JP2017080732A - Ore screening method and device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable screening of ore with compact equipment constitution by needing no complicated carrying control.SOLUTION: There is provided an ore screening device for screening nondefective 1a and defective 1b of ore previously decided by inclusion ratio of a target mineral from ground rock 1. The device comprises: a feeder 2 feeding the ground rock 1 by dropping on a predetermined fall trajectory w; an imaging instrument 3 imaging the ground rock 1 fed by the feeder 2 on the way to the drop trajectory w; a screening unit 4 screening the nondefective 1a and defective 1b from among the ground rock 1 on the basis of an imaging result by the imaging instrument 3; and an air blowing apparatus 5 blowing air toward any one object of the nondefective 1a and defective 1b of the ore from a direction crossing with a gravity direction to differentiate the fall trajectories w of the nondefective and defective of the ore dropped below the imaging position by the imaging instrument 3 based on the screening result by the screening unit 4.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an ore sorting method for sorting out ore non-defective / defective products from crushed rocks, and more particularly to an ore sorting method and apparatus for sorting out ore non-defective / defective products during the fall of a rock crushed material.

As a conventional ore sorting method, for example, gold ore as an object to be sorted, the gold ore is crushed and then pulverized to an appropriate particle size, and the obtained ore is suspended in a cyanide aqueous solution. A method of separating and concentrating gold from gangue minerals and sulfide minerals by so-called bluening method that leaches gold, and further separating and concentrating gold minerals from gangue minerals and sulfide minerals by specific gravity flotation and flotation. The method of separating and concentrating gold is used.
However, in order to carry out these methods, the ore has to be pulverized from several tens of microns to several hundreds of microns, which requires enormous energy. In other words, the ore as it is mined contains a lot of host rock mass that contains almost no gold and silver, and pulverizing such host rock into such fine particles consumes much energy. Will do. In addition, since the host rock contains a lot of clay minerals, it is generally well known that clay minerals have an adverse effect on any of the methods of bluening, copper refining, and flotation. It is.

Originally, quartz containing gold and silver is white, and can be easily distinguished from a gray or black mother rock by visual observation. Therefore, as a method of removing the host rock from the coarsely crushed material, automatic sorting by an ore sorter that performs optical inspection and discriminates whether or not the host rock is known is known.
The ore sorting apparatus as described above, for example, as described in Patent Document 1, conveys articles at a high speed with a belt conveyor at a high speed, jumps out from a pulley end of the belt conveyor, and jumps out of the pulley end. It is possible to apply a technique for selecting the quality of an article by inspecting an image in a horizontal flight state immediately after that, and by using an air nozzle row in which the determination result is controlled by a solenoid valve, and changing the trajectory of the falling flight.

Moreover, although the selection object is not an ore, what is described in patent documents 2-4 is already known as a grain sorter, for example.
Patent Document 2 discloses that different kinds of mixed grains supplied from a vibration supply device via fluency are passed through a gap of a photoelectric device formed by a light source and a light receiving element with a substantially constant trajectory. The light receiving element receives the light beam transmitted from the light source to the mixed grain through the grain, and is provided at a position where the grain passing through the gap can be blown from the signal of the light receiving element depending on the amount of light. There is disclosed a grain color sorting device in which an electromagnet control device for opening and closing a blower tube opening / closing valve and a light receiving element are connected.

Further, in Patent Document 3, a vibration supply rod is provided on the conveying start end side of the conveying belt for raw material which is horizontally arranged by a pair of rollers, while the vicinity of the locus of the raw material falling from the conveying terminal end of the conveying belt. And a color sorter for a granular material in which an ejector that is operated by a signal from a control unit that communicates with the detection unit is arranged on the locus, and the conveyance surface of the conveyance belt is arranged on the conveyance end side. Further, there is disclosed a granular material color sorter that is provided so as to be inclined so that the conveyance start end side is higher.
Furthermore, in Patent Document 4, a rotary valve is provided immediately below the raw material supply hopper and the reselection hopper, and a belt conveyor is disposed on a horizontal plane below the rotary valve. A grain sorter is disclosed that is discharged from a belt conveyor onto a belt conveyor, transported, and dropped freely from a terminal portion to be supplied to an inspection / sorting position.

JP 2008-55274 A (Best Mode for Carrying Out the Invention, FIG. 1) JP 55-56874 A (Detailed description of the invention, FIG. 2) JP-A-8-108146 (Example, FIG. 1) JP-A-9-122606 (Embodiment of the Invention, FIG. 3)

However, for example, in Patent Document 1, since it is a method of selecting the quality of the ore that is an article by horizontal flight by high-speed conveyance, it is necessary not only to secure a wide installation space for the apparatus in the horizontal direction. In addition, it is necessary to control the conveyance of the ore so that it flies horizontally with respect to the horizontal distance between the image inspection camera and the air nozzle array.
Furthermore, in Patent Document 1, when ores are supplied and transported in a dense state on a belt conveyor in order to earn a processing amount, the ores may overlap each other, and if they overlap each other, they are hidden below. Ore will not appear in the image, and ore sorting performance will drop. Also, if the ores do not overlap but are next to each other, shooting with an air nozzle increases the probability of shooting down to ores that should not be shot, resulting in reduced beneficiation performance. Therefore, it is necessary to transport the ores in a scattered state so that the ores are not adjacent to each other and do not overlap, and there is a concern that it is difficult to earn a processing amount.

Moreover, in patent documents 2 and 3, although it is a system which sorts a grain based on the permeation information of a grain and blows away a different kind of grain, the grain is comparatively sized and is fluent. The falling speed, the falling trajectory, and the rotational speed at the time of falling are stable even when sliding and dropping, but the rock crushed material containing the ore that is the subject of selection of this application is not the same size and shape If the same method is adopted, the sliding speed of fluency may not be stable due to the difference in sliding resistance, or it may slide down as if rolling. Is likely to be unstable, and there is a concern that the sorting performance of the ore is lowered.
Moreover, in patent document 4, a grain can be regularly and uniformly sent stably to a test | inspection position, and also the supply amount of the grain sent to a test | inspection position can be changed. Thereby, it is possible to efficiently inspect and select whether or not the grain is defective. However, it is difficult to adopt the same method as it is because the pulverized rocks containing the ores that are the selection targets of the present application are not uniform in size and various in shape.

  A technical problem to be solved by the present invention is to make it possible to sort ore without a complicated transport control with a compact equipment configuration.

  In the invention according to claim 1, when selecting a non-defective product or a defective product of the ore predetermined by the content ratio of the target mineral from the crushed rock, the crushed rock is dropped with a predetermined fall trajectory. An ore out of the rock pulverized material that has undergone the imaging step based on the imaging result of the imaging step, and the imaging step of imaging the rock pulverized material supplied in the supplying step in the middle of the fall trajectory A sorting process of blowing air from the direction intersecting the direction of gravity toward either one of the objects so as to sort out the non-defective / defective products of the selected ore, and to change the falling trajectory of the selected good / defective products of the ore, Ore sorting method characterized by comprising:

  The invention according to claim 2 is an ore sorting device that sorts non-defective / defective products of ores predetermined from the rock pulverized material by the content ratio of the target mineral, and the rock pulverized material has a predetermined fall trajectory. A supply device that is supplied so as to be dropped, an imaging device that images the rock crushed material supplied by the supply device in the middle of the fall trajectory, and the rock pulverized material based on the imaging result of the imaging device Either a discriminating device for discriminating between non-defective or defective products of ore and a different orbit of the ore that has fallen below the imaging position by the imaging device based on the discrimination result by the discriminating device. An ore sorting apparatus comprising: an air blowing device that blows air from a direction crossing the direction of gravity toward one of the objects.

