HU201278B - Electrolyzer for treating sewages and concentrates comprising cations as well as electrolytically oxidizable anions and/or organic compounds - Google Patents

Abstract

Field of the Invention The present invention relates to an electrolysis apparatus for the treatment of wastes and concentrates containing cations and electrolytically oxidizable anions and / or organic compounds having a vertical cylindrical housing with a lower inlet and an upper outlet (concentric cylindrical housing (3) of 3jCampamine and a concentric cylindrical interior and exterior). It is an object of the present invention that the outer electrode is formed as a spiral electrode disposed between the cylindrical inner electrode and the cylindrical housing (3), spaced from the cylindrical housing (3), and into both the lower inlet and the top. The outlet opening is connected to a tangential inlet or outlet (8 or 9) .The scope of the description is 4 pages, Fig. 1 EN 201 278 A -1-

Description

Field of the Invention The present invention relates to electrolyzing cations, especially heavy and non-ferrous metal cations such as Au ⁺ , Ag ⁺ , Zn ⁺⁺ , Cd ⁺⁺ , Cu ⁺ and Ni ^{+ +} ions and electrolytically oxidizable anions and / or organic compounds such as Cl and CN. ions, etc. - treating wastewater and concentrates. In addition to treating wastewater and concentrates, the present invention is also suitable for recovering metal in powder form during electrolysis.

Many variants of equipment for treating wastewater and concentrates by electrolysis are known. For example, Hungarian Patent No. 165,292 relates to a process and apparatus for treating wastewater containing fine suspended solids or organic and / or inorganic impurities dissolved, emulsified or suspended. The essence of the process is that the waste water purified from coarse contamination is electrolyzed continuously through a horizontal electric field in the presence of foaming agents and the foam formed is removed. The proposed apparatus has a pre-filtration and pre-purification system and closed electrolysis cells formed from vertical electrodes. The wastewater in the electrolysis cells is pumped from below. From the electrolysis cells, the liquid enters the drainage chamber. The resulting foam is removed with a foam separator. Generally, multiple parallel electrolysis cells are required to achieve the desired cleaning effect.

U.S. Pat. No. 4,439,290 discloses a device for the continuous separation of oil-in-water emulsions by electrolysis. The apparatus has a cylindrical electrolysis cell consisting of a cylindrical outer metal housing bonded to a cathode potential and a rod-shaped anode centrally located therein. The vertical electrolysis cell has a lower fluid inlet and an upper fluid outlet. The fluid to be treated is pumped from the bottom up into the cylindrical electrolysis cell by means of a pump. During passage through the electrolysis cell, the emulsion decomposes under the influence of the metal in solution in the vicinity of the anode, forming a metal hydroxide which absorbs the oil particles released from the amulsion. Metal hydroxide oil flakes adsorb the gas evolved during electrolysis to their surface, thereby lighter and rising to the surface of the liquid. The biphasic mixture is discharged from the electrolysis cell through the upper outlet. An open separator is connected to the electrolysis cell, whereby the suspension in the fluid coming from the closed electrolysis cell rises to the surface of the liquid under the influence of hydrogen and flows from there to a sludge collection vessel.

Thus, the mechanism of action of the above solutions is that the gases or surfactants evolving on the electrodes produce a lighter foam than water, which contains contaminating colloidal particles and rises to the surface of the liquid. The collected foam, together with the impurities present therein, can be skimmed off the surface of the liquid.

No. 4,293,400. U.S. Pat. No. 4,123,195 relates to electrolysis of water, in particular to a process and apparatus for electrolytic decomposition of aqueous solutions to disintegrate and select particles dissolved in water. The essence of the process is to pass the aqueous solution through an electrolytic cross-sectional area between a negatively charged cylindrical steel electrode and a positively charged cylindrical aluminum electrode coaxially arranged therewith. The proposed apparatus has a plurality of electrolysis cells having a plurality of cross-sections arranged in a closed plastic tube. The cylindrical outer electrode of the electrolysis cells is preferably the anode and also the cylindrical inner electrode is the cathode. In a preferred embodiment of the apparatus, a helical insulator is provided in the annular space between the cylindrical anode and the cylindrical cathode to define the helical flow path and concentrate the inner cylindrical electrode on the outer cylinder surface of Thus, it creates a helical flow path for the fluid in the annular space between the electrodes. Preferably, the solution to be treated is passed in the opposite direction, prior to the flow through the helical electrolysis path, inside the cylindrical cathode, the inner electrode, so that the separation efficiency is significantly better than being introduced directly into the helical electrolysis path. The liquid discharged from the electrolysis cell of the annular cross-section is transferred to a filter or settling vessel.

