瑞典专利SE537255C2 Method for sorting particulate matter

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专利摘要:
Summary A method of sorting particulate matter comprising creating an unobstructed monolayer feed stream of ore particles moving in a gaseous medium in a free space with an initial first path; exposing the monolayer feed stream while it is in the gaseous medium in the open space to a magnetic field of sufficient strength to affect the path of at least some particles in the feed stream to cause a scattering of particle paths from the first path. The particles are sorted and collected on the basis of their orbits.
公开号:SE537255C2
申请号:SE1250337
申请日:2010-09-07
公开日:2015-03-17
发明作者:Vladimir Arkadievich Golovanevskiy
申请人:Univ Curtin Tech；
IPC主号:

专利说明:

FIELD OF THE INVENTION The present invention relates to the sorting of particulate matter on the basis of the magnetic response of the material.
Background of the Invention The present invention has its origins in economic considerations in mining iron ore. There are considerable variations in the type of material found in the deposits that contain iron ore. The materials are usually in the form of particles and include, for example, one or more of the following types of materials: magnetite, hematite, gotite (vitros and limonitic), clay, slate and hornstone.
An important issue for mining operators is to produce a salable product or range of products. Marketable products include products that have a specified minimum amount of jam in the products. Marketable products can be mixtures of one or more of magnetite, hematite, and gotit that come from a mine hall in an iron ore deposit or several iron ore deposits.
It is possible to mine iron ore in large blocks of the ore. In accordance with the above background and the following description focusing on iron ore as an example of particulate matter, it is emphasized that the present invention is not limited to use in iron ore. In addition, it is also emphasized that the present invention is not limited to particulate matter in the form of bulk granular material.
Summary of the Invention The present invention encompasses the sorting of all kinds of particulate materials which respond differently to magnetic fields so that it is possible to distinguish between materials on the basis of the magnetic response and thus the types of materials.
The present invention is based on the insight that different materials in iron ore deposits have different magnetic sensitivities and that the application of a magnetic field to broken iron ore particles can be advantageous to separate the particles on the basis of the types of materials, for example the composition of the materials. , for example the composition.
More specifically, in a situation where broken ore particles include particles containing hematite and particles containing quartz which correspond very differently to a magnetic field, the present invention makes it possible to separate these types of materials. This is advantageous in the production of salable iron ore products.
The present invention is also based on the realization that the response of different kinds of material to an applied magnetic field can be used more productively to sort the material if the particles are in a gas carried on a surface such as a conveyor belt, vibration feeder or the like.
Thus, the embodiments of the invention utilize differences in magnetic probability arising from different physical compositions, such as mineralogical and / or elemental composition of the particles, to enable sorting of particulate matter on the basis of physical composition. In addition, the differences in physical composition are or may be associated with differences in the value of the particles.
Therefore, by conveniently placing one or more feed chutes, containers or other collecting devices on the road for the tracks, particulate or granular material can be sorted, using the embodiments of this method, on the basis of product properties and / or value. Further embodiments of the present methods enable a one-step process of identifying particles with different physical compositions (ie products with different values) and separating the particles into portions of equal physical composition / value. The term "particulate matter" as used is intended to encompass all kinds of matter, materials of form whether they occur naturally or are man-made and which are in the form of discrete particles or granules. Examples include, but are not limited to, broken corn or minerals, grains (such as wheat, rice and barley), and manufactured goods and components.
The terms "matter" and "material" are used interchangeably unless excluded by the specific context of use.
The term "physical composition" as used has been understood to refer to properties, such as one or more of: morphology, microstructure and / or mineralogical, chemical or basic composition of matter which can characterize matter and allow matter to be categorized together or in different categories of matter , and physical composition is determined in relation to these properties.
The term "monolayer" is used in the context of particulate matter and is understood to refer to a layer of particles having a depth or thickness as a particle.
In broad terms, the invention provides a method of sorting particulate matter comprising: exposing a monolayer of particles of the material that freely rotate through a gaseous medium to a magnetic field; and; allowing the moving particles to deviate in response to the action of the magnetic field to create a scattering of orbits for the moving particles, where the orbits are indicative of the physical composition of the particles, thus enabling sorting of particles on the basis of their orbits.
The invention also provides a method of sorting materials comprising: creating an unobstructed monolayer feed stream of particulate material moving with an initial first web in a gaseous medium; exposing the monolayer feed stream while in the gaseous medium to a magnetic field of sufficient strength to affect the path of at least some particles in the feed stream to cause a scattering of particle paths from the first path, and sorting the particles based on their paths. The method may comprise arranging a bulk portion of particulate material into the monolayer feed stream of particles.
