EP3894080A1 - Device for stressing particles by means of electric pulses - Google Patents

Abstract

The invention relates to devices for stressing particles (9) by means of electric pulses (11) using an apparatus for supplying particles, at least one vertically arranged piece of piping (2) with a reaction space for stressing particles, and an apparatus for discharging particles. The devices are distinguished, in particular, in that they are already present in a manner better or completely separated into relatively coarse fractions for the purpose of subsequent comminution. To this end, the piece of piping (2) and therefore the reaction space is a flow duct of a flowable medium (10). Furthermore, a device (4) which conveys the medium is connected to the pipe section such that the medium flows counter to the direction of movement of particles which are fed to the piece of piping and drop through the piece of piping (2). The pipe section has at least two electrodes (5) which are arranged at a distance from one another and are connected to at least one pulse voltage generator in the form of a Marx generator (6). Furthermore, the electrodes end with or in front of the inner surface of the piece of piping , so that the electrodes (5) do not protrude into the piece of piping(2) and do not impede the flow of the medium in the piece of piping.

Description

Device for stressing particles by means of electrical impulses

The invention relates to devices for stressing particles by means of electro pulses with a device for supplying particles, at least one vertically arranged pipe section with a reaction chamber for stressing particles and a device for discharging particles.

The principle of the comminution of solids by electrical impulses is known. These electro pulse processes have disadvantages, in particular in the continuous conveyance of feed material consisting of solids through the reaction space and in the required residence times in the reaction space which vary depending on the material and particle size. There is also a risk of damage to components due to the electrical impulses used.

From the document FR 1 341 851 A, a system for continuous electrohydraulic comminution and mixing of substances in a liquid medium is known. The electrical discharges occur through the liquid surrounding the material to be shredded, usually water. Due to the plasma channel created in the liquid, a pressure wave is generated in it, which hits the material to be shredded and stresses it. The necessary generation of the electrical impulses takes place by means of resonant circuits, which results in a correspondingly slow increase in impulses. The liquid reservoir is pressure shock resistant in order to withstand the indirect exposure of the substances (pulverization) due to the shock wave generated in the water by means of electrical impulses. Flat electrodes are also described in the device in order to maximize the effect of the shock wave. However, these protrude into the process space or are built up flat in a tapered pipe section. The liquid flow is hindered and the electrodes are therefore subject to increased wear. A liquid flows through the reactor in order to discharge the comminution products completely upwards or downwards.

Another method for comminuting solids by means of electrical impulses is electrodynamic comminution.

A device and a method for the continuous comminution of solids by means of electrical pulses are known from the document DE 10 2014 008 989 A1. This has at least one reaction space to which the solids are fed by means of a transport means, the reaction space being located in a reaction vessel. This has at least one electrode set consisting of at least two electrodes arranged at a predetermined distance from one another, which form an electrode gap in the reaction space. At least one central electrode and electrodes surrounding it are present. A device for generating electrical pulses delivers the electrical pulses to the electrodes of the electrode set, the solids being pressed against the electrode set until the solids present there are comminuted by means of the electrical pulses so that the comminuted solids are smaller than the distance between them are opposite electrodes. The shredded solids pass through the gap between the electrodes together with the flowing means of transport. Continuous comminution is essentially only possible with solids of approximately the same size. No or insufficient comminution can lead to the accumulation of solids.

The publication WO 2012 129 713 A relates to an electrode arrangement for an electrodynamic fragmentation system with a passage opening or a passage channel for material to be fragmented and with one or more pairs of electrodes. By applying high-voltage pulses to the fragments of the electrodes, high-voltage discharges are generated within the passage opening or the passage channel. Rod-shaped, pointed or rounded electrodes protrude from the edge of a surrounding jacket and, if appropriate, from a centrally located dome-shaped insulation body into the comminution space in order to obtain approximately spherical comminution material. For this purpose, the electrode distance is smaller than the maximum particle size that can pass through the passage opening or the passage channel.

