RU2225454C1 - Method of extraction of gold and silver from low- concentration solutions and device for realization of this method - Google Patents

Abstract

FIELD: hydrometallurgy of noble metals; extraction of gold and silver form low-concentration solutions (discharge pulp of tailing dumps and sea water). SUBSTANCE: proposed method includes extraction of gold and silver in presence of ions of other metals by adsorption of these metals in anion form; magnetic powder-like adsorbent placed in solution containing ions of gold and silver is kept in this solution for 24-28 h, after which it is removed by mans of pump, dried and molten with fluxing additives, thus obtaining crude metal. Device proposed for realization of this method includes perforated magnetic disk coated with powder-like adsorbent and positioned between two foam plastic rings. EFFECT: enhanced efficiency and selectivity of extraction of gold and silver. 3 cl, 1 dwg, 3 ex

Description

 The invention relates to hydrometallurgy of precious metals, in particular to processes for the extraction of gold and silver from solutions with a low content (waste pulp tailings and seawater).

 At present, cost-effective technologies for the extraction of Au and Ag from solutions with a low content of these metals are not known.

The disadvantages of the used ion-exchange technologies for the extraction of Au, Ag on coals, zeolites, Al ₂ O ₃ , and ion-exchange resins are the high energy consumption for pumping solutions through adsorbers, the high cost and difficulty of regenerating adsorbents [Metallurgy of precious metals. M., Metallurgy, 1987; RF patent 2152448, C 22 V 11/00, BI 19, 2000].

 Closest to the invention is a method for extracting Au from seawater [Ladeishchikov V.V. Technique and technology for the extraction of gold from ores abroad. M., Nedra, 1974], in which the ion-exchange resin is applied to the hull of a floating vessel, after the voyage, the resin is removed and subjected to treatment with acids and special eluants, followed by electrolysis of the eluate.

 Closest to the invention is a device [Ladeishchikov V.V. Technique and technology for the extraction of gold from ores abroad. M., Nedra, 1974], including a basis for applying an adsorbent to it.

 The main disadvantages of the known method and device are the low selectivity of polymer adsorbents with respect to Au, Ag in the presence of salts of other metals, the low adsorption speed of gold and silver ions, the difficulty of fixing and regeneration of ion exchangers on the surface of the carrier, the high cost and loss of adsorbents.

 The objective of the invention is to increase the efficiency and selectivity of the extraction of gold and silver from solutions with a low content.

 The technical result is to increase the degree of selective adsorption of gold and silver. It is achieved by the method of extracting gold and silver from solutions with a low concentration in the presence of ions of other metals, including adsorption of gold and silver in anionic form, removal of the adsorbent with gold and silver ions and its melting, while the adsorption is carried out using magnetic adsorbent as an adsorbent when placing it in the initial solution and keeping it for 24-48 hours, the adsorbent is removed by a pump, dried and melted with fluxing additives to obtain a crude metal.

A device for extracting gold and silver from solutions with a low concentration in the presence of ions of other metals includes a base for applying an adsorbent to it, the base being made in the form of a perforated magnetic disk fixed between two rings of foam. An adsorbent made from a mixture of an anionic adsorbent, Fe ₃ O ₄ powder and a binder (water glass or organic binder) can be used as a magnetic one. After solidification, the mixture is crushed and the magnetic adsorbent is fractionated.

 A device for extracting gold and silver from solutions with low concentration (see drawing) includes a disk of perforated magnetic material (1), on which powder magnetic adsorbent (3) is fixed on both sides, and two foam rings (2), which provide buoyancy device. The magnetic disk is fixed between the foam rings. The weight of the device operating in real conditions can be 35-40 kg, the thickness of the adsorbent layer is 5-6 mm on both sides of the magnetic disk, the weight of the adsorbent is 20-25 kg.

 Examples of specific performance.

 Preparation of magnetic adsorbent.

