JPH0390587A - Device for electrolytically refining gold - Google Patents

Abstract

PURPOSE:To regularly refine gold without causing the concn. segregation of an electrolyte by providing an air supply means in an electrolytic cell to agitate the electrolyte. CONSTITUTION:The electrolytic cell 20 is filled with a gold electrolyte 20a. An anode rail 21 and a cathode rail 22 are horizontally laid respectively on both sides of the cell 20, and a cathode 23 and an anode 24 are alternately arranged in the cell 20 at regular intervals in parallel with each other. An air pipeline 26 is set above the cell 20, plural branch pipes 26a are extended between the cathode 23 and the anode 24, and the injection nozzle 28 at the tip is directed toward the bottom of the anode 24. The air 27 is injected as bubbles toward the bottom of the anode 24 from the nozzle 28. Consequently, the electrolyte 20a is always agitated, the concn. segregation of the electrolyte 20a is not caused, and gold refining is regularly carried out.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a wall-will type gold electrolytic smelting apparatus.

[Prior Art] FIGS. 3 and 4 are a plan view and a front view showing a conventional four-vessel overflow type wall-will metal electrolytic smelting apparatus.

Symbol l in the figure, 2.3.4 is total electrolytic tL (ft outside hydrochloric acid)
The gold electrolyte 1a in these electrolytic cells sequentially overflows and flows into the next electrolytic cell when the allowable liquid amount of the electrolytic cell is exceeded. , and finally flows into the circulation cylinder 5. Then, the gold electrolyte 1a stored in the circulation cylinder 5 is supplied with an appropriate amount of stock solution of gold electrolyte + a from the Nn supply container 6, and the air pump 7
After being pushed up to the head pin 8, it passes through the circulation gutter a19b again and flows into the uppermost electrolytic cell l and electrolytic cell 3.

In addition, inside the electrolytic cell 1.2.3.4, there is a cathode 10
and anodes 11 are alternately arranged in parallel at regular intervals.

In the cathode 0, a thin plate of high-purity gold was suspended in an electrolytic cell, so that gold was sequentially deposited on the surface of the thin plate. Also, is anode 11 out of durability? This is a storage bag made of high quality metal, etc., and a lump of coarse gold is stored inside it. The structure is such that a cathode 10 is connected to the cathode of an external power source, and an anode 11 is connected to the anode.

In order to smelt gold using such a gold electrolytic smelting apparatus, the air pump 7 is operated and the electrolytic tank l, 2.3.4
The internal gold electrolyte 1a is circulated while overflowing, and the cathode lO and anode 1. Connect the external power supply to l.

As a result, in the anode 11 on the anode side, Au
−3e + 48C1−−AuC1+ + 41(”
Then, a reaction of “Au −e + 28C14AuCL + 2H” occurs, and the crude gold is dissolved.

In addition, near the surface of the cathode lO on the cathode side, ALIC14+ 3e ” 4H” →
A reaction between Au''4HC1 and AuCl,+e+28''-*Au+2HC1 occurs, and gold is sequentially deposited on the cathode IO.

[Problems to be solved by the invention] However, in the conventional gold electrolytic smelting apparatus described above,
A circulation device is required to circulate a large amount of the gold electrolyte 1a, and there is a problem in that the device cost, operating cost, and gold in the gold electrolyte Ia are expensive.

In addition, the circulation method using the overflow of the gold electrolyte 1a is such that the electrolyte in the deep part of the gold electrolyte 1a tank is sufficiently circulated (
There was a problem that it was difficult to stir the gold electrolyte 1a, which caused deterioration of the gold electrolyte 1a.

Furthermore, on the surface of the anode 11, the above reaction and AuC1+ + 2Au + 2C1→3ALIC1
2 reaction occurs, and negative valent gold ions (Au'') are likely to be generated.As a result, a lower equivalent reaction occurs in which gold is deposited inside the gold electrolyte la, 3AuC1t.
-b 2Au + AuC14+ 2CI occurs. This precipitated gold gradually spreads as a thick layer of gold on the surface of the gold electrolyte 1a, causing a short circuit between the cathode 1O and the anode 11, which may cause heat generation and damage to various parts due to excessive current. . Therefore, this floating gold is constantly removed from the surface of the gold electrolyte 1a by the overflow function of the electrolytic cell, but some of it is removed by the air pump 7 or the reflux gutter 9.
There is a problem in that maintenance must be performed constantly because the insides of the circulation devices such as a and 9b are clogged and the circulation devices thereof are affected.

The present invention aims to solve the above problems.

[Means for Solving the Problems] The gold electrolytic smelting apparatus according to the present invention includes an electrolytic solution in an electrolytic cell,
A gold electrolytic smelting apparatus in which a cathode and an anode are immersed with a distance between them is characterized in that an air supply means is disposed inside the electrolytic cell to stir the electrolytic solution in the electrolytic cell by blowing out air. It is something to do.

[Function] According to the gold electrolytic smelting apparatus of the present invention, the inside of the gold electrolyte is constantly stirred by supplying air in the form of bubbles to the inside of the gold electrolyte, thereby preventing concentration segregation of the gold electrolyte. All smelting operations can be carried out normally.

In addition, by supplying this air into the gold electrolyte, the generation of gold inside the gold electrolyte is suppressed due to the oxidizing effect of the air, and furthermore, the vibration of the electrolyte caused by the blown air causes floating gold. By physically removing the air bubbles that cause the generation of nucleation, floating gold on the surface of the gold electrolyte is reduced, thereby preventing short-circuit phenomena between the cathode and the anode.

