DE187285C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 49 ρ GROUP ßf, Jt

Addendum to patent 153826 from January 20, 1903.

Patented in the German Empire on March 27, 1906. Longest duration: January 19, 1918.

In the patent 153826 is a method for the production of homogeneous bodies from tantalum metal or other difficult-to-melt metals according to patent 152848, according to which the melting of the metal in a direct current arc is best done in a vacuum, the body to be melted serving as a positive electrode. With a very high vacuum the arc is now difficult to pass between the electrodes. According to the present invention a long and powerful arc can easily be formed even with a very high vacuum will. At the same time, the advantage is achieved that the electrodes for the purpose of forming the Need not bring the arcs into contact with each other. Rather, the current goes by itself between the electrodes.

This effect is achieved by removing the gas residues that are still in the vacuum furnace be ionized. The ionization occurs when a metal oxide enters the furnace is brought and heated. The oxide is conveniently connected to the cathode and The easiest way of heating is by means of an electrical one passed through a Put electricity into embers, wire made of platinum, tantalum or the like embedded in the oxide.

Barium oxide is particularly suitable for ionization, and can also be used. Strontium oxide, Ka ¹ -zium oxide or magnesium oxide or other oxides can be used.

An arrangement of this type is shown schematically in Fig. 1 and 2, α means the body to be melted, b is the oxide, d the vacuum vessel in which the melting is to take place. The oxide is heated by a wire embedded in the oxide which is connected to the power source c. The same wire can at the same time be connected to the cathode of the melting current source, which is used to form the arc, while the body to be melted α is connected to the anode the arc between α and b over by itself. Even with a considerable distance between the anode and cathode, very significant currents can be sent through the ionized vacuum space. For example, at a distance of several centimeters between the electrodes and at a voltage of about 100 volts, an arc of 50 amperes and more current intensity can be generated, through which the melting of the body α is easy.

The current strength can be regulated in two ways, namely on the one hand by regulating the temperature of the oxide body and on the other hand by regulating the current strength by means of a series resistor e in the main circuit.

In Fig. 2 an arrangement is shown using a three-wire network. In the positive outer conductor to be melted body α leads to the, is the current

Claims (1)

regulator e. The heating resistance for the oxide h lies between the neutral conductor and the negative outer conductor; In the neutral conductor there is also a rule resistor f, which is used to regulate the temperature of the oxide. The current passes between the two outer conductors through the ionized vacuum. Although the use of direct current is primarily considered for this process comes, it is also possible to achieve similar effects with alternating current " Godfather ν t claim: Process for the production of homogeneous bodies from tantalum metal or others Difficult-to-melt metals according to patent 153826, characterized in that in A metal oxide is arranged in connection with the cathode, which ions when heated sends out, for the purpose of also the transition of the current between the electrodes at a very high vacuum. 1 sheet of drawings.