The method may comprise projecting the monolayer of particles horizontally into the gaseous medium.
In an alternative embodiment, the method may comprise projecting the monolayer of particles upwardly into the gaseous medium.
In yet another embodiment, the method may comprise introducing the particles into a free-falling monolayer from the magnetic field. The monolayer may be located radially about an axis.
The method may comprise drying the particulate material before the monolayer of particles exposed to the magnetic field.
A suitable gaseous medium is air.
The method may comprise that before arranging the bulk portion, fractionating the bulk portion into two or more fractionated bulk portions of particulate material having different particle size ranges, the method is applied separately to the usual fractionated portion.
The method may comprise collecting particles having a specific path or range of paths and transporting the collected particles for further treatment or handling of the collected particles, as claimed.
The further treatment may include, for example, size separation. The handling may include, for example, transporting the particles to customers.
The particulate material may be any of the paramagnetic, ferromagnetic, and diamagnetic materials. However, embodiments of the invention depend on the application of a magnetic field of only sufficient strength to act on the paths in the free space of at least some of the particles in the monolayer. It is understood that the magnetic field should not cause a change in the trajectory of each particle in a monolayer. Basically, the monolayer feed stream of particles may be in any form heist which allows exposure of the particles to the magnetic field and allows a response of the particles from the field which allows separation of the moving particles in different downstream paths and thus sorting of the particles in downstream paths. .
A single path or a range of paths can be considered as a particle stream.
It can be predicted that the freely movable monolayer feed stream will spread to a continuous spread of paths. However, depending on the nature of the particulate matter, for example whether the matter contains particles having sharply defined and wide scattering magnetic properties, instead of a continuous scattering of orbits a number of discrete groups of orbits can be created in a similar manner to separate particulate streams.
Pitcher characteristics, such as the strength of and the exposure time in, the magnetic field can be selected as needed given the physical composition of the material to be sorted. Where the magnetic field is generated by an electromagnet, the field strength can be varied electronically by varying the current through the electromagnet. The strength of the field affecting the monolayer can also be varied for either an electromagnet or a permanent magnet by varying the distance (ie the air gap) between the magnet and the monolayer.
The materials can be all kinds of materials that respond differently to magnetic fields as often as possible. It is possible to distinguish between materials on the basis of the magnetic response and thus the type of material, such as compositions of the materials.
For example, the materials may be bulk of granular material, such as iron ore.
The iron ore particles may be broken iron ore particles.
The invention also provides a method of sorting bulk of broken iron ore particles comprising: creating an unobstructed monolayer feed stream of iron ore particles moving with an initial first web in a gaseous medium; exposing the monolayer feed stream while it is in the gaseous medium to a magnetic field of sufficient strength to affect the path of at least some particles in the feed stream to cause a scattering of particle paths from the first path, and sorting the particles based on their paths. The method may comprise arranging a bulk portion of the iron ore particles into at least one monolayer feed stream of iron ore particles and wherein the unobstructed monolayer feed stream is created from one of the at least one monolayer.
The arrangement of the bulk portion in at least one monolayer may comprise fractionating the bulk portion into two or more fractionating bulk portions of iron ore particles having different ranges of particle sizes, and wherein the unobstructed monolayer feed stream is created by a selected fractionated bulk portion of iron ore particles.
The method may comprise providing a bulk portion such as a portion having particles of a size in the range of 1 mm to 100 mm.
The bulk portion may be fractionated into, for example, size fractions of 2 mm to 6 mm; 6 mm to 32 mm; and 32 mm to 80 mm.
Alternatively, the unobstructed monolayer feed stream can be created by a fractionated portion having an average maximum particle size in relation to a minimum particle size between 2: 1 to 4: 1 where an average maximum particle size is between two to four times the size of a particle of average minimum size.
In a further alternative, the unobstructed monolayer feed stream may be created by a fractionated portion having an average maximum particle size in relation to a minimum particle size between 2: 1 to 3: 1 where an average maximum particle size is between two to three times the size of an average minimum particle. size.
The magnetic field strength can fall within a range of 1 Tesla to 10 Tesla.
The method may comprise providing particles in the unobstructed monolayer at a speed of between 1 m / s to 15 m / s as it moves through the magnetic field.
The method may comprise providing a mechanism for varying the field strength which may vary the field strength of the magnetic field affecting the particles. 6 537 25 The broken ore may be broken by any suitable method and apparatus. For example, the ore can be mined by drilling and blasting ore blocks from a mining deposit and transporting the broken ore from the mine tail by truck and / or conveyors.
Through further examples, the ore can be mined with opencast mines that are rooted over a mine neck bottom and transported from the mine by truck and / or conveyors.
