EP2445642A1 - Pneumatic flotation machine and flotation method - Google Patents

Abstract

The invention relates to a pneumatic flotation machine (100), comprising a housing (1) with a flotation chamber (3), at least one nozzle arrangement (4) for feeding gas and a suspension into the flotation chamber as well as at least one gassing arrangement (5) for feeding further gas into the flotation chamber (3), which arrangement is disposed within the flotation chamber (3) and below the at least one nozzle arrangement (4), wherein there is furthermore at least one adjusting device (9) for changing a position of the at least one gassing arrangement (5) in the flotation chamber (3). The invention also relates to a flotation method using a flotation machine of this type.

Description

description

Pneumatic flotation machine and flotation process

The invention relates to a pneumatic flotation machine, comprising a housing with a flotation chamber, at least one nozzle arrangement for supplying gas and a suspension in the flotation and at least one gassing arrangement for further supply of gas into the Flotationskam- mer, in the flotation below the at least one Nozzle arrangement is arranged, and at least one adjusting device for changing a position of the at least one gassing arrangement in the flotation chamber. The invention further relates to a process for the flotation of particles from a suspension to form a foam product by means of such a pneumatic flotation machine.

Flotation is a physical separation process for the separation of fine-grained mixtures of solids, such as

Ores and gait, in an aqueous slurry by means of air bubbles due to a different surface wettability of the particles contained in the suspension. It is used for the treatment of soil values and in the processing of preferably mineral substances with a low to medium content of a useful component or of a valuable substance, for example in the form of non-ferrous metals, iron, metals of rare earths and / or precious metals and non-ferrous metals. see mineral resources.

Pneumatic flotation machines are known. WO 2006/069995 A1 describes a flotation machine with a housing, which comprises a flotation chamber, with at least one nozzle arrangement, here referred to as ejectors, furthermore with at least one gassing device, when using air aeration devices or aerators. called, as well as a collecting container for a formed during the flotation foam product.

DE 33 12 070 A1 describes a flotation cell in which a fumigation of the turbid takes place by means of gassing devices outside the pulp, wherein the inflow direction of the fumigated pulp in the vertical and / or lateral direction is changeable.

German Patent No. 726,709 describes a device for the pneumatic foam flotation of ores, coal and other minerals, in which height-adjustable air supply pipes are present.

In the case of pneumatic flotation, a suspension of water and fine-grained reagents is generally used

Solid introduced via at least one nozzle assembly in a flotation chamber. The purpose of the reagents is to ensure that, in particular, the valuable particles, which are preferably to be separated off, are rendered hydrophobic in the suspension. Simultaneously with the suspension, the at least one nozzle arrangement is supplied with gas, in particular with air, which comes into contact with the hydrophobic particles in the suspension. The hydrophobic particles adhere to forming gas bubbles, so that the gas bubble structures, also called aeroflocs, float and form the foam product on the surface of the suspension. The foam product is discharged into a collecting container and usually thickened.

It has been shown that the quality of the foam product or the separation efficiency of the pneumatic flotation process depends inter alia on the probability of collision between a hydrophobic particle and a gas bubble. The higher the probability of collision, the greater the number of hydrophobic particles that adhere to a gas bubble, rise to the surface and together with the particles form the foam product. The collision probability is influenced inter alia by the position of the at least one gassing device in the flotation chamber. The optimal position has hitherto been selected depending on the properties of the suspension used, such as a volume concentration of solids, an ore content, a mineral composition, a particle size distribution, etc., and the flow conditions in the flotation chamber and over the service life of the flotation machine - to keep.

It has now been found that these influencing variables also change frequently during the operating period, so that the once selected position of the at least one gassing device no longer corresponds to the optimum and the quality of the

Foam product or the separation efficiency decreases or fluctuates.

So far, among other things, a change in an added amount or type of reagents has been made to counteract a change in the influencing variables. However, these measures are only limited suitable to maintain the quality of the foam product or the separation success.

It is therefore an object of the invention to provide a pneumatic flotation machine or a flotation method which (s) achieves an improved separation efficiency when the influencing variables are changed.