The invention according to claim 3 is the ore sorting device according to claim 2, wherein the supply device is circulated and moved over a plurality of stretching rolls, and conveys the rock crushed material, The portion of the belt-like transporter that is stretched over the stretch roll positioned at the downstream end in the transport direction has a curvature that is close to the curvature of the peripheral surface of the portion of the rock that has been stretched over the stretch roll. And a driving device that drives the belt-shaped transport body at a predetermined transport speed so as to convey a fall locus without slipping at a contact portion with the belt-shaped transport body. It is an ore sorter.
According to a fourth aspect of the present invention, in the ore sorting apparatus according to the second aspect, the discriminating device extracts the grayscale information resulting from the ore from the imaging result of the rock pulverized material, and the ratio of the grayscale information is predetermined. It is an ore sorter characterized by discriminating that the ore is a non-defective product when it is equal to or greater than the threshold value.
The invention according to claim 5 is the ore sorting device according to claim 2, wherein the discrimination device is based on a result of imaging by the imaging instrument, and a time at which the air spray target is sprayed and a direction of gravity of the air spray target. The ore sorting apparatus is characterized in that the air blowing time by the air blowing device is adjusted by calculating the projected area facing the surface.
The invention according to claim 6 is the ore sorting apparatus according to claim 2, wherein when the size of the crushed rock is within a range between a predetermined minimum dimension and a maximum dimension, the air blowing device It is an ore sorter characterized in that nozzles that are individually sprayable and have a diameter smaller than the minimum dimension are arranged in parallel in a horizontal direction at a pitch less than the minimum dimension.
The invention according to claim 7 is the ore sorting device according to claim 2, wherein the air spraying device has nozzles capable of spraying air in parallel in the horizontal direction and has a plurality of stages in the direction of gravity. Ore sorting device.
The invention according to claim 8 is the ore sorting apparatus according to claim 2, wherein the air spraying device blows air to one of the non-defective or defective ore objects. The ore sorting device is characterized in that air is blown so as to generate a blowing force component directed upward.
The invention according to claim 9 is the ore sorting device according to claim 2, wherein the air blowing device blows air onto one of the non-defective or defective ore objects, and the gravity of the air blowing target object An ore sorter characterized in that air is blown over a majority region of a projection surface facing in a direction.

According to the first aspect of the present invention, a non-defective product or a defective product can be selected with a compact equipment configuration without requiring complicated conveyance control.
According to the second aspect of the present invention, it is possible to embody an ore sorting method that can sort out non-defective or defective ore with a compact equipment configuration without requiring complicated conveyance control.
According to the third aspect of the present invention, the crushed rock can be supplied to the ore imaging / sorting stage along a stable fall trajectory from the downstream end in the transport direction of the belt-shaped transport body.
According to the invention which concerns on Claim 4, in the aspect in which the ore which is a selection object has a light and dark characteristic, the quality goods and inferior goods can be discriminate | determined correctly.
According to the invention which concerns on Claim 5, the spraying of the air with an air spraying tool can be implemented without waste with respect to the air spraying target object.
According to the invention which concerns on Claim 6, the spraying of the air by an air spraying tool can be implemented reliably, without affecting the size of a rock ground material.
According to the invention which concerns on Claim 7, compared with the aspect which has a nozzle row | line | column, it can ensure many blowing amounts of the air by an air blowing instrument.
According to the invention which concerns on Claim 8, many flight distances of the air spraying target object can be ensured with the spraying of the air by an air spraying tool, and the selection accuracy of the non-defective product / defective product is improved correspondingly. be able to.
According to the ninth aspect of the present invention, it is possible to ensure a large amount of air sprayed by the air spraying tool against the air spray target.

It is explanatory drawing which shows the outline | summary of embodiment of the ore sorting method and its apparatus with which this invention was applied. It is explanatory drawing which shows the whole structure of the ore sorting apparatus which concerns on Embodiment 1. FIG. It is explanatory drawing which shows the principal part of the ore sorting apparatus which concerns on Embodiment 1. FIG. 3 is an explanatory diagram showing a control system of the ore sorting apparatus according to Embodiment 1. FIG. 3 is a flowchart showing an ore sorting process according to the first embodiment. (A) is explanatory drawing which shows the method of discriminating whether it is an ore from the imaging result by a camera, (b) is explanatory drawing which shows the discrimination example from the imaging result by a camera. (A) camera, velocity _v of the ore pass in front of the nozzle array (v _{1, v} 2), explanatory view showing a calculation example of the drop elapsed time _{t (t 1, t 2)} , by (b) the camera It is explanatory drawing which shows the calculation example of the magnitude | size of an ore from an imaging result, (c) is explanatory drawing which shows the calculation example of the air spraying time by a spray nozzle. (A) is explanatory drawing which shows the behavior of the ore accompanying the blowing of the air by a blowing nozzle, (b) is explanatory drawing which shows typically the blowing operation of the air by the blowing nozzle accompanying the fall of an ore. It is explanatory drawing which shows the principal part of the ore sorting apparatus which concerns on Embodiment 2. FIG. (A) is explanatory drawing which shows an example of the air blowing operation | movement by the 2 row type blowing nozzle used in Embodiment 2, (b) shows the other example of the air blowing operation by the blowing nozzle. Explanatory drawing, (c) is explanatory drawing which shows typically the spraying operation | movement of the air by the 2 row type spray nozzle accompanying the fall of an ore. (A) is explanatory drawing which shows an example of the air blowing operation | movement by the 3 row type spray nozzle used by the deformation | transformation form, (b)-(d) is another of the air blowing operation | movement by the same spray nozzle. It is explanatory drawing which shows an example. (A) is explanatory drawing which shows the behavior of the ore dropped from the belt conveyor in the ore sorting apparatus which concerns on Example 1, (b) is explanatory drawing which contrasted the behavior of the ore at the time of the fall by a belt conveyor system and a vibration feeder system. It is. It is explanatory drawing which shows the relationship between the fall time of the ore which falls from a belt conveyor in the ore sorting apparatus which concerns on Example 1, and the conveyance speed of a belt conveyor. It is explanatory drawing which shows the relationship between the jumping-out amount of the ore falling from a belt conveyor in the ore sorting apparatus which concerns on Example 1, and the conveyance speed of a belt conveyor. It is explanatory drawing which shows the relationship between the rotation amount of the ore falling from a belt conveyor in the ore sorting apparatus which concerns on Example 1, and the conveyance speed of a belt conveyor. It is explanatory drawing which shows the simulation of the fall locus | trajectory of the ore from the conveyor front-end | tip in each conveyance speed of the belt conveyor (roll diameter: 200 mm) used in Example 1. FIG. It is explanatory drawing which shows the simulation of the fall locus | trajectory of the ore from the conveyor front-end | tip in each conveyance speed of the belt conveyor (roll diameter: 300 mm) used in Example 1. FIG. It is explanatory drawing which shows distribution of the flight distance accompanying the air spraying in the ore sorting apparatus (head 550mm from a belt conveyor conveyance surface to an air spraying position) which concerns on Example 2-1. It is explanatory drawing which shows distribution of the flight distance accompanying the air spraying in the ore sorting apparatus (head drop 750mm from a belt conveyor conveyance surface to an air spraying position) which concerns on Example 2-2. It is explanatory drawing which shows distribution of the rotation amount of the ore in the head 550mm in the ore sorting apparatus which concerns on Example 2-1. It is explanatory drawing which shows distribution of the rotation amount of the ore in the head 750mm in the ore sorting apparatus which concerns on Example 2-2. It is explanatory drawing which shows the change of the flight distance accompanying the difference in the air blowing conditions in the ore sorting apparatus which concerns on Example 3. FIG. It is explanatory drawing which shows the change of the fall angle of an ore with the difference in the air blowing conditions in the ore sorting apparatus which concerns on Example 3. FIG.