The invention also provides an apparatus for sorting particulate matter comprising: an apparatus capable of forming a monolayer of particles from a bulk portion of the particles; and, a sorter capable of exposing a monolayer feed stream of particles of the material moving freely in a gaseous medium receives a magnetic field so that the threshing of at least some particles is affected by the magnetic field to create scattering of the particles' paths, where the paths are an indication of physical composition of the particles.
The invention also provides an apparatus for sorting broken iron ore particles comprising: an apparatus capable of forming a monolayer of particles from a bulk portion of the particles; and, a sorter capable of exposing a monolayer feed stream of particles of the material freely rooting in a gaseous medium to a magnetic field so that the motion of at least some particles is affected by the magnetic field to create scattering of the paths of the particles, the paths being an indication of physical composition of the particles.
The apparatus may comprise a means for forming a feed stream of particulate material to the movable monolayer feed stream of particles to be sorted in the sorter and a means for transporting the monolayer feed stream to the sorter to be exposed by the magnetic fait.
The apparatus may comprise one or more particle collection devices, such as feed troughs, containers, which are capable of being positioned to collect particles having the same path, or a range of paths. For example, there are three containers that can be provided and positioned to collect particles having webs in a first, second and third range of webs.
In this case, the apparatus sorts the monolayer of particles into three different batches, each batch containing particles of the same or similar physical composition, while particles of a different batch have a different physical composition.
The apparatus may comprise a drying apparatus for drying feed particles before exposing the feed stream of particles to the magnetic field.
The apparatus may comprise a delivery device such as a conveyor belt or a radial spreader which delivers the monolayer to the magnetic field and which may be controllable to vary the feed rate of the monolayer and thus the sorting speed.
The apparatus may further comprise fractionation equipment capable of fractionating on the basis of size, a bulk portion of the particles into size fractions and where one of the size fractions is used to form the monolayer.
The invention also provides a mining process comprising: mining mines to produce mined ore particles; fractionating the broken ore on the basis of particle size to form two or more size fractions; forming a monolayer feed stream from one of the size fractions of the ore particles; creating from the monolayer feed stream an unobstructed monolayer feed stream of ore particles which tears into a gaseous medium in a free space with an initial first path; exposing the monolayer feed stream while it is in the gaseous medium in the free space creates a magnetic field of sufficient strength to affect the path of at least some particles in the feed stream to cause a scattering of particle paths from the first path; and, sort the particles based on their orbits.
Brief Description of the Figures The present invention is further described by way of example with reference to the accompanying figures, in which: Figure 53 illustrates a process flow for an embodiment of the present method and apparatus for sorting particulate matter; Figure 2 is a schematic diagram illustrating an embodiment of a method and apparatus for sorting iron ore particles in accordance with the present invention; Figure 3 is a representation of a mining process incorporating an embodiment of the present method and apparatus; and Figure 4 is a graph illustrating experimental results of applying embodiments of the invention to sort a feed stream of iron ore particles.
Detailed Description of Preferred Embodiments Figure 1 is a process flow diagram of an embodiment of a method 10 and a corresponding apparatus using the method for sorting particulate matter. This illustrated embodiment of method 10 is shown as comprising two overall processes or steps namely, a process or step 12 of exposing a monolayer of particles which move freely through a gaseous medium i.e. a free or tipped space, to a magnetic field, and process or step 14 of allowing the moving particles to deflect in response to the magnetic field to create a scattering of paths of moving particles so that the particles can be sorted and / or collected on the basis of the different paths.
The scattering of orbits occurs depending on and is an indication of different physical compositions of the particles, which gives rise to different effects on the motion of these particles from the magnetic field.
As is readily understood by those skilled in the art, an orbit of an object is generally vaguely described by such an object moving in the air under the influence of such forces as initial velocity, wind resistance, and gravity.
Accordingly, in the present arrangement, the path of the particles is generally determined by a velocity at which the particles are introduced into free space, the angle at which they enter free space (relative to the horizontal) and the effect of the magnetic field on the respective particles. wind resistance and gravity. As will be described in more detail below, the effect of the magnetic field on each particle depends on the magnetic probability of the particle as such which is determined by the physical composition of the particle.
The step or process 12 comprises three sub-processes 12a, 12b and 12c. Process 12a is the initial supply or formation of a monolayer stream of particles. As described later below, this may be by, for example, passing a bulk particulate material through an operating machine or device such as a vibration feeder and then onto a conveyor belt to produce a monolayer feed stream. In this context, a monolayer is presented as a distribution of particles across a surface where the majority of the particles sit next to each other on the surface and no (or very few) sit on top of other particles.