A disadvantage of the solution is that the proposed construction delimits the realizable cathode surface / anode surface ratio, which results in a limitation of application. Furthermore, the apparatus is not capable of extracting metal from a solution containing heavy and non-ferrous ions.

SUMMARY OF THE INVENTION The object of the present invention is to provide a simple, low-cost, easy-to-clean, easy-to-maintain device for the economical treatment of wastewater, concentrates containing heavy and non-ferrous ions, electrolytically oxidizable anions and organic compounds. it may be reused where appropriate.

SUMMARY OF THE INVENTION This object is solved by providing an electrolyser having a vertical cylindrical housing with a lower inlet and an upper outlet, a concentrically arranged cylindrical inner and outer electrode and a pump for transporting the fluid to be treated, the inner electrode preferably being centrally disposed according to the invention

- the outer electrode is formed in the annular space between the rod-shaped inner electrode and the cylindrical housing in the form of a spiral electrode spaced from the wall of the cylindrical housing, and

- the inlet and outlet ports are connected tangentially to the lower inlet and the upper outlet.

By the construction of the present invention, the surface ratio of the electrodes to the diameter of the cylindrical inner electrode and the helical outer electrode

-2EN 201278 Practically adjustable by selecting your diameter, cross section and / or "rise".

Preferably, a funnel-shaped hopper with a downwardly tapered cross-section is connected to the lower end face of the cylindrical housing, which is provided with a drain plug at the bottom. In the hopper-shaped hopper, the metal particles in the powder form can be collected. During electrolysis, the particulate metal particles on the cathode, which are captured by the liquid stream, are easily recovered by separators attached to the apparatus. The device can thus be operated continuously.

In the annular space between the cylindrical inner electrode and the helical outer electrode, a cylindrical diaphragm can be concentricly positioned with the electrodes. The cylindrical diaphragm divides the electrode space into an anode space and a cathode space. The top and bottom faces of the cylindrical diaphragm are open inside the cylindrical housing.

Due to the diaphragm, the electrolyte in the anode space and the cathode space cannot mix with each other, so that the oxygen produced in the anode does not get into the cathode space and thus does not interfere with the reduction and does not reduce its efficiency.

Due to the fact that the outer electrode is not formed as a continuous cylindrical surface but rather as a spiral electrode, the metal particles precipitated by the electrolysis in the spiral flow fluid collide not with the cathode wall but with the inner wall surface of the cylindrical housing. no dissolution occurs.

Due to the simple construction of the invention, it is easy to implement, easy to handle, capable of handling a variety of wastewater and concentrates, and can be disassembled for cleaning and maintenance.

By flowing the fluid to be treated in a spiral form, the present invention further achieves a reduction in concentration polarization and an increase in current utilization. By increasing the flow rate, the efficiency of the electrolysis can be significantly increased, especially in the case of low ionic solutions.

The device of the present invention can also be used to effectively treat odors containing heavy metal ions.

The invention will now be described with reference to the drawing. In the drawing:

FIG. 1 illustrates an electrolyzer according to the invention as an example. an outline of an embodiment thereof is shown in side view, partly in longitudinal section;

Figure 2 is a cross-sectional view of the apparatus of Figure 1.

As can be seen from the drawing, the electrolysis device according to the invention has a rod-shaped anode 1 and a concentrically arranged helical cathode 5 around it. The rod-shaped anode 1 and the helical cathode 5 are arranged in a cylindrical housing 3 with a vertical axis, provided with a tangential inlet 8 at the bottom. The helical cathode 5 has a cathode projection 2 projecting upwardly from the cylinder housing 3. The rod-shaped anode 1 also extends upwardly from the cylindrical housing 3.

