In this proportionality, the current flowing through the varistor when the voltage V is applied and C is a constant which corresponds to the electrical voltage dropping in the direction of the current along one millimeter of the resistor body, namely if the current density is 1 mA per cm ² . Instead of the letter C, the symbol V'i is also used. The variable λ (also referred to as η in the prior art) is the exponent of the non-linear voltage dependence of the varistor. It should be pointed out that even a numerically only slight increase in the exponent corresponds to an already substantial improvement in the non-linearity

From DE-OS 22 15 933 a bismuth-free composition of such a resistor body is known, which contains zinc oxide as an additive to silica It can thus only relatively low exponent η of the non-linearity at low voltage values C erreichea

Other bismuth-free varistors have also been made using two different approaches. In one case, zinc oxide, which is favorable for varistors, has been abandoned and silicon carbide and selenium have been used for this purpose Create a barrier layer in the area of the electrode. Reference is made to DE-OS 20 09 319 in this regard. Lanthanum oxide and / or yttrium oxide were used as dopants and cobalt oxide and manganese oxide as further dopants In this way, values for the exponent « (see also the table in this publication) are insufficiently low.

It is the object of the present invention to provide a non-linear resistance body of the type mentioned at the beginning To create kind on the basis of zinc oxide, despite the achievable high non-linearity and one for limiting voltages C-value adjusted in the low-voltage range with the simplest possible procedure can be produced using simple, technically unproblematic substances

This object is achieved with the features of claim 1.

According to the invention, neodymium in an amount of 0.1 to 10 atomic% and cobalt are used as additives also used in an amount of 0.1 to 10 atomic% in each case as an element or as a compound of the element, The quantities given are based on the elements and the firing temperature is between 1150 and 1400 ° C. It has been shown that the specified Additives alone are sufficient to produce resistors with the desired properties.

It has proven to be beneficial to burn the pressed resistor body at a temperature of 1300 to 1350 ° C. The elements used as additives neodymium and cobalt can be in the form of their oxides, for. B. as Nd ₂ O ₃ or Co ₃ O ₄ , or as compounds of a different formula or in elemental form. The elements or their compounds are converted into oxides of neodymium and cobalt during the burning of the resistor bodies.

The ceramic resistor bodies according to the invention can have different values of C and oc depending on the amount of additives added and on the choice of the firing temperature. For this reason, it is desirable that the amounts of the additives added and the firing temperatures of the substances be selected toward the largest possible values of λ at a desired value of C.

The ceramic based on zinc oxide

see Resistance bodies with a voltage-dependent characteristic curve do not obtain the desired advantageous properties if only neodymium or only nedodymium or only cobalt is used as an additive. If only neodymium is added, the exponent κ becomes so small that the resistance body cannot be used in practice, while if only cobalt is added, essentially an ohmic resistance with very little non-linearity is obtained. On the other hand, resistance bodies with excellent non-linear tension are obtained if neodymium and cobalt are added in suitable proportions and amounts according to the invention.

The reason why the lower limit for neodymium and cobalt is limited to 0.1 atomic% while the The upper limit for the same substances is 10 atomic percent is as follows:

Apart from differences which arise depending on the firing temperature, if the addition of neodymium and cobalt is less than 0.1 atomic%, no noticeable effect is produced, and the properties of resistor bodies assembled in this way become inferior and indeterminate. If, on the other hand, quantities of neodymium and cobalt of more than 10 atom% are chosen, the exponent <x becomes smaller and the characteristics of the resistance bodies become unstable.

The firing of the pressed resistor body is z. B. in air at a temperature of 1150 to 1400 ⁰ C or preferably between 1300 and 1350 ° C carried out. If the temperature is lower than 1150 ° C, the density of the fired product will decrease, and at the same time the mechanical strength will decrease and the electrical properties will be inferior. At firing temperatures above 1400 ^° C. the value of the exponent decreases, and above 1500 ^° C. it becomes difficult to obtain uniform fired substances and to ensure the repeatability and controllability of the characteristic values of the products.

The invention will now be described in more detail using an exemplary embodiment.

The F i g. 1 and 2 show graphical representations of the characteristics of ceramic resistor bodies according to FIG Invention depending on the ratio and amount of additives added.

Neodymium and cobalt in the form of their oxides Nd2C> 3 and CO3O4 were added to zinc oxide in different proportions and quantities. The mixtures obtained in this way were sufficiently kneaded and ^{fired at 700 °} C. for one hour. Each of the substances thus obtained was sufficiently ground, shaped into circular disks 16 mm in diameter, and fired at various temperatures for one hour. The ceramic bodies produced in this way were subjected to an ablation process until a thickness of 1 mm was reached, and after electrodes were placed on the opposite surfaces of the bodies, the electrical characteristics were measured.

In Fig. 1, the maximum values of the exponent are plotted against the added amount of cobalt, wherein the firing temperature was 1300 ⁰ C, and neodymium being in the form of its oxide in an amount of 0.1 to 10 atomic% as converted to the element added Nd2Ü3. The corresponding values for the constant C are given in FIG. C is indicated in each case as the voltage K at a current of 1 mA.

It can be seen from FIGS. 1 and 2 that ceramic resistor bodies with excellent non-linearity of the voltage, the constant C of which was about 50 to 450 V, could be produced. In addition, it is of course possible to change the constant C towards larger values by changing the firing temperature of the pressed resistor body compared to the specified value

As described above, according to the invention ceramic resistance bodies for different limiting voltages with strong non-linearity Establish the tension by determining the firing temperature and the amounts added and the ratio of the Additives influenced in this way can be used particularly for the protection of electronic devices with low Establish suitable protective resistances for operating voltages.

1 sheet of drawings

Claims (2)

Patent claims: 1. Non-linear, due to its composition, voltage-dependent resistance body made of cobalt-containing zinc oxide and zinc oxide containing other additives, which after mixing and compression molding at a temperature between 1100 and 1450 ^° C 'is burned and then provided with electrodes, characterized in that as a further Addition of neodymium in an amount of 0.1 to 10 atom% with an amount of 0.1 to 10 atom% Cobalt content is included, the firing is carried out at 1150 to 1400 ° C 2. Non-linear resistance body according to claim 1, characterized in that the firing is carried out at 1300 to 1350 ° C