EP2537590A1 - Method for recovering non-magnetic ores from a suspension-like mass flow containing non-magnetic ore particles - Google Patents

Abstract

The method involves forming a separator concentrate flow containing ore particle-magnetic particle agglomerates (A) and a separator residual flow containing remaining constituents of a mass flow. Ore particles (E) are separated from the particle-magnetic particle agglomerates contained in the separator concentrate flow. Information (I) indicating a measurement of the content of ore particles or magnetic particles (M) in the separator feed flow and/or the separator concentrate flow and/or a separator residual flow is determined for determining an efficiency of a process step. An independent claim is also included for a device for performing a method for obtaining non-magnetic ores from a suspension-like mass flow containing non-magnetic ore particles.

Description

• Vermischen des Massestroms mit Magnetpartikeln in wenigstens einer Mischeinrichtung unter Ausbildung von Erzpartikel-Magnetpartikel-Agglomeraten,
• Zuführen des Massestroms als Separatorzustrom in wenigstens einen magnetischen Separator zur Abtrennung der Erzpartikel-Magnetpartikel-Agglomerate aus dem Separatorzustrom,
• Bilden eines Erzpartikel-Magnetpartikel-Agglomerate enthaltenden Separatorkonzentratstroms und eines die übrigen Bestandteile des Massestroms enthaltenden Separatorreststroms,
• Abtrennen der Erzpartikel aus den in dem Separatorkonzentratstrom enthaltenen Erzpartikel-Magnetpartikel-Agglomeraten.

The invention relates to a method for obtaining non-magnetic ores from a suspension-like mass flow comprising non-magnetic ore particles, comprising the steps:

• Mixing the mass flow with magnetic particles in at least one mixing device to form ore particle magnetic particle agglomerates,
• Supplying the mass flow as a separator feed into at least one magnetic separator for separating the ore particle magnetic particle agglomerates from the separator feed,
• Forming a separator concentrate stream containing ore-particle magnetic particle agglomerates and a separator remainder stream containing the remaining constituents of the mass stream,
• Separating the ore particles from the ore particle magnetic particle agglomerates contained in the separator concentrate stream.

The use of flotation cells for the extraction of ore from ore-bearing bulk material is well known. In this case, a flotation cell or a flotation reactor is a mass flow in the form of an ore-containing pulp, i. essentially a suspension of water, ground rock (gangue) and ground ore fed.

In the context of what are known as magnetic flotation processes, the mass flow containing the pulp is charged with magnetic particles, which include, for example, magnetic particles in the form of magnetite, to form so-called ore particle magnetic particle agglomerates (so-called "load process"). To form the ore particle magnetic particle agglomerates is usually a prior hydrophobation of both the ore particles as well as the magnetic particles required. The formation of the orbital magnetic particle agglomerates produced essentially by hydrophobic interactions or forces of attraction takes place by mixing the starting materials in a mixing device taking into account certain mixing parameters, such as shear forces, time, temperature, etc.

The mass flow containing the ore particle magnetic particle agglomerates is subsequently supplied as so-called separator flow to a (first) separation device in the form of a magnetic separator. The magnetic separator serves to separate the ore particle-magnetic particle agglomerates from the bulk stream or pulp, i. the magnetic ore particle magnetic particle agglomerates are discharged from the pulp and transferred to a so-called separator concentrate stream which essentially contains the ore particle-magnetic particle agglomerates, minor amounts of gait and water. The remaining constituents or residues (so-called tailing) are fed into what is known as a separator residual stream.

Subsequently, the ore particle magnetic particle agglomerates are incorporated into their constituents, i. Ore particles and magnetic particles, split, so that they are present in the form of a mixture unbound or separately next to each other (so-called "un-load" process). Typically, the ore particle-magnetic particle agglomerates are separated by means of a further or second separation device via chemical processes through the use of appropriate chemicals such as solvents or the like.

The separation of the substantially isolated magnetic particles from the ore particles and the other constituents is then equally within the "unlo-ad" process via a further or third separation device again typically in the form of or comprising a magnetic separator in which the magnetic particles magnetic be separated. This is followed by a separation into a first magnetic particle-containing mass flow and a second ore particles containing mass flow, which are present separately and basically or ideally only the respective pure substance, ie either pure magnetic particles or pure ore particles containing.

A generic method is for example off EP 2 090 367 A1 which relates to a process for the continuous recovery of non-magnetic ores from non-magnetic ore particles having pulp. Magnetic or magnetizable magnetic particles, which form ore magnetic particle agglomerates with the non-magnetic ore particles, are fed to a pulp flowing continuously through a reactor. The ore magnetic particle agglomerates are moved by means of a magnetic field into an accumulation region of the reactor and removed from the accumulation region of the reactor.

In the known methods, it is regularly problematic that the separation of the corresponding ore particle magnetic particle agglomerates from the Separatorkonzentratstrom can not be realized with sufficient efficiency. Separation of all ore particulate magnetic particle agglomerates from the separator concentrate stream is usually not possible, i.e., some unidentified residue of ore particle magnetic particle agglomerates remains in the separator concentrate stream. This is primarily due to statistical reasons, according to which a certain proportion of ore particle magnetic particle agglomerates can not always be separated from the separator concentrate stream and secondly by the efficiency of the magnetic separator used to separate the ore particle magnetic particle agglomerates from the separator stream (US Pat. first separator).

