EP2392414A1 - Method and device for detecting an object containing a target mineral - Google Patents

Abstract

The method involves exposing objects (14) to near-infrared (NIR)-light, where the objects fall at a preset region of a bulk material flow (16). The NIR light is filtered by a filter such that a preset frequency range passes, where the frequency range corresponds to a frequency range in which light reflected by target mineral has higher light intensity than reflected light of other materials. The filtered NIR light is detected by a line or matrix camera (24) and is supplied to an evaluation unit (26) that sends a signal when light intensity of the detected light exceeds a preset threshold. Independent claims are also included for the following: (1) a device for detecting a target mineral-containing object from a bulk material flow (2) a method for manufacturing a device for detecting a target mineral-containing object from a bulk material flow.

Description

The present invention relates to a method for detecting an object containing a target mineral from a free-flowing bulk flow of a plurality of objects according to the preamble of claim 1, a device therefor according to the preamble of claim 4 and a method of manufacturing the device according to the preamble of claim 10.

In the mining of minerals, such as gemstones, borates (Colemanit), talc or the like, in the open pit or in the context of an underground mine, other unwanted materials, such as other minerals, rocks or other impurities are usually promoted in their degradation. The recovered material is crushed for further processing to a predetermined size, typically 0.5 mm to 350 mm diameter. Until this time, the target material and the foreign matter in a mixture is present as a bulk material, including objects that have some foreign matter and some of the target mineral. In the case of foreign matter, a distinction is made between unusable peat and economically exploitable minerals. For an economic reuse of the target minerals, it is first necessary to separate out those objects from the mined material that consist entirely or partially of the target mineral.

This is from the DE 195 04 932 A1 known to feed the conveyed objects by means of a conveyor belt to a sorting unit, wherein the objects are distributed over the entire width of the conveyor belt and separated there, and wherein the objects form a flow of bulk material, which is on leaving the conveyor belt in a free fall. These objects falling freely in the flow of bulk material are exposed to visible light and the light reflected by the objects then has a certain color which is detected by corresponding camels. By means of an evaluation unit, the received colors are then evaluated to determine at which point of the bulk material flow there is an object having a target mineral. This object is then blown out of the bulk flow with a correspondingly activated air nozzle and collected in a container provided.

To make this process economical, the target minerals must reflect a significantly different color of light than the foreign materials. Because the individual color differences are not always very large, a correspondingly clean ambient air is required for the implementation of the method, since, for example, dust, water vapor or other impurities in the air make it difficult to recognize the respective color.

Based on this, the object of the present invention is to provide a method and an apparatus for detecting a target mineral of the type mentioned at the outset in which significant differences between the target and the foreign material occur in order to achieve reliable differentiation.

As a technical solution to this problem, a detection method according to the invention with the features of claim 1, a device with the features of claim 4 and a manufacturing method with the features of claim 10 is proposed. Advantageous developments of this method and this device can be found in the respective subclaims.

A method carried out according to this technical teaching and a device designed according to this technical teaching have the advantage that when using infrared light, in particular NIR light having a wavelength of 800 nm to 10,000 nm, each mineral emits an individual IR light, which has a typical spectral property for each mineral. Thus, based on the spectral properties can be drawn conclusions as to which mineral it is. At the same time, the spectral lines of each of the individual minerals at different points have so-called peaks, that is, wavelengths of particular high light intensity. You go Now, choosing a wavelength in which the target mineral has a peak, while the other materials in the bulk material flow in this area have no peak, it can be concluded that this is due to the presence of this peak in the particular wavelength range the target mineral. The filtering of the IR light ensures that only the desired wavelength range is detected by the camera, so that the presence of a high light intensity also indicates the presence of the target mineral.

In simple terms, this means that the camera only needs to determine that there is high light intensity at a particular location within the bulk flow to indicate that it is a target mineral. Such a binary situation provides easily recognizable signals, so that such a recognition system can also be used in a dust or steam-polluting environment. It follows, inter alia, that such detection systems can be used underground in the mine with the result that the unneeded foreign matter left on site and need not be promoted to day, which in turn leads to a significant saving on production costs.

By using a line or matrix camera, it is possible to capture a broad flow of bulk material quasi online and still recognize at what point within the bulk material flow, the target mineral is present. On the basis of the recognized position of the target mineral, a compressed-air nozzle is then activated at the desired location, for example, in order to convey the object containing the target mineral from the bulk material stream into a separate container.

In an advantageous embodiment, the filter is arranged inside the camera between the objective and the photosensitive sensor. This has the advantage that also here a contamination of the filter is avoided, since this is located inside the camera body.

In a preferred embodiment, it has proven to be advantageous to form the frequency range not greater than 50 nm, but preferably only 30 nm. It has been found that such a narrow frequency range is sufficient to detect the peak in the spectral range of the target mineral. Another advantage of this narrow frequency range is that unwanted secondary peaks are not detected.