At step 12b, this monolayer feed stream is projected or otherwise delivered to flow along an initial path in a gaseous medium in a free space. The gaseous medium is most suitably air. Usually the free space is enclosed in some kind of building, house or similar construction. For example, the monolayer feed stream of particles is projected along a path by a transport & into a start free space inside a building or the like. This now forms a freely movable monolayer of particulate matter. The terms "free-flowing", "freely movable" and "unobstructed" in relation to the particulate material are intended to mean that the matter can move without restrictions or limitation which otherwise arises, for example, when in contact with a surface such as a conveyor belt or cradles of a conical separator.
In one example, the dimensions of the free space may be such that a distance between a point where the monolayer of particles is delivered or projected into the free space and a point for collecting the particles after being exposed to the magnetic field Or greater On 1 m and preferably in range 5 m to 25 m.
In addition, a height between a point where the monolayer of particles is delivered into the free space and a point where the collection of the particles takes place Or in the range of 0 m to 30 m.
Similarly, it will be appreciated that, for example, an effect of the magnetic field on some of the particles, i.e. attractiveness, may be such that certain particles may deviate upwardly, allowing them to be collected at or near the same height as they have delivered at into the free space.
According to the above example, it is to be understood that the free space Or usually resides inside a lampy building. One reason for this Or to allow appropriate dust control by enclosing the free space of a building or the like.
Now when the monolayer Or is freely movable within the free space, at step 12c, the freely movable particles are exposed to a magnetic field. The magnetic waste will have different effects on the orbits of the moving particles. The variation in the effect may be between causing a deviation in the motion of the particle in the direction of the magnet, causing a deviation in the motion of the particle away from the magnet, or no cause of a deviation of the path.
Assuming that the monolayer of particles contains particles having at least two different physical compositions that give rise to different magnetic responses, a scattering of particle paths will be formed under the influence of the magnetic field. This makes it possible at step 14, sorting the particles on the basis of their orbits and thus their physical composition.
When mining in general, it is advantageous in terms of maximizing profit to separate low-grade particles from high-grade grinding particles. In the context of iron ore mining, a low grade particle is a particle with a large proportion of non-iron ore-containing material such as aluminum, silicon and phosphorus. A high-grade particle is one with more than 55% Fe by weight. In a feed stream of broken iron ore particles, there will be a spectrum of particles between waste materials, low grade particles and high grade particles.
By separating the waste from the low-grade and high-grade particles, the total average grade of the ore recovered from a block / bank of a mine can be increased. Embodiments of the present invention thus enable the separation of particles of varying degrees.
Figure 2 illustrates in a very general manner an embodiment of a sorting apparatus 20 capable of sorting particulate material such as broken iron ore particles according to the method 10.
A monolayer feed stream 22 of broken iron ore particles comprising different kinds of particles, including particles having different physical compositions, is transported along a belt conveyor 24 in the direction of the arrow X in the figure and projected from the duck 26 on the conveyor 24 into a free space to create a monolayer feed stream. of particles moving freely along an initial path through the air, the initial path of the feed stream exposes the particles to a magnetic field generated by a magnetic field generator 28.
The monolayer feed stream of particles is a freely movable stream of particles in air, where the particles have no or minimal contact with other particles or surfaces of equipment or structures as they move through the magnetic field and therefore have maximum freedom to be affected by the magnetic field.
The magnetic field is selected to have sufficient strength to deviate from at least some of the particles in the moving feed stream of particles as a function of the magnetic feasibility of the materials in the particles so that the particles form a scattering of paths. In this example, the scattering of the paths is symbolically divided into a series of three streams of particles 30a, 30b and 30c where the selected stream comprises a range of paths. The apparatus also includes three product containers 32a, 32b and 32c where each product stream 30a, 30b and 30c falls. Each stream contains particles and the same; or, similar kind or composition of materials. In the context of broken iron ore particles, the particles in the monolayer will have a range of compositions and the particles in the vale strom have the same or an edge prescribed range (ie similar) composition. Consequently, the method makes it possible to sort iron ore particles on the basis of iron ore grade.
For example, different types of iron ore may contain magnetite, hematite and / or gotite. As such, the magnetic fidelity x value of these materials measured in 6cm3 / g, is usually magnetite - 80,000; hematite - 290; and gotit - 25. According to armed, an applied magnetic field will have a much clearer effect on magnetite than hematite or gotit. Similarly, a magnetic field will have a more pronounced effect on hematite when compared to gotit. Accordingly, if the iron ore particles having substantially similar dimensions are subjected to a uniform magnetic field in a free space, a scattering of paths will be produced according to the physical composition of the particles. The sorting of the particles on the basis of their physical composition can be easily done by selecting a point in the scattering or the spectrum of paths for the collection of the particles. Ordinary iron ore from the Pilbara region in Western Australia contains a lot of hematite and gotit. The present embodiments can separate high-grade hematite particles from low-grade and waste particles by causing a deviation of the high-grade hematite particles from the pathways of waste particles.