Finely ground natural or synthetic sulfides (FeS ₂ or Sb ₂ S ₃ ) and Fe ₃ O _{4 are} mixed with epoxy in a ratio of 2: 2: 1. After solidification, the mixture is ground and a magnetic fraction of less than 0.5 mm is taken. A distinctive feature of the proposed adsorbents is that they exhibit selective chemical adsorption with respect to ions of Au, Ag. The following chemical reaction proceeds intensively on the surface of pyrite and antimonite:
9FeS ₂ + 40AuCl ₃ + 6FeCl ₃ + 72H ₂ O = 8FeSO ₄ + 7FeCl ₂ + 10HSO ₄ + 124HCl + 40Au
In this case, the recovery of Fe ³⁺ -> Fe ²⁺ proceeds.

Example 1. A magnetic adsorbent with FeS ₂ weighing 0.5 g is fixed on a perforated magnetic disk with a thickness of 0.1 cm with an area of 6 cm ² on both sides, the disk with adsorbent is placed between two foam rings. A model device is immersed in a solution of 3 L volume containing AgCl ₂ ^- ions, Ag concentration 0.05 mg / L, for 24 hours. A model solution is prepared on the basis of a solution of sea salt with a concentration of 30 g / l. After reaching the adsorption equilibrium, the adsorbent is separated by a pump and alloyed with fluxing additives to obtain a crude metal. The residual concentration of silver in the solution after extraction is 5 • 10 ^-3 mg / l.

Example 2. A magnetic adsorbent with Sb ₂ S ₃ weighing 1 g is fixed on a perforated magnetic disk with a thickness of 0.1 cm with an area of 12 cm ² on both sides, the disk with adsorbent is placed between two foam rings. The model device is immersed in a solution of 3 l volume containing AgCl ₂ ^- ions, Ag concentration 0.1 mg / l, for 48 hours. A model solution is prepared on the basis of a solution of sea salt with a concentration of 30 g / l. After reaching the adsorption equilibrium, the adsorbent is separated by a pump and alloyed with fluxing additives to obtain a crude metal. The residual concentration of silver in the solution after extraction was 3 • 10 ^-3 mg / L.

Example 3. A magnetic adsorbent with Sb ₂ S ₃ weighing 0.5 g is fixed on a perforated magnetic disk with a thickness of 0.1 cm with an area of 6 cm ² on both sides, a disk with adsorbent is placed between two foam rings. The model device is immersed in a solution of 3 l volume, containing AuCl ₄ ^- ions, concentration at Au 0.05 mg / l, for 36 hours. A model solution is prepared on the basis of a solution of sea salt with a concentration of 30 g / l. After reaching the adsorption equilibrium, the adsorbent is separated by a pump and alloyed with fluxing additives to obtain a crude metal. The residual concentration of gold in the solution after extraction was 10 ^-3 mg / L.

 The proposed method for the extraction of gold and silver from solutions with a low concentration (less than 0.1 mg / l) allows to achieve a high degree (90%) of selective adsorption of gold and silver in anionic form from solutions in the presence of salts of other metals. In real conditions, the extraction can be 2-3 kg of metal per 1 ton of adsorbent.

 The proposed device allows adsorption from weakly concentrated solutions of gold and silver for a long time until equilibrium is established without pumping the solutions through the adsorber under conditions of natural mixing, which significantly reduces the energy consumption of the process.

 The proposed method and device can be used for additional extraction of gold and silver from solutions of tailings and sea water.

Claims (2)

1. The method of extraction of gold and silver from solutions with a low concentration in the presence of ions of other metals, including adsorption of gold and silver in anionic form, removal of the adsorbent with gold and silver ions and its melting, characterized in that the adsorption is carried out using a magnetic adsorbent powder adsorbent when placed in the initial solution and kept there for 24-48 hours, the adsorbent is removed by a pump, dried and melted with fluxing additives to obtain a crude metal. 2. A device for extracting gold and silver from solutions with a low concentration in the presence of ions of other metals, comprising a base with an adsorbent deposited on it, characterized in that the base is made in the form of a perforated magnetic disk fixed between two rings of foam.