JP 11-33 430 A discloses a comminution process and a device for carrying out the process. For this purpose, there are electrode plates inclined at an angle to one another, between which high-voltage discharges occur due to voltage pulses. The electrode plates form a tapering gap. The particles must be smaller than the distance between the electrode plates at the respective point in order to pass through the tapering gap. A solution consisting of shredding and classifying function is described. The material must therefore be shredded in order to pass through the facility.

The object of the invention specified in claim 1 is to at least claim particles in such a way that they are already better or completely digested in coarser fractions for subsequent mechanical comminution. This object is achieved with the features listed in claim 1.

The devices for stressing particles by means of electrical pulses with a device for supplying particles, at least one vertically arranged pipe section with a reaction chamber for stressing particles and a device for discharging particles are characterized in particular by the fact that they are already in coarser fractions for subsequent comminution better or completely open minded.

For this purpose, the pipe section and thus the reaction space is a flow channel of a flowable medium. Furthermore, a device conveying the medium is connected to the pipe section in such a way that the medium flows against the direction of movement of particles supplied to the pipe section and sinking through the pipe section. The pipe section has at least two electrodes spaced apart from one another and connected to at least one Marx generator as a pulse voltage generator, the pulse rise time of the Marx generator being less than 500 ns. In addition, the electrodes end with or in front of the inner surface of the pipe section, so that the electrodes do not protrude into the pipe section and do not hinder the flow of the medium in the pipe section.

The particles passing through the pipe section are electrodynamically stressed by means of the electrical impulses, which also includes the electrodynamic comminution of particles. The so-called Marx generator is used, which is a surge voltage generator. This is used to generate pulses with a pulse rise time of less than 500 ns. During these short rise times, the discharge between the electrodes arranged at a distance from one another preferably takes place directly through the particle or a plurality of particles simultaneously. The resulting plasma channel leads to an immediate stress on the particle. The plasma channel within the particle is accompanied by high pressures and temperatures, which weaken or completely loosen the bonds along the discharge channel and are broken down within the particle. This results in a reduction in the strength of the particle and thus also supports selective decomposition into different components. The direct energy input in the particles to be stressed is energy-efficient and advantageously does not require a pressure-shock-proof pipe section as a reaction space for stressing particles. The pipe section can have a cross section that is constant over its length, so that the flow of the medium is not influenced thereby either. The particles can be checked and discharged size-selectively. Continuous operation is easy to implement. The voltage of the Marx generator can be, for example, 400 kV to 600 kV. The frequency can be equal to or greater than 25 Hz. The energy range can be greater than / equal to 7 J to equal to / less than 700 J.

The device is further characterized by the fact that no movable conveying devices are required in the reaction space. Furthermore, the particles can also pass through the process space without stress and the associated damage or comminution. The residence time of the particles in the reaction space can advantageously be set as a function of the material, the throughput and / or the size by means of the device which conveys the medium, the medium flowing against the direction of movement of particles supplied to and falling through the pipe section. Unintentionally produced fine particles and very fine particles can be continuously discharged from the reaction space by means of the flowing medium against the direction of the particles to be damaged.

The electrodes do not protrude into the reaction space, so that contact between the particles to be stressed and the electrodes and thus abrasive wear on the electrodes is largely avoided. The electrodes can advantageously be controlled individually. Respective electrode pairs can be controlled simultaneously or sequentially, it being possible for electrode pairs to be arranged next to one another and / or one below the other.

The particles, also as mineral grains, are therefore advantageously present in coarser fractions in a better or completely digested form for subsequent comminution, so that less energy may be required for this. This means, for example, that metal-containing minerals can be better applied to ores, more completely and in higher concentrations. This means that even deposits with low ore contents can still be used economically, the required completeness of the use of the deposits can be increased and the sustainability of the raw material processing can be improved.