In an iron ore example, in the dispersion of particle webs produced in this way, an upper end of the dispersion may contain particles with an iron content of + 60% while at the other end of the dispersion there are particles with 0% iron content.
By dividing the scatter in an appropriate manner, it is possible, for example, to sort the particles into a heap with 0% to 45% content of iron ore, a heap of 45% to 55% content of iron ore, and a heap of + 55% content of iron ore, depending on the requirements.
The magnetic field generator 28 is arranged to apply a magnetic field uniformly across the width of the freely movable monolayer of particles. The fold acts in a direction substantially perpendicular to a dominant direction of movement of the particles. Consequently, if the dominant direction of motion at the location of the field is horizontal, then the lines of magnetic flux are directed substantially vertically. When the generator 28 is an electromagnet, the apparatus 20 may include a control unit for controlling the current supplied to the generator 28 to vary the strength of the magnetic field. Alternatively, whether the generator 28 is an electromagnet or a permanent magnet, the apparatus 20 may include a mechanism for varying the distance or air gap between the generator 28 and the freely movable monolayer of particles so as to vary the strength of the magnetic field applied to the particles.
Method 10 and apparatus 20 Applicable to both dry and wet particulate matter. However, it will be appreciated that with wet particulate matter, greater similarities may be involved in the initial preparation of the monolayer due to inboard adhesion of wet particles. Accordingly, it is contemplated that embodiments of the method and apparatus 20 also provide a dryer for drying the particulate material to a certain minimum moisture level on the surface before it reaches the magnetic field.
It will be apparent from the above description that the method 10 and the apparatus 20 in fact allow a one-step process of identifying particles with different physical compositions and separating the particles on the basis of different physical compositions.
This is in contrast to other sorting techniques which initially require a process for aft identifying matter of different kinds or composition and a second process kw physical separation of the identified products of the desired physical composition from a bulk flow of products.
In the embodiment of the apparatus 20 shown in Figure 2, the scattering of the paths of the monolayer after being affected by the magnetic generator 28 is divided into three streams each falling into a separate container. However, as mentioned above, the scattering of the paths can be divided into the number of lifts of streams only depending on the number of different kinds of particles that are desired to be sorted. Furthermore, rather than having the particles falling into product containers, they may fall on other collection or material handling devices such as conveyors for conveyors, or the like.
Transport & 24 in the apparatus 20 is depicted as running in a horizontal plane or direction and therefore the monolayer is projected by particles with a horizontal velocity component from the spirit 26. Rather, the conveyor 24 may be inclined or inclined relative to the horizontal plane. In the former case, the monolayer of particles will be projected with a vertically upward velocity component into the magnetic field. In addition, the conveyor 24, regardless of its angle to the horizontal plane, introduces the monolayer of particles as a flat layer.
However, a monolayer can be created in other shapes and configurations, in particular in a radial or circular configuration, for example by delivering the monolayer through a cone. In this variant, Ors effect on the monolayer after passing through the cone and free falling through air or other gaseous medium. In this case, a magnetic field generator can be placed either on the inside, or alternatively disposed around the outside of the freely movable circular monolayer of particles.
Figure 3 illustrates an embodiment of a mining process 30 containing the method 10 and the apparatus 20. An initial stage 32 in the process 30 is the mining of an ore, e.g. jarnmalm. Which mining method heist can be used such as drilling and blasting, or by using machines for day mining that are moved over a mine neck floor.
In stage 34, the broken ore is transported to a crusher 36. The transport can take place with a truck, transport & or rals. The crusher 36 crushes the broken ore to produce a bulk load of particulate maim which has a reduced particle size within a predetermined size range, for example from 1 mm to 100 mm. Embodiments of the method 10 and apparatus 20 can be applied to such a particle size range, but it will be appreciated that better sorting quality can be achieved by including a screening or fractionation stage 38 which fractionates the bulk of ore particles into a plurality (in this case three) fraction sizes. Size fractions can be selected by a process manager or a mining manager. The separate size fractions are kept in trays or supports 40a, 40b and 40c. When it is difficult to sort the particles in each tray / storage, corresponding particles pass through the device 42, such as a vibrating screen which arranges the bulk of fractionated particles into a monolayer feed stream for each apparatus 20a, 20b and 20c. Each apparatus 20a, 20b, 20c conforms to and operates on the same principles and principles as apparatus 20 described above. Salades, each size fraction is formed into a monolayer feed stream, the particles in the usual feed stream are subjected to a magnetic field when traveling in an unobstructed manner in a free space, and are sorted on the basis of the path deviation from an initial monolayer path.
