RU2416653C2 - Procedure for processing ore with minimal acidic wastes - Google Patents

Abstract

FIELD: metallurgy. ^ SUBSTANCE: procedure consists in addition of carbonates to ore, in their combined crumbling and in producing treated ore mixture, in mixing and homogenisation ensuring neutralisation of sulphuric acid formed in the said ore mixture treated with carbonates. Carbonates are added at amount sufficient for neutralisation of acid. Added to ore carbonates in essence are not dissolved in water. As carbonates added to ore there are used, for example, dolomite or calcite. ^ EFFECT: production of ore wastes not forming acid at relatively low expenditures and relatively easy implementation of procedure into known methods of ore treatment. ^ 12 cl, 1 dwg

Description

The present invention relates to the general field of mining and, in particular, relates to a method for processing ore to minimize the formation of acid waste.

It is well known in the state of the art that mining and storing sulphide-containing materials such as mine waste, metal ores, coal seams and residues after enrichment, among other things, often lead to the formation of acid waste, which, in turn, is harmful to the environment Wednesday. Indeed, acidic waste adversely affects fauna and flora. Moreover, when the acid generation potential of the ore exceeds the neutralizing ability of the ore, sulfuric acid is often formed. Sulfuric acid can then be dissolved in water to form a solution of sulfuric acid. Such sulfuric acid solutions have an undesirable effect on concrete structures such as bridges and dams. In addition, acids and heavy metals such as iron and arsenic, which are soluble in acids, damage the quality of water and can poison crustaceans, fish, and the like.

Oxidation of sulfur-containing compounds such as pyrite or the like minerals does lead to the formation of acidic solutions. Chemical reactions include the oxidation of sulfur-containing compounds in the presence of oxygen and water to form iron hydroxide and sulfuric acid. Acidic solutions are commonly referred to as acidic mine waters or acidic mine waters. These acidic solutions dissolve and mobilize certain metals, in particular iron and manganese, which remain relatively insoluble under neutral or basic conditions.

In prior technology, problems associated with mine waters were solved mainly by concentrating acid-forming sulfides and storing them in bodies of water such as a pool or lake. The flooding or immersion of such sulfides prevents contact with air and thereby prevents the oxidation of sulfides. Although useful in some respects, the preceding method has numerous disadvantages.

Indeed, for some cases, sulphide immersion requires the creation of a precipitation pond and its maintenance in such a state as to prevent the pond from being drained, which would inevitably lead to the oxidation of sulfides and, therefore, to the formation of acid. Further, for some ores, it is simply not possible to extract enough sulfides to turn waste into non-acidic material.

Based on this prior art, there is a need for an improved method of processing ore to minimize acid waste generation. The aim of the present invention is the provision of such a method of processing ore, which would minimize the formation of acid waste.

In a first broad aspect, the invention provides a method for processing ore using carbonates in such a way as to minimize the formation of acid waste. The method includes adding carbonates to the ore and, after carbonates have been added to the ore, essentially co-grinding the ore and carbonates to prepare a processed ore mixture. Essentially co-grinding the ore and carbonates substantially mixes and homogenizes the ore and carbonates so that acids subsequently formed in the treated ore mixture are substantially neutralized in the treated ore mixture by these carbonates.

The advantages of the present invention include the fact that the proposed method allows to obtain mine waste, not forming acid, at relatively low cost. Also, this method is relatively easily integrated into existing ore processing methods.

Further, the proposed method is directed to the source of the problem associated with the formation of acid waste and is therefore relatively effective. In addition, the resulting mine waste can be stored in conditions that require only minimal maintenance or do not require it at all. Therefore, this method provides an essentially relatively safe method for storing waste that is not affected by socio-economic unrest, such as armed conflict and bankruptcy, which could make it impossible to maintain the waste site properly.

In some embodiments of the invention, carbonates are added in the form of minerals, which, conveniently, are produced near the ore processing plant, which improves the profitability of the proposed method.

It turned out that the processed ore mixture is relatively stable and can be subjected to most commonly used stages of ore processing without loss of neutralizing properties.

In another broad aspect, the invention provides a method for processing ore using carbonates in such a way as to minimize the formation of acid waste. The method includes grinding carbonates and ores so that carbonates and ores have substantially similar particle size distribution, and mixing the crushed carbonates and the crushed ore to produce a processed ore mixture. By mixing carbonates and ores, a processed ore mixture is prepared such that acids subsequently formed in the treated ore mixture are substantially neutralized in this processed ore mixture by carbonates.