Accordingly, based on the overall process, both the ore particles and the magnetic particles suffer from certain losses, as both the non-agglomerated ore particles or magnetic particles as well as not separated from the Separatorzustrom ore particles magnetic particle agglomerates of another use are not accessible or only with considerable effort. There is no monitoring of the process of formation of the ore particle magnetic particle agglomerates nor monitoring of the process of separation of the ore particle magnetic particle agglomerates from the separator feed.

The invention is therefore based on the problem of specifying an improved method for obtaining non-magnetic ores, in particular with regard to monitoring the process yield of the "load" process.

The problem is solved according to the invention by a method of the type mentioned above, which is characterized in that at least one information indicating a measure of the proportion of ore particles or magnetic particles in the Separatorzustrom and / or the Separatorkonzentratstrom and / or the Separatorreststrom information is determined.

The inventive method provides to determine the proportion of ore particles or magnetic particles or the ore particle magnetic particle agglomerates qualitatively or quantitatively. This is done on the basis of at least one information indicating the proportion of ore particles or magnetic particles in the Separatorzustrom and / or the Separatorkonzentratstrom and / or the Separatorreststrom information.

The information makes it possible to draw conclusions about the efficiency or process yield, in particular of the "load" process and possibly also on the separation of the ore particle magnetic particle agglomerates following, in particular the separation of the ore particles from the ore particle magnetic particle agglomerates process steps of the invention To start proceedings.

Accordingly, the efficiency or yield of the process step of forming the ore particle magnetic particle agglomerates and / or the process step of separating the ore particle magnetic particle agglomerates from the Separatorzustrom first qualitatively or quantitatively described. Thus, direct or indirect knowledge about the efficiencies of the corresponding process steps can be obtained.

The determination of the at least one information indicating a measure of the proportion of ore particles or magnetic particles in the Separatorzustrom and / or the Separatorkonzentratstrom and / or the Separatorreststrom information is preferably carried out by X-ray analysis method, in particular X-ray fluorescence analysis (XRF) or X-ray diffractometry (XRD). Of course, other suitable methods for determining the information are conceivable.

Magnetic particles in the sense of the invention are to be understood as meaning all magnetic or magnetizable particles. By way of example only, ferrimagnetic particles such as magnetite (Fe ₃ O ₄ ) are mentioned.

As ore particles in the sense of the invention are all non-magnetic, ie neither originally or in relation to the magnetic particles only weak magnetic still magnetizable or in relation to the magnetic particles only weakly magnetizable ore particles to understand. For example, only copper ores such as chalcocin (Cu ₂ S) are called.

The formation of ore particle magnetic particle agglomerates, which comprise at least one ore particle and at least one magnetic particle, carried out in the context of the method according to the invention takes place via at least one suitable mixing device. The subsequent deposition of the ore particle magnetic particle agglomerates from the Separatorzustrom via a magnetic separator, which optionally comprises a plurality of magnetic devices. The separation of the ore particles from the ore particle magnetic particle agglomerates via suitable separation devices.

The separation of the ore particles from the deposited ore particle magnetic particle agglomerates provided by the process of the invention may be accomplished by a step of feeding the ore particle magnetic particle agglomerates into a separation apparatus in which the ore particle magnetic particle agglomerates into a mixture of separately present ore particles and magnetic particles, and a step of feeding the mixture into a separation device in which the magnetic particles are magnetically separated from the mixture via a magnetic device associated with the separation device to form a first magnetic particle containing mass flow and a second mass containing second ore particles.

Thus, the magnetic separator for separating the ore particle magnetic particle agglomerates from the Separatorzustrom as a first separation device, the separation device for separating the separated from the Separatorkonzentratstrom ore particles magnetic particle agglomerates in the mixture of separately coexistent ore particles and magnetic particles as a second separation device and the separation device for separating the magnetic particles from the mixture may be referred to as a third separating device.

All separation devices may have one or more associated or associated separation regions, separation chambers, separation devices or the like.

The determination of the information can be done, for example, from the residues remaining after separation of the ore particle magnetic particle agglomerates from the separator concentrate stream, ie from the separator residual stream. This is in particular a qualitative consideration of the process yield of "load" process possible. Certain levels of ore particles and / or magnetic particles in the separator tail stream (so-called tailing) indicate that the process step of the formation of the ore particle magnetic particle agglomerates should be optimized, since in the residues still a certain number of unbound, ie not to ore particles Magnetic particle agglomerates agglomerated ore particles respectively magnetic particles is present.

In particular, knowledge about the proportion of ore particles contained in the residues can be used early on conclusions on the efficiency or yield, in particular the "load" process, i. essentially the content of ore particles bound in the ore particle magnetic particle agglomerates.

However, certain levels of ore particle magnetic particle agglomerates in the separator residual stream indicate that the process step of separating the ore particle magnetic particle agglomerates from the separator feed should be optimized.

Thus, knowledge of the process efficiency, in particular of the "load" process, can already be obtained on the basis of the qualitative statement about possibly temporally changing contents of ore particles, magnetic particles or ore particle magnetic particle agglomerates in the separator residual stream To increase the proportion of ore particles bound in the ore particle magnetic particle agglomerates that is relevant for the efficiency of the overall process.