Since the usual size fraction naturally has particles with different size ranges, operating parameters for each apparatus 20a, 20b and 20c can be set to optimize the spread of the respective paths and thus the degree or "sharpness" of sorting. The operating parameters include magnetic field strength and velocity of movement of the conveyor 24 which corresponds to the speed of the monolayer at the initial projection into the magnetic field. Of course, the sieving / fractionation 38 in process can also be controlled.
In one embodiment of the process 30, the size fractions contained in trays / supports 40a, 40b and 40c may be 2 mm-6 mm; 6 mm to 32 mm; and, 32 to 80 mm or 100 mm.
However, the fractionation may alternatively be arranged to provide different size ranges based on particle size ratios. For example, size fractions may be arranged to include particles having an average maximum particle size in a ratio to a minimum particle size between 2: 1 to 4: 1. In such a size fraction, an average maximum particle size is between two and four times the size of a particle of average minimum size. Alternatively, this ratio may be on the order of about 2: 1 to 3: 1.
The strength of the magnetic field is typically between the range of 0.5 Tesla to 5 Tesla, but it is assumed that up to 10 Tesla may be possible. As such, depending on the requirements and properties of the particles to be sorted, at a range! of 0.5 Tesla to 3 Tesla also possible. In a further example kw an iron ore monolayer feed stream having particles in the range of either 2 mm to 6 mm; or, 6 mm to 32 mm, a field strength of 0.5 Tesla to 1.5 Tesla may be appropriate. However, for a particle size range of 32 mm to 100 mm, a field strength of 1.5 Tesla to 5 Tesla may be suitable. As those skilled in the art will appreciate, the size of the particles and their physical composition will also be important for the requirements for suitable field strength, as larger particles typically require higher field strength. However, sorting of larger particles comprising materials having a high magnetic probability is possible with a smaller field strength.
In an example of the speed of the belt 24, and thus the monolayer of particles before the introduction into the magnetic field between 1 m / s and 10 m / s, however, up to 15 m / s may be possible. 537 However, in alternative examples, the speed range is 1m / s to 8 m / s; or, 2 m / s to 6 m / s. The velocity of the strip can be selected on the basis of the maximum particle size in the range, where size ranges having a smaller maximum size of the particles generally have a higher strip velocity than size ranges having a larger maximum size of particles. For example, for a particle size range of 32 mm to 100 mm, the belt speed is less than or equal to 3 m / s; for 6 mm to 32 mm the speed can be greater than 2 m / s; and for 2 mm to 6 mm the speed can be greater than 4 m / s.
In an example of application of the method 10, the apparatus 20 and the process 30 in the context of separation of bulk of granulated iron ore, it is conceivable that the process speed is in the order of 250 tons / hour / meter of the presentation length of the monolayer. By, by presentation length is meant the width of a monolayer passing through the magnetic field, for example the width of the conveyor belt which projects or fires the monolayer feed stream into the free space with the gaseous medium which the iron ore particles cross through.
Figure 4 illustrates experimental results of applications of one embodiment of the method for sorting a monolayer feed stream of iron ore flowing through air at three different feed stream velocities. The graph indicates the scattering of particle paths coinciding with different physical compositions, in this case iron content, of the particles. In each of the illustrated examples, the magnetic field density along the width of the feed current through air was 0.5 TI of the magnet was 118 mm in length.
In the usual situation, the magnetic field and other operating conditions, such as the mass flow rate of the particles rooting downwards, the size distribution of the particles, the distance and time of exposure of the particles to the magnetic field, will depend on the magnetic properties of the material in the particles. determined.
Many modifications may be made to the embodiment of the present invention described above without departing from the spirit and scope of the invention.
By way of example, while the above-described embodiment is described in the context of sorting iron ore particles, the present invention is not limited thereto and encompasses sorting of other granular bulk materials and, more generally, to all kinds of materials showing different responses to a magnetic field. By further examples, the embodiments of the method and the apparatus make it possible to vary the strength of the magnetic field to control the scattering of paths and thus the fall points and collection points of particles with different paths or intervals! of paths to thereby control where the sorted particles fall. Thus, while the above description indicates the possibility of moving the container 32 to enable the collection of particles of the same or similar kind, one can instead keep the container in a fixed position and vary the field strength to ensure that the particles having the same or desired properties fall in. in a specified container.
In general terms, the present invention encompasses all kinds of combinations of structures and working conditions that make it possible to form particles into a monolayer feed stream of particles and to separate the particles into separate streams in response to an applied magnetic field and to collect the separated streams for downstream processing of the particles. , according to requirements.
It is considered advantageous that the present arrangement provides means by which a particular material can be sorted depending on the magnetic sensitivity of the material. In particular, the present arrangement allows a preparation of dispersion of webs of particles comprising the material which facilitates the sorting of the material. Instead of having only the possibility of sorting materials into magnetic and non-magnetic particles, the present particles enable degree-level sorting where the scattering of paths can be assigned according to the requirements. This grade-level sorting eliminates the need for additional sorting with associated savings in time and money. 17

