DE493223C - Device for depositing metals by electrolytic means - Google Patents

Description

Device for depositing metals by electrolytic means The present invention relates to methods and apparatus for deposition of metals such as iron, nickel and copper by electrolytic means. She concerns Facilities that prevent sludge from accumulating in the anode compartment or the anode compartment of the electrolyzer and also the formation of arcs or bridges in the anode material prevent; which also prevent or reduce the wear and tear of the conductor by which the current is supplied to the anode material in which the conductor is embedded.

In the accompanying drawings, Fig. = Shows a longitudinal section of a Electrolyzer with circulation devices for the electrolyte.

Fig. 2, 3 and q. are longitudinal sections of individual parts and show three Modified arrangements that prevent the sludge from flowing out of the anode compartment of the electrolyzer facilitate.

Fig. 5 is a cross-section of the grid in the bottom of the anode compartment of the Electrolyser shown in Fig. x on a larger scale.

Identify the same reference numbers in the various figures same or corresponding parts.

In Fig. I, a denotes the circular anode compartment and b the cathode compartment in the electrolyzer c; A suitable diaphragm d is located between spaces a and b. e designates a spindle on which the metal is to be electroplated. The electrolyte passes through tube f to the bottom of the cathode compartment, flows over the notched end of diaphragm d and then down through the anode compartment to settling chamber or trap g, from which it is drained by pump h through tube i, to return to the cathode compartment via the filter j and the heater k. The temperature of the electrolyte leaving the heating device can be regulated independently by means of a thermostat shown schematically at m.

According to the invention, the anode material consists of spheres or small ones Pieces made entirely or largely of the metal to be deposited put together. They rest on a number of glass o. The like. Balls o that through the electrolysis process cannot be attacked. These balls have a suitable one Diameter, so that there are gaps between them through which the mud, which occurs in the anode compartment when the anode metal dissolves, seeps through and accumulate in the settling or collection chamber g at the lower end of the electrolyzer can, The glass spheres o are supported by the grid shown in plan in Fig. 5 is.

On the base of the anode compartment is a circular ring or Slot q attached, through the air or another, for the contents of the trough harmless gas, possibly a mixture of both (here generally referred to as air), is fed under pressure through the openings y to the space around the grid p, so that it then penetrates upwards through the glass balls o to the anode material. She causes there is a sufficiently strong whirling up and ventilation through which the formation of Prevents arches or bridges in the anode material and the following, by the downward flow des-electrolyte caused sinking of the sludge in the anode material to the bottom of the electrolyzer is facilitated.

If so that of the dissolution of the metal to be deposited the resulting sludge is appropriately removed from the anode compartment the increase in current resistance caused by the presence of excessive impurities is conditional on the metals to be dissolved, and. also the uneven operation, caused by local arches or bridges.

Fig. 2 shows in section a part of the lower left part of the in Fig. I shown electrolyzer in a modified form. With this arrangement instead of the grid P, one of two parts is bolted together Used ring that runs around the annular space through which the electrolyte from the anode space to the outlet port or ports s flows.

Fig. 3 shows another arrangement of the base P, which the glass balls o and above carries the anode material.

Fig.q. shows part of the lower right part of the electrolyzer. Here, the base P, which carries the anode material, is inclined.

One can adjust the flow rate of the electrolyte through enlarge the anode compartment without swirling up the electrolyte in the cathode compartment by the electrolyte through a secondary line from the lower part of the anode compartment drains and pumps him to the upper part of this room without him how described above, flows through the filter, heater and cathode compartment. Such Secondary line can be actuated by the pump t (Fig. T), which carries the electrolyte from the settling chamber g and sucked it through a ring around the upper part of the The anode compartment arranged distributor head u can flow off. Usually the flows Electrolyte of course through the cathode compartment b, but the flow through the secondary line assists in flushing down the impurities that accumulate in the anode compartment want to go to the settling chamber g. At this chamber g is a drainage device for periodic emptying of the impurities appropriate.

Claims (3)

PATENT CLAIMS: x. Device for depositing metals by electrolytic means, characterized in that on the bottom of the anode space of the electrolyser there are a number of glass or similar spheres which are not attacked by the electrolysis process and which carry the anode material, with spaces between these spheres remain unaffected, through which the sludge produced in the dissolution of the metal in the anode compartment can seep through, so that the anode compartment is freed from it. 2. Apparatus according to claim i, characterized in that for storage the balls carrying the anode material have a base through which the electrolyte and the sludge can flow through. 3. Procedure to when knocking down of metals electrolytically removing the sludge from the anode compartment of the electrolyser and the formation of arcs or bridges in the anode material, to prevent, using the device characterized in claims i and 2, characterized in that air under pressure enters the lower part of the anode space is injected, which then flows upwards through the anode material. q .. device according to claims i and 2, characterized by an additional or secondary line through that of the electrolyte directly from the lower to the upper part of the anode compartment of the electrolyzer can flow, which makes it easier to wash off the sludge which tends to accumulate in the anode compartment j.