The object is for the pneumatic flotation machine, comprising a housing with a flotation chamber, at least one nozzle arrangement for supplying gas and a suspension in the flotation and at least one gassing arrangement for further supply of gas into the flotation, which within the flotation and below the At least one nozzle arrangement is arranged, and at least one adjusting device for changing a position of the at least one gassing arrangement within the flotation chamber, achieved in that at least one further Measuring device for analyzing a foam product formed and / or the suspension is present and at least one arithmetic unit is present, which is connected to the at least one measuring device, wherein the at least one computer unit is set, from an analysis value supplied by the at least one measuring device to a manipulated variable calculate and output, according to which the position of the at least one gassing arrangement is variable by means of the at least one adjusting device.

The object is achieved for the method for flotation of particles from a suspension to form a foam product by means of a pneumatic flotation machine according to the invention, wherein a position of the at least one Bega- sungsanungsanordnung is changed within the flotation by means of at least one adjustment during flotation, solved by means of the at least one measuring device is carried out an analysis of the foam product and / or the suspension and the position of the at least one gassing arrangement in the flotation chamber is changed by means of the at least one adjusting device in dependence on the analysis.

The flotation machine according to the invention and the method according to the invention make it possible to continuously change the position of the at least one gassing arrangement during operation of the flotation machine and to flexibly adapt to changing influencing variables, in particular changing properties of the suspension used and flow conditions in the flotation chamber. This allows a

Positioning the at least one gassing device such that the gas bubbles are discharged at any time directly into the flow line (s) carrying an increased number of particles / wear. As a result, the probability of collision between a gas bubble and a hydrophobic particle is kept continuously at a consistently high level, and thus the separation success is maintained or even increased despite changing influencing variables. siege. The separation performance of the flotation machine can thus be optimized online depending on the analysis values. The result is an increase in the total yield in the flotation with optimal utilization of the plant capacity.

The at least one gassing arrangement, by means of which gas, but no suspension is introduced into the flotation chamber, the amount of gas can be varied as needed and greatly increased, without a supply amount of suspension would have to be changed in the flotation chamber. This makes the flotation process more uniform and increases the yield to a surprising extent.

It may be possible to dispense with a change in the addition amount of reagents for suspension and to avoid additional costs for excessive use of the reagents. When the influencing variables change, a combination of the method according to the invention with an adaptation of the amount added and / or the type of reagents, however, can often further increase the efficiency of the focussing machine.

Existing flotation machines can be upgraded in a simple manner and thus their performance can be increased.

By means of the at least one measuring device for analyzing a formed foam product and / or the suspension, the monitoring of changes in the suspension and / or the foam product can be automated in a simple manner. In particular, there is a permanent monitoring of the foam product and / or the suspension so that rapid changes in the influencing variables can be reacted.

The position of the at least one gassing arrangement in the flotation chamber is preferably changed by means of the at least one adjusting device as a function of the analysis such that a maximum separation performance of the flotation machine is achieved at all times. The manipulated variable calculated by the at least one arithmetic unit enables an immediate and particularly rapid optimization of the position of the at least one gassing arrangement, since the adjusting device only has to be adjusted by the amount predetermined by the manipulated variable. This significantly increases the yield overall.

Overall, therefore, the output of the flotation machine improves considerably. The continuous operation requires no operator on site and the device is extremely reliable. As a result, personnel costs can be saved.

Preferably, the at least one adjusting device is also connected to the at least one arithmetic unit, wherein the position of the at least one gassing arrangement can be automatically changed as a function of the manipulated variable by means of the at least one adjusting device. For this purpose, the at least one adjusting device preferably has a drive motor which changes the position of the at least one gassing device in the flotation chamber in accordance with the manipulated variable.

Alternatively, the adjusting device may also be manually operable and, for example, a crank, a lever or the like operatively connected to a linkage, in particular toothed rod, a cable system or the like.

The position of the at least one gassing arrangement can be changed in particular vertically and / or horizontally by means of the at least one adjusting device. As a result, the path traveled by the gas bubbles when floating in the direction of the surface in the suspension, changed and thereby extended or shortened.

The at least one gassing arrangement preferably comprises a gas supply line, a gas distribution system and at least two Gaseinströmdüsen. The gas, in particular air, is guided via the gas supply line into the flotation chamber, fed into the gas distributor system and distributed therein to equal proportions of the individual gas inlet nozzles.

In this case, a change only or substantially the position of the gas inlet nozzles of such a gassing arrangement is already understood as a change in the position of the gassing arrangement. The position of the gas supply line and / or the gas distribution system remains essentially the same.

Alternatively, it is possible that a gassing arrangement is formed only from a gas inlet nozzle, which is connected directly to its own gas supply line. On the gas distribution system can be omitted. Such a gassing arrangement can be arranged, for example, directly movably on the wall of the housing in the region of the flotation chamber.