Outline of Embodiment FIG. 1 shows an outline of an embodiment of an ore sorting method and apparatus to which the present invention is applied.
In the figure, the ore sorting method is performed by sorting the rock pulverized material 1 from the rock crushed material 1 in advance to select the non-defective product 1a and the defective product 1b of the ore predetermined by the content ratio of the target mineral. Supply step A to be dropped at step S, imaging step B for imaging the rock crushed material 1 supplied at the supply step A in the middle of the fall trajectory w, and imaging step B based on the imaging result of the imaging step B In order to select the good ore 1a and defective 1b of the ore from the crushed rock 1 that has passed through, the falling trajectories w (w1 and w2 in this example) of the selected ore good 1a and defective 1b are made different. And a sorting step C in which air is blown from the direction intersecting the direction of gravity toward one of the objects (the good ore 1a is illustrated in FIG. 1).

In this example, the selection method of the non-defective product 1a / defective product 1b is that the threshold value of the content ratio of the target mineral in the ore is determined in advance, the ore above the threshold value as the non-defective product 1a, and the ore below the threshold value as the defective product 1b It is what is selected.
Here, the supply process A is typically a mode in which the rock pulverized material 1 is fed out and dropped by a belt conveyor system at a predetermined speed and supplied to the sorting stage.
Moreover, as the imaging process B, what is necessary is just the process which image | photographs the ore in the middle of a fall as an image using the imaging device 3, and you may image from not only the imaging from one direction but from several directions.
Further, as the sorting process C, the ore non-defective product 1a and the defective product 1b to be sorted are sorted through the imaging process B, and the falling trajectory w is changed by blowing air on one of the objects, thereby the good ore product. What is necessary is just to physically sort 1a / defective product 1b. In this case, it is permissible to select the non-defective product 1b or the defective product 1b as the target of spraying. However, depending on which ratio is higher among the objects to be sorted, the one with the lower ratio is blown. It is preferable to attach it. The reason for this is that the smaller the ratio of the objects to be sprayed, the smaller the amount of air sprayed, which makes it possible to reduce the load on the compressor for air compression.

As shown in FIG. 1, the ore sorting device embodying the ore sorting method sorts the ore non-defective product 1a and defective product 1b determined in advance from the crushed rock 1 by the content ratio of the target mineral. An apparatus for supplying the rock crushed material 1 so as to drop the rock crushed object 1 with a predetermined fall trajectory w, and imaging for imaging the rock pulverized material 1 supplied by the supply apparatus 2 in the middle of the fall trajectory w. An imaging device 3, a discrimination device 4 that discriminates a non-defective product 1 a or a defective product 1 b from the crushed rock 1 based on the imaging result of the imaging device 3, and an imaging by the imaging device 3 based on the discrimination result by the discrimination device 4 Air from the direction intersecting the direction of gravity toward one of the objects so that the falling trajectories w (w1, w2 in this example) of the non-defective product 1a and the defective product 1b of the ore falling below the position are different. Blowing air And with the instrument 5, it is those with a.
In FIG. 1, reference numeral 8 denotes a sorting container for sorting and storing the ore non-defective product 1 a or the defective product 1 b, and includes, for example, an ore non-defective product 1 a storage region R 1 and an ore defective product 1 b storage region R 2. The structure is divided by a partition wall.

In such technical means, the discriminating device 4 recognizes that the ore is a good product 1a or a defective ore 1b based on the imaging result of the imaging device 3, and thereby the good ore product 1a. -What is necessary is just to identify the inferior goods 1b. The discrimination method here is based on the characteristics of the minerals in the ore, for example, for minerals having concentration characteristics, pay attention to the density information, and a method of selecting the mineral ratio from this density information can be mentioned. A mineral having color characteristics may be selected as appropriate by paying attention to color information and selecting a mineral ratio from this color information.
Moreover, as the air spraying instrument 5, the rock pulverized material 1 that has fallen below the imaging position is a target to be sprayed, and the spraying direction intersects with the direction of gravity (in addition to the horizontal direction, the direction inclined with respect to the horizontal direction). As long as it is included).

Next, a typical aspect or a preferable aspect of the ore sorting apparatus in the present embodiment will be described.
First, as a typical embodiment of the supply device 2, as shown in FIG. 1, a belt-like carrier 6 that circulates and moves over a plurality of stretch rolls and conveys the crushed rock 1, and a belt-like carrier. In the portion that is stretched over the stretch roll 9a located at the downstream end in the transport direction of the body 6, the fall trajectory w having a curvature close to the curvature of the peripheral surface of the portion where the rock crushed material 1 is stretched over the stretch roll 9a. And a driving device 7 that drives the belt-shaped transport body 6 at a predetermined transport speed v so that the belt-shaped transport body 6 is transported without slipping at a contact portion with the belt-shaped transport body 6.
This example is an aspect in which the crushed rock 1 is fed out and dropped by the belt-like transport body 6 having a predetermined transport speed v.
Here, when transporting the rock crushed material 1 by the belt-shaped transport body 6, the transport speed v of the belt-shaped transport body 6 is preferably adjusted within a predetermined range. In this example, the fact that the conveyance speed v of the belt-like conveyance body 6 is adjusted to a predetermined range is that the belt-like conveyance body 6 is stretched over the stretching roll 9a located at the downstream end in the conveyance direction. In the portion, the rock pulverized material 1 is conveyed without slipping at the contact portion with the belt-shaped transport body 6 while drawing a fall trajectory w having a curvature close to the curvature of the peripheral surface of the portion stretched over the stretch roll 9a. The condition was to show behavior.
Assuming that the conveyance speed v of the belt-shaped transport body 6 exceeds a predetermined range, the rock pulverized material 1 has a large horizontal speed component at the downstream end of the belt-shaped transport body 6 in the transport direction. Fly in state. In this state, the falling trajectory w of the rock pulverized material 1 is obtained as stable, but since the horizontal velocity component is large, the flight distance of the rock pulverized material 1 in the horizontal direction becomes large. There is a concern that the horizontal dimension of the mineral sorting apparatus is increased.
On the other hand, when the conveyance speed v of the belt-shaped conveyance body 6 falls below a predetermined range, the conveyance speed v of the belt-shaped conveyance body 6 is slow in the portion of the belt-shaped conveyance body 6 that is stretched over the stretching roll 9a. For this reason, the rock crushed material 1 slides and moves at the contact portion with the belt-shaped transport body 6, and the falling start position of the rock crushed material 1 separated from the belt-shaped transport body 6 varies, or the belt-shaped transport body 6. There is a concern that the falling start posture of the rock pulverized material 1 that is separated from the rock is likely to vary, and the fall trajectory w of the rock pulverized material 1 is likely to be unstable.
Further, as a representative aspect of the discriminating device 4, the grayscale information resulting from the ore is extracted from the imaging result of the rock pulverized material 1, and when the ratio of the grayscale information is equal to or higher than a predetermined threshold, The mode which discriminate | determines that there exists is mentioned.
Furthermore, as a preferable aspect of the discriminating device 4, the air blowing target time and the projected area of the air blowing object facing in the gravity direction are calculated based on the imaging result of the imaging device 3. The aspect which adjusts the air spraying time by the spraying instrument 5 is mentioned. This example was calculated by calculating the spray start time of the air spray target object passing in front of the air spray device 5 and the projected area facing the direction of gravity based on the imaging result by the image capturing device 3. The air blowing operation by the air blowing device 5 may be started from the spray start time, and the air blowing operation may be continued in opposition to the size of the projected area of the air blowing object. Thus, the air blowing operation is performed on the air blowing object passing in front of the air blowing device 5 and is rarely performed on a useless area other than the air blowing object.

