RU152478U1 - DEVICE FOR ELECTROLYTIC GOLD REFINING - Google Patents

Abstract

1. Device for electrolytic refining of gold, characterized in that it includes a housing filled with an electrolyte, with cathodes and anode rods installed in it with anodes suspended on them, and the anodes or cathodes are placed, respectively, in the anode or cathode cells, which are a frame in the form of a parallelepiped made of a polymeric material and fitted with a filter cloth, anode and cathode current-carrying buses mounted on insulators, as well as a means for controlling the pace The electrolyte temperature within the specified limits, made in the form of a jacket mounted in a housing into which, if necessary, hot or cold coolant is supplied. 2. The device according to claim 1, characterized in that the anode and cathode current-carrying busbars are protected against corrosion by plates of conductive material resistant to aggressive gas environments. The device according to claim 2, characterized in that the overlays in the cross section are U-shaped. The device according to any one of paragraphs. 2 and 3, characterized in that the plates are made of titanium. 5. The device according to claim 1, characterized in that the anode and cathode current-carrying busbars are made of electrical copper. The device according to claim 1, characterized in that the anode rods are made of a material resistant to aggressive gas environments. The device according to claim 6, characterized in that the anode rods are made of titanium. The device according to claim 1, characterized in that titanium hooks are welded to the anode rods for hanging the anodes. The device according to claim 8, characterized in that the anodes have in the upper part of the hole, through

Description

Technical field

The claimed utility model relates to element chemistry, in particular to the field of chemistry and metallurgy of precious, non-ferrous and rare metals and can be used in enterprises processing concentrates and alloys of precious metals, electronic scrap and waste from the electronic and electrochemical industries containing precious, non-ferrous and rare metals.

State of the art

A device of an electrolyzer is known for implementing a method for extracting precious metals from waste from the electronics industry, including obtaining copper-nickel anodes from them, containing impurities of precious metals, electrolytic anodic dissolution thereof with deposition of copper on the cathode and producing a nickel solution and sludge with precious metals, electrolytic anodic dissolution of the anode containing 6-10% iron, when placing the cathode and anode in separate mesh diaphragms to create a cathode of the anode and the anode spaces with a chlorine-containing electrolyte located in them, and the electrolyte obtained during the electrolysis from the cathode space is sent to the anode space, (see RU 2357012 C1, 05.27.2009, C01G 7/00).

A known cell containing a bath with an electrolyte, electrodes, a rod, a power source, while the electrodes in the bath are installed horizontally or at an angle to a horizontal surface, while an insulating layer or a coating of an insulating film is applied to the upper surface of the anodes to prevent ions from moving to the cathode from below up, and the anodes are made porous with a large area of contact with the electrolyte by blowing the anode plates in the liquid state with compressed air (see RU 2422559 C1, 06/27/2011, C01G 7/00).

A known cell containing a woven diaphragm made by plain weaving of the main and weft yarns of twisted yarn from polyvinyl alcohol of linear density from 5544 to 20044 tex with a twist from 100 to 130 torsions / meter with a thread density of 10 cm in the fabric based on 110 to 135 and for weft from 95 to 110, while the breaking load of the fabric is 368-375 kgf on the basis, and 474-483 kgf for the weft, and the elongation at break of the base is 40.6, and for the weft - 13.1 (see RU 2430706 C2, 12/10/2008, C01G 7/00).

A known cell for extracting indium from an indium-containing melt, including a heated anode bath, a cathode cell in the form of a perforated cylinder having two diaphragms from quartz fabric, a current lead and a bowl fixed thereon for collecting indium extracted from the melt, contains an melt receiving bath as an anode bath condensate from a vacuum furnace containing lead, bismuth, tin and indium, the cathode cell is made in the form of a perforated cylinder, fitted with a quartz fabric diaphragm equipped with a sheath a cylindrical insert made of electrical insulating material located at the bottom and the shell and the cylindrical insert are covered with a quartz fabric diaphragm with a gap between two 2-5 mm diaphragms in the form of a pocket for filling electrolyte (see RU 2490375 C2, 08/20/2013) .