Preferably, at least one information indicating a measure of the proportion of ore particles and magnetic particles in the Separatorzustrom and / or the Separatorkonzentratstrom and / or the Separatorreststrom information is determined. That is, it is possible to know about both the proportion of ore particles and the proportion of magnetic particles in the respective streams to obtain, so that a comprehensive picture of the efficiency of the respective process steps of the method according to the invention both in terms of the respective proportions of ore particles and magnetic particles is feasible.

It is also conceivable that the information indicating the measure of the proportion of ore particles and / or magnetic particles is determined for at least two of the streams, wherein based on the information, in particular after a comparison of the relevant currents, the measure of the proportion of ore particles and / or magnetic particle indicating information, at least one operating parameter of the mixing device and / or the magnetic separator is set. Accordingly, for example, the content of ore particles and / or magnetic particles in the Separatorzustrom be determined and compared with the corresponding contents in the Separatorkonzentratstrom. With ideal attachment of the ore particles to the magnetic particles, the separator concentrate stream contains no unbound, i. isolated ore particles or magnetic particles. The same applies of course to the Separatorreststrom.

If the information for the Separatorzustrom and the Separatorreststrom is determined, it can also be adjusted based on the comparison of the separatorzustromseitigen information and the separatorreststromseitigen information at least one operating parameters of the mixing device and / or the magnetic separator.

Suitably, the respective contents of ore particles or magnetic particles for all three streams, i. the Separatorzustrom, the Separatorkonzentratstrom and the Separatorreststrom, determined via appropriate information concerning the respective streams and compared with each other.

In principle, high contents of unbound ore particles or magnetic particles in the separator concentrate stream and the separator residual stream in each case give indications of an insufficient Formation of corresponding ore particle magnetic particle agglomerates, ie, the mixing process of the ore particles contained in the original mass flow with the magnetic particles is to be improved. High levels of ore particle magnetic particle agglomerates in the separator residual stream also provide knowledge of the process efficiency, particularly of the process steps of formation or separation of the ore particle magnetic particle agglomerates.

Also, if a determination of the original mass flow information, which is a measure of the fraction of ore particles in the deposited ore particle magnetic particle agglomerates, is provided. the mass flow to be supplied to the mixing device can be determined quantitatively from a comparison of the proportion of ore particles contained in the mass flow and the proportion of ore particles contained in the separated ore particle magnetic particle agglomerates in the separated ore particle magnetic particle agglomerates to be possible. Here, the content of ore particles in the mass flow is known even before the formation of ore particle magnetic particle agglomerates, so that the efficiency of the "load" process from the difference of the initial content of ore particles in the mass flow and the content of ore particles in the results in separated ore particle magnetic particle agglomerates containing Separatorkonzentratstrom. A corresponding consideration also applies to the conventionally known proportion of added magnetic particles.

Of course, the content of ore particles or magnetic particles of the mass flow can also be compared with the corresponding contents of ore particles or magnetic particles in Separatorzustrom what equally provides knowledge about the efficiency of the mixing process performed in the mixing device.

The setting of the respective operating parameters, in particular the mixing device and the magnetic separator is basically such that the proportion of ore particles and / or magnetic particles in the Separatorreststrom is reduced or minimized.

In general, the method according to the invention preferably provides the information indicative of the proportion of ore particles or magnetic particles in the respective streams not only as an indication of the efficiency of the corresponding process steps for forming the ore particle magnetic particle agglomerates or for separating the ore particle magnetic particles Agglomerates from the Separatorzustrom use, but this equally as a control signal for the adjustment or change of corresponding mixing devices or magnetic separators for separating the ore particles magnetic particle agglomerates from the Separatorzustrom to use.

In an expedient development of the invention, it is provided that the information is compared with at least one threshold value indicating a minimum or maximum concentration of ore particles in the separator concentrate stream and / or in the separator residual stream, wherein at least one operating parameter of the mixing device and / or the magnetic separator is set as a function of the comparison result becomes. By setting a threshold value, which of course also corresponding threshold ranges are understood, a particularly simple and fast quality monitoring in particular the "load" process can take place and therefore settings corresponding operating parameters of the mixing device (s) and / or the or the magnetic separators for the purpose of Process optimization are made.

If, for example, an exceeding of a threshold value, which threshold value may naturally also include corresponding tolerance ranges, is detected on ore particles in the separator concentrate stream or in the separator residual stream, ie the proportion of ore particles in the separator concentrate stream or in the separator stream Separator residual flow is increased above a predetermined or specifiable standard value, this also indicates that the proportion of ore particles in the separated ore particle magnetic particle agglomerates is too low. Accordingly, a corresponding adaptation of in particular at least one operating parameter of the mixing device used to form the ore particle magnetic particle agglomerates takes place, and consequently the process step involves the formation of the ore particle magnetic particle agglomerates. The same applies when detecting an exceeding of a threshold value of magnetic particles in Separatorreststrom.

Optionally, an excess of the proportion of ore particle magnetic particle agglomerates in Separatorreststrom be detected, which indicates that process technology should be intervened in the process step of separating the ore particle magnetic particle agglomerates from the Separatorzustrom. Consequently, at least one operating parameter required for the operation of the magnetic separator for separating off the ore particle magnetic particle agglomerates from the separator flow is hereby primarily adapted or optimized.