Furthermore, as a typical aspect of the air spraying device 5, when the size of the rock pulverized material 1 is within a range between a predetermined minimum dimension and a maximum dimension, the air spraying device 5 can spray air individually. In this case, nozzles having a diameter smaller than the minimum dimension may be arranged in the horizontal direction at a pitch smaller than the minimum dimension. When the size of the rock pulverized material 1 is determined within a predetermined range by sieving, when selecting the air blowing device 5, if nozzles having a diameter smaller than the minimum dimension are arranged in parallel in the horizontal direction at a pitch less than the minimum dimension, the minimum Even the rock pulverized material 1 having a size can be blown with air.
Furthermore, as a preferable aspect of the air blowing device 5, there is an aspect in which nozzles capable of individually blowing air are arranged in parallel in the horizontal direction and have a plurality of stages in the direction of gravity. In this example, the nozzle row has a plurality of stages, but the air blowing timing of the nozzles in each row may be the same or different. Moreover, the spraying direction may be parallel, or it may be sprayed concentrated on one place as non-parallel.
Moreover, as another preferable aspect of the air spraying device 5, when air is sprayed on either one of the non-defective products 1a and the defective products 1b, the spray force component is directed upward with respect to the air spray target. The mode which blows air so that may be generated is mentioned.
In this example, paying attention to the behavior of the falling air blowing object falling while rotating along the fall trajectory w, the rotating posture of the falling air blowing object is, for example, the upper side of the air blowing object is lower. If it comes to the attitude | position inclined so that it may approach the air spraying instrument 5 side rather than the side, the spraying force component which goes upwards with respect to a spraying target object will be given with the spraying force of air. In this case, an upward spraying force component acts on the spraying object to generate a resistance force when the spraying object falls, and accordingly, it is possible to earn a time for the spraying object to fall. It is possible to secure a large flight distance of the object associated with the air blowing by 5.
Moreover, as another preferable aspect of the air blowing device 5, when air is blown onto either the non-defective product 1a or the defective product 1b, the projection surface of the air blowing object facing in the gravity direction is used. The aspect which blows air over a majority region is mentioned. In this example, since the air spray target falls, a sufficient air spray force is required to move the target in the direction intersecting the direction of gravity. For this reason, it is preferable to ensure the air blowing area as wide as possible with respect to the spraying object, and in this example, it is a majority region of the projection surface facing the gravity direction of the air spraying object.

Hereinafter, the present invention will be described in more detail based on embodiments shown in the accompanying drawings.
Embodiment 1
-Overall configuration of ore sorting device-
FIG. 2 is an explanatory diagram showing the overall configuration of the ore sorting apparatus according to the first embodiment.
In the figure, the ore sorting device 20 has a storage container 21 in which a crushed rock containing ore (for example, gold ore) to be selected is stored, and the crushed rock is predetermined in the storage container 21. A sieve 22 for adjusting the size, for example, a maximum diameter size of 50 to 75 mm, is attached, and a water washing device (not shown) is attached. Only the crushed rock of the size of the range is passed.
In this example, a vibration feeder 23 is disposed below the sieve 22 of the storage container 21, and a belt conveyor 25 is disposed on the downstream side of the vibration feeder 23 via a guide chute 24. .

In the present embodiment, the belt conveyor 25 is, for example, a belt in which a conveyor belt 26 is circulated between a pair of tension rolls 27 and 28 so as to be able to circulate. Is a drive roll that can transmit the circulatory belt, and the conveyor belt 26 is circulated and moved.
In this example, the conveyor belt 26 is formed using a thick wear-resistant belt material (for example, elastic rubber such as ethylene or propylene containing a reinforcing material such as a steel cord or a nonwoven fabric) that can convey rocks. The surface portion is provided with an appropriate frictional resistance so that the rock crushed material introduced via the guide chute 24 is held and transported at an appropriate interval without unnecessarily rolling. It has become.
In this example, the belt conveyor 25 is adjusted by the drive motor 29 so as to convey the conveyor belt 26 at a predetermined speed vc.
In FIG. 2, the rock pulverized product G is placed on the belt conveyor 25 within a predetermined allowable width dimension. The rock pulverized product G has a non-defective Ga of the ore to be selected (in the drawing). And a defective product Gb (denoted by ● in the figure) called a so-called shear. Details of the discrimination criteria for the non-defective Ga and defective Gb of the ore here will be described later.

Further, as shown in FIGS. 2 and 3, the belt conveyor 25 drops the rock crushed material G from the tip portion of the portion that is stretched over the stretching roll 28 at the downstream end in the conveying direction of the conveying belt 26. It is made to fall along the locus | trajectory w.
A camera 30 as an imaging tool is disposed in a substantially horizontal direction at a portion facing the imaging position Q1 located in the middle of the fall trajectory w of the rock crushed material G, and further, in the vicinity of the camera 30. Are provided with one or a plurality of illumination lamps 40 for illuminating the imaging position Q1.
Further, a nozzle array 51 that is an element of the air spraying device 50 is disposed in a part of the fall trajectory w of the crushed rock G that faces the spraying position Q2 located below the imaging position Q1.
Furthermore, below the spray position Q2 on the fall trajectory w of the crushed rock G, a sorting container 70 for sorting and storing the non-defective Ga and defective Gb of the ore to be sorted is installed.
Reference numeral 80 denotes a control device that sends predetermined control signals to the camera 30, the illumination lamp 40, the air blowing device 50, and the drive motor 29 to control each element.

<Selection of conveyor speed for belt conveyor>
In the present embodiment, the transport speed vc of the belt conveyor 25 (specifically, the transport belt 26) is selected as follows.
In this example, the tension roll 28 positioned downstream in the conveyance direction of the belt conveyor 25 has a diameter d, and the conveyance belt 26 is stretched over the tension roll 28 having the diameter d and is arranged in a curved manner in a semicircular cross section. Yes.
Here, the crushed rock G is placed and conveyed on a linear portion 26a extending in the horizontal direction of the conveyor belt 26 of the belt conveyor 25, and is horizontally aligned at a site from the linear portion 26a to the curved portion 26b of the conveyor belt 26. To be released.
At this time, if the conveyance speed of the conveyance belt 26 is set to be faster than a predetermined threshold, the discharge speed of the rock pulverized material G in the horizontal direction is increased, and the rock pulverized material G is separated from the curved portion 26 b of the conveyance belt 26. I will fly in. In this case, although the fall trajectory w of the rock pulverized product G varies depending on the difference in particle size (weight), it can be obtained as a relatively stable one. However, if the discharge rate of the rock pulverized product G in the horizontal direction is too high. The horizontal flight distance of the rock crushed material G becomes large, and accordingly, it is necessary to secure the installation space for the camera 30 and the air blowing device 50 at a position sufficiently away from the belt conveyor 25. There is a concern that the size of the sorting device 20 may increase.
On the other hand, when the conveyance speed of the conveyance belt 26 falls below a predetermined threshold value, the rock crushed material G is conveyed in contact with the conveyance belt 26 until reaching the drop start position corresponding to the tip position of the curved portion 26b of the conveyance belt 26. When the transport speed of the transport belt 26 becomes extremely slow, the rock crushed material G slides at the contact portion with the curved portion 26b of the transport belt 26, and the rock crushed away from the transport belt 26. The falling start position of the object G varies, or the crushed rock G that has been slid and rolled on the curved portion 26b, and the falling start posture of the crushed rock G that is separated from the conveyor belt 26 varies, and the crushed rock There is a concern that the fall trajectory w of G tends to be unstable.
Therefore, in the present embodiment, at the curved portion 26b of the conveyor belt 26, the rock crushed material G draws a falling trajectory w having a curvature close to the curvature of the peripheral surface of the curved portion 26b, and slips at the contact portion with the curved portion 26b. The transport speed of the transport belt 26 is selected to be a predetermined transport speed vc so that the transport belt 26 is transported without being moved.
Specific examples of selection will be described in detail in the examples.

