DD200766A1 - METHOD FOR THE PRODUCTION OF VALVE METAL INTERMEDIATE BODIES FOR ELECTROLYTE CONDENSERS - Google Patents

Abstract

The invention relates to the production of valve metal sintered bodies of high specific charge and reduced valve metal use. The aim is to propose a process for the production of porous sintered bodies of high specific surface area and reduced tantalum use weight using valve metal-plated metal balls while avoiding the previous disadvantages. A below 800 degrees melting metal powder with a higher cubic expansion coefficient than the valve metal is coated with a maximum of 0.5 micron thick valve metal layer, the plated powder mechanically preformed and melted under vacuum or inert gas at elevated temperature of the metal core completely or partially to form valve hollow metal balls. The invention is applied to low-voltage electrolytic capacitors, optionally also as contact metal for chemical conversion processes.

Description

a) Title of the invention

"Process for producing yenmetal sintered bodies for electrolytic capacitors"

b) Field of application of the invention

The invention relates to the production of valve sintered sintered bodies of high specific charge and reduced Yield metal use. Such sintered bodies are used for the production of electrolytic capacitors.

c) Characteristic of the known technical solutions

In the production of anodes from Yentilaetallen, z, B. 'tantalum, niobium, titanium and alloys thereof, suitable for capacitors, present in selected grain sizes high-purity metals by mechanical shaping with subsequent sintering in a high vacuum in the desired open-pored and mechanically stable geometric Shape transferred. Hur part of the metal is required as an active part for the production of the dielectric and as a contact, while most of it serves as a supporting and electrically conductive skeleton substance. For a number of reasons, the above-mentioned yentil metals are subject to a constant increase in price, so that the optimization of the yenmetal metal fraction serving as builder substance is imperative.

Such anodes suitable for capacitors must have a high porosity. This is directly related to the specific surface of the anode body and thus to the surface of the dielectric to be formed or the capacity that can be achieved.

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For description, the specific charge (in, μC / g) is used as the product of Pormierspannung (in volts) and capacity (in / Ui ¹ ) related to the mass unit of the existing valve metal portion · According to the current state of the art are specific charges of about 7000 / UC / g the lower and 20000 / UC / g the upper limit.

The specific surface area is significantly influenced by low sintering temperatures, low densities and short sintering times. A minimization of all influencing variables is practically impossible, since both the mechanical stability of the anode body has to be considered and the fact that a subsequent cleaning of the sintered body by evaporation processes is desirable due to the sintering process. Thus, both the lowering of the sintering temperature and the sintering time is a limit, if not by other technological measures. These effects are minimized.

With a view to reducing the valve metal working weight, methods are known for producing the sintered bodies from tantalum-coated particles consisting of non-conductive and non-combustible materials or metals (DE-JiS 2127941, DE-OS 2721068, DE-OS 2524868, TJS 3708728, DE US-A-227941, DE 1105991, British Patent 1030004) or hollow spheres (US 3684929, DE-OS 2056875).

On the other hand, in order to increase the specific surface area, so-called gluster anodes consisting of agglomerates of particles of diameter from 1 to 100 are used (US Pat. No. 3,641,399) or leachable by use of leachable (DE-OS 2361197) (US Pat 4154609), ausschmelzbarer (DE-AS 2636279) or pore preserving (DE-OS 2361197) pressing aids to influence the degree of porosity or by using so-called sponge powders (DE-OS 2361197) or otherwise (DE-OS 2721068) to avoid a sintering process ,

In addition to the solutions in US Pat. No. 3,684,929 and German Offenlegungsschrift No. 2056875, these proposed technical solutions, on the one hand, dispense with the use of hollow spheres to increase the surface area and, on the other hand, reduce the

Use of valve metal-plated metal particles as .Ousgangsmaterial for the production of sintered bodies (DI 1105991) so far disadvantages that either in the case of faulty valve metal coatings short circuits between acting as an anode metal particles and the applied on the Ventilmetallüberzug cathode occur (DE-AS 2127941 Sp. 2) or when using soft metal particles at the necessary pressing pressure, inter alia too low a porosity results (DE-AS 2127941 Sp. 2).

d) Object of the invention

The described state of. Thus, the art discloses that the provision of a highly porous sintered body having reduced valve mass and high specific charge without adversely affecting other desirable properties, e.g. As low dissipation factor and low leakage current, could not be achieved with metal-valve metallplatierten balls with sufficient production safety, especially in thin valve metal coatings, could be achieved *

Thus, the object of the invention is to propose a process for the production of porous sintered bodies of high surface area and reduced tantalum weight using valve metal-plated metal balls while avoiding the previous disadvantages.

d) Presentation of the essence of the invention

The causes of the technical defect are that when using valve metal-plated metal particles in the case of faulty Ventilmetallüberzüge short circuits occur between the metal particles acting as an anode and the applied on the valve metal coating cathode or when using soft metal particles at the necessary pressing pressure u.a. too low a porosity results or the use of hollow spheres to increase the specific surface is only partially used.