Preferably, the threshold value is formed in consideration of a degree of pulverization and / or digestion of the ore particles in the mass flow. Of course, other parameters, in particular the ore particles, can also be taken into account within the framework of the formation of the threshold value.

It is conceivable that, prior to the actual setting of the at least one operating parameter, a change in the information which is expected to be associated with it is simulated. A simulation, which typically takes place by means of suitable simulation algorithms, thus enables a forward-looking evaluation of the effects associated with the setting of the at least one operating parameter with regard to the information. If necessary, it is conceivable, temporally past settings of the respective operating parameters respectively to store the associated effects on the proportion of ore particles in the deposited ore particle magnetic particle agglomerates in a storage means and to take into account in the simulation. Such a largely automated, dynamic optimization of the contents of desired or unwanted particles in the respective streams can be realized.

In the following, various operating parameters required for the operation of corresponding mixing devices or magnetic separators are mentioned by way of example. The list is not exhaustive.

As an operating parameter for a corresponding mixing device, for example, the concentration of the magnetic particles, in particular the concentration of the magnetic particles relative to the ore particles, and / or the concentration and / or composition of a hydrophobizing the ore particles and / or the magnetic particles hydrophobicizing and / or the shear rate and / or the mixing time and / or the composition of the mass flow, in particular a water content of the mass flow, and / or the flow rate of the mass flow are used.

As operating parameters for a corresponding magnetic separator, for example, at least one magnetic parameter, in particular the field strength and / or a field gradient, and / or the mass flow through the magnetic separator fluid influencing means, in particular in the form of orifices and / or displacement bodies, and / or the Flow rate of the mass flow is used by the magnetic separator.

The adjustment of magnetic parameters is particularly useful when using a traveling magnetic field separator as a magnetic device correspondingly associated with the magnetic separator for separating the ore particle magnetic particle agglomerates from the separator feed. This also applies the setting of corresponding signal exciter forms, signal frequencies, signal phase positions of relative signal characteristics such as countercurrent, synchronization, velocity relative to the flow of Separatorzustroms or the pulp and other, the magnetic field influencing magnetic parameters.

All processes are determined by several communicating decentralized or a central control and / or regulating device, recorded and evaluated in particular via suitable computer-based evaluation algorithms and optionally deposited in a storage means.

The determination of a measure of the proportion of ore particles or magnetic particles in the respective streams indicating information can be continuous or discontinuous. In the case of continuous determination of the information, this information is constantly determined at all times, so that a complete image of the process control with regard to the yield, in particular of the "load" process, is given. In the case of a discontinuous determination of the information, these are determined at given or predefinable times, for example once a minute. Both variants allow a so-called in situ or online determination of the information. A discontinuous determination of the information also means sampling of ore particle magnetic particle agglomerates separated from the mass flow, which sample, separately from the method according to the invention, for example in a laboratory, is tested for its corresponding composition, i. in particular the proportion of ore particles.

Advantageously, the determination of the information is carried out continuously, wherein on the basis of the continuously determined information, a continuous control and / or regulation of the method is performed. Consequently, within the scope of the method according to the invention, a measure of the proportion of ore particles or magnetic particles in the respective streams can be determined continuously. The continuous identification of the corresponding, Information associated with the respective streams permits continuous or dynamic regulation or optimization of the process, so that the process control of changing process parameters, such as the composition of the mass flow, can be readjusted quickly, ie possibly even in real time.

It is also conceivable that at least a part of the Separatorreststroms the mass flow or the Separatorzustrom is supplied again. Thus, the further usable ore particles, magnetic particles or ore particle magnetic particle agglomerates contained in the Separatorreststrom are fed again to the mass flow or the Separatorzustrom. Thus, unbound present, the mass flow supplied ore particles or magnetic particles in the mixing device are again bonded to ore particle magnetic particle agglomerates respectively not transferred from the Separatorzustrom transferred to the Separatorkonzentratstrom Erzpartikel magnetic particle agglomerates again promoted by the magnetic separator and optionally separated. The process efficiency can be increased in such a way, as fundamentally reusable or reusable materials are not lost.

The Separatorzustrom can for example have a solids content of non-magnetic ore particles below 10%, in particular less than 10%, preferably between 1 and 10% nickel ore particles. The solids content of copper or molybdenum ore particles may be below 5%, preferably between 1 and 5%. The proportion of copper ore particles can be between 0.3 and 2.5%. The proportion of molybdenum ore particles may be between 0.025 and 0.1%. All salary information is purely exemplary nature. The operating parameters of the mixing device and / or of the magnetic separator are advantageously set such that the proportion of ore particles and / or magnetic particles in the separator residual stream is reduced, in particular minimized. This embodiment is then advantageously used when the mined ore is a first extraction step, often also Grobflotation called, goes through. At this stage, the maximum mass flow to be processed is present, which may be on the order of several thousand to 10,000 m ³ / h, since only the ore fraction present in the pulp is present in the pulp, and accordingly a comparatively large proportion of deaf rock , The goal here is to extract as much of the ore from the pulp as possible. The ore, which is not extracted from the pulp in this first extraction step, is usually lost and is discharged from the plant into a so-called Tailing Dam. If this first recovery step is sub-optimal with regard to the yield of the ore, this considerably reduces the economic efficiency of the entire process, since the missing yield in this process step can hardly be compensated in later process steps.