权利要求:
Claims (3)
[1]
1. • 32h • at. YSI 32c 30c 30a 24 32a 537 3/4 Size range 40a Size range Size- In range I a 40b 40c 42c 20c, Maim break Transport 34 Crusher 36 32 42b Monolayer a Sort Monolayer Sort Sort 42a Monolayer 20a 20b Sift / Fraction 38 FIGURE 3,537 4 / 4 Iron content,% •> 60 -m11. imm. 50-60 <ow 'lot I •
[2]
2. ■ 111 = 11
[3]
3. MIMI • - 4.75 Ink - 5.5 m / c 6.0 mfc Speed Speed Speed 150 Separation power, mm FIGURE 4

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CA3133583A1|2020-09-24|Method and apparatus for separating feed material

JP2011025208A|2011-02-10|Sorting and classifying apparatus

JPH0975773A|1997-03-25|Eddy current sorting method and its device

JP2000246177A|2000-09-12|Raw material screening method and device

JPH07275799A|1995-10-24|Granular body classifying device

GB2256819A|1992-12-23|Separating solids

RU2164448C1|2001-03-27|Method of dry magnetic separation of ores and materials

同族专利:

公开号 | 公开日

CA2772272A1|2011-03-10|

IN2012DN01951A|2015-08-21|

CN102574128B|2014-11-19|

DE112010003564T5|2013-05-16|

SE1250337A1|2012-06-05|

WO2011026195A1|2011-03-10|

ZA201202406B|2014-06-26|

EA201270389A1|2012-08-30|

UA106632C2|2014-09-25|

US20120199520A1|2012-08-09|

AU2010291880B2|2016-03-10|

AP3290A|2015-05-31|

US8919566B2|2014-12-30|

AP2012006154A0|2012-04-30|

AU2010291880A1|2012-03-08|

EA023865B1|2016-07-29|

CN102574128A|2012-07-11|

CA2772272C|2019-02-12|

CL2012000597A1|2013-01-25|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US3382977A|1965-03-08|1968-05-14|Interior Usa|Magnetic separator with a combination field|

US4083774A|1976-02-03|1978-04-11|Uop Inc.|Magnetic segregation of mixed non-ferrous solid materials in refuse|

US4370225A|1981-08-24|1983-01-25|United States Steel Corporation|Dry magnetic separators for increased recovery or ore at high belt speeds|

GB8530360D0|1985-12-10|1986-01-22|Gec Elliott Mech Handling|Magnetic separators|

US4781821A|1987-01-30|1988-11-01|Usx Corporation|Process for operating a short-belt type magnetic separator|

DE3823944C1|1988-04-25|1989-11-30|Steinert Elektromagnetbau Gmbh, 5000 Koeln, De|

US6095337A|1993-12-22|2000-08-01|Particle Separation Technologies, Lc|System and method for sorting electrically conductive particles|

DE19521415C2|1995-06-14|1997-07-03|Lindemann Maschfab Gmbh|Arrangement for separating non-magnetizable metals from a solid mixture|

US6173840B1|1998-02-20|2001-01-16|Environmental Projects, Inc.|Beneficiation of saline minerals|

DE10057535C1|2000-11-20|2002-08-22|Steinert Gmbh Elektromagnetbau|Device for separating non-magnetizable metals and Fe components from a solid mixture|

US6629010B2|2001-05-18|2003-09-30|Advanced Vision Particle Measurement, Inc.|Control feedback system and method for bulk material industrial processes using automated object or particle analysis|

CN201130115Y|2007-11-29|2008-10-08|攀钢集团矿业公司|Disperse-shaped material sampler|NL2001431C2|2008-04-02|2009-10-05|Univ Delft Tech|Method for separating a waste stream.|

