Method for Defining Element Content and/or Mineral Content

Abstract

The invention relates to a method for defining particle and/or mineral content in real time in a mineral separation process from finely divided particle material flowing either in solid or slurry-like form, so that from the particle material, there is extracted a representative sample, which sample is then subjected to grain size analysis, on the basis of which there is calculated the element and/or mineral content of the particle material.

Description

The present invention relates to a method for defining particle and/or mineral contents in real time in a mineral separation process from finely divided particle material flowing in either solid or slurry-like form.

In the concentration of minerals, the material obtained from a mine is first made finer by crushing and grinding, so that the valuable minerals contained in the ore are present as separate grains. In mineral separation processes, valuable minerals are recovered as concentrate for further refining. Typically the separation process is flotation, gravity separation, magnetic separation or electrostatic separation, or a combination of these.

In controlling separation processes, there is generally needed real-time measurement data as regards the element and/or mineral contents of the various material flows in the process. On the basis of concentrate content measurements, there is typically ensured that the process produces a product with an optimal quality with respect to further refining. On the basis of the contents of the separation process feed, it is possible to make preliminary adjustments, and on the basis of the measurements of waste flow contents, it is ensured that the process operates with an optimal yield. Separation often includes internal circulation and several different process steps, in which case the measuring of the various intermediate products is necessary for the process control.

Measurements of process material flows are known to be realized with online analyzers. The commonest method for analyzing element contents in mineral processes is X-Ray fluorescence. From the publication FI 51872, there is known a device for analyzing moving solid or pulverous material according to the X-Ray fluorescence principle. When applying said principle there are, however, remarkable restrictions caused by the method. In practice, with wet processes, a measurement carried out directly from the mineral slurry is with the required level of precision possible for certain elements only. The measurement of lighter elements is successful only with complicated sample processing methods that are both sensitive to interference and expensive to realize, in which methods the slurry sample is typically dried, ground finer and briquetted for the analysis. Respectively, in dry mineral processes, X-Ray fluorescence in practice works reliably with directly processed material only with elements heavier than silicon.

With respect to the controlling of separation processes, it often is important to measure the contents of light-weight elements as well. For example the contents of magnesium, silicon, phosphorus and sulfur are important indicators of impurities in the concentrates. From the point of view of process control, in certain separation processes it would also be important to measure mineral contents instead of element contents; for instance in the concentration of serpentinized nickel ores, it is essential for the process control to know, in addition to the magnesium content of the concentrate, whether the magnesium contained in the concentrate is obtained from soapstone or other serpentinite minerals.

In the online measurement of the contents of light-weight elements and minerals, it is known to apply for example Prompt Gamma Neutron Activation Analysis (PGNAA). In that case the measurement is carried out directly from slurry or dry matter. Accuracy often remains modest, or the duration of the measurement becomes immoderately long. In order to get sufficient gammma pulses from the sample, the measurement must be applied to a large sample volume, but the maintenance of said large volume in suspension makes the slurry measurement more difficult. Owing to radiation safety standards, the equipment becomes expensive and difficult to maintain and keep up.

In addition, for example X-Ray Diffraction (XRD) is known to be applied in the online measurement of element and mineral contents; in this case the analysis can be made directly from the slurry or dry matter. Among other applications, let us point out content measurement methods based on optical spectroscopy and nuclear magnetic resonance, which methods are characterized by high expenses, sample match problems, slowness and poor analytic accuracy of the measurement as well as problems connected to repeatability.

The object of the present invention is to eliminate drawbacks of the prior art and to realize an improved method for defining particle and/or mineral contents in real time from finely divided particle material flowing either in solid or slurry-like form, so that for defining the particle and/or mineral content, there is utilized the grain size distribution obtained from the particle material through grain size analysis. The essential novel features of the invention are apparent from the appended claims.

The method according to the invention has several advantages. The invention relates to a method for defining particle and/or mineral contents in real time in a mineral separation process from finely divided particle material, flowing either in solid or slurry-like form, so that from the particle material, there is taken a representative sample, which sample is subjected to grain size analysis, by means of which there is calculated the element and/or mineral content of the particle material. Further, according to a preferred embodiment of the invention, on the basis of grain size analysis, there is defined the grain size distribution, where the value of the cumulative grain size distribution is described as a function of the grain size; on the basis of this, the element and/or mineral content is mathematically calculated by utilizing-constants describing the properties of said element or mineral, defined by calibration. The information obtained from grain size distribution can be used for defining element and/or mineral content from the process feed, product or side product in a mineral separation process, and this data can be utilized in the process control.

According to an embodiment of the invention, grain size distribution is defined by methods based on X-Ray diffraction. According to another embodiment of the invention, grain size distribution is defined by a method based on ultrasonic absorption. According to another embodiment of the invention, grain size distribution is defined by a method based on optical image analysis. According to the invention, on the basis of defining in real time the particle and/or mineral content of finely divided particle material flowing in solid or slurry-like form, a mineral separation process is controlled for producing an optimal feed, product or side product. According to an embodiment of the invention, the mineral separation process is flotation. According to another embodiment of the invention, the separation process is gravity separation. According to yet an embodiment of the invention, the separation process is magnetic separation. According to an embodiment of the invention, the separation process is electrostatic separation. According to an embodiment of the invention, the separation process is classification.

The invention is described in more detail with reference to the accompanying drawings, where

FIG. 1 illustrates the invention by way of a process diagram; and

FIGS. 2 a, 2b and 2c illustrate an example according to the invention.