It is further conceivable that the Separatorzustrom has a solids content of more than 5%, in particular between 5 and 40%, wherein the operating parameters of the mixing device and / or the magnetic separator are adjusted such that the proportion of ore particles in the Separatorkonzentratstrom increased, in particular maximized , becomes. In this embodiment, the process is used for concentrate processing. A separator stream enriched with ore particle magnetic particle agglomerates is already fed to the magnetic separator to further increase the fraction of ore particle magnetic particle agglomerates by their magnetic separation by means of the magnetic separator in a separator concentrate stream. In general, a plurality of these steps is required in order to achieve a desired for further processing ore content in the concentrate stream.

In addition to the method according to the invention, the present invention also relates to an apparatus for carrying out the method described above. The device comprises at least one mixing device for mixing the mass flow with magnetic particles to form ore particle magnetic particle agglomerates, at least one feed device for feeding the mass flow as Separatorzustrom in at least one magnetic separator for separating the ore particle magnetic particle agglomerates from the mass flow, at least one separation device for separating the ore particles from the Separatorkonzentratstrom, at least one detection means for determining at least one a measure of the proportion of Ore particles and / or magnetic particles in the Separatorzustrom and / or the Separatorkonzentratstrom and / or the Separatorreststrom and at least one control and / or regulating device. The control and / or regulating device comprises at least one machine-readable program means, the program means being designed as a function of the determined information for controlling and / or regulating the mixing device and / or the magnetic separator and / or the separating device.

In addition, the present invention relates to a control and / or regulating device for a device as described above. The control and / or regulating device comprises at least one machine-readable program means, wherein the program means in dependence of a measure of the proportion of ore particles or magnetic particles in the Separatorzustrom and / or Separatorkonzentratstrom and / or Separatorreststrom determined information for controlling and / or regulating a mixing device and / or the magnetic separator and / or the separating device is formed.

Fig. 1

ein Blockschaubild des erfindungsgemäßen Verfahrens zur Gewinnung von nichtmagnetischen Erzen aus einer nichtmagnetische Erzpartikel sowie Magnetpartikel enthaltenden Suspension.

Further advantages, features and details of the invention will become apparent from the embodiments described below and from the drawing. Showing:

Fig. 1

a block diagram of the method according to the invention for the recovery of non-magnetic ores from a non-magnetic ore particles and suspension containing magnetic particles.

Fig. 1 shows a block diagram of the method according to the invention for the recovery of non-magnetic ores from a non-magnetic ore particles and magnetic particles containing suspension-like mass flow. It is preferably a continuous process.

In a first method step (see Box 1), in a device 13 for extracting non-magnetic ores from a non-magnetic ore particle E containing mass flow, which device 13 can be referred to as a magnetic flotation cell associated mixing device 14 is a mass flow in the form of a pulp P and Magnetic particles M supplied. The pulp P consists essentially of non-magnetic ore particles E, such as Cu ₂ S particles, the magnetic particles M are for example in the form of magnetite (Fe ₃ O ₄ ) before. If appropriate, the magnetic particles M may already be hydrophobized.

It is carried out with the addition of other additives such as in particular of water repellents H, such. Xanthat, which enable a hydrophobization of the magnetic particles M and / or the ore particles E, by means of the mixing device 14, a mixing process of the substances supplied to these.

In the second process step (see Box 2), the so-called "load" process takes place in which the hydrophobized magnetic particles M are deposited on the hydrophobized ore particles E or interact with them to form ore magnetic particle agglomerates A. The ore magnetic particle agglomerates A contained in the mass flow comprise at least one hydrophobized magnetic particle M and at least one hydrophobized ore particle E. The magnetic particles M are to be considered as carrier particles for the ore particles E.

Essential influencing factors for the formation of an efficient yield of ore particle magnetic particle agglomerates A are the mixing time, shear forces prevailing during the mixing process and, if appropriate, the freeness or the particle size or particle size distribution of the ore particles E contained in the mass flow.

For carrying out the third method step (compare box 4), the mass flow is supplied as separator flow (see arrow 11) to a magnetic separator 16, in particular by means of a feed device 15. In the third process step, magnetic separation of the ore particle-magnetic particle agglomerates A from the separator feed takes place, i. essentially of gait G. For this purpose, the magnetic separator 16, which may also be referred to as the first separating device, has at least one magnetic device (not shown). The magnetic particle particles magnetic particle agglomerates A, which are magnetic due to the magnetic particles M, accumulate in the region of the magnetic device and can thus largely be separated from the gait G, i. discharged from the Separatorzustrom and transferred to a Separatorkonzentratstrom (see arrow 12). Non-agglomerated ore particles E and magnetic particles M are removed as residues in a Separatorreststrom (so-called tailing) (see arrow 3).