Ideally, the frequency range is determined by determining the half width of the peak. The half-width is that area of the peak at which half the maximum light intensity of the peak is reached.

In a particularly preferred embodiment, the light source is designed as a quartz tube light source. This has the advantage that in this way a linear light source is used, which emits its light at least over a larger part of the width of the bulk material flow.

In a very preferred embodiment, two or even four such quartz tube light sources are used, which are located around the bulk material flow around.

In another preferred embodiment, four light sources are arranged around the bulk material flow, with two Light sources above and two light sources are provided below the camera plane, and wherein two light sources are provided on this side and two light sources beyond the bulk material flow. This is accompanied by the use of two different cameras, so that the bulk material flow is captured on both sides of the camera as well as on the other side. This has the advantage that, as a result, such objects are also assigned to the target minerals, which only partially consist of target minerals and whose other part consists of a foreign material. When using only a single camera, there is a risk that only the foreign material is detected, so that this object can not be detected and thus can not be used economically.

When using three or four cameras, preferably in a plane around the bulk flow, the accuracy of the detection is further increased accordingly.

In a further preferred embodiment, the light source is designed to emit this polarized light of an adjustable vibration level. This has the advantage that in this way the contrast of the light signals is increased, so that an even better recognition is possible. It has proven to be advantageous to adapt the vibration level to the respective detection process in order to achieve optimum results.

The inventive method and apparatus of the invention can be used not only for gemstones such as diamonds or the like. Or talc, but also in borates (drilling salt) such. Colemanite or other minerals that are infrared active.

Further advantages of the method and the device according to the invention will become apparent from the attached Drawing and the embodiments described below. Likewise, according to the invention, the above-mentioned features and those which are still further developed can be used individually or in any desired combinations with one another. The mentioned embodiments are not to be understood as an exhaustive list, but rather have exemplary character. Show it:

Fig. 1 a schematic representation of the device according to the invention in side view;

Fig. 1 the device according to Fig. 1 in front view.

In the Fig. 1 and 2 is shown in a schematic representation of an apparatus for detecting an object containing a target mineral, wherein a plurality of objects of different minerals via corresponding conveyor belts 10, 12 are supplied. On these conveyor belts 10, 12, a plurality of objects 14 is arranged, which are distributed over the entire width of the conveyor belt 10, 12. The individual objects 14 may have a size up to 350 mm in diameter, but may also only have a diameter of 0.5 mm. The objects 14 on the conveyor belts 10 and 12 are sorted in such a way that only objects of similar size are used simultaneously, wherein the scattering should not exceed factor 3.

At the end of the conveyor belt 12 fall the individual objects 14 in a bulk flow 16 of this down and are from now on in free fall. In this case, the flow of bulk material of a curvature or parabola line, the course of which strongly depends on the speed of the objects 14 and the inclination of the conveyor belt 12.

At a certain distance from the conveyor belt 12, a predetermined area 18 is selected around which four near infrared (NIR) light sources 20 are arranged. In this case, two light sources 20 are arranged above and two light sources 20 below the predetermined range, while two light sources 20 are arranged on the right and two light sources 20 to the left of the bulk material flow 16.

Orthogonal to the predetermined area 18, a virtual camera plane 22 is provided, in which two lines. or matrix cameras 24 are provided. Inside the camera 24, a filter not shown here is installed between the lens and the photosensitive sensor. Both cameras 24 are connected to an evaluation unit 26, which in turn is connected to an evaluation unit not shown here. The evaluation unit is connected to a number of nozzles 28, with which selected objects 14 can be conveyed out of the bulk material flow 16.

The evaluation unit evaluates the signals coming from the evaluation unit 26, at which point of the width of the bulk material flow 16 is an object containing a target material 14 and activates the associated nozzle 28, so that the target object 14 blown out of the bulk flow 16 and in a container 30 is collected. All other objects 14 pass through the nozzles 28 and fall into another container 32.

The method for detecting an object 14 containing a target mineral is described in more detail below: Minerals such as diamonds, borates, colemanite, talc or the like are infrared active. That is, these minerals are excited by the reception of IR light, especially NIR light and emit their own IR light with an individual spectral profile. That is, each mineral mimics NIR light with peaks (high-intensity wavelength band) in another wavelength range. Thus, by making a spectral analysis, one can find out in which wavelength range, e.g. B. Colemanit, peaks, ie high light intensity points, has. Performing such a spectral analysis for all or almost all minerals and other materials within a bulk flow, then a wavelength range can be found by differential analysis, in which only the target mineral, here colemanite, has a peak, while the other minerals in this wavelength range even have no or at least no significant peak. If such a wavelength range is found, then a filter, in particular a bandpass filter is created, which passes only the found wavelength range of the NIR light.

