EA006105B1 - Method for adaptation of bacteria for use in leaching of ores and concentrates - Google Patents

Abstract

A method for the adaptation of bacteria for use in the leaching of ores and concentrates, the method characterised by the steps of: a) Obtaining samples of bacteria exhibiting salt tolerance; b) Combining bacterial samples from step a) with a stock bacterial culture known to have the ability to oxidise sulphide minerals, whereby the resulting combined bacterial culture ultimately expresses salt tolerance and the ability to oxidise sulphide minerals.

Description

This invention relates to methods of adapting bacteria for use in the leaching of ores and concentrates. In particular, the method according to this invention relates to the adaptation of bacterial cultures oxidizing sulfide minerals to work effectively in specific environmental conditions, including salinity conditions.

Prior art

For bacterial oxidation of sulphide minerals, appropriate amounts of industrial water are needed, regardless of whether leaching is carried out in tanks, vats, dumps or heaps. The bacterial cultures used in these leaches work well in waters with a low total content of dissolved solids (ΤΏ8) and, more importantly, with low levels of chloride ions. In some parts of the world, especially in Australia, it is very difficult to find good quality water and the cost of improving water quality through the use of water treatment plants is very high. In order to apply bacterial leaching using data from low-quality industrial waters, it is important that sulfide-oxidizing bacteria be adapted to media containing salts.

Bacteria are ubiquistic (have a wide ecological amplitude) relative to the environment and can be found in such diverse environmental conditions as thermal sources of the ocean floor, sulfur sources and salt crystals. It is known that plasmids are found in most species of bacteria. Plasmids are extrachromosomal regions of circular DNA. Plasmid genes are often important for the growth of bacteria under certain extreme environmental conditions (see the monograph by David Freyfelder (Eugene1 Όανίά) The Basics of Molecular Biology (E hayan MotioniGurus), 1st and 11th, Ipasc, Step, Ipp., App. . It is known that plasmids are often and rapidly transferred among bacteria.

It is possible that any bacterium living in saline conditions may contain plasmids that make this possible. Subsequently, these plasmids could be transferred to sulphide-oxidizing bacteria.

The main method of adaptation of bacteria for use in the leaching of ores and concentrates was described by the present applicant in the simultaneously considered international application PCT / Ai02 / 00182 and its content is fully entered into this context by reference.

The foregoing discussion of prior art is intended only to facilitate understanding of the present invention. It should be noted that this discussion is not an acceptance or acceptance of the fact that any of the reviewed materials is a piece of ordinary general knowledge in Australia at the priority date of the application.

Throughout the description, unless the context indicates otherwise, the word contains or its variants, as it contains or it should be understood to include a specific feature or group of features, but not exclude any other feature or features.

Summary of Invention

In accordance with the present invention, a method for adapting bacteria for use in the leaching of ores and concentrates is presented, which is characterized by the following stages:

a) obtaining samples of bacteria with salt tolerance (soletolerant);

b) mixing samples of bacteria obtained in stage a) with a uterine bacterial culture that has the ability to oxidize sulphide minerals and

c) growing the mixed culture obtained in stage b) for a period of time under saline conditions, where the resulting mixed bacterial culture ultimately exhibits both salt tolerance and the ability to oxidize sulphide minerals.

In addition, in accordance with this invention, a method for the adaptation of bacteria for use in the leaching of ores and concentrates under general salinity conditions is proposed, which is characterized by the following stages:

a) obtaining water samples containing salt-tolerant bacteria,

b) mixing and growing samples of bacteria obtained in stage a),

c) mixing a uterine bacterial culture, which has the ability to oxidize sulphide minerals, with a nutrient solution prepared from one or more samples obtained in step a), thereby starting the adaptation of the uterine bacterial culture to salinity conditions,

g) mixing the sample of bacteria obtained in stage b) with a sample of the culture obtained in stage c), and

e) growing mixed samples obtained in stage d), gradually increasing the salt content, while the mixed bacterial culture ultimately exhibits both salt tolerance and the ability to oxidize sulfide minerals.

