RU178766U1 - Magnetic mixer for electrochemical synthesis - Google Patents

Abstract

The utility model relates to the field of electrochemical production technology, for example, to the synthesis of titanium (III) sulfate in the sulfuric acid production of pigment titanium dioxide (TiO). The magnetic mixer for electrochemical synthesis includes a magnetic field source acting on charged particles in the reaction chamber, the magnetic field source has a mushroom a shape with the same profile of the upper and lower parts made of soft magnetic alloys having high magnetic conductivity, for example permalloy, the central part g the ribbed design is made of a set of alternating elements of permanent magnets made of NdFeB alloy and soft magnetic alloys, while the mushroom-shaped flanges and permanent magnets with magnetically conductive inserts are isolated from contact with the electrolyte by coating them with fluoroplastic. The technical result of the utility model is to increase the efficiency of active reduction of metal ions in technological processes and reducing the cost of obtaining an active titanium (III) sulfate reducing agent by convectively applying diffusion to ensure turbulent electrolyte movement mezhkatodnom space.

Description

The utility model relates to the field of technology of electrochemical production, for example, to the synthesis of titanium (III) sulfate in the sulfuric acid production of pigment titanium dioxide (TiO ₂ ).

In the sulfate technology for the production of pigment TiO _2, titanium (III) sulfate is an active reducer of iron (III) ions, because Fe ^{3+ is} hydrolyzed in technological solutions at pH = 1.6 ... 3.5 with the formation of insoluble colored colloids interacting with TiO (OH) ₂ paste, which prevents the production of white pigment. When titanium (III) sulfate, which is an Fe ³⁺ blocker, is used in the technology, the use of iron scrap and aluminum powder is excluded.

One of the methods for the synthesis of titanium (III) sulfate is based on the principle of replacing molecular by convective diffusion under the influence of a pulse transmitted to the electrolyte by a mechanical stirrer [Kasatkin AG Basic processes and apparatuses of chemical technology. 9th ed. M .: Chemistry, 1973. - 750 p.]. In this case, intensification of mass transfer processes and improvement of heat transfer of solutions and uniform distribution of electrolyte ions over the volume of the solution and, especially, at the surface of the electrodes of the double electric layer (Guy) are achieved.

Mixing solutions can be achieved in various ways, however, it should be noted that titanium (III) is a strong reducing agent, therefore, the use of an effective method of bubbling gas through a solution layer can only be inert gases. An equally effective method is the mechanical mixing of the electrolyte. The arsenal of designs of mechanical stirrers with rotational movement includes a large number. These include magnetic stirrers with turntables, paddle mixers, etc.

The disadvantages of the known technical solutions include the fact that the use of inert gases in the process for mixing sulfuric acid solutions in the presence of titanyl sulfate and titanium (III) sulfate forces the use of a gas outlet to neutralize entrained sulfuric acid.

When using the mechanical method of mixing solutions, it is necessary to use mixers made of materials resistant to sulfuric acid.

However, using traditional mechanical methods to increase the speed of movement of electrolytes in the cell is very problematic due to the small spaces between the cathode and anode (10-20 mm). In addition, the effect of mixing electrolytes is achieved only in the lower part of the cell. The use of these methods of mixing electrolytes significantly increases the cost of finished products due to gas consumption and the neutralization of sulfuric acid or the cost of wear of mixers, electrical equipment and electricity.

As a prototype, the closest in technical essence and achieved effect was chosen - a ferro-vortex apparatus [RF patent No. 2323040, Ferro-vortex apparatus, Cl. B01F 13/08, published: 04/27/2008], which relates to the electromechanical processing of liquid, bulk and other mixtures. The apparatus comprises a cylindrical body with a reaction chamber of non-magnetic material. The chamber contains a working area with ferromagnetic particles and an axial magnetic circuit, in the form of a burlap ring of rectangular cross section. The inductor magnetic circuit is a lined rectangular ring with grooves and a three-phase winding embedded in them. When the winding is connected to a three-phase alternating current, a rotating electromagnetic field arises in the working zone of the reaction chamber, which carries away the ferromagnetic particles, and they, in turn, act on the substances in the chamber. The processed substance is mixed due to the complex of forces acting on the particles.

The disadvantages of the prototype are:

- energy costs to ensure a rotating electromagnetic field in the working area;

- when electric current passes through a three-phase winding, the wires are heated with heat spreading to the working area, this leads to poorly controlled electrochemical processes;

- the cost of electricity for the mandatory temperature control of electrolytes in the working area;

- contamination of electrolytes with materials formed during wear of the inner surface of the reaction chamber and ferromagnetic particles;

- the ferro-vortex apparatus is structurally very complex and requires the use of cooling media and ferromagnetic particles, which are difficult to pick up when using sulfuric acid electrolytes with pH = 0.5-3.5.

The technical result of the utility model is to increase the efficiency of active recovery of metal ions in technological processes and reduce the cost of obtaining an active titanium (III) sulfate reducing agent by applying convective diffusion to ensure turbulent motion of the electrolyte in the cathode space.