It goes without saying that such a spectral analysis does not necessarily have to be carried out for all minerals of the bulk material flow, however, the precision of the sorting increases as more minerals are detected by spectral analysis. It is also possible that in the bulk material in addition to minerals (crystalline structure) other materials such. As inorganic substances, substances with amorphous structures, plastics or the like, are present. Here, too, the same applies as before, d. H. it is not detrimental to carrying out the process according to the invention if other foreign materials than minerals occur in the bulk material flow, but it increases the sorting quality, even if these other materials are infrared-active or are sorted out in other ways beforehand.

The objects to be examined 14 are transported by a conveyor belt 12 and leave the conveyor belt 12 in a free fall. In a camera level 22 is on each side of the Schüttgutstromes 16 each arranged a camera 24. In this camera 24, the filter not shown here between the lens and the photosensitive sensor of the camera 24 is arranged.

The IR light emitted by the light sources 20 impinges on both sides of the bulk material flow 16 in a predetermined region 18, the individual objects 14 of the bulk material flow 16 being exposed to IR light from four different directions. The objects 14 each emit an individual IR light, which is detected by the cameras 24. By filtering out the IR light to a small wavelength range of preferably 30 nm, but at most 50 nm, it is achieved that the camera 24, if present, perceives only the peak of the target mineral as a bright spot of light. That is, for each location in the predetermined area 18 of the bulk material flow 16, the camera 24 can determine by means of the light sensor whether there is light or not, which is why it can be determined very reliably via the evaluation unit 26, whether at the relevant point containing a target mineral Object is or is not.

When using a line or matrix camera, it is possible to scan the bulk material flow 16 line by line or matrix and by the binary detection system, it is easily possible to assign a specific point on the photosensitive sensor a certain point within the bulk flow, so that the evaluation unit Activate nozzle 28 to blow out the target object 14 from the bulk material flow 16.

The wavelength range is determined by the size and the course of the peak, with the beginning and the end of the wavelength range corresponding to the point at which the peak has just half its light intensity.

Claims (12)

Method for detecting an object (14) containing a target mineral from a bulk material stream (16) in freefall from a plurality of objects (14) of different materials, wherein the object (14) falling past a predetermined region of the bulk material stream (16) being exposed to light and wherein the light coming back from the objects (14) is detected by a line or matrix camera (24) and supplied to an evaluation unit (26),
characterized,
in that the objects (14) are exposed to IR light, preferably to NIR light, in such a way that the IR light is filtered by means of a filter such that only a predetermined frequency range of the IR light is transmitted so that the predetermined frequency range corresponds to that frequency range in that the IR light returned by the target mineral has a higher light intensity than the returned IR light of the other materials, that the thus filtered IR light from the line or matrix camera (24) detected and the evaluation unit (26) is supplied and that the evaluation unit (26) emits a signal as soon as the light intensity of the detected IR light exceeds a predetermined limit value. Method according to claim 1,
characterized,
that infrared light (NIR light) is used as the IR light. Method according to one of the preceding claims,
characterized,
that the camera (24) transmits the returned IR light of the whole,
detected predetermined area (18). Device for detecting an object (14) containing a target mineral from a bulk material flow (16) comprising a plurality of objects (14) of different materials, with a light source (20) acting on a predetermined region of the bulk material flow (16) with a line or matrix camera (24) for detecting the light returning from the objects (14) and with an evaluation unit (26) for evaluating the detected light,
characterized,
in that the light source (20) emits IR light, preferably NIR light, that a filter is provided which transmits only a predetermined frequency range of the IR light, the predetermined frequency range corresponding to the frequency range in which the IR emitted from the target mineral Light has a higher light intensity than the returned IR light of the other materials. Device according to claim 4,
characterized,
that two, three or four cameras (24) are arranged in a plane around the predetermined area, preferably equidistantly. Device according to one of claims 4 to 5,
characterized,
that the filter is designed as a bandpass filter. Device according to one of claims 4 to 6,
characterized,
that the filter has a frequency range of the IR light of a maximum of 50 nm, preferably 30 nm. Device according to one of claims 4 to 7,
characterized,
that the light source (20) is formed as a quartz tube light source. Device according to one of claims 4 to 8,
characterized,
in that the light source (20) emits polarized light of an adjustable vibration plane. Method for producing an apparatus for detecting an object (14) containing a target mineral from a bulk material flow (16) in freefall from a multiplicity of objects (20) of different materials, in particular according to one of claims 4 to 9, with the following steps : A: performing a spectral analysis for essentially all minerals in the bulk material; B: making a difference analysis and determining a frequency range in which the target mineral emits IR light with a higher light intensity than the IR light emitted by the other minerals; C: Providing a filter that passes only the detected frequency range of the IR light; D: providing a photosensitive device that determines the light intensity of the detected IR light; and E: Provision of an evaluation unit (26). Method according to claim 10,
characterized,
that the following step follows at step D: F: Determine the half width of the peak and set this half width as the frequency range. Method according to one of claims 10 to 11,
characterized,
that step E is carried out as follows: E1: providing an evaluation unit (26) which determines the light intensity of the detected IR light, compares this value with a predetermined limit value and transmits a signal as soon as the limit value is exceeded.

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