Preferably, when the water samples obtained in stage a), are used as a standard for the preparation of artificial salt solutions, which, in turn, are used for the preparation of artificial salt nutrient solutions used in stage c). In addition, at stage c)

- 1 006105 it is preferable to use a nutrient solution prepared from the sample with the lowest concentration of chloride ions among the samples obtained in step a).

The list of figures drawings and other materials

The drawing shows a schematic representation of the process of adaptation of bacteria for use in the leaching of ores and concentrates under conditions of total salinity in accordance with this invention.

Information confirming the possibility of carrying out the invention

In general, this invention is intended to collect bacteria capable of working in saline waters and mixing these bacteria with sulphide-oxidizing bacteria in order to transfer the sign of salt tolerance from bacteria from saline water to sulphide-oxidizing bacteria by transferring DNA from one species to another.

The method according to the invention will now be described with reference to an example and a drawing. The example is not intended to limit the general provisions of the preceding description. The drawing should be considered by linking it with the following description.

The authors found that DNA transfer is most likely to occur between bacteria from close environmental conditions. Samples of natural bacteria are harvested from black emissions (Husk kshokega) into the sea. Black emissions are sulphide deposits found on the ocean floor. Emission studies show that they are densely populated with bacteria. Additional samples are collected from ponds with water for processing in or around sulphide mines. Samples of ore or liquids from saline environments are also collected from mines; these samples consist of liquids, dirt, and dry solids. In all cases, water / liquid samples are taken from each site.

Each of the collected liquid / water samples is subjected to a complete analysis of 1CP-OE8 (spectral spectrometry of optical emission induced plasma), including analysis of sodium, chloride and ΤΏ8 (total dissolved solids) in order to determine the levels of different salts in the samples. Also determine the pH of liquids and precipitation.

Samples containing liquids are examined under a microscope and the number of bacteria is determined.

The results of the analysis of TO 8 and 1CP are mainly used as a standard for the preparation of artificial salt solutions for the corresponding samples using salts for aquariums. The calculations are carried out to a greater extent on the levels of C1 ^- than on 8. Synthetic salt solutions are used to prepare artificial salt nutrient solutions, since it is often difficult to obtain water samples in sufficient quantities for testing.

Standard approved nutrient solutions are prepared using artificial saline solutions.

Any of the solid samples is divided in half, one half is crushed and used as a sulfide power source for samples of autochthonous bacteria from this place, the other half of the sample is not crushed, because the bacteria can be damaged by shear.

The unground solid sample is mixed with an artificial saline solution, like the salt water from which it originates, and the bacteria on the solids are grown in shake flasks.

Solid and liquid samples from one place are mixed and placed in a shaking bath at 45 ° C. Yeast extract is added to these tests at a concentration of 0.1 g / l. Yeast extract is a source of nutrients for heterotrophic bacteria.

The pH value of all suspensions down to the natural pH value of samples taken from the environment.

Each week, the pH of the tests is reduced by 0.5 units to obtain a pH <2.0, which is maintained. All pH adjustments are carried out by adding concentrated sulfuric acid.

In shake flasks, weekly bacterial activity is checked, fluid samples are taken and analyzed for the presence of metals in solution.

Uterine bacterial culture capable of oxidizing sulphide minerals is slowly adapted to waters containing salts. The culture is grown in a sample of an artificial nutrient solution with minimal levels of C1 ^- (approximately 13 g / l). Levels C1 ^- gradually increase over time, in some cases over eight months, to levels of chloride 98 g / l.

When the number of bacteria from their native salt samples becomes high enough (> 10 ⁷ cells / ml), the cultures are divided into three parts. The first sample is supplied with nutrients and stored, the second sample is propagated, supplied with nutrients and maintained, and the third sample is mixed with an equal amount of uterine bacterial culture adapted to low salinity levels, as described above.

