DE1280777B - Process for dissolving uranium ores in situ with the help of electric current - Google Patents

Description

Process for dissolving uranium ores in situ with the assistance of electrical Electricity The solution of uranium ores in situ is being used successfully at various deposits applied. In this process, the dissolving water is passed through at suitable points Inlet wells or other suitable facilities fed into the mountains and through Withdrawal wells pumped out again after flowing through the deposit to be loosened and fed to the corresponding systems for producing concentrate from the dissolving water.

In order to achieve an economical dissolving effect, the dissolving water acidic or alkaline up to the empirically determined pH value, to speed up the solving process in situ.

Acidic or alkaline additives to the dissolving water can be undesirable Cause impairment of the vegetation present in the work area; also is due to the tolerance limits the addition of acidic or alkaline salts to the natural open water as well as in the groundwater by legal regulations limited.

The following invention describes a method which overcomes the disadvantages avoids the use of acids or alkaline additives in dissolving water and allowing an economic recovery of the deposit in situ by using natural Water used under the influence of electricity.

In order to accelerate the dissolving process, this is done by means of swallowing wells or with similar facilities, such as open trenches or well-like depressions, dissolving water to be brought to percolation beforehand with oxygen or air or other appropriate additives enriched to the appropriate extent to oxidizing or other Reactions to the dissolution of mineral on the rock crevices or in sandstones or other substances occurring in porous rocks.

By the action of an electrical circuit on the dissolving water in the dissolution area, the solution of the deposit is in situ with natural waters, which are taken from the reservoir or the groundwater, made economically possible.

The electrodes that are connected to the electrical circuit, are in the immediate vicinity of the feed and withdrawal points for the dissolving water to be arranged, with the deposit part to be loosened lying between the electrodes got to. The electrical current strength depends on the extent of the ore area to be leached and adjusted according to the amount of dissolving water in the lye area and by measuring instruments controlled.

The molecules of most of the compounds soluble in water are subject to it in solving a spontaneous cleavage in oppositely charged atoms or Groups of atoms (ions). This turns the dissolving water into an electrolyte, its conductivity can be increased by the action of electric current, because the electrolytic The conductivity of solutions is based on their spontaneous splitting (dissociation).

The solutes are positively charged cations that are under the Effect of an electrical voltage migrate to the cathode and negatively charged anions, flowing towards the anode.

The ions can be one or more depending on the nature of the substances involved be multi-valued and also occur mixed, but the solutions themselves stay electrically neutral. The electrical conductivity of a solution is determined by the ion concentration of the solutions, d. H. by concentrating on dissolved Substances and by the degree of cleavage (degree of dissociation) as a ratio of the electrical split to the total of molecules present in a solution, with the Ion mobility, a product of the field strength, as well as temperature and viscosity contribute.

The electric field strength is the electric power supplied from the outside Energy and has the same effect as supplying heat to the dissolving water. The improved Dissolving effects through heat are well known.

Because the ions, like the neutral molecules, and unlike electrons are also material carriers, they are deposited on the feed electrodes in a form, which is determined by the chemical conditions. It is therefore possible through The effect of an electric current on the solution path increases the yield without the addition of acid to increase if sufficient energy is supplied by suitable current intensities to break the molecular bonds. Depending on the type of ion exchanger used to recover the Mineral from the solution water selected the polarity of the electrical voltage on the feed electrodes, d. H., if the ion exchanger used is a cation exchanger, the electrode must be connected to the cathode at the dissolving water suction point.

With the help of the electric current in the solution in In situ, the dissolving water becomes differently charged by the marked direction Ions, which are also material carriers, in a predetermined path, namely between the two feeding electrodes, forced. This makes it possible to use the solution by selecting the appropriate electrode arrangement for a specific solution area to concentrate. .By scanning the electrical potentials in the release zone the direction of release and the release effect are controlled by electrical display instruments will.

With electrophoresis, the colloidal particles are transported through the electric field moved in the dissolving water. The mobility is directly proportional with the applied electric field. The electrophoresis thus accelerates the Dissolving effect of the dissolving water.

By applying the electric field in the solution zone (ore deposit) the electroosmosis is also effective, the dissolving water as an electrolyte by the porous solids (ore-containing rock) moved and thus also for improvement contributes to the dissolving effect.

The splitting (decomposition) of part of the electrolyte Dissolving water into hydrogen and oxygen by the action of the electric Electricity is also used for the necessary oxygen supply to the dissolving water, in order to accelerate the dissolving process. This procedure can analogously also can be used for other ore deposits (other metal elements).

Claims (2)

Claims: 1. Process for uranium ore leaching in situ, marked in that natural water acts as the dissolving water in the leaching zone be used by electricity. 2. The method according to claim 1, characterized in that that the electrical potential arising in the dissolving water to control the dissolving direction and loosening action is used in the deposit.