In the subsequent fourth process step (see box 5), the concentrated ore particle magnetic particle agglomerates A contained in the separator concentrate stream are fed to a second separation device 17 in which the ore particle magnetic particle agglomerates A are mixed with separately present unbonded ore particles E and Magnetic particles M are separated (so-called "unload" process). The separation of the ore particle magnetic particle agglomerates A, for example, chemically, in particular via a change in the pH and / or an addition of chemical release agents T done. Also conceivable is the use of ultrasonic waves introduced by one of the second separating device 17 assigned to the ultrasonic device. Overall, here is a mixing process that causes a dehydrophobicization of the magnetic particles M and ore particles E by introducing shear forces and chemical substances in the form of, for example, based on surfactants release agent T, which decomposes the ore particles magnetic particle agglomerates A into their constituents. It is possible that in the second separating device 17, a certain proportion of gait G is still present, which could not be properly separated in the previous third step.

In the box labeled 6, the "unload" process is largely completed, i. there is a mixture of separately present unbound ore particles E and magnetic particles M. The isolated magnetic particles M are magnetically separated from the non-magnetic ore particles E via a third separating device 21 comprising a magnetic device, in particular a traveling-field magnetic separator, and converted into a mass flow MS1 containing a first magnetic particle M.

As can be seen, the first mass flow MS1 can be recycled, so that the magnetic particles M contained in it can be reused at the beginning of the process (see arrow 10). Accordingly, the overall process can be optimized in economic and environmental terms.

The ore particles E are converted into a mass stream MS2 containing a second ore particle E, which is subsequently dehydrated or dried (cf., box 7), so that dried ore particles E are largely present after dehydration or drying. The water W is discharged separately.

Ideally, the first mass flow MS1 contains exclusively magnetic particles M and the second mass flow MS2 exclusively ore particles E. However, this is difficult to realize in practice, so that there are certain losses of magnetic particles bound in the first mass flow MS1 and magnetic particles bound in the second mass flow MS2 M is coming.

Concerning the third method step of separating the ore particle magnetic particle agglomerates A from the Separatorzustrom, not 100% of the first separator in the form of the magnetic separator 16 supplied ore particle magnetic particle agglomerates A can be regularly separated, which is partly for reasons of statistics and second, from the efficiency of the magnetic separator 16, which is below one hundred percent.

However, the loss of ore particles E in the magnetic separation by means of the magnetic separator 16 in the context of the method according to the invention can be determined in order to estimate the efficiency and the yield of the "load" process and possibly also of the overall process and optionally to optimize.

The inventive method is characterized accordingly by the fact that at least one is a measure of the proportion of ore particles E or magnetic particles M in the Separatorzustrom and / or the Separatorkonzentratstrom and / or the Separatorreststrom indicating information I is determined.

The information I indicating a measure of the proportion of ore particles E or magnetic particles M, it being understood that corresponding information I can be determined both for the proportion of ore particles E and magnetic particles M, can thus be determined at different process steps of the method described above. Particularly suitable are at least indirectly associated with the "lo-ad" Prozz process steps of mixing the nonmagnetic ore particles E containing mass flow or the pulp P with the magnetic particles M in the mixing device 14, so that the information I from the Mixing device 14 and optionally the feed device 15 leaving Separatorzustrom (see arrow 11) is determined. It is also conceivable that information I from the separator concentrate stream containing the ore particle magnetic particle agglomerates A (see arrow 12) or the residues, that is, the tailing, Separatorreststrom containing (see arrow 3) to determine. In this way, a measure of the yield, in particular of the "load" process, is possible, and furthermore the process control of the continuously operating process according to the invention can be regulated.

In this case, the information I indicating the measure of the proportion of ore particles E and / or magnetic particles M is determined for preferably for all three streams, that is to say the separator flow, the separator concentrate flow and the separator residual flow, the information I relating to the respective flows being determined on the basis of a comparison. at least one operating parameter of the mixing device 14 and / or the magnetic separator 16 is set.

In particular, the comparison of the information I concerning the separator flow and the information I concerning the separator concentrate flow for the respective proportion of ore particles E allows a quantitative statement about the yield of the "load" process. That is, it can be quantitatively determined what proportion of ore particles E could be separated from the ore particle magnetic particle agglomerates A separated from the separator feed. In this way, overall relevant findings can be obtained for the process yield of the method according to the invention.

The same applies to the comparison of the information I concerning the separator flow and the information I regarding the separator residual flow to ore particle or magnetic particle contents. On the basis of this comparison as well, overall relevant qualitative or quantitative findings are obtained for the process yield of the method according to the invention.

The determination of the respective information I is preferably carried out continuously by means of X-ray fluorescence analysis methods, such as, for example, X-ray fluorescence analysis (XRF) or X-ray diffractometry analysis (XRD). On the basis of continuous determined information (s) I is carried out a continuous control and / or regulation of the process or individual process steps or operating or process parameters used in the process, for which examples are given below.

As mentioned, preferably at least one operating parameter of the mixing device 14 and / or of the magnetic separator 16 is adjusted on the basis of the determined respective information I or comparison results of specific information I. Optionally, of course, other devices used in the context of the method according to the invention, such as, in particular, further separating devices 17, 21 or the like, or their operating parameters, can be set or optimized as a function of the determined information (I).

Exemplary operating parameters for the mixing device 14 are the concentration of the magnetic particles M, in particular the concentration of the magnetic particles M relative to the ore particles E, and / or the concentration and / or composition of a water repellent H and / or hydrophobizing the ore particles E and / or the magnetic particles M the shear rate and / or the mixing time and / or the composition of the mass flow, in particular a water content of the mass flow, and / or the flow rate of the mass flow.