In analyzes of the availability of sulfides for exposure to bacteria, mixed cultures of bacteria are used as inoculum. The test is carried out on volumes up to 3 liters using an appropriate salt nutrient medium and the tests are carried out in standard tank-type reactors at a temperature

- 006105 re, lying in the range of 40-55 ° C. Sulfide ore / concentrate is introduced into the test and yeast extract is added to obtain a concentration of 0.1 g / l.

The test is monitored by determining the levels of metals present in the solution.

The transfer of genetic material from one species of bacteria to another species may occur for some time. However, the resulting bacterial culture can both grow under conditions of salinity and oxidize sulphide minerals.

The salt content during testing can be increased at each subsequent stage to chloride levels of at least 40-55 g / l and up to approximately 98 g / l or to levels ΤΌ8 at least 80000-90000 ppm (ppm) and up to approximately 200,000 ppm However, if necessary, the levels of chloride and могут8 can be increased relative to these levels.

Other modifications and variations that should be obvious to a competent person will be within the scope of this invention.

Claims (12)

CLAIM 1. A method of adapting bacteria for use in leaching ores and concentrates, characterized in that first obtain samples of salt-tolerant bacteria, then mix the obtained bacteria samples with a uterine bacterial culture capable of oxidizing sulfide minerals, and then the resulting mixed culture is grown for a period of time in saline conditions and get a mixed bacterial culture with salt tolerance and the simultaneous oxidation ability of sulfide minerals. 2. The method according to claim 1, characterized in that the samples of salt-tolerant bacteria are isolated from water samples, while these water samples are used as a standard for the preparation of artificial solutions, which then, in turn, are used to prepare nutrient solutions for the uterine bacterial culture. 3. The method according to claim 1 or 2, characterized in that the samples of salt-tolerant bacteria are isolated from at least two places, then they are mixed and grown, while this mixed culture is further mixed with the uterine bacterial culture. 4. A method of adapting bacteria for use in leaching ores and concentrates under conditions of general salinity, characterized in that water samples containing salt-tolerant bacteria are first obtained, then samples of salt-resistant bacteria are mixed and grown, after which the uterine bacterial culture is adapted to salinity conditions by mixing uterine bacterial culture with the ability to oxidize sulfide minerals, with a nutrient solution prepared from one or more obtained samples , To obtain a culture sample; after that, the obtained bacterial sample is mixed with the obtained culture sample, and the mixed obtained samples are grown with a gradual increase in the salt content and obtaining a mixed bacterial culture exhibiting salt tolerance properties and the simultaneous oxidation ability of sulfide minerals. 5. The method according to claim 4, characterized in that the obtained water samples are used as a reference for the preparation of artificial salt solutions, which, in turn, are used for the preparation of artificial used saline nutrient solutions. 6. The method according to claim 5, characterized in that the nutrient solution prepared from a water sample with the lowest concentration of chloride ions among the samples is used at the stage of mixing the uterine bacterial culture with the nutrient solution. 7. The method according to claim 6, characterized in that the lowest chloride concentration is approximately 13 g / L. 8. The method according to any one of claims 4 to 7, characterized in that the salt levels are increased at the stage of mixing the obtained bacterial sample with the obtained culture sample to levels of at least 40 g / L. 9. The method according to any one of claims 4 to 8, characterized in that the salt levels are increased at the stage of mixing the obtained bacterial sample with the obtained culture sample to levels of at least about 98 g / L. 10. The method according to any one of claims 4 to 9, characterized in that the salt levels are increased at the stage of mixing the obtained bacterial sample with the obtained culture sample for about eight months. 11. The method according to any one of claims 4 to 10, characterized in that the salt levels are determined by the levels of total dissolved solids (ΤΌ8), which are increased to at least about 80,000 ppm. 12. The method according to any one of claims 4 to 11, characterized in that the salt levels are determined by the levels of total dissolved solids (ΤΌ8), which are increased to at least about 200,000 ppm.