Furthermore, by using a simple gold electrolyzer that supplies air inside the electrolytic cell, the equipment becomes simple and the cost required for the entire smelting process is reduced.

[Example] Regarding an example of the gold electrolytic smelting apparatus according to the present invention, the first
This will be explained with reference to the drawings and FIG.

The apparatus according to the present invention uses a single electrolytic cell 20, and the inside of this electrolytic cell 20 is filled with an appropriate amount of gold electrolyte (hydrochloric acid acidic liquid) 20a. Also, on both sides of the electrolytic 1v20, there are anode rails 21. connected to the anode of the power supply. and a cathode rail 22 connected to the cathode are arranged horizontally. Furthermore, a cathode 2 is provided inside the electrolytic cell 20.
3 and anodes 24 are alternately arranged in parallel at regular intervals, and their upper ends are supported by a support member 25 and extend over cathode and anode rails 21 and 22. Note that the anode 24 is electrically connected only to the anode rail 21, and similarly, the cathode 23 is electrically connected only to the cathode rail 22.

Further, an air pipe 26 for supplying compressed air (hereinafter abbreviated as air) is arranged above the electrolytic cell 20, and a branch from this air pipe 26 extends into the gold electrolyte 20a. A plurality of branch pipes 26a are arranged. This branch pipe 26a extends between the cathode 23 and the anode 24, and has air 27 at its tip.
An air jet nozzle 28 is attached with its jet port directed toward the bottom of the anode 24. here,
The branch pipe 20a and the air jet nozzle 28 are made of glass or the like, and the inner diameter of the air jet nozzle 28 is about 3 to 4 mm. Furthermore, a supply pipe 29 is disposed above the electrolytic cell 20 so that the gold electrolyte 20a can be supplied as needed.

To perform gold electrolysis using such a gold electrolytic smelting apparatus, the anode rail 21 and the cathode rail 22 are electrically connected, air 27 is supplied from the air piping 26, and air is injected from the air jet nozzle 28. 27 in a bubble state at the anode 2
Squirt toward the bottom of 4.

In this way, by supplying the air 27 in the form of bubbles into the gold electrolyte 20a, the gold electrolyte 20a is constantly stirred, and thereby the concentration segregation of the gold electrolyte 20a does not occur and normal overall production is achieved. Can perform training work.

Furthermore, by supplying this air 27 into the gold electrolyte 20a, the generation of negative valent gold ions (A u") is suppressed. In other words, due to the oxidizing action of the air, HzO+ Au" + 1/20t →
A reaction of 20 H-+ Au'' occurs, and the gold ion changes into a -valent gold ion (A u'') or a trivalent gold ion (A 1+'').

As a result, the average equivalent reaction described above in the conventional example does not occur, and the generation of gold inside the gold electrolyte 20a is suppressed.Furthermore, the vibration of the gold electrolyte 20a caused by the blown air causes the generation of floating gold nuclei. By physically removing the bubbles, floating gold on the surface of the gold electrolyte 2Qa is reduced, thereby preventing a short circuit phenomenon between the cathode 23 and the anode 24.

Furthermore, by using a simple gold electrolysis device that supplies air 27 into the electrolytic cell 20a, the device becomes simple and the cost required for the entire smelting process can be reduced.

In addition, in the above embodiment, the branch pipe 26a inside the gold electrolyte 20a is connected to the air jet nozzle 2 at the lower part of the anode 24.
Although the cathode 23 is disposed facing toward the lower part of the cathode 23, the same effect can be obtained even if it is disposed toward the lower part of the cathode 23.

[Effects of the Invention] According to the gold electrolytic smelting apparatus of the present invention, the inside of the gold electrolyte is constantly stirred by supplying air in the form of bubbles to the inside of the gold electrolyte, thereby reducing the concentration segregation of the gold electrolyte. All smelting operations can be performed normally when the machine wakes up.

In addition, by supplying this air into the gold electrolyte, the generation of gold inside the gold electrolyte is suppressed due to the oxidizing effect of the air, and furthermore, the vibration of the electrolyte caused by the blown air causes floating gold. By physically removing the bubbles that cause the generation of nuclei, floating gold on the surface of the gold electrolyte can be reduced, and short circuit phenomena between the cathode and the anode can be prevented.

Furthermore, by using a simple gold electrolysis device that supplies air into the electrolytic cell, it is possible to simplify the device and further reduce the cost required for the entire smelting process.

[Brief explanation of drawings]

1 and 2 show an embodiment of the gold electrolytic refining apparatus according to the present invention, FIG. 1 is a partially omitted plan view, FIG. 2 is a partially omitted front sectional view, and FIGS. FIG. 4 shows a conventional gold electrolytic smelting apparatus, FIG. 3 is a plan view, and FIG. 4 is a partially sectional front view. 20... Electrolytic cell, 23... Cathode, 26... Air piping, 27... Air 2 20a... Gold electrolytic branch, 24... Anode, 26a...Branch pipe, 8...Air jet nozzle.

Claims (1)

[Claims] In a gold electrolytic smelting apparatus in which a cathode and an anode are separately immersed in an electrolytic solution in an electrolytic cell, air is supplied to stir the electrolytic solution in the electrolytic cell by jetting air into the electrolytic cell. A gold electrolytic smelting device characterized in that a means is provided.