Advantageous embodiments of the invention are specified in claims 2 to 11.

The device for feeding particles is optionally arranged so that the particles to be loaded sink from top to bottom through the pipe section. So that can the particles are also fed continuously, so that a continuous loading of particles with electrical impulses in the pipe section can be realized.

In one embodiment, a plurality of electrodes are distributed around the inner circumference of the tube piece and are arranged at a distance from one another. Furthermore, the electrodes are connected to pulse voltage generators.

Two electrodes each are optionally arranged in at least two mutually spaced planes of the pipe section, these electrodes being connected to the Marx generator or to Marx generators. The loading of the particles can thus take place in several levels while the particles are sinking.

In one embodiment, electrodes are distributed around the inner circumference of the pipe section in a plane and / or in planes spaced apart from one another. Furthermore, the electrodes are connected to the Marx generator or to Marx generators. The electrodes can also be arranged helically.

The electrodes of one level can be connected to the Marx generator or to Marx generators. Furthermore, the Marx generator or the Marx generators are connected together with a control device in such a way that the voltages and / or impulses of the planes which are present at the same time differ from one another.

The device for discharging particles is optionally arranged such that the particles sinking through the pipe section are transported away from the device for stressing particles.

In one embodiment, the device conveying the medium is connected to a control device, so that the flow velocity of the medium and thus the speed of the particles sinking through the pipe section can be influenced.

A device for the discharge of fine and / or very fine particles is optionally arranged outside the reaction space in the direction of the device for supplying particles. This can be an opening in the wall of the pipe section, which can be connected to a suction device. The device for supplying particles, the vertically arranged pipe section, the medium-conveying device and lines are a medium-carrying circuit.

The medium can in particular be a gas or a liquid.

An embodiment of the invention is shown in principle in the drawings and is described in more detail below.

Show it:

Fig. 1 shows a device for stressing particles by means of electrical pulses and

Fig. 2 shows a piece of pipe with electrodes and a reaction space.

A device for stressing particles 9 by means of electrical pulses 11 essentially consists of a device 1 for supplying particles 9, a vertically arranged pipe section 2 with a reaction chamber, a device 3 for discharging particles 9, a device 4 which conveys medium 10, electrodes 5 , a Marx generator 6 and a control device 7.

Fig. 1 shows a device for stressing particles 9 by means of electrical pulses 11 in a basic representation.

The device 1 for supplying particles 9 is arranged such that the particles 9 sink from top to bottom through the pipe section 2. The device 3 for discharging particles 9 is located in such a way that the particles 9 that have sunk through the pipe section 2 are transported away from the device for stressing particles 9. The device 4 conveying the medium 10 is connected to the control device 7 such that the flow velocity of the medium 11 and thus the speed of the particles 9 falling through the pipe section 2 can be influenced. A device 8 for discharging fine and / or very fine particles 9 can be arranged in the direction of the device 1 for supplying particles 9.

2 shows a tube section 2 with electrodes 5 and a reaction space in a basic representation.

The pipe section 2 and thus the reaction space represents a flow channel of the flowable medium 10. For this purpose, the device 4 conveying the medium 10 with the pipe section 2 connected in such a way that the medium 10 flows against the direction of movement of the particles 9 fed to the pipe section 2 and falling through the pipe section 2.

The pipe section 2 has the electrodes 5 spaced apart and connected to the Marx generator 6, the electrodes 5 ending with or in front of the inner surface of the pipe section 2, so that the electrodes 5 do not protrude into the pipe section 2 and the flow of the Do not hinder the medium 10 in the pipe section 2. Electrodes 5 can also be connected to several Marx generators 6. This means that different pulses can be generated in their frequency and / or pulse duration. The voltage can be, for example, 400 kV to 600 kV. The frequency can be equal to or greater than 25 Hz. The energy range can be greater than / equal to 7 J to equal to / less than 700 J.