<Camera>
In the present embodiment, as shown in FIGS. 2 to 4, the camera 30 is configured by a line sensor in which imaging elements 31 such as monochrome CCDs are arranged along a horizontal direction at a predetermined pixel density interval k, and imaging is performed. The rock crushed material G falling at the position Q1 is sequentially imaged.
In this example, the camera 30 has an imaging position Q1 that is lower by h1 in the vertical direction from the horizontal position along the linear portion 26a of the conveyor belt 26 of the belt conveyor 25, and the rock crushed material G that crosses the imaging position Q1. Imaging information including the projected area and the density information of the crushed rock G is acquired. In this example, the selection object is gold ore, and gold as the target mineral is an image close to white in a monochrome image, so that it is close to white in the grayscale image within the projected area of the rock crushed material G. The ratio occupied by the image portion is the content ratio of the target mineral, and it is possible to determine whether the ore is non-defective or defective according to whether the content ratio is equal to or greater than a predetermined threshold.

<Air spray appliance>
In the present embodiment, as shown in FIGS. 2 to 4, the nozzle array 51, which is an element of the air blowing device 50, extends from the horizontal position along the straight portion 26 a of the conveyor belt 26 of the belt conveyor 25 in the vertical direction. h2 (h2> h1) is arranged to face the lower blowing position Q2, and a plurality of blowing nozzles 52 are arranged at a predetermined pitch interval p over a substantially horizontal direction. The on / off control is performed by the corresponding electromagnetic valves 53.
Here, the inner diameter u and the pitch interval p of the spray nozzle 52 may be appropriately selected. However, from the viewpoint of maintaining good air blowing to the rock pulverized material G, the minimum size of the rock pulverized material G ( In this example, it may be set smaller than 50 mm), and for example, it is set to about 8 to 20 mm (in this example, all are around 10 mm).
In this example, assuming that the nozzle array 51 has, for example, n spray nozzles 52 arranged in a line, the solenoid valves 53 corresponding to each spray nozzle 52 are divided into a plurality of stages (in this example, four stages). Are configured as solenoid valve units 54 arranged n / 4 each. And the air tank 55 in which the compressed air pressurized to predetermined pressure (for example, 0.7-1.0 MPa) is stored is provided, and this air tank 55 is connected to the flow path of each solenoid valve 53. The compressed air of the air tank 55 is supplied to the corresponding blowing nozzle 52 in accordance with the ON operation of the corresponding electromagnetic valve 53, and the blowing operation of the air by the blowing nozzle 52 is performed.
Each electromagnetic valve 53 is configured to generate an on / off signal from an electromagnetic valve driving circuit 56, and a control signal from a control device 80 is sent to the electromagnetic valve driving circuit 56.
In particular, in this example, when the control device 80 determines that the rock pulverized material G is a non-defective Ga from the imaging results of the camera 30, the control device 80 responds at the timing when the non-defective Ga of the ore passes the spray position Q2. The electromagnetic valve 53 is turned on, and the air blowing operation by the corresponding blowing nozzle 52 is performed.

<Selection container>
In the present embodiment, as shown in FIG. 2 and FIG. 3, the sorting container 70 has a storage area (in this example, the first or lower non-defective Ga / defective Gb storage area ore in the vertical direction from the spray position Q2 by h3). Storage region R1 is used as a non-defective product Ga and second storage region R2 is used as a storage region for defective products Gb), and each storage region R1, R2 is located substantially directly below the spraying position Q2. Has a partition wall 71 for partitioning.
Here, when the non-defective Ga of the ore is sprayed along with the air blowing operation by each of the spray nozzles 52, the non-defective Ga of the ore falls on a fall trajectory w1 different from the drop trajectory w2 of the defective Gb. However, as the falling trajectory w1 of the non-defective Ga of the ore, it is sufficient that the amount of projection j from the partition wall 71 is sufficiently secured so that the non-defective Ga is reliably accommodated in the determined accommodation region R1. The distance h3 from the spray position Q2 to the sorting container 70 may be selected so that the jump amount j is sufficiently secured.

-Ore sorting process-
In the present embodiment, the control device 80 has an ore sorting process program (see FIG. 5) that can sort out the non-defective Ga and defective Gb of the ore from the crushed rock G, and by executing this program The selection of the non-defective product Ga and the defective product Gb is performed.
Now, as shown in FIG. 5, when the start switch (not shown) is turned on, the ore sorting device 20 is operated, and the rock crushed material G is passed through the sieve 22 while being washed in the storage container 21, and the dimensions are within a predetermined range. After being squeezed, the rock crushed material G is supplied onto the belt conveyor 25 through the vibration feeder 23 and the guide chute 24.
At this time, the belt conveyor 25 is transported at a predetermined transport speed vc, and the rock crushed material G on the belt conveyor 25 is transported at a predetermined transport speed vc and is stretched downstream in the transport direction of the belt conveyor 25. It falls while drawing a fall trajectory w having a curvature close to the curvature of the peripheral surface of the curved portion 26b of the conveyor belt 26 along the gantry roll 28.

Then, when the rock crushed material G passes through the imaging position Q1, the camera 30 images the rock crushed material G in a state of being illuminated by the illumination light from the illumination lamp 40.
In this state, the control device 80 discriminates the non-defective product Ga / defective product Gb for the crushed rock G.
As a discrimination method used in this example, as shown in FIG. 6A, based on the imaging result from the camera 30, the occupation area Sa of the target mineral (gold in this example) in the captured image, the rock crushed material G After calculating the projected area Sb of the ore, the non-defective Ga and defective Gb of the ore are determined from the following equations.
(Sa / Sb) ≧ α (Formula 1)
Here, α indicates a ratio (for example, 30%) that allows the ore to be good quality Ga.
In this example, since quartz containing gold which is the target mineral is white, Sa is calculated based on light / dark information (corresponding to white) of an image captured by the camera 30. On the other hand, since other than the target mineral is gray or black, Sb may be calculated by calculating the total projected area of the rock crushed material G containing Sa. Specifically, the control device 80 acquires a monochrome gradation 8-bit multi-gradation (256 gradations in this example) image from the imaging result (projection area, gradation information) by the camera 30, and ternizes this image. After (white area, gray area, black area), it is determined whether or not the occupation ratio of the white area (occupation ratio of the target mineral) is greater than or equal to the threshold value α. In this case, since the black region is the background, the white region and the gray region are the whole ore as the rock pulverized product G, and the white region is gold which is the target mineral, Sa / Sb = (white region) / (white region) + Gray area).
Then, based on the calculation result of (Equation 1), for example, as shown in case 1 of FIG. 6B, the rock pulverized product G is discriminated as ore good Ga under the condition of (Sa / Sb) ≧ α. To do.
Further, as shown in case 2 in FIG. 6B, the rock pulverized product G is determined to be an ore defective product Gb under the condition of (Sa / Sb) <α (a condition in which the mineral content is low).
Further, as shown in case 3 of FIG. 6C, when Sa is substantially 0, the rock pulverized product G is determined to be an ore defective product Gb.