In a preferred embodiment, the housing has a cylindrical housing section whose axis of symmetry is arranged vertically, wherein the position of the at least one gassing arrangement within the cylindrical housing section can be changed. In particular, the position of the at least one gassing arrangement within the cylindrical housing section in the direction of the symmetry axis is variable by a maximum of 50% of the height of the cylindrical housing section.

The gas supply line of the at least one gassing arrangement is in this case preferably arranged along the axis of symmetry and centered on this. This creates an optimal range of motion and allows a particularly simple and uncomplicated position change of the gassing arrangement.

The at least one measuring device can be located in or outside the housing. To minimize the reaction time To achieve ten, it has proven useful when the at least one measuring device is disposed within the housing.

By means of the at least one measuring device, an analysis of the foam product and / or the suspension is carried out in the method according to the invention and the position of the at least one gassing arrangement in the flotation chamber is changed by means of the at least one adjusting device as a function of the analysis. The continuous monitoring of the influencing variables makes possible a direct and timely adaptation of the position of the at least one gassing arrangement when they are changed.

From the analysis values provided by the at least one measuring device, a manipulated variable is calculated and output by means of the at least one arithmetic unit, according to which the position of the at least one gassing arrangement is changed. In particular, the position of the at least one gassing arrangement is automatically changed as a function of the manipulated variable.

It has proven useful to carry out an analysis of a foam height of the foam product and / or a solids content of the foam product and / or a valuable substance content of the foam product and / or a bubble size at the surface of the foam product and / or a solids content of the suspension by means of the at least one measuring device , Alternatively, it is also possible to analyze the viscosity of the suspension, its valuable substance content, etc., in order to make it possible to draw conclusions about the optimum position of the at least one gassing device, in particular its gas inlet nozzles, in the suspension.

FIGS. 1 and 2 are intended to illustrate, by way of example, a flotation machine according to the invention and its mode of operation. So shows 1 shows schematically a pneumatic flotation machine in a sectional view; and

2 shows a plan view of the pneumatic flotation machine according to FIG. 1

1 shows a pneumatic flotation machine 100 with a housing 1, which comprises a flotation chamber 3. Within the flotation chamber 3 is a foam channel 2 with nozzle 7 for discharging the foam product formed. The flotation chamber 3 is equipped with at least one nozzle arrangement 4 for supplying gas, in particular air, and a suspension into the flotation chamber 3. The housing 1 has a cylindrical housing portion Ia, at the lower end of a gassing arrangement 5 is arranged. The housing 1 furthermore has a bottom discharge opening 6. The upper edge of the outer wall of the housing 1 is located above the upper edge of the foam channel 2, whereby an overflow of the foam product on the upper edge of the housing 1 is excluded. Particles of the suspension which are provided, for example, with an insufficiently hydrophobized surface or have not collided with a gas bubble and hydrophilic particles sink in the direction of the bottom discharge opening 6. By means of the gassing device 5, additional gas, in particular air, is blown into the cylindrical housing section 1a, so that further hydrophobic particles are bound to it and rise. Ideally, especially the hydrophilic particles continue to sink and are discharged via the bottom discharge opening 6. The foam product passes from the flotation chamber 3 into the foam channel 2 and is discharged via the connecting piece 7 and optionally thickened.

In this embodiment, the gassing device 5 comprises a gas supply line 5a, a gas distributor system 5b and four gas inlet nozzles 5c. A schematically illustrated adjusting device 9 acts here on the gas supply line 5a to the position of the gassing assembly 5 in the flotation chamber 3, in particular by vertical (see double arrow) raising or lowering.

Above the foam channel 2, a measuring device 10 is arranged, by means of which, for example, an analysis of the

Foam height of the foam product in the foam channel 2 or a solids content of the foam product is performed.

The measuring device 10 is connected via a data line 8a to a computing unit 11, via which analysis or measured values determined during the analysis are transmitted to the arithmetic unit 11. Comparative values are stored in the arithmetic unit 11, with which the measured values are compared. If an impermissibly large deviation of the measured values from the comparison values is determined, the arithmetic unit 11 calculates and outputs a manipulated variable which specifies a required change in the position of the gassing arrangement 5. The required change in position can now be carried out manually, for example, by means of the adjusting device 9.

Alternatively, the manipulated variable can be transmitted to the adjusting device 9 via a further data line 8b and the required change in position can be carried out automatically by means of the adjusting device 9.