FIG. 1 illustrates a method according to the invention by way of a process diagram. From the feed, product or waste of a mineral separation process, there is extracted a representative sample in a known way, for example by extracting a sample in two steps from a flowing slurry flow. On the basis of the sample, there is made a grain size analysis describing the grain size of the particles contained in the particle material flowing in the process. The sample can be extracted at desired intervals while the process is going on, either from the feed, product or waste. Data concerning a certain content for the needs of process control is available in real time, i.e. nearly immediately, with allowance for delay times in the calculation. The obtained samples are processed to get a grain size distribution by a method based for instance on ultrasonic absorption, laser diffraction or optical image analysis. On the basis of the grain size analysis, there is formed the grain size distribution, i.e. the value of the cumulative grain size distribution as a function of the grain size. From the grain size distribution, there is mathematically calculated the content of a desired element and/or mineral by means of a calibration model, which calibration model describes the dependence between the element and/or mineral content and grain size distribution. In the calculation of the content, there can generally be used any mathematical function G(F(x)), where F(x) is the measured cumulative or differential grain size distribution, or a parameter calculated from the distribution; the shape of the function G can be defined by calibration, by applying multivariate statistical methods. Generally a calibration model is formed as data based, by extracting from the measured slurry a statistically representative number of single samples, by analyzing the element and/or mineral contents of the samples in a laboratory and by matching the grain size distributions obtained by statistical methods, for example by Multilinear Regression (MLR), Principal Components Regression (PCR) or Partial Least Squares regression (PLS) analysis, with the laboratory measurement results. The content to be analyzed can be either element or mineral content, depending on the process in question and the need for process control. Said defined content value is used in the process control by adjusting the process in the desired direction on the basis thereof, by adjusting for instance the contents of the feed, product or side product contents.

The results shown in FIGS. 2a, 2b and 2c illustrate the invention, together with the example described below. The example refers to the concentration of sedimentary phosphate ore, in which case the applied separation process is gravity separation and classification carried out in cyclones. The task is to recover apatite minerals from the ore, which apatite minerals are in the separation process feed clearly coarser than silicate minerals. In FIGS. 2a, 2b and 2c, the curve describes the cumulative grain size distribution, which is formed from the grain size analysis of the process feed, concentrate and waste. FIG. 2a illustrates the grain size distribution of the process feed, measured by an online grain size analyzer based on laser diffraction. FIG. 2b illustrates the grain size distribution of the process concentrate, and FIG. 2c illustrates the grain size distribution of the process waste. On the vertical axis in the Figures, there is illustrated the cumulative grain size quantity in percentages (% V), and on the horizontal axis, there is illustrated the diameter of a solid particle in micrometers (D μm). In the feed, nearly 100% of the apatite is over 50 micrometers in size. As regards the silicate gangue, it is again clearly finer, so that it is distinguished in the cumulative grain size distribution as a separate step in FIG. 2a. After the separation process, the concentrate (FIG. 2b) mainly consists of coarse apatite, whereas the waste (FIG. 2c) consists nearly exclusively of fine silicates. In this exemplary case, the described method proceeds as follows. When the value of the cumulative grain size distribution is obtained from the online grain size measurement as a function of the grain size, F(x), for example phosphate content is calculated therefrom according to the formula % P₂O₅=a*F(50 μm)+b, where a and b are numerical constants. The defining of the value F(50 μm) is illustrated in FIG. 2a. The values of the constants a and b are defined by calibration from known samples, by matching the values of the grain size distribution F(50 μm) of samples with a known P₂O₅ content statistically, by regression analysis, with % P₂O₅ contents. Content measurement is utilized so that the control variables of cyclonization (the number of used cyclones, their feed flow, solid content in feed or feed pressure) are adjusted in order to get the P₂O₅ content in the concentrate on the required level.

For a man skilled in the art, it is obvious that the various different embodiments of the invention are not restricted to the above described examples, but may vary within the scope of the accompanying claims.

Claims

1-11. (canceled)

12. A method for defining the whole particle and/or mineral content and receiving the content data in real time in a mineral separation process from finely divided particle material flowing either in solid or slurry-like form, wherein from the particle material, there is extracted a representative sample in real time at desired intervals while the process is going on, which sample is then subjected to grain size analysis in real time with repeatability, on the basis of which there is calculated the element and/or mineral content of the particle material and which data is available in real time.

13. A method according to claim 12, wherein from the grain size analysis, there is defined the grain size distribution, where the value of the cumulative grain size distribution is described as a function of the grain size, and the element and/or mineral content is calculated mathematically from said value by using constants, defined by calibration, describing the properties of the element or mineral in question.

14. A method according to claim 13, wherein the grain size distribution is defined by methods based on laser diffraction.

15. A method according to claim 13, wherein the grain size distribution is defined by a method based on ultrasonic absorption.

16. A method according to claim 13, wherein the grain size distribution is defined by a method based on optical image analysis.

17. A method according to claim 12, wherein on the basis of defining in real time the particle and/or mineral content of finely divided particle material flowing in solid or slurry-like form, a mineral separation process is controlled for obtaining an optimal feed, product or side product.

18. A method according to claim 12, wherein the applied mineral separation process is flotation.

19. A method according to claim 12, wherein the applied separation process is gravity separation.

20. A method according to claim 12, wherein the applied separation process is magnetic separation.

21. A method according to claim 12, wherein the applied separation process is electrostatic separation.

22. A method according to claim 12, wherein the applied separation process is classification.