Next, when the control device 80 determines, for example, that the rock pulverized material G is a good ore Ga, based on the imaging result of the camera 30, at the timing when the good ore Ga passes through the spray position Q2. Corresponding spray nozzles 52 blow air against the fine ore Ga.
At this time, the imaging position Q1 and the spraying position Q2 have different falling speeds of the good ore Ga, but since the distance between them is constant, the ore good Ga that has passed the imaging position Q1 reaches the spraying position Q2. The drop time until this is fixed, and based on this, the air blowing operation timing by the blowing nozzle 52 is determined.
In this example, as shown in FIG. 5, the control device 80 performs the air blowing condition so as to perform the air blowing operation by the corresponding blowing nozzle 52 on the non-defective Ga of the ore that passes the blowing position Q2. Then, a control signal is generated based on the air blowing condition.

Here, an example of a calculation method of air blowing conditions by the corresponding blowing nozzle 52 will be described.
In this example, as the air blowing conditions, the size of the ore and the elapsed time from the imaging position Q1 to the spraying position Q2 are calculated based on the imaging result by the camera 30, and the air spraying operation by the corresponding spraying nozzle 52 is performed. And calculating the air blowing time according to the ore size.
(1) Ore speed and time at imaging position Q1 and spraying position Q2 In this example, as shown in FIG. 7A, imaging position Q1 is set downward by h1 in the vertical direction from the ore fall start position. The spray position Q2 is set downward by h2 (h2> h1) in the vertical direction from the ore fall start position.
The information h1 and h2 are input in advance in the memory of the control device 80. The control device 80 uses the information h1 and h2 to use the speed v1 at the imaging position Q1 and the elapsed time t1 from the drop start position. The ore speed v2 at the spray position Q2, the elapsed time t2 from the drop start position, and the elapsed time Δt (t2-t1) from the imaging position Q1 to the spray position Q2 are calculated and recorded in advance. In the following formula, g represents gravitational acceleration.

v1 = √ (2 · g · h1) (Formula 1)
v2 = √ (2 · g · h2) (Formula 2)
h1 = (1/2) because it is ^{g · t1 2, t1 = √} (2 · h1 / g) ...... ( Equation 3)
Since h2 = (1/2) g · t2 ² , t2 = √ (2 · h2 / g) (Equation 4)
Δt = t2−t1 = √ (2 · h2 / g) −√ (2 · h1 / g) (Formula 5)
Therefore, it is understood that the ore reaches the spraying position Q2 when Δt has elapsed after reaching the imaging position Q1, and the velocity v at that time is √ (2 · g · h2).
In this state, the control device 80 may calculate the elapsed time from the imaging position Q1 to the spray position Q2 for the ore and start the air spraying operation by the spray nozzle 52.
In this example, the method of calculating Δt using (Equation 5) is adopted. However, the present invention is not limited to this. For example, when the distance difference between h1 and h2 is short or the ore is small, imaging is performed. You may make it calculate simply by the following (Formula 5 ') using the ore speed v1 in the position Q1.
Δt = (h2−h1) / v1 (Formula 5 ′)

(2) Size of ore In this example, as shown in FIG. 7B, the ore is photographed by the camera 30 at the imaging position Q1, and a projection image facing in the direction of gravity is obtained. At this time, as described above, it is determined whether the ore is non-defective Ga or defective Gb based on the density difference information of the ore projection image. In this example, in the vertical direction of the ore projection image. indexing the uppermost position _{y max} of y, and a lowermost position _{y min,} calculates the difference between them _{L (y} max _{-y min).} At this time, in order to calculate the vertical dimension L of the projected image of the ore, for example, the number of pixels (pixels) in the vertical direction of the projected image of the ore sample (the vertical dimension is L0) whose dimensions are measured in advance is used. If it is n0, the vertical dimension L of the ore is calculated by the following (formula 6) when the number of pixels n in the vertical direction of the projection image of the ore to be imaged is counted.
L = (n / n0) · L0 (Formula 6)
For example, when L0 is 0.05 [m] and the number of pixels n0 is 2500, for example, when the number of pixels n corresponding to the vertical dimension L of the projected image of the ore is 2000, L is Calculated as 0.04 [m].
In particular, in this example, since the camera 30 is a line camera using a line sensor, the speed at the imaging position Q1 is v1 [m / s] with respect to the imaging rate f [Hz] (if it is a line camera, Since the line rate for each line is constant, the pixel resolution B [m / pixel] can be calculated by B = v1 / f [m / pixel]. Therefore, the uppermost position y _max in the vertical direction y of the projected image of the ore, and the number of pixels up to the lowermost position y _min and n [pixel], the vertical direction of the ore dimension L the following (formula 6 ′).
L = B · n (Formula 6 ')

(3) About adjustment of air blowing time by spray nozzle In the calculation process of (1) described above, the start point of air blowing by the spray nozzle 52 and the ore velocity v2 at the spray position Q2 are recognized. In the calculation process (2), the vertical dimension L of the projection image of the ore is recognized as a parameter of the ore size.
In this example, the control device 80 performs the following (formula 7) so that the ore of the dimension L passes the spray position Q2 of the spray nozzle 52 at the speed v2 and performs the air spraying operation by the spray nozzle 52. Then, the air blowing time t _air by the blowing nozzle 52 is calculated.
t _air = L / v2 (Expression 7)
Therefore, if the control apparatus 80 starts air blowing operation from the time of the start of air blowing by the blowing nozzle 52 and continues the air blowing operation for the calculated air blowing time t _air , it is stopped. Good.
By performing such air spray control, it is possible to spray air only on the ore that should be sprayed with air (good ore Ga in this example). Since the air from the spray nozzle 52 is rarely sprayed on the non-defective product Gb), the ore sorting rate is kept good.

When the non-defective Ga of the ore falls now facing the nozzle array 51, the control device 80 recognizes the falling movement position of the non-defective Ga of the ore passing through the spraying position Q2, and the time shown in FIG. With the passage of time (t = Δt → 6Δt), an air blowing operation is performed by the blowing nozzle 52 at a position corresponding to the non-defective Ga. In FIG. 8B, the ◯ spray nozzle 52 does not perform the air blowing operation, and the ● spray nozzle 52 indicates the state in which the air blowing operation is performed.
When such an air blowing operation by the spray nozzle 52 is performed, compressed air is blown over substantially the entire projection surface facing the gravity direction of the non-defective product Ga, and the partition wall 71 of the sorting container 70 is sprayed. Are accommodated in the second accommodation region R2 via a drop trajectory w2 having a sufficient pop-out amount j. In this example, compressed air is blown over substantially the entire projection surface facing the direction of gravity of the good ore Ga, but if the compressed air is blown over the majority of the projection surface described above, The ore sorting operation can be carried out satisfactorily.
In addition, since the blowing operation of the air by the spray nozzle 52 is not performed for the ore defective product Gb, the ore defective product Gb passes through the fall trajectory w2 that is continuous with the predetermined fall trajectory w2. It is accommodated in the accommodation area R2.

In the present embodiment, as shown in FIG. 8 (a), the spray nozzle 52 blows air against the falling ore non-defective Ga while rotating in the M direction. However, when it reaches a posture in which the upper side of the non-defective Ga is inclined so as to be closer to the spray nozzle 52 side than the lower side, when the air from the spray nozzle 52 is blown to the non-defective Ga, In addition to the spraying force component Fh that pushes to the top, the upwardly directed spraying force component Fv is given. At this time, the upward spraying force component Fv acts on the non-defective Ga, so that a resistance force when the non-defective Ga falls is generated, and accordingly, the falling time of the non-defective Ga can be earned. It is possible to ensure a large flight distance of the non-defective Ga that accompanies the spraying.
Further, in the present embodiment, the ore that is the rock pulverized material G that has fallen from the belt conveyor 25 exhibits a behavior in which gravitational acceleration acts as it falls and is scattered in the falling direction. For this reason, the amount of rock crushed material G supplied onto the belt conveyor 25 may be varied so that the rock crushed material G does not overlap, and is distributed on the belt conveyor 25 as in the case of adopting the horizontal flight method. It is not necessary to supply the crushed rock G in the state.