Exemplary operating parameters for the magnetic separator 16 are at least one magnetic parameter, in particular the field strength and / or a field gradient, and / or the mass flow through the magnetic separator 16 fluid influencing means, in particular in the form of diaphragms and / or displacement bodies, and / or the Flow rate of the mass flow through the magnetic separator 16.

In particular, all control and regulatory interventions in the inventive method under the premise of increasing the efficiency of the process, ie, for example, that the proportion of ore particle magnetic particle agglomerates A in the separator concentrate stream is increased or maximized or the proportion of ore particles E and / or magnetic particles M and / or ore particle magnetic particle agglomerates A in the separator residual stream is reduced or is minimized.

In this case, the information I can be compared with at least one threshold value indicating a minimum or maximum concentration of ore particles E in the separator concentrate stream and / or in the separator residual stream, wherein at least one operating parameter of the mixing device 14 and / or of the magnetic separator 16 is set as a function of the comparison result. In the present case, it is thus possible to provide various threshold values concerning the proportion of ore particles E, magnetic particles M and / or ore particle magnetic particle agglomerates A in the respective streams. By comparing the determined information I with the respective threshold values, the process yield can be checked in a simple manner. The threshold value (s), of which, of course, corresponding threshold ranges, are advantageously formed taking into account a degree of pulverization and / or digestion of the ore particles E in the mass flow originally used.

Overall, a dynamization of the method is possible with the principle according to the invention, since depending on the information I always an individual and needs-based adaptation of the corresponding operating parameters used in the context of the inventive method, in particular with respect to the "lo-ad" process, mixing device (s) 14 respectively separating device (s) 16, 17, 21, d. H. in particular of the magnetic separator 16 for separating the ore particle magnetic particle agglomerates A from the Separatorzustrom is possible.

Particular embodiments of the method according to the invention provide that before the actual setting of at least an operating parameter is simulated a change of the information I which is expected to be associated therewith.

Furthermore, it is conceivable that the separator residual stream (see arrow 3) is again supplied to the original mass flow or to the separator feed after separation of the ore particle magnetic particle agglomerates A. Corresponding ore particles E and / or magnetic particles M contained in the separator residual stream may if appropriate be converted into corresponding ore particle magnetic particle agglomerates A or, in relation to the recycled ore magnetic particle agglomerates A, be separated from the separator stream. The reusable particles present in the Separatorreststrom are thus not lost, which is beneficial to the efficiency of the method according to the invention.

The Separatorzustrom may for example have a solids content of non-magnetic ore particles E below 10%, in particular less than 10%, preferably between 1 and 10% nickel ore particles. The solids content of copper or molybdenum ore particles may be below 5%, preferably between 1 and 5%. The proportion of copper ore particles can be between 0.3 and 2.5%. The proportion of molybdenum ore particles may be between 0.025 and 0.1%. All salary information is purely exemplary nature. The operating parameters of the mixing device 14 and / or of the magnetic separator 16 are advantageously adjusted in such a way that the proportion of ore particles E and / or magnetic particles M in the separator residual stream is reduced, in particular minimized.

It is further conceivable that the Separatorzustrom has a solids content of more than 5%, in particular between 5 and 40%, wherein the operating parameters of the mixing device 14 and / or the magnetic separator 16 are adjusted such that the proportion of ore particles E increases in Separatorkonzentratstrom , in particular, is maximized. The boxes 8, 9 shown in dashed lines indicate that, if necessary, a renewed mixing process (see box 8) may be required in order to recycle residues, ie non-separated or agglomerated particles of ore particles A, after the separation carried out in the fifth method step mix thoroughly. In this case, an addition of a more highly concentrated release agent T may be expedient. Accordingly, a new dewatering or drying takes place (see Box 9).

In its minimal configuration, the device 13 used for carrying out the method according to the invention has at least one mixing device 14 for mixing the mass flow with optionally pre-hydrophobized magnetic particles M to form ore particle magnetic particle agglomerates A, at least one feed device 15 for feeding the mass flow as Separatorzustrom in at least one Magnetic separator 16 for separating the ore particle magnetic particle agglomerates A from the Separatorzustrom, at least one separator 17 for separating the ore particles E from the Separatorkonzentratstrom, at least one detection means 18 for determining at least one measure of the proportion of ore particles E or magnetic particles M in the Separatorzustrom and / or Separatorkonzentratstrom and / or Separatorreststrom indicating information I and at least one control and / or regulating device 19. The control and / or regulating device 19 comprises at least one machine-readable program means 20, the program means 20 depending on the determined information I for controlling and / or regulating the mixing device 14 and / or the magnetic separator 16 and / or the separation device (s) 17th , 21 is formed.