FIG. 2 shows the pneumatic flotation machine 100 in a top view, although the representation of the adjusting device 9, the measuring device 10 and the arithmetic unit 11 has been omitted here for the sake of clarity.

The pneumatic flotation machine shown in FIGS. 1 and 2 is merely one example of a multiplicity of suitable flotation machines which a skilled person can equip according to the invention. Thus, suitable flotation machines with respect to the design and arrangement of the foam collector, the number of nozzle arrangements for injecting suspension and gas, the number, arrangement and operation of the adjustment for varying the position of the gassing (s), the number, type and arrangement of measuring devices, the design of the gassing arrangement, etc., without departing from the spirit of the invention.

Claims

claims 1. Pneumatic flotation machine (100), comprising a housing (1) with a flotation chamber (3), at least one nozzle arrangement (4) for supplying gas and a suspension into the flotation chamber (3) and at least one gassing arrangement (5) further supply of gas into the flotation chamber (3), which is arranged within the flotation chamber (3) and below the at least one nozzle arrangement (4), and furthermore at least one adjusting device (9) for changing a position of the at least one gassing arrangement (5 ) in the flotation chamber (3), wherein at least one measuring device (10) for analyzing a formed foam product and / or the suspension is present and at least one computing unit (11) is present, which is connected to the at least one measuring device (10), and wherein the at least one arithmetic unit (11) is set up from an analysis value supplied by the at least one measuring device (10) to compute SSE and exclusively admit according to which the position of at least one Begasungsanordnung (5) by means of at least one adjusting device (9) is variable. 2. Pneumatic flotation machine according to claim 1, wherein the at least one adjusting device (9) is connected to the at least one arithmetic unit (11), and wherein by means of the at least one adjusting device (9) the position of the at least one gassing arrangement (5) in dependence on the Manipulated variable is automatically changed. 3. Pneumatic flotation machine according to one of claims 1 or 2, wherein the position of the at least one gassing arrangement (5) by means of the at least one adjusting device (9) vertically and / or horizontally changeable. 4. Pneumatic flotation machine according to one of claims 1 to 3, wherein the at least one gassing arrangement (5) a Gas supply line (5a), a gas distribution system (5b) and at least two Gaseinströmdüsen (5c). 5. Pneumatic flotation machine according to one of claims 1 to 4, wherein the housing (1) has a cylindrical housing portion (Ia) whose axis of symmetry is arranged vertically, and wherein the position of the at least one gassing arrangement (5) within the cylindrical housing portion (Ia) is changeable. 6. Pneumatic flotation machine according to claim 5, wherein the position of the at least one gassing arrangement (5) within the cylindrical housing section (Ia) in the direction of the symmetry axis by a maximum of 50% of the height of the cylindrical housing section (Ia) is variable 7. A pneumatic flotation machine according to claim 5 or claim 6, wherein the gas supply line (5a) is arranged along the axis of symmetry and centered on this. 8. Pneumatic flotation machine according to one of claims 1 to 7, wherein the at least one measuring device (10) is in the housing (1). 9. A method for flotation of particles from a suspension to form a foam product by means of a pneumatic flotation machine (100) according to one of claims 1 to 8, wherein a position of the at least one gassing arrangement (5) within the flotation chamber (3) by means of at least an adjustment device (9) is changed during the flotation, and wherein by means of the at least one measuring device (10) an analysis of the foam product and / or the suspension is carried out and the position of the at least one gassing arrangement (5) in the flotation chamber (3) mit- the at least one adjusting device (9) is changed as a function of the analysis. 10. The method according to claim 9, wherein the position of the at least one gassing arrangement in the flotation chamber is changed by means of the at least one adjusting device depending on the analysis in such a way that a maximum separation performance of the flotation machine is achieved at all times becomes. 11. The method of claim 9 or claim 10, wherein from the at least one measuring device (10) provided analysis values by means of the at least one arithmetic unit (11) a manipulated variable is calculated and output, according to which the position of the at least one gassing arrangement (5) changes becomes. 12. The method of claim 11, wherein the position of the at least one gassing arrangement (5) is changed automatically in dependence on the manipulated variable. 13. The method according to any one of claims 9 to 12, wherein by means of the at least one measuring device (10), an analysis of a foam height of the foam product and / or a solids content of the foam product and / or a valuable material content of the foam product and / or a bubble size at the surface the foam product and / or a solids content of the suspension is carried out.