Embodiment 2
FIG. 9 is an explanatory diagram showing a main part of the ore sorting apparatus according to the second embodiment.
In the figure, the basic configuration of the ore sorting apparatus 20 is substantially the same as that of the first embodiment, but includes an air blowing device 50 different from that of the first embodiment. Components similar to those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and detailed description thereof is omitted here.
In this example, the air blowing device 50 has two upper and lower nozzle arrays 51a and 51b. In each nozzle array 51a and 51b, the blowing nozzles 52 are arranged at predetermined pitch intervals.
In the present embodiment, the upper and lower two-stage nozzle arrays 51a and 51b, for example, as shown in FIG. 10A, perform the air blowing operation by the blowing nozzles 52 in each row at the same time (simultaneous striking method). Alternatively, as shown in FIG. 10B, a mode (time difference impact method) in which the air blowing operation by the blowing nozzles 52 in each row is performed with a time difference may be used.
In this example, when the ore non-defective Ga drops now facing the nozzle arrays 51a and 51b, the control device 80 recognizes the falling movement position of the ore non-defective Ga passing through the spraying position Q2. As the time elapses in FIG. 10C (t = Δt → 6Δt), an air blowing operation is performed by the blowing nozzle 52 at a position corresponding to the non-defective Ga. In FIG. 10C, the ◯ spray nozzle 52 does not perform the air blowing operation, and the ● spray nozzle 52 indicates the state where the air blowing operation is performed.
When such an air blowing operation by the spray nozzle 52 is performed, the ore non-defective Ga is sprayed by about twice the compressed air as compared with the first embodiment, and further from the partition wall 71 of the sorting container 70. It is accommodated in 1st accommodation area | region R1 through the fall locus | trajectory w1 with sufficient jumping amount j.

In this embodiment, the upper and lower nozzle arrays 51a and 51b are employed as the air blowing device 50. However, the present invention is not limited to this, for example, as shown in FIG. The nozzle arrays 51a to 51c have three upper and lower nozzle arrays, and the nozzles 51a to 51c are each arranged with spray nozzles 52 arranged at predetermined pitch intervals.
In this modification, the upper and lower three-stage nozzle arrays 51a and 51b are configured to simultaneously perform the air blowing operation by the blowing nozzles 52 in each row as shown in FIG. Alternatively, as shown in FIG. 11B, a mode (time difference impact method) in which the air blowing operation by the blowing nozzles 52 in each row is performed with a time difference may be used.
Further, as shown in FIG. 11 (c), the spray nozzles 52 in each row may be arranged in parallel, and a spraying operation by a parallel air flow (parallel hitting method) may be used, or FIG. 11 (d). As shown in FIG. 5, the spray nozzles 52 of each row may be arranged so as to be concentrated at one point at an angle, and a spraying operation by an air flow concentrated at one point (single point concentrated hitting method) may be employed.
As a matter of course, the air blowing device 50 may employ a nozzle array having four or more upper and lower stages.

Example 1
In this example, the performance of the ore sorting apparatus according to the first embodiment is evaluated.
In this embodiment, as shown in FIG. 12A, a rock pulverized product G containing ore is fed out and dropped from the end of the belt conveyor 25 in the transport direction.
Here, the rock pulverized material G was selected to have a shape that is easy to roll.
12A, A is a position 0.5 m below the conveying surface of the rock crushed material G of the belt conveyor 25, and B is a position 0.5 m below the A position.
tf is the drop time from A to B (fall distance), x is the amount of protrusion from the tip of the belt conveyor 25 to B (when dropped by 1 m), and θ is the amount of rotation from A to B ( Per 100 ms), and the experiment was performed several times (N = 10 times).
In this example, the tension roll diameter of the belt conveyor 25 is 200 mm, and the conveyance speed of the belt conveyor 25 is 1 m / s.
In the first comparative example, the belt conveyor 25 is not used, and it is dropped directly from the vibration feeder 23. However, the vibration condition of the vibration feeder 23 is 60 Hz, and the conveyance speed is 8 m / min. It is.
The result of the comparison item about Example 1 and Comparative Example 1 is shown in FIG.
It is understood that Example 1 has less variation than Comparative Example 1 in all comparative items, and the falling behavior of the rock crushed material G is stable.

In Example 1, the experiment was performed 20 times at each conveyance speed under the condition that the conveyance speed of the belt conveyor 25 was changed, and the variation in the drop time, the variation in the pop-out amount, and the variation in the rotation amount were examined. The results shown in FIG. 15 were obtained.
However, the variation in drop time was 700 mm to 1200 mm. In addition, regarding the variation in the pop-out amount, the drop was set to 1200 mm. Furthermore, the variation in the rotation amount was between the heads of 700 mm to 1200 mm.
FIG. 13 shows the variation in drop time.
Here, the “bite-in amount 0” means that the rock crushed material is conveyed on the belt conveyor so as to draw a fall trajectory along the curvature of the peripheral surface of the curved portion of the conveying belt that is stretched over the stretch roll. It corresponds to the case where the speed is selected, and “no bite” means that the rock crushed material is conveyed on the belt conveyor so that it draws a curvature trajectory that is less than the curvature of the curved portion stretched over the stretch roll. Corresponding to the case where the speed is selected, “With bite” means that the conveyor speed of the belt conveyor is such that the rock crushed material is conveyed with a curvature locus larger than the curvature of the curved portion stretched over the stretch roll. Corresponds to the selected equivalent.
According to the figure, it is understood that the variation in fall time is smaller in the case of “no bite” than in the case of “bite in”, and in the case of “bite in”, the “bite amount” It is understood that the variation in the drop time increases as the speed decreases with respect to the speed corresponding to “0” (1.04 m / s in FIG. 13). This means that when the conveyor speed of the belt conveyor is extremely slow, the rock crushed material slides and moves at the contact area with the curved portion of the belt conveyor when the rock crushed material rolls out from the curved portion of the belt conveyor and falls. In connection with this, it is presumed that the fall start position and fall start posture from the belt conveyor vary.
FIG. 14 shows the variation in the amount of rock pulverized material, and FIG. 15 shows the variation in the amount of rotation of the crushed rock material. In both cases, the “bite amount” is “no bite amount” and “no bite amount”. It is understood that there is less variation in the amount of rock crushed and the amount of rotation compared to the case of “with”, and when “with bite”, it is slower than the speed corresponding to “bite-in amount of 0”. It will be understood that the larger the deviation, the larger the variation in the pop-out amount and the rotation amount.
In Example 1, the tension roll diameter was changed from 200 mm to 300 mm, and the experiment was performed 20 times at each conveyance speed under the condition that the conveyance speed of the belt conveyor 25 was changed. When the variation in time, the variation in the pop-out amount, and the variation in the rotation amount were examined, a tendency similar to that in the case where the stretch roll was 200 mm was observed.

