METHOD FOR THE MANUFACTURE OF INSOLUBLE LEAD ANODES, USED IN ELECTROWINNING OR ELECTRO-REFINING PROCESSES OF HIGH PURITY METALS

Abstract

A method for the manufacture of insoluble lead anodes, with low segregation of the constituent elements of the anodic alloy for the electrowinning of metals, free of buckling, used in electrolytic processes, which comprises: Obtaining a continuous plate (4) of lead or lead alloy 10 to 30 mm thick by 900 to 1,100 mm wide by means of a continuous casting process; Cut the continuous plate (4) according to a determined length obtaining a pre-plate (6) that will give the length of one or more plates of the anode (8); Roll the lead or lead alloy pre-plate (6) using a cold rolling mill (7) to a thickness of 6 to 12 mm, keeping the cold rolling temperature of the pre-plate under 60° C., obtaining the anode plate(s) (8); Remove the anode plate (8) from the rolling mill (7); Weld (12) a copper bar (10) to the upper end of the anode plate (11).

Claims

1. A method for the manufacturing process of lead insoluble anodes, with low segregation of components making up the anodes alloy used for electro winning of metals, combing free, used in electrolytic processes, wherein comprises: obtaining a continuous plate made of lead/lead alloy by using continuous casting; cutting the continuous plate, according to a pre-determined length, thus obtaining a pre-plate which shall be the length mold for one or several anode plates; laminating the lead/lead alloy pre-plate by using a cold lamination station till getting a thickness of 6 to 12 mm, and maintaining a cold lamination temperature of the pre-plate under 60° C. (140° F.), thus obtaining the anode plate(s); removing the anode plate from the lamination station; and welding a copper bar on an upper corner of the anode plate.

2. A method for the manufacturing process of lead insoluble anodes, used in electrolytic processes, as per claim 1, wherein the temperature of the lead/lead alloy bath of the continuous casting is between 350° C. to 450° C. (662° F.-842° F.).

3. A method for the manufacturing process of lead insoluble anodes, used in electrolytic processes, as per claim 1, wherein the continuous plate dimensions are 10 to 30 mm thick and 900 to 1,100 mm wide.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0005] In order to better understand this invention, a selected embodiment shall be described. This does not mean the protection is related thereto, but, all those variations deriving from the exposition of this invention and from the claims are an integral part of the protection. The example for this invention shall be used as a base for the exposition of this invention, as described in the drawings, where:

[0006] FIG. 1 describes a Schematic Diagram of the method for manufacturing lead plates.

[0007] FIG. 2 describes a lead anode and its components.

[0008] FIG. 3 describes welding of the copper bar onto the lead plate.

DESCRIPTION OF THE INVENTION

[0009] The method of this Invention proposes a manufacturing process technology aimed to technically solve the negative aspects of hot lamination systems, by proposing a structural anode providing excellent conductivity, excellent corrosion rate, combing free, the copper bar/lead plate joint does not come off, no segregation, cheaper and operationally simpler to be manufactured, obtaining such features by making significant modifications in the lead plate manufacturing process.

[0010] These significant modifications mainly have to do with replacing hot lamination by continuous casting system, for the manufacturing process of the anode lead plates.

[0011] This method eliminates pre-plates hot lamination. In the State of the Art this is between 100 to 200 mm thick. It is replaced by a continuous casting pre-plate (6). Just as described in FIG. 1, in the proposed method the continuous casting is gravity driven. This consist of initially feeding a reservoir (1) with liquid melted lead, at a temperature between 350 to 450° C. Through the tube (2) the reservoir (1) feeds a cooled mold (3) where a continuous plate (4) is formed. This plate comes off the mold by using constant traction on the the cold edge. At this stage it is also possible to obtain the thickness and the width of the continuous plate (4). The continuous plate (4) is transferred by using rollers positioned on top and below and it is cut with a saw (5) into pre-plates (6) thus getting a final thickness between 10 to 30 mm and a width between 900 to 1,100 mm. After this, the pre-plates (6) obtained are transferred to a cold lamination station (7) in order to provide final thickness of the pre-plate (6), between 6 to 12 mm. This process makes the plate (8) to have highly effective mechanical properties against those resulting from combining hot/cold lamination, as it minimizes segregation, specially on the eutectic alloys, such as lead-silver alloys used for zinc electro-winning anodes.

[0012] Namely, when the initial 100-200-mm thick billets are manufactured for hot lamination, the cooling process is very slow, as the billet is very thick, and the alloy is segregated, i.e. the composition of the alloy components vary in certain percentages, thus getting richer in one of the components and less in the others on the central shallow surface area and towards the center of the billet thickness, which is the last area to be solidified. This percentage variation—differenced at the core of the alloy—causes different wear out levels on the anode surface, which may cause severe damages in the operation thereof.

[0013] This system aimed to obtain 10-30 mm pre-plates (6) for cold lamination, by using continuous casting significantly reduces segregation as the thickness is much lower and the cooling speed of the continuous plate (4) during continuous casting is much higher than cooling and very even, thus guaranteeing a very low segregation, and also significantly decreasing the huge energy costs involved in hot laminating a 100-200 mm billet. The following cold lamination process , whether if it is conventional hot lamination or for a pre-plate (6) obtained from continuous casting herein described must be executed in such a way that, none of the cold lamination stages exceeds a temperature higher than 60° C. (140° F.), so that the grain size is correct, thus improving corrosion resistance.

[0014] Finally, the plate (8) obtained from continuous casting pre-plate (6) lamination is cut, according to the length of the anode and a copper bar (10) is attached by welding (12), the upper corner of the anode (11) plate, thus allowing its installation at the electro winning cells.

[0015] Using this system allows to obtain anodes with the aforementioned features, providing better conductivity, longer duration, less combing, better handling at production stages, lower costs, and a very small segregation of the components making up the anodes alloy.