A known electrolyzer, including a cylindrical body with a jacket and a lid, a paddle mixer, electrode sets in the form of anode and cathode tires, and anode chambers with diaphragms, cathodes are flat and placed horizontally under the corresponding anodes, the diaphragms are made of ion-exchange material and are mounted on the bodies of the anode chambers made of electrical insulation material (see SU 477738 A1 C01G 7/00).

The disadvantages of the existing well-known, in particular specified, technical solutions are:

- the use of precious metals for the manufacture of busbars, anode and cathode rods, cathodes, which significantly increases the amount of precious metals in work in progress;

- the anodic sludge formed during the dissolution of anodes from ligature gold is in contact with the cathode deposit, which does not allow to achieve the required degree of gold purification in one electrolysis stage;

- there is no possibility of regulating the temperature of the electrolyte, which forces the process to be carried out at a relatively low current density and, therefore, reduces the performance of the cell.

Utility Model Disclosure

The technical problem that the present utility model aims to solve is to increase the efficiency of the gold refining process by electrolysis, while reducing the amount of precious metals involved in work in progress.

The technical result of the claimed technical solution is to improve the quality of the cathode deposit by reducing the amount of impurities in it, while reducing energy consumption due to the fact that the required degree of gold purification is achieved in one electrolysis stage.

The technical result is achieved due to the fact that the device for electrolytic refining of gold, according to a utility model, includes a housing filled with an electrolyte, with cathodes and anode rods installed in it with anodes suspended on them, and the anodes or cathodes are placed, respectively, in the anode or cathode cells, which are a frame in the form of a parallelepiped made of a polymeric material and fitted with a filter cloth, anode and cathode current-carrying buses mounted on olators, as well as means for regulating the temperature of the electrolyte within specified limits, made in the form of a jacket mounted in a housing into which, if necessary, hot or cold coolant is supplied.

The following particular forms of execution are allowed:

The anode and cathode current-carrying busbars are protected against corrosion by plates of conductive material resistant to aggressive gas environments.

The anode and cathode cells are made of materials thermally and chemically stable under operating conditions.

Pads in cross section are U-shaped.

In the particular case of the execution of the lining made of titanium.

Anode and cathode current-carrying busbars can be made of electrical copper.

Anode rods can be made of a material resistant to aggressive gas environments, for example, titanium.

Titanium hooks can be welded to the anode rods to hang the anodes.

The anodes may have holes in the upper part through which the anodes are suspended on the hooks of the anode rods.

Cathodes can be made of titanium.

The filter cloth was made by plain weaving of the main and weft yarns of twisted yarn from polyvinyl alcohol of linear density from 55 × 4 to 200 × 4 tex with a twist from 100 to 130 torsions / meter with a thread density of 10 cm in the fabric based on 110 to 135 and duck from 95 to 110.

In another particular case, the filter cloth is made of polymer-asbestos fiber.

It is possible that the filter cloth is made on the basis of polymers of vinyl monomers, in particular polyvinyl chloride or polypropylene, or from fluorone-4 (polytetrafluoroethylene).

It is possible that the filter cloth is made on the basis of thermoplastic fibers.

In a particular embodiment, the diaphragm is made of porous synthetic fabric.

In yet another particular embodiment, the diaphragm is made two-layer. It is possible that the cell frame is made of polyvinyl chloride. It is possible that the cell framework is made of fluoroplastic.

The shirt can be made of a material resistant to the aggressive environment, for example, titanium.

The shirt can be made single-walled, with the formation of the internal volume with the wall of the housing for the coolant, or the shirt is made double-walled, with the formation of the internal volume between its walls for the coolant.

Utility Model Implementation

The electrolyzer for electrolytic refining of gold includes a housing in which cathodes of titanium and anodes of ligature gold are installed.