Claims (17)

A process for recovering non-magnetic ores from a suspension-like mass flow containing non-magnetic ore particles, comprising the steps of: Mixing the mass flow with magnetic particles in at least one mixing device to form ore particle magnetic particle agglomerates, Feeding the mass flow as separator flow into at least one magnetic separator for separating the ore particle magnetic particle agglomerates from the mass flow, Forming a separator concentrate stream containing orbital magnetic particle agglomerates and a separator residual stream containing the remaining constituents of the mass flow, Separating the ore particles from the ore particle magnetic particle agglomerates contained in the separator concentrate stream,
characterized in that at least one indicative of the proportion of ore particles or magnetic particles in the Separatorzustrom and / or the Separatorkonzentratstrom and / or the Separatorreststrom information is determined. Method according to claim 1,
characterized in that at least one of a measure of the proportion of ore particles and magnetic particles in the Separatorzustrom and / or the Separatorkonzentratstrom and / or the Separatorreststrom indicating information is determined. Method according to claim 1 or 2,
characterized in that the information indicative of the amount of ore particles and / or magnetic particles is determined for at least two of the streams, wherein based on the information, in particular after a comparison of the respective streams, the measure of the proportion of ore particles and / or magnetic particles indicating information, at least one operating parameter of the mixing device and / or the magnetic separator is set. Method according to claim 3,
characterized in that the information for the Separatorzustrom and the Separatorreststrom is determined, wherein based on the comparison of the separatorzustromseitigen information and the separatorreststromseitigen information at least one operating parameter of the mixing device and / or the magnetic separator is set. Method according to one of the preceding claims,
characterized in that the information is compared with at least one of a minimum or maximum concentration of ore particles in Separatorkonzentratstrom and / or Separatorreststrom specifying threshold, wherein at least one operating parameter of the mixing device and / or the magnetic separator is set depending on the comparison result. Method according to claim 5,
characterized in that the threshold value is formed in consideration of a degree of pulverization and / or digestion of the ore particles in the mass flow. Method according to one of claims 3 to 6,
characterized in that prior to the actual setting of the at least one operating parameter, a change in the information which is expected to be associated with it is simulated. Method according to one of claims 3 to 7,
characterized in that the operating parameters for the mixing device, the concentration of the magnetic particles, in particular the concentration of the magnetic particles relative to the ore particles, and / or the concentration and / or composition of a hydrophobing agent hydrophobizing the ore particles and / or the shear rate and / or the mixing time and / or the composition of the mass flow, in particular a water content of the mass flow, and / or the flow rate of the mass flow is used. Method according to one of claims 3 to 8,
characterized in that as operating parameters for the magnetic separator at least one magnetic parameter, in particular the field strength and / or a field gradient, and / or the mass flow through the magnetic separator fluid influencing means, in particular in the form of orifices and / or displacement bodies, and / or the flow rate of the mass flow through the magnetic separator is used. Method according to one of the preceding claims,
characterized in that the determination of the information takes place continuously or discontinuously. Method according to claim 10,
characterized in that the determination of the information takes place continuously, wherein based on the continuously determined information, a continuous control and / or regulation of the method is performed. Method according to one of the preceding claims,
characterized in that the determination of the information by means of X-ray analysis method, in particular X-ray fluorescence analysis or X-ray diffraction analysis, takes place. Method according to one of the preceding claims,
characterized in that at least a portion of the separator residual stream is recycled to the mass flow or the separator feed. Method according to one of claims 3 to 13,
characterized in that the Separatorzustrom a solids content of non-magnetic ore particles below 10%, in particular less than 10% for nickel ore particles, in particular below 5% for copper or Molybdänerzpartikel, in particular 0.3 to 2.5% for Kupfererzpartikel, in particular 0.025 to 0, 1% for Molybdänerzpartikel, wherein the operating parameters of the mixing device and / or the magnetic separator are set such that the proportion of ores and / or magnetic particles in Separatorreststrom reduced, in particular minimized, is. Method according to one of claims 3 to 13,
characterized in that the Separatorzustrom a solids content of non-magnetic ores of more than 5%, in particular between 5 to 40%, wherein the operating parameters of the mixing device and / or the magnetic separator are adjusted such that the proportion of ore particles increases in the Separatorkonzentratstrom, in particular, is maximized. Apparatus (13) for carrying out the method according to one of the preceding claims, comprising at least one mixing device (14) for mixing the mass flow with magnetic particles (M) to form ore particle magnetic particle agglomerates (A), at least one feed device (15) for feeding the mass flow as Separatorzustrom (11) in at least one magnetic separator (16) for separating the ore particle magnetic particle agglomerates (A) from the Separatorzustrom (11), at least one separation device (17, 21) for separating the ore particles (E) from the Separate concentrate stream (12), at least one detection device (18) for determining at least one information (I) indicative of the proportion of ore particles (E) or magnetic particles (M) in the separator flow (11) and / or separator concentrate stream (12) and / or separator waste stream (3), and at least one control and / or regulating device (19), which control and / or regulating device (19) comprises at least one machine-readable program means (20), the program means (20) depending on the determined information (I) for controlling and / or regulating at least the mixing device (14) and / or the magnetic separator (16) and / or the separating device (17, 21) is formed. Control and / or regulating device (19) for a device according to claim 16, which control and / or regulating device (19) comprises at least one machine-readable program means (20), wherein the program means (20) as a function of a measure of the proportion of Ore particles (E) or magnetic particles (M) in a Separatorzustrom (11) and / or Separatorkonzentratstrom (12) and / or Separatorreststrom (3) indicative, determined information (I) for controlling and / or regulating at least the mixing device (14) and / or the magnetic separator (16) and / or the separating device (17, 21) is formed.

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