The magnetic mixer for electrochemical synthesis includes a magnetic field source acting on charged particles of ions in the reaction chamber, the magnetic field source has a mushroom shape with the same profile of the upper and lower parts made of soft magnetic alloys having high magnetic conductivity, for example permalloy, the central part of the mushroom structure made of a set of alternating elements of permanent magnets made of NdFeB alloy and soft magnetic alloys, with mushroom-shaped flanges and permanent ma nits with magnetically permeable inserts are isolated from contact with the electrolyte by coating them with Teflon.

The device is presented graphically (Fig.), Which shows a schematic diagram of an electrolyzer with a directional magnetic field: 1 - bath; 2 - mushroom-shaped magnetic circuit; 3 - cathode; 4 - magnetic field; 5 - membrane; 6 - anode; 7 - permanent magnets; 8 - chemical protection coating with fluoroplastic; 9 - permalloy alloy.

The mushroom-shaped source of the magnetic field — the magnetic core 2 — is made of a set of alternating permanent magnets 7 of an NdFeB alloy having high magnetic conductivity, and of soft magnetic alloys 9 (permalloy) in the central part.

Permanent magnets of the NdFeB composition are used in the electrolyzer to use the Lorentz force to ensure the turbulent movement of solutions in the cathode space. To reduce the number of permanent magnets, soft magnetic alloys are used alternately. When conducting electrolysis in a bath 1 with a technological solution is placed a magnetic mixer for electrochemical synthesis - a special device with a directed magnetic field.

The electrolysis implementation scheme includes the following elements: a mushroom-shaped magnetic core 2 with a set of alternating magnets from an NdFeB 7 alloy and soft magnetic alloys 9 (permalloy); cathode 3 from a 12Kh18N10T polymetallic grid, which allows electrolyte to pass through it; directional magnetic field 4 created using mushroom-shaped magnetic cores; membranes 5 of polypropylene fabric separating the cathode and anode space; anode 6 of a polymetallic network folded in five layers and coated up to eight times with manganese dioxide in a thermal manner. Mushroom flanges and permanent magnets with magnetically conductive inserts are isolated from contact with the electrolyte by coating them with fluoroplastic 8.

The use of magnetic fields for turbulent mixing of an electrolyte is based on the interaction of the electric charges of electrolyte ions during their movement with magnetic fields, resulting in a magnetic component of the Lorentz force, which causes a change in the direction of motion of the charged particles, but does not affect their speed. Comparative studies were performed to prove the advantages of a dynamic electrolysis regime with the presence of turbulent mixing of solutions with respect to the static regime.

Examples of specific performance.

осуществлено в технологическом растворе с плотностью 1,51 г/см³ и массовой концентрацией TiO²⁺ в пересчете на TiO₂ = 140 г/дм³ в присутствии H₂SO₄ с массовой концентрацией 475 г/дм³ (свободная H₂SO₄ 150 г/дм³) при температуре 60±2°С. Процесс электролиза проводили в течение 2,5 часа в статическом режиме с током 5,5 А/дм³ и напряжении 3,5 В. За период восстановления 1,0 дм³ раствора с титанилсульфатом образовалось 18,4 г Ti³⁺, что составляет выход по току 74,8%.The first example. Titanyl Sulfate Recovery

carried out in a technological solution with a density of 1.51 g / cm ³ and a mass concentration of TiO ²⁺ in terms of TiO ₂ = 140 g / dm ³ in the presence of H ₂ SO ₄ with a mass concentration of 475 g / dm ³ (free H ₂ SO ₄ 150 g / dm ³ ) at a temperature of 60 ± 2 ° C. The electrolysis process was carried out for 2.5 hours in a static mode with a current of 5.5 A / dm ³ and a voltage of 3.5 V. During the recovery period of 1.0 dm ^{3 of a} solution with titanyl sulfate, 18.4 g of Ti ^{3+ was formed} , which is current efficiency of 74.8%.

An example of the second. The reduction of titanyl sulfate was carried out in a technological solution with a density of 1.51 g / cm ³ and a mass concentration of TiO ²⁺ in terms of TiO ₂ = 140 g / dm ³ in the presence of H ₂ SO ₄ with a mass concentration of 475 g / dm ³ (free H ₂ SO ₄ 150 g / dm ³ ) at a temperature of 60 ± 2 ° C. The electrolysis process was carried out for 2.5 hours in dynamic mode (using a magnetic mixer for electrochemical synthesis) with a current of 5.5 A / dm ³ and a voltage of 3.5 V. During the recovery period of 1.0 dm ^{3, a} solution with titanyl sulfate was formed , 3 g of Ti ³⁺ , which is a current efficiency of 94.7%.

Claims (1)

A magnetic mixer for electrochemical synthesis, comprising a magnetic field source acting on charged particles in the reaction chamber, characterized in that the magnetic field source has a mushroom shape with the same profile of the upper and lower parts made of soft magnetic alloys having high magnetic conductivity, for example permalloy , the central part of the mushroom structure is made of a set of alternating elements of permanent magnets of the NdFeB alloy and soft magnetic alloys, while the mushroom flange s and permanent magnets with magnetically conductive inserts are isolated from contact with the electrolyte by coating them with fluoroplastic.

Images