In turn, the cathodes and anodes are installed, respectively, in the cathode or anode cells and are separated by a diaphragm in the form of a polypropylene filter cloth.

In another example, the filter membrane of the diaphragm is made by plain weaving of the warp and weft yarns of twisted yarn from any polymer resistant to “royal vodka” - fluoroplastic with a linear density of 55 × 4 to 200 × 4 tex with a twist of 100 to 130 torsions / meter when the density of threads in the fabric is 10 cm on the basis from 110 to 135 and weft from 95 to 110.

In addition, in other embodiments, the filter cloth may be polyvinyl chloride, or from fluorlon-4 (polytetrafluoroethylene), or chlorin.

Polytetrafluoroethylene (PTFE) fibers that can be used can have various sizes. Preferably, PTFE fibers are used, the average sizes of which are from 1 to 4 mm for the length and between 50 and 200 mm for the diameter.

Among the inorganic fibers that may be part of the diaphragms, zirconia or titanate fibers can be used.

As a thermoplastic fiber, a fiber is used that consists of a mixture of a polypropylene polymer having a crystallinity of at least 98% and a non-oriented block copolymer of polyethylene and polypropylene with a melting point below 160 ° C, with a ratio of polypropylene polymer and said block copolymer of about 50-95: 5-50 wt. % respectively.

Anode (cathode) cells are made of a polymeric material, such as, for example, fluoroplast or polypropylene.

To the anode rods to which the titanium hooks are welded, the anodes are suspended through the corresponding holes made in the latter.

Anode rods are made of a material resistant to aggressive gas environments, such as titanium.

The anode and cathode current-carrying buses are made of electrotechnical copper and protected from above by U-shaped in cross section titanium overlays, and mounted on insulators.

A shirt is mounted in the electrolytic cell body, which acts as a regulator of the electrolyte temperature in predetermined limits, which allows maintaining the optimum electrolyte temperature regardless of current density, i.e. it is possible to increase the current density without overheating of the electrolyte, thereby increasing the productivity of the process, and to increase the temperature of the electrolyte to optimal values if it is necessary to conduct the process at low current densities. In addition, the electrolyte is heated before turning on the electrolyzer after a long stop.

The shirt can be made double-walled or single-walled. When performing a single-wall shirt, an internal volume is formed between the wall of the case and the wall of the shirt.

The shirt can be made of a material resistant to aggressive environments with good heat transfer, for example, titanium. In other special cases, the shirt can be made of other corrosion-resistant steels, for example SMO254, HASTELLOY, TANTAL, and others.

As a coolant can be used, superheated steam, water, antifreeze or any other coolant.

The cell operates as follows.

Anode rods are installed in the device, the anode rods are installed and their electrical contacts are screwed to the anode busbar. Two options are possible:

a) the anode cells are immersed in the electrolyte and placed under the anode rods, on which the anodes are suspended, placing them inside the anode cells, in this case the cathodes are placed in the cell volume without cells in the middle between the anode cells and their electrical contacts are screwed to the cathode busbar;

b) the cathode cells are immersed in the electrolyte and installed in the middle between two adjacent anode rods, the cathodes are placed in the cathode cells and their electrical contacts are screwed to the cathode busbar, in this case, the anodes are placed in the cell volume without cells in the middle between the cathode cells and their electrical contacts are screwed to the anode busbar;

In both cases, the cathode is separated from the anode and anode sludge by a filter cloth (diaphragm).

Next, a hot coolant is pumped through the jacket of the heat exchanger, the electrolyte is heated to the required temperature and the direct current source is turned on. After that, the heat exchange device operates in the mode of regulating the temperature of the electrolyte according to the task. During electrolysis, refined gold is deposited on the cathode. Periodically, the cathodes are removed from the device, gold is removed from them with titanium blades, washed with water and sent for melting, the cathodes are returned to the device and the electrolysis process continues. When dissolving the anodes, insoluble anode slurries are formed, which settle either to the bottom of the anode cell (option a) or to the bottom of the device (option b). Periodically they are unloaded and sent for further processing. The cathode gold obtained in this way during one electrolysis stage corresponds in chemical composition to the requirements of the relevant regulatory documentation.