Other objectives, advantages and features of the present invention will become more apparent when reading the following non-limiting description of its preferred embodiments, given here only as examples and with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The attached drawing is a diagram illustrating a method of processing ore using carbonates in such a way as to minimize the formation of acid waste in accordance with an embodiment of the present invention.

The proposed method is based on the observation that the difference between acid-forming ores and non-acid-forming ores often lies in the fact that the former do not contain enough natural carbonates to absorb all the acid that can form. The amount of acid formed is mainly due to the difference between the amount of acid that sulfides contained in the ore can form and the amount of acid that the carbonates contained in the ore can neutralize.

Therefore, the proposed method is based on adding carbonates to the ore, such as, for example, dolomite, calcite, a combination of dolomite and calcite, or any other suitable carbonates. For example, but not limited to, carbonates are added at a predetermined ratio to the grinding site of the processing plant.

The use of carbonates is opposed in the mining industry to the old tradition of using hydroxide products to neutralize acids. Indeed, in the mining industry, the most commonly used neutralizing products are, as a rule, quicklime and slaked lime (CaO or Ca (OH) ₂ ). Although these products are powerful acid scavengers, they are relatively easily leached by rainwater.

Surprisingly, it has been found that after adding to the ore, carbonates remain mixed with the ore during most of the operations currently carried out with such ores. Furthermore, in embodiments of the invention where the carbonates are substantially insoluble in water, carbonates can remain in the ore for a relatively long period of time, even when the ore is stored in the rain.

The person skilled in the art will immediately appreciate that it seems illogical to add a neutralizing agent to the ore before processing the ore in order to extract certain ore components, such as metals, as this increases the amount of ore to be processed. However, it turned out that the additional costs of processing an increased amount of ore may in future compensate for the maintenance costs of the waste site, which are required when a neutralizing substance is not used in this way.

Based on the foregoing, a method 100 for processing ore using carbonates in such a way as to minimize the formation of acidic waste, as shown in the drawing, is proposed. Method 100 begins at step 105. At step 110, the ore is crushed. Then, at step 115, the magnitude of the acid generation potential and the ore neutralization potential are determined. Subsequently, in step 120, carbonates are added to the ore, and carbonates and ore, essentially together, are ground in step 125 to prepare a processed ore mixture. By essentially co-grinding the ore and carbonates, the ore and carbonates are substantially mixed and homogenized in such a way that acids subsequently formed in the treated ore mixture are substantially neutralized in the treated ore mixture by carbonates. The method 100 then ends at step 130. After the method 100 is implemented, the processed ore mixture can be processed essentially in the same way as the ore is usually processed.

Step 115 of determining the magnitude of the acid-forming potential and the neutralization potential of the ore can be performed at any suitable stage. In some embodiments of the invention, step 115 is omitted and carbonates are added to the ore in a predetermined amount. In other embodiments of the invention, the neutralization potential of the ore is not determined, but only the acid formation potential of the ore is determined.

At step 120, carbonates are added to the ore. In some embodiments of the invention, carbonates are substantially insoluble in water, which serves to protect the treated ore mixture from external influences. For example, carbonates in the form of dolomite, calcite, a combination of calcite and dolomite, or any other suitable carbonates are added. Indeed, such substances are sometimes found near ore processing plants, which provides a relatively inexpensive source of carbonates. In other embodiments of the invention, carbonates are at least partially soluble in water.

In some embodiments of the invention, the carbonates are added to the ore in an amount having an acid neutralization potential sufficient to neutralize at least the acid formation potential of the ore so as to ensure that at least it is possible to neutralize all the acid that the ore can form. For example, carbonates are added to the ore in an amount having an acid neutralization potential sufficient to neutralize the approximately doubled acid formation potential of the ore. Such an amount of added ore was considered useful because it provides a safety margin in case some of the carbonates become inaccessible to neutralize the acids formed in the ore, although they remain relatively inexpensive.

In some embodiments of the invention, carbonates are added in an amount that takes into account only the acid potential of the ore. In these embodiments, there is no need to determine the magnitude of the neutralization potential of the ore. In other embodiments of the invention, the carbonates are added in an amount sufficient to supplement the natural neutralization potential of the ore.

It turned out that carbonates are effective in neutralizing sulfuric acid formed in ores containing sulfites. However, the processing of ores in which acids are formed from other substances also lies within the scope of this invention.

At step 125, in some embodiments of the invention, the ore and carbonates are ground so as to obtain a processed ore mixture in which the ore and carbonates have substantially similar particle size distribution. This facilitates the homogenization and mixing of ore and carbonates.