For this purpose, a plurality of electrodes 5 can be distributed around the inner circumference of the pipe section 2 and arranged at a distance from one another. For this purpose, an electrode 5 can be located in at least two mutually spaced planes of the pipe section 2. In one embodiment, electrodes 5 can also be arranged in a plane and / or in mutually spaced planes distributed around the inner circumference of the pipe section 2, so that the electrodes 5 are arranged in a screw shape.

At least the device 1 for supplying particles, the vertically arranged pipe section 2, the device 4 conveying the medium 10 and lines can be a circuit carrying the medium 10. In a continuation, the device 3 can also be integrated into this circuit for the discharge of particles 9.

The medium 10 is a gas or a liquid.

Reference symbol list

1 device for feeding particles

2 pipe section

3 device for discharging particles

4 Medium-promoting institution

5 electrode

6 Marx generator

7 control device

8 Device for the discharge of fine and / or very fine particles

9 particles

10 medium

11 electrical impulse

Claims

Claims

1. Device for stressing particles (9) by means of electrical pulses (11) with a device (1) for feeding particles (9), at least one vertically arranged pipe section (2) with a reaction chamber for stressing particles (9) and a device (3) for the discharge of particles (9), characterized in that the pipe section (2) and thus the reaction space is a flow channel of a flowable medium (10), that a device (4) conveying the medium (10) with the pipe section ( 2) is connected in such a way that the medium (10) flows against the direction of movement of the pipe section (2) and particles (9) sinking through the pipe section (2) such that the pipe section (2) is arranged at least two spaced apart and with at least one Marx generator (6) has connected electrodes (5), the pulse rise time of the Marx generator (6) being less than 500 ns, and that the electrodes (5) end with or in front of the inner surface of the pipe section (2), so that di e Do not protrude electrodes (5) into the pipe section (2) and do not hinder the flow of the medium (10) in the pipe section (2).

2. Device according to claim 1, characterized in that the device (1) for supplying particles (9) is arranged so that the particles to be claimed (9) sink from top to bottom through the pipe section (2).

3. Device according to claim 1, characterized in that a plurality of electrodes (5) are distributed around the inner circumference of the pipe section (2) and spaced apart and that the electrodes (5) with the Marx generator or with Marx generators (6) are connected.

4. Device according to claim 1, characterized in that two electrodes (5) are arranged in at least two mutually spaced planes of the pipe section (2) and that these electrodes (5) are connected to the Marx generator (6).

5. Device according to claim 1, characterized in that electrodes (5) are arranged in a plane and / or in spaced planes distributed around the inner circumference of the pipe section (2) and that the electrodes (5) with the Marx generator ( 6) or connected to Marx generators (6).

6. Device according to claims 1, 2 and 5, characterized in that the electrodes (5) on one level are connected to the Marx generator (6) or to Marx generators (6), that the Marx generator (6) or the Marx generators (6) are or are connected to a control device (7) in such a way that the voltages and / or impulses of the planes present at the electrodes (5) differ from one another.

7. Device according to claim 1, characterized in that the device (3) for discharging particles (9) is arranged such that the particles (9) which have sunk through the pipe section (2) are removed from the device for stressing particles (9). be transported away.

8. Device according to claim 1, characterized in that the medium (10) conveying device (4) is connected to a control device (7), so that the flow rate of the medium (10) and thus the speed of the pipe section (2nd ) sinking particles (9) can be influenced.

9. Device according to claim 1, characterized in that a device (8) for discharging fine particles and / or very fine particles (9) is arranged outside the reaction chamber in the direction of the device (1) for supplying particles (9).

10. Device according to claim 1, characterized in that the device (1) for supplying particles (9), the vertically arranged pipe section (9), the medium (10) conveying device (4) and lines a the medium (10 ) are the leading cycle.

11. Device according to claim 1, characterized in that the medium (10) is a gas or a liquid.