Solution mining Introduction Technology of solution mining Technology of the salt production Geological conditions Pros and cons
Solution mining - Introduction The method of solution mining is a very old technological process. Natural brine sources were already used in antiquity. Brine was produced by squirting water into mining chambers as well as by injection of water in the deposit through wells. In the 50th and 60th new fields of the technology were developed. The present status of equipment of the well was developed. The erected cavern by solution mining often used as underground storages for gas or oil. Besides the exploitation of rock salt other minerals obtains a great importance (i.e. sylvinite, carnallite, bischofite, trona). The control and measurement methods for steering the size and the form of the cavities were elaborated.
Technology of Solution Mining (1) A bore hole was drilled from the surface of the earth to the bottom of the salt layer. A casing was worked in the bore well and was cemented from the surface to the top side of the deposit. The cement must shut tight against the pressure of the blanket. The surface of the bore hole in the area of the deposit is free. The salt can be dissolved.
Technology of Solution Mining (2) The dissolution of the salt begins with the solution of a cavern sump. The sump shall be accommodate the insolubles of the deposit near the casings in the well. During the solution of the sump only water is used . The water current is directly, that means that the current of brine in the cavern has the same direction as in the production casing. The solution of the sump can be ended if the diameter of the cavern is 5 – 10 m.
Technology of Solution Mining (3) The next step is the undercut phase. The injected water is going trough the outer casing and the brine leave the cavern trough the inner casing. This current direction is named indirectly. Important for the forming of the cavern is the precise controlling of the blanket level.
Technology of Solution Mining (4) For winning of the salt in the deposit the level of the casings and the blanket was arranged higher. Because in the cavern the density of the brine increases from the top to the bottom, the brine current goes from the end of the outer casing under the blanket level to the side and then it flows to the inner casing and to the surface.
Technology of Solution Mining (5) The last step is reached, if the cavern arrives the top of the deposit.
Technology of Solution Mining (6) Last of all the tubes were removed and the bore hole will be cemented.
Technology of Solution Mining (7) The equipment of the brine place is very simply. For the production of brine is needed: (1) a building for a control room and an office, (2) a workshop and a storage, (3) a building for pumps, (4) a blanket station, (5-7) tanks for water and brine
Technology of Solution Mining (8) Another technology is used for the erection of underground storages. In this case the salt was dissolved after the undercut in only one step. The entry of the solvent into the cavern is trough the inner tube. From there the solvent rises up, dissolves the salt and goes to the outer casing. The sides of this cavern are more straightly as the caverns which is leached with the step-by-step technology. A disadvantage of this procedure is that the brine is in the most cases not saturated.
Technology of Solution Mining (9) Methods to control the size of the caverns 1. Measurement of radial distance between the well and the cavern surface with ultrasonic sondes (sonar). 2. Measurement of the area by addition of blanket into the cavern and determination of height difference of the blanket level. 3. Mass- and volume balance of solvent injection and brine recovery This three methods used together allows an precise assessment of the cavern area and size.
Technology of the salt production (1) The most important salt minerals, which produced by solution mining are: Rock salt (NaCl) Sylvinite (NaCl + KCl) Carnallite (MgCl2 * KCl * 6H2O) Because these minerals have very different thermodynamic properties, the production technology for each salt had to developed specifically. How we have to see later for the winning of carnallite the development of a new solution mining technology was necessary.
Technology of the salt production (2) – Rock salt The most important property of NaCl is the independence of the saturation concentration from the temperature. Because of this the whole water contains in the brine must be evaporated. For example contains 1000 l saturated NaCl brine 317 kg KCl and 882 kg H2O. That means the production of NaCl is a very energetic intensive process. In locations with arid climate often used the evaporation in solar ponds. Otherwise the evaporation must take place in technical plants. As energy base is used steam or electrical power.
Technology of the salt production (3) – Rock salt Flowsheet of NaCl production in a solar pond process Brine Solar pond Harvested crystalline crop Crushing, screening Water Soiled brine Washing Oil or gas Water Drying Storage NaCl
Technology of the salt production (4) – Rock salt Flowsheet of NaCl production in a technical process Brine Chemical purification, precipitation of Mg++, Ca++,SO4-- Steam or electrical power Water Evaporation, crystallisation Water Oil or gas Drying Storage NaCl
Technology of the salt production (5) –Sylvinite Sylvinite is a mixture of NaCl and KCl. In the case of contact with water by solution mining will be dissolved both components. At first in relation of their concentration in the raw salt and later the dissolution is appraoching to the invariant point M (red line), as shown in the following picture.
Technology of the salt production (6) Sylvinite Flowsheet of NaCl + KCl production in a technical process Brine Chemical purification, precipitation of Mg++, Ca++,SO4-- Steam or electrical power Water Evaporation, NaCl crystallisation NaCl Water Soiled brine Washing Vaccum cooling, KCl crystallisation Oil or gas Water Drying Oil or gas Drying Storage Storage NaCl KCl
Technology of the salt production (7) –Carnallite Carnallite is a double salt of MgCl2, KCl and six crystall water (MgCl2 * KCl * 6 H2O). The solubility of the system Mg – K – Cl – H2O is shown in the following diagram. Carnallite crystallisation by vacuum cooling Evaporation Cold leaching KCl loss by decomposition Cold leaching
Technology of the salt production (8) Carnallite How we can see the cold leaching has no efficiency, because - the brine is not high concentrated and many water must evaporated - the losses of KCl by decomposition of carnallite are very high Therefore the hot leaching technology for solution mining of carnallite must used. This procedure has not the named disadvantages and has the following advantages: - The brine is high concentrated. Carnallite can be crystallised by evaporation of a few amount of water and cooling the brine - The solvent is saturated on NaCl. Therefore halite and also kieserite remain in the cavern as residue. - In the cavern remains a high concentrated brine, which not worries the environment. Because the solvent has a high temperature, the cavern has two wells as shown in the following picture. In only one well would exchange the heat between the concentric inner and outher tube or casing.
Technology of the salt production (9) Carnallite Solution mining of carnallitite with: - two wells - selective dissolution - hot leaching
Technology of the salt production (10) Carnallite
Geological conditions The very best to use the solution mining technology is: - a great height of the deposit - and a low depth But by using new developed technologies the winning of mineral salts in deposits with low height is possible. This new technology is named solution mining with „tunnel caverns“. In this case one bore hole was drilled verticaly and the other was drilled at first verticaly and then it follows in the deposit the direction of the salt layer with a deviation. This technologie is not usable if the deposit has tectonical breakdown and other disturbances or great changes in the direction. The drilling of the bore holes can be complicated and expensivly if the overburden contains gas or water.
Pros and cons Pros: Cons: In the most cases solution mining has a very high economic efficiency because: The investment costs are low. (We don‘t need a mine) The drilling of the bore holes are running costs The demand of manpower is low Solution mining can also used by difficult hydrogeological conditions. The first step of the potash mill (hot leaching) is in the underground. There are no costs for this equipment. Residue and high concentrated brine stays in the cavern, therefore there environmental burdens are low. Cons: If the geological and tectonical conditions are very difficult, the solution mining is not usable.