EP2412452B1|2010-07-28|2013-06-05|Inashco R&D B.V.|Separation apparatus|

NL2006306C2|2011-02-28|2012-08-29|Inashco R & D B V|Eddy current seperation apparatus, separation module, separation method and method for adjusting an eddy current separation apparatus.|

WO2014094038A1|2012-12-17|2014-06-26|Technological Resources Pty Limited|Mined material bulk sorting system and method|

NL2013925B1|2014-12-05|2016-10-11|Urban Mining Corp Bv|Sensor separation apparatus and method.|

CN104823604B|2015-04-27|2017-07-14|山东棉花研究中心|A kind of machine pick cotton removal of impurities control system|

CN105249569B|2015-11-25|2018-01-19|西人马（厦门）科技有限公司|Electromagnetic type protector|

CN105689118A|2016-03-24|2016-06-22|陈勇|Belt magnetite separation combination device with small partition grids|

CN105689119A|2016-03-24|2016-06-22|陈勇|Conveyor belt type ultrahigh magnetic field magnetite separation device|

CN105618253A|2016-03-24|2016-06-01|陈勇|Device for magnetite separation by impacting ore sand through paraboloid|

CN105562201A|2016-03-24|2016-05-11|陈勇|Waterwheel track type ore sand scraping and magnetite concentrating combined device|

CN105597923A|2016-03-24|2016-05-25|陈勇|Belt type magnetite separating device with small lattices|

CN105562203A|2016-03-24|2016-05-11|陈勇|Superhigh magnetic field iron ore dressing device|

CN105618261A|2016-03-24|2016-06-01|陈勇|Device for magnetite separation by blowing ore sand through strong breeze|

CN105689123A|2016-03-24|2016-06-22|陈勇|Multi-time ultrahigh magnetic field iron ore separation device|

CN105689122A|2016-03-24|2016-06-22|陈勇|Paraboloidal magnetite sand bombarding type magnetite separation combination device|

CN105728186A|2016-03-24|2016-07-06|陈勇|Magnetite beneficiation device with belt with small grids|

CN106807543A|2016-03-24|2017-06-09|四川语文通科技有限责任公司|Super-high magnetic field iron ore device|

CN105618258A|2016-03-24|2016-06-01|陈勇|Magnetite beneficiation device implemented by scraping ore sand with waterwheel type caterpillar band|

CN105597924A|2016-03-24|2016-05-25|陈勇|Watercart-type crawler belt-based ore sand scraping and magnetite screening device|

CN105689120A|2016-03-24|2016-06-22|陈勇|Device used for pulling magnetite out of magnetic field|

CN105642439A|2016-03-24|2016-06-08|陈勇|Ultra-strong magnetic field iron ore dressing device|

CN105618260A|2016-03-24|2016-06-01|陈勇|Device for magnetite separation by blowing ore sand through strong breeze|

CN105618262A|2016-03-24|2016-06-01|陈勇|Magnetite beneficiation device implemented by impacting ore sand with paraboloids|

CN105618259A|2016-03-24|2016-06-01|陈勇|Combination device for magnetite separation by blowing ore sand through strong breeze|

CN105964395A|2016-07-12|2016-09-28|陈勇|Spray nozzle type ultrahigh-magnetism ore dressing device|

CN105944831A|2016-07-12|2016-09-21|陈勇|Conveying belt type ultra-high magnetic field magnetite separating device|

CN106269243B|2016-09-07|2018-07-06|重庆市九瑞粉末冶金有限责任公司|A kind of ferrous powder granules pulse magnetic separating device|

CN106423552B|2016-09-07|2019-01-22|重庆市九瑞粉末冶金有限责任公司|A kind of annular ferrous powder granules sorting unit|

AT520710A1|2017-11-24|2019-06-15|Ife Aufbereitungstechnik Gmbh|magnetic separators|

US10960444B2|2018-04-06|2021-03-30|Karl William Yost|Closure methods for mines|

CA3105780A1|2018-07-09|2020-01-16|Novelis Inc.|Systems and methods for improving the stability of non-ferrous metals on a conveyor|

CN111013701A|2019-12-27|2020-04-17|永康悠长矿产开采技术有限公司|Iron ore classification collecting equipment|

法律状态:
2020-05-05| NUG| Patent has lapsed|

优先权:

申请号 | 申请日 | 专利标题

AU2009904302A|AU2009904302A0|2009-09-07|A method of sorting bulk granular materials|

PCT/AU2010/001154|WO2011026195A1|2009-09-07|2010-09-07|A method of sorting particulate matter|

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