The technical problem is valve metal hollow spheres

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to use in order to reduce the valve metal working weight for the production of porous sintered bodies and to link their Herst elimination process with the sintering process of the valve metal.

Erfindungsg EMM is achieved the object of the invention characterized by a below about 800 ⁰ C melting metal powder having substantially globular habit, which has a higher coefficient of cubic expansion than the valve metal is coated with a thin discontinuous valve metal layer and such platiertes powder using mechanically preformed at low pressure and then under high vacuum or at atmospheric pressure under inert gas at elevated temperature of the metal core wholly or partially removed from the system by Seiger * and'Abdampfprozesse.

As valve metals advantageously tantalum, alumina, tungsten, hafnium, titanium, zirconium or alloys thereof can be used. »

The dielectrically active oxides of these valve metals are characterized by particularly high dielectric constants. The undesired transition from the amorphous to the crystalline state is slowed down, in particular in the case of Job and Tantalum, so that the use of these valve metals is given priority.

The usable as core material metals having a melting point below 800 ⁰ C and a tantalum increased cubic expansion coefficient are limited in terms of the required physical constants, so that are suitable for the application mainly aluminum, antimony, magnesium, cadmium, bismuth or zinc. They are to be used in a purity of at least 99j99 % and should have a spherical habit. However, the spherical shape is not a mandatory necessity, since even irregularly shaped particles, sometimes even more advantageous because of the increased surface area, are usable. By irregularly shaped particles layer thickness differences of the plating may be due, but which are so far without concern, as long as an electrically conductive sheath corresponding thickness of the valve metal is maintained. With thickness

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Separate plating is useful in the later segregation process, even because of the desired partial destruction of the valve metal shell.

With regard to the methods applicable to the plating of the core metals, both the electrolytic deposition of the valve metals from solutions of their halides or a plasmachemic reductive deposition from the vapor phase are possible, as well as the deposition via a sputtering or similar method familiar to those skilled in the art, wherein the metal powder below the sputtering on a flat disc and is mechanically circulated during the Piatierungsvorgangs.

In particular, the electrolytic deposition leads to a high purity of the valve metal coating, since both the coming to use as an electrolyte halide can be highly purified by a distillative Peinaufbereitung than seeks the deposition process itself because of the different Abscheidungspotentiale further purification. The plasma-chemical reductive deposition in the Hiederoruck range is similarly favorable because of the possible reduction of the deposition temperature compared with the classical CVD method.

The core metal powders themselves are prepared by suitable methods, e.g. by pressure evaporation, and are concentrated to nuclear fractions between 3 to 50 / um. In a further embodiment of the method, it is possible to accommodate the preformed valve metal-plated powders in cavities corresponding to the geometrical shape prior to thermal treatment of a material whose coefficient of expansion is smaller than that of the core metal and which may or may not be different from the molten core metal is low benetit, and there to heat under vacuum or inert gas so high that the melting point of the core metal is at least achieved. Alternatively, the shape of the valve-metal-plated powder may also be made such that the compression molds themselves are made of such a material and contain drainage facilities for the molten core metal.

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The advantages of such a procedure are that the pressing pressure of the valve-metal-plated powder is very low

can be kept (on the order of 100 to 600 kp / cm.sup.-1), thus avoiding excessive deformation of the core metal and, owing to the greater yolumen deletion of the core metal compared to the valve metal, upon heating, due to the small contact surfaces, forces of several .1Cr kp occur between the individual powder particles, which in combination with diffusionary alloying processes ^lead to mechanically stable anode bodies even at temperatures around 100 ° C. It also shows that such anode bodies have a density increasing from the inside to the outside and their average pore radius also from inside to outside decreases.

This results in e.g. with regard to the impregnation processes necessary in the course of further technological production steps for producing the cathode covering of the capacitor and with respect to the circulation of the Eormier electrolyte during the anodic oxidation necessary for the generation of the dielectric, compared to sintered bodies which are obtained by conventional methods The volume contraction occurring in the sintering process is precisely characterized in that. average pore radius decreases from outside to inside.

The sintered bodies obtained in this way can, depending on the core metal used, be heated up to max. 170O ⁰ C under vacuum heated to additionally produce any tantalum-core metal alloys formed, leaving behind a spongy tantalum with a serene specific surface.

The required layer thickness of the valve metal coating on the core metal isi? Depending on the anodization conditions and is composed of a maintenance of the electrically conductive connection just enough pilm thickness of about 0.05, and the computable for a respective anodization voltage layer thickness decrease of the valve metal together.