Although in method 100, carbonates and ore are ground substantially together, the scope of the invention includes the ability to mix carbonates and ore in any other suitable way to prepare a processed ore mixture. In some embodiments of the invention, the carbonates and ore are ground so that the carbonates and ore have substantially similar particle size distribution and are then mixed. For example, carbonates and ore are crushed separately from each other before being mixed together.

In embodiments of the invention where the ore and carbonates are ground substantially together, carbonates can be added at any stage before grinding, such as, for example, crushing stage 110.

Although the method 100 includes an ore crushing step 110, in an alternative embodiment of the invention, the processed ore has a particle size distribution that makes step 110 unnecessary, and this step can then be omitted.

When carbonates are used, acidic products, such as acid formed by mine waste, are the main substances with which they interact. When minerals form acid, it is captured by carbonates, which convert the acid into non-polluting gypsum.

Typically, carbonates are added to the grinding site of the processing plant in such a way that the granule size of the added carbonates is substantially similar to the granule size of the carbonates contained in the ore. Therefore, the addition of carbonates creates a homogeneous mixture in which the natural and added carbonates are essentially indistinguishable.

It should be understood that although the term “carbonate” is used throughout the text, it will be understood by one skilled in the art that calcium carbonate (calcite), calcium magnesium carbonate (dolomite) or any other suitable substance can be used without departing from the scope of the present inventions.

Carbonates can also be mixed into waste rock when sent to a dump. Again, carbonates and gangue should be similar in size to the granules.

The proposed method affects the amount of sulfuric acid formed by sulfites contained in the waste by converting the acid dissolved in water and sulfur in the form of sulfite to gypsum, as shown in the following equation:

for calcite:

CaCO ₃ + H ₂ SO ₄ = CaSO ₄ + H ₂ O + CO ₂

CaCO ₃ + ZnSO ₄ = CaCO ₄ + ZnCO ₃

for dolomite:

CaMg (CO ₃ ) ₂ + H ₂ SO ₄ = CaSO ₄ + MgCO ₃ + 2H ₂ O + CO ₂ .

The skilled person knows that calcium sulfide is insoluble. Therefore, it will remain in the waste and will not harm the environment. Similarly, metal carbonates, such as zinc carbonate, will also remain in the waste.

Although the present invention has been described above using its preferred embodiments, it can be modified without deviating from the idea of the subject invention, as defined in the attached claims.

Claims (12)

1. A method of processing a sulfide-containing acid-forming ore during oxidation using carbonates to minimize the formation of acidic waste, including adding carbonates to the ore, co-grinding the ore and carbonates to produce a processed ore mixture, mixing and homogenizing it so that sulfuric acid, subsequently formed in the specified treated ore mixture is neutralized in the treated ore mixture with carbonates added in an amount sufficient to neutralize the acid. 2. The method according to claim 1, wherein the carbonates added to the ore are substantially insoluble in water. 3. The method according to claim 1, in which dolomite is added to the ore as carbonates. 4. The method according to claim 1, in which calcite is added to the ore as carbonates. 5. The method according to claim 1, further comprising determining the value of the acidification potential of said ore, said carbonates being added to said ore in an amount having an acid neutralization potential sufficient to neutralize at least said acidification potential of said ore. 6. The method according to claim 5, in which said carbonates are added to said ore in an amount having an acid neutralization potential sufficient to neutralize about twice the indicated acid formation potential of said ore. 7. The method according to claim 1, further comprising determining the acid potential of said ore and the acid neutralization potential for said ore, said carbonates being added to said ore in such an amount that the acid neutralizing potentials for said carbonates and said acid neutralizing potential for said ore was totally sufficient to neutralize at least the indicated acidification potential of said ore. 8. The method according to claim 7, in which said carbonates are added to said ore in such an amount that the indicated acid neutralization potentials for said carbonates and said acid neutralization potential for said ore are totally sufficient to neutralize about twice the value of said acid formation potential of said ore. 9. The method according to claim 1, wherein said ore and said carbonates are crushed so as to obtain a processed ore mixture in which said ore and said carbonates have substantially similar particle size distribution. 10. The method according to claim 1, in which the specified ore includes sulfites having the potential for the formation of sulfuric acid. 11. The method according to claim 1, further comprising crushing said ore before grinding said ore. 12. The method according to claim 11, in which said carbonates are added to said ore before crushing said ore and co-crushing said ore and said carbonates.

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