In the cylindrical housing 3, a cylindrical diaphragm 4 is arranged concentrically between the rod-shaped anode 1 and the helical cathode 5. The cylindrical diaphragm 4 divides the space between the rod-shaped anode 1 and the cylindrical housing 3 into an annular anode space and an annular cathode space. The cylindrical diaphragm 4 has an open end face at the bottom and top of the cylinder housing 3, which allows free fluid inlet and outlet.

A collecting container 6 with a tapered tapered cross-section is connected to the lower end face of the cylindrical housing 3. A drain valve 7 is provided at the bottom of the collection container 6. By means of the drain valve 7, the powdered metal particles collected in the collecting tank 6 can be removed from the apparatus.

The sizing and material selection of the electrodes depends on the particular application. The material of the rod-shaped anode 1 may be, for example, graphite, platinum or titanium coated with platinum or radium oxide, depending on the composition of the electrolyte to be treated. The spiral cathode 5 is preferably made of a rod of circular cross-section, such as KO-steel, titanium, molybdenum, tantalum, niobium or alloys thereof. The cylindrical diaphragm 4 can be formed, for example, from porous ceramic or textile, or possibly from foam-like plastic. The 3-cylinder housing is preferably a plastic tube.

The apparatus is provided with a fluid transport device (not shown), such as a rotary vane pump, which is connected to the tangential inlet port 8 of the cylinder housing 3.

In support of our claims, the following are some examples of experiments carried out on an electrolyzer of the present invention:

Example 1

The solution to be treated contains 50 g / l of Cu ^{+ +} and 50-2 g / l of sulfuric acid, with a pH of less than 1. / solution of copper was obtained with an efficiency of 90 to 100% by reusing the remaining sulfuric acid for copper pickling.

Electrolysis parameters:

Cathodic current density: 1-10 A / dnr

Anode current density: 2-20 A / dm ²

Cathode / anode surface ratio: 2: 1

Anode: rod-shaped graphite

Cathode: spiral copper

Electrolyte flow rate: 200 times the volume of the electrolysis cell.

Example 2

The wastewater to be treated contains 7 g / l Zn ⁺⁺ and an amount of impurities corresponding to 153 g / l COD, pH 5-6. Concentrations after completion of electrolysis:

Zn ⁺⁺ ion concentration: 0.05 g / l

COD value: 0.45 g / l.

Electrolysis parameters:

duration: 4 hours average efficiency (cathode): 70%

2012GB 201278 Cathodic Current Density: 2 AJamf Anodic Current Density: 4 A / dm ² Cathode: KO Spiral Rod Anode: Graphite Rod

Electrolyte flowrate: 200-250 times the volume of the electrolyte cell per minute.

Example 3

The solution to be treated contains 5 g / l Ag ⁺ and 5-10 g / l Cl 'and 50 g / l CN impurity, pH 10-11. At the end of the treatment, the concentrations:

Ag ⁺ km concentration: 0.001 g / l

O * ion concentration: 0.001 g / l

CN * km concentration: 0.001 g / l

Electrolysis parameters: Duration: 7 hours Anodic current density: 12 A / dm ² Cathodic current density: 0.5 A / dm ² Average cathodic efficiency: 30-35% Average anodic efficiency: 50-60% Anode: Graphite rod cathode: Spiral KO- steel electrode.

Electrolyte flow rate per minute: 15 to 300 times the volume of the electrolysis cell.

Claims (3)

1. Electrolysis device for treating wastewater and concentrates containing cations, electronically oxidizable anions and / or organic compounds, having a vertical inlet housing with a lower inlet 5 and an upper outlet, and having a concentrically arranged cylindrical inner and outer electrode, and means for transporting it; characterized in that the outer electrode is formed between the inner cylindrical electrode and the hen10 bore housing (3) as spaced spiral electrodes spaced from the cylindrical housing (3), and a tangential inlet (8) to the lower inlet 9) to join15. Electrolysis device according to Claim 1, characterized in that a funnel-shaped receptacle (6) with a tapering cross-section is connected to the lower end face of the cylindrical housing (3), which It is equipped with 20 lowering pins (7). The electrolysis device according to claim 1 or 2, characterized in that a cylindrical diaphragm (4) is arranged concentrically between the inner electrode and the outer electrode, which divides the electrode space into an annular anode space and an annular cathode space, and its upper and lower front faces are open inside the cylindrical housing (3).