Thus, as evident from the above, it is precisely due to the joint use of the diaphragm in the form of anode or cathode cells fitted with a filter cloth, as well as a cooling / heating circuit made in the form of a jacket, that improves the quality of the cathode deposit in the form of refined gold due to reducing in it the amount of impurities obtained by filtration, while reducing energy consumption due to the fact that the required degree of gold purification is achieved in one electrolysis step.

Therefore, due to the claimed combination of essential features indicated in an independent electrolytic cell execution point, the claimed substantial result will be achieved, since all the signs are in a causal connection with it.

The analysis of the prior art did not reveal sources of information that would disclose the claimed combination of features of an independent clause, which allows us to conclude that the claimed technical solution meets the patentability condition of “novelty”.

As can be seen from the description of the operation of the device and its direct implementation, this technical solution is industrially applicable.

Claims (22)

1. Device for electrolytic refining of gold, characterized in that it includes a housing filled with an electrolyte, with cathodes and anode rods installed in it with anodes suspended on them, and the anodes or cathodes are placed, respectively, in the anode or cathode cells, which are a frame in the form of a parallelepiped made of a polymeric material and fitted with a filter cloth, anode and cathode current-carrying buses mounted on insulators, as well as a means for controlling the pace The electrolyte temperature within specified limits, made in the form of a jacket mounted in a housing into which, if necessary, hot or cold coolant is supplied. 2. The device according to p. 1, characterized in that the anode and cathode current-supplying busbars are protected from corrosion by plates of conductive material resistant to aggressive gas environments. 3. The device according to claim 2, characterized in that the overlays in the cross section are U-shaped. 4. The device according to any one of paragraphs. 2 and 3, characterized in that the lining is made of titanium. 5. The device according to p. 1, characterized in that the anode and cathode current-carrying busbars are made of electrical copper. 6. The device according to claim 1, characterized in that the anode rods are made of a material resistant to aggressive gas environments. 7. The device according to claim 6, characterized in that the anode rods are made of titanium. 8. The device according to claim 1, characterized in that titanium hooks are welded to the anode rods for hanging the anodes. 9. The device according to claim 8, characterized in that the anodes have holes in the upper part through which the anodes are suspended on the hooks of the anode rods. 10. The device according to claim 1, characterized in that the cathodes are made of titanium. 11. The device according to claim 1, characterized in that the filter cloth is made by plain weaving of the main and weft yarns of twisted yarn from polyvinyl alcohol of linear density from 55 × 4 to 200 × 4 tex with a twist from 100 to 130 torsions / meter with a density of threads in fabrics per 10 cm on the basis of 110 to 135 and weft from 95 to 110. 12. The device according to p. 1, characterized in that the filter cloth is made of polymer-asbestos fiber. 13. The device according to claim 1, characterized in that the filter cloth is made on the basis of polymers of vinyl monomers, in particular polyvinyl chloride or from fluorlon-4. 14. The device according to claim 1, characterized in that the filter cloth is made on the basis of thermoplastic fibers. 15. The device according to claim 1, characterized in that the filter cloth is made of porous synthetic fabric. 16. The device according to p. 1, characterized in that the filter cloth is made two-layer. 17. The device according to claim 1, characterized in that the frame is made of polyvinyl chloride. 18. The device according to p. 1, characterized in that the frame is made of fluoroplastic. 19. The device according to claim 1, characterized in that the frame is made of polypropylene. 20. The device according to claim 1, characterized in that the shirt is made of titanium. 21. The device according to p. 20, characterized in that the shirt is made single-wall, with the formation of the internal volume with the wall of the housing for the coolant. 22. The device according to p. 20, characterized in that the shirt is double-walled with the formation of an internal volume between its walls for the coolant.