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For tantalum the rate of decrease 7 is "1 · 10" / Um per Volt For a hollow sphere of the valve metal that can be oxidized on both sides, an optimum valve metal layer thickness of 2, 7.1, erre "" ^{4 is} calculated, eg for a forming chip of 250 V. ". 250 + 0.05 = 0.40, um. Thus, the valve metal layer thicknesses of the plated core metal can be optimized with respect to the selected lubrication conditions.

A calculation of the theoretically possible specific charges of a sintered body made of hollow spheres shows that these are on the one hand almost independent of the total diameter of the hollow spheres, but on the other hand increase sharply with decreasing valve metal layer thickness. This eliminates the need to extremely reduce the hollow ball diameter as is essential in conventional valve metal powders to achieve high specific charges, so that they can be in the range of about 10 to 40 microns. The limitation is only given by an increase in the required volume of sintered body per unit load. However, this increase is also less pronounced in contrast to conventional powders. However, the use of coarse-grained powders has a number of technological advantages, such as: in semiconductor impregnation.

example

Tantalum-plated aluminum powder with an average grain diameter of 20 / um (tantalum thickness about 0.5 / U.ni) is coated with a 0.5 wt. % solution of stearic acid in benzene moistened so that the powder after evaporation of the solvent contains 0.1 wt.% Stearic acid and then to 1 g of the powder using a 0.3 mm thick anode wire with a pressure of 180 kgf / cm Domes with a diameter of 4.7 iom pressed. The bodies are dewaxed and heated under a pressure of 10 "" · ⁷ Torr within 30 minutes under segregation of the aluminum to 700 ⁰ G. Subsequently, the vacuum is increased to 10 Torr, the temperature increased to 155O ⁰ C and held for 30 minutes. The mass loss of the obtained sintered bodies is approx. 0.5 g ·

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Are the sintered bodies in O, l% phosphoric acid at a constant current "of 17.6 m & per anode at 85 ° C up to a maximum anodization potential of 100 V and then at a constant voltage up to a current of 500 / UA Anoaisiert, they have the following electrical properties after subsequent rinsing and drying:

Capacity 86.5 / U-F (which corresponds to a specific charge

of 17300 / UC / g tantalum) breakdown voltage 245 V loss factor 5%

_r - leakage current 8,6. 10 "* - '/ UA /, uC

Series resistance 6.3 ohms

If the bodies are pressed after the pressing process in forms of silicon nitride whose dimensions correspond to the geometry of the compacts, and the Entwachsungs- and Seigervorgang made there, we obtain. at a maximum sintering temperature of 120O ⁰ G (30 minutes) under a vacuum of 10 "" ° Torr anode bodies which have the following electrical properties after onodic oxidation under the conditions described above:

Capacity 92.5 / uF (corresponding to a specific charge

from.18500, uC / g tantalum)

Breakdown voltage 230 V ' .

Loss factor 4.8 %

Leakage current 9.2. 10 ~ 5.uA / uC

Series resistance 7.4 ohms

The breakdown voltage was measured with a measuring instrument which increases the voltage applied to the capacitor in constant steps (1 V / sec) using the forming electrolyte up to the registered breakdown.

The determination of the leakage current takes place directly in the forming system, in which a constant anodization potential of 2 hours was followed. The leakage current was measured at 25 ° C.

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The capacity and the loss factor were measured in 35% sulfuric acid at 1000 Hertz and an AC voltage of 1 Y. The series resistance was determined by the capacity and the loss factor.

Claims (6)

Invention claim. 1. A process for the production of valve metal sintered bodies for electrolytic capacitors using valve metal-plated metal balls, characterized in that a below about 800 ⁰ C melting metal powder having a substantially spherical habit, which has a higher cubic expansion coefficient than the Ventilmetall.aufweist, with a thin discontinuous Valve metal layer is coated. And a powder thus shaped mechanically preformed using auxiliary means at low pressure and then under high vacuum or at atmospheric pressure under inert gas at elevated temperature, the metal core is completely or partially removed from the system by Seiger and Abdampfprozesse. 2. The method according to item 1, characterized in that are used as valve metals tantalum, Eiob, tungsten, hafnium, titanium, zirconium or alloys thereof. 3. The method according to item 1 and 2, characterized in that the metal powder consist primarily of aluminum, antimony, magnesium, cadmium, bismuth or zinc. 4. The method according to item 1 to 3, characterized in that the preformed valve metal-plated powders are placed before the thermal treatment in wells of such material whose coefficient of expansion is smaller than that of the core metal. 5. The method according to item 1 to 4, characterized dachirch that a maximum sintering temperature of 1700 ° C and a minimum sintering temperature of about 1000 G can be used. 6. The method according to item 1 to 5, characterized in that the Ventilßietallschichtdicke is adapted to JOrmierbedingungen.