Moreover, when the fall locus | trajectory of the rock pulverized material in the part stretched over the stretch roll (belt roll diameter: 200 mm in this example) of a belt conveyor was investigated by changing the conveyance speed of a belt conveyor, the result shown in FIG. was gotten.
According to the figure, when the conveying speed of the belt conveyor is 1 m / s (speed substantially corresponding to “biting amount 0”), the fall trajectory of the rock crushed material substantially corresponds to the curvature of the curved portion of the belt conveyor. It is understood that the falling trajectory is stable. Also, when the conveyor speed of the belt conveyor is set to 1.2 m / s, for example, the falling trajectory of the rock crushed material becomes less than the curvature of the curved portion of the belt conveyor, but changes to a curvature locus close to the curvature of the curved portion of the belt conveyor. To be understood. Even in the case of “with bite”, if the bite amount is in the vicinity of 0 (for example, the conveyor speed of the belt conveyor is set to 0.8 m / s), the falling trajectory of the rock pulverized material will be the curvature of the curved part of the belt conveyor. It is understood that it becomes a close locus.
Further, when the trajectory of the crushed rock in the portion stretched over the belt conveyor stretch roll (in this example, the stretch roll diameter: 300 mm) was examined by changing the conveyor speed of the belt conveyor, the results shown in FIG. was gotten.
According to the figure, when the conveyor speed of the belt conveyor is 1.2 m / s (speed substantially equivalent to “biting amount 0”), the falling trajectory of the rock crushed material substantially corresponds to the curvature of the curved portion of the belt conveyor. It is understood that the fall trajectory is stable. Also, if the conveyor speed of the belt conveyor is set to 1.4 m / s, for example, the fall trajectory of the rock crushed material is less than the curvature of the curved portion of the belt conveyor, but changes to a curvature locus close to the curvature of the curved portion of the belt conveyor. To be understood. Even in the case of “with bite”, if the bite amount is in the vicinity of 0 (for example, the conveyor speed of the belt conveyor is set to 1.0 m / s), the fall trajectory of the rock pulverized material is the curvature of the curved part of the belt conveyor. It is understood that it becomes a close locus.
Therefore, in the case of “no bite”, that is, if the speed condition exceeds the speed of the belt conveyor corresponding to “no bite”, the rock trajectory will be stable, but the belt conveyor speed should be set faster. If it is too much, the amount of movement of the rock pulverized material along the horizontal direction will increase. From the viewpoint of reducing the amount of movement of the rock pulverized material along the horizontal direction, the speed of the belt conveyor corresponding to “biting amount 0”. It is preferable to select a speed close to.
In addition, in the case of “with bite”, the fall trajectory of the rock crushed material is close to the curvature of the curved portion of the belt conveyor near “biting amount 0”, but depending on the shape of the rock crushed material, Since there is a possibility that variations in the fall time, pop-out amount, or rotation amount of objects may increase, at the time of selecting the conveyor speed of the belt conveyor, except for “with bite”, “no bite” or “no bite” It is preferable to select the vicinity of “bite-in amount 0” as an allowable range.

Example 2
This example embodies the ore sorting apparatus according to the first embodiment. As shown in FIG. 3, as shown in FIG. 3, the air blowing position Q <b> 2 by the air blowing device 50 from the conveying surface of the rock crushed material G of the belt conveyor 25. The head h2 is changed to 550 mm and 750 mm, and the influence on the ore sorting performance (the flying distance from the partition wall of the sorting container in this example) is examined. In this embodiment, h3 = 500 mm.
FIG. 18 shows a result of carrying out 160 times 8 times for the ore which is 20 kinds of rock pulverized products G, in which air is blown by the blowing nozzle 52 for the mode of h2 = 550 mm.
Further, FIG. 19 shows a result of carrying out 160 times 8 times for ores which are 20 kinds of rock pulverized products G, in which air is blown by the blowing nozzle 52 for the mode of h2 = 750 mm. .
In FIG. 18 and FIG. 19, Pz indicates the drop position of the ore 8 when the air blowing operation by the spray nozzle 52 is not performed.

According to FIGS. 18 and 19, the flight distance (jumping amount) j as a whole is higher in the air blowing operation method at the drop of 550 mm than in the air blowing operation method at the drop of 750 mm. Is understood.
Here, when the distribution of the rotation amount of the ore up to the spray position Q2 was examined at h2 = 550 mm, the result shown in FIG. 20 was obtained.
According to FIG. 20, the median value of the amount of rotation of the ore was 95 degrees within a range of 40 degrees to 145 degrees.
Further, when the distribution of the rotation amount of the ore up to the spray position Q2 was examined at h2 = 750 mm, the result shown in FIG. 21 was obtained.
According to FIG. 21, the rotation amount of the ore has a median value of 110 degrees within a range of 50 degrees to 165 degrees.
In this way, the h2 = 550 mm aspect has an increased flying distance (jump amount) j as a whole because the ore rotation amount is optimized, and air is blown upward by the spray nozzle 52. It is speculated that this is due to the fact that the spray force component acts effectively and that the ore fall speed has slowed accordingly.

Example 3
Example 3 embodies the ore sorting apparatus according to the second embodiment, and evaluates the ore sorting performance by changing the air blowing conditions by the air blowing device 50.
In this example, ore sorting performance (flight distance j) was evaluated for the following four aspects.
(1) Single row spray nozzle Air pressure 0.7MPa
(2) Two-row spray nozzle Air pressure 0.7 MPa
Simultaneous blow method (3) Two-row spray nozzle Air pressure 1.0 MPa
Simultaneous impact method (4) Two-row spray nozzle Air pressure 1.0 MPa
Time difference impact method In addition, (1) performed the same experiment about the 1 row spray nozzle system for the comparison.

When each case was measured 10 times, the result shown in FIG. 22 was obtained.
It is understood that the distance (jumping amount) j from the partition wall of the sorting container is larger and the ore sorting performance is higher when the air blowing operation by the two-row nozzle method is performed than the one-row nozzle method. The
In the two-row spray nozzle system, it is understood that the flight distance j is larger when the air pressure is higher.
Further, it is understood that in the two-row spray nozzle method, the flight distance j is larger in the time difference impact method than in the simultaneous impact method.
In addition, in FIG. 22, Pz shows the fall position of the defective ore product on the conditions which do not implement the air spraying operation by a spray nozzle.

Further, in Example 3, the number of spray nozzles and the air pressure were changed, and the inclination angle from the spray position Q2 to the ore fall position (flying distance) was measured 30 times for each case as a fall angle. The result shown in 23 was obtained.
According to the figure, it is understood that if the air pressure is the same, the two-row spray nozzle method can obtain a larger drop angle than the single-row nozzle method.
Further, it is understood that in the one-row spray nozzle method and the two-row spray nozzle, the direction in which the air pressure is 1 MPa rather than 0.7 MPa has a larger drop angle.
In FIG. 23, the theoretical increase rate indicates the ratio of the theoretical air blowing force in each case when the air blowing force in the mode of the air pressure of 0.7 MPa is set to 1 with a single row nozzle. .

DESCRIPTION OF SYMBOLS 1 Rock pulverized material 1a Ore good product 1b Ore defective product 2 Supply device 3 Imaging tool 4 Discriminating device 5 Air blowing tool 6 Belt-like carrier 7 Drive device 8 Sorting container 9a Stretch roll A Supply process B Imaging process C Sorting process

Claims (9)

When selecting non-defective or defective ores determined in advance by the content ratio of the target mineral from the crushed rock,
A supply step of supplying the rock pulverized material so as to fall along a predetermined fall trajectory;
An imaging step of imaging the rock crushed material supplied in the supply step in the middle of a fall trajectory,
Based on the imaging result of the imaging step, either ore non-defective / defective product is selected from the crushed rocks that have undergone the imaging step, and the falling trajectory of the selected ore good / defective product is different, either A sorting process in which air is blown from the direction intersecting the direction of gravity toward one object,
An ore sorting method characterized by comprising: An ore sorting device that sorts non-defective / defective products of ore predetermined by the content ratio of target minerals from crushed rocks,
A supply device for supplying the rock pulverized material to fall along a predetermined fall trajectory;
An imaging instrument that images the rock crushed material supplied by the supply device in the middle of a fall trajectory,
A discriminator for discriminating between non-defective and defective ores from the crushed rocks based on the imaging results of the imaging instrument,
Crossing in the direction of gravity toward either one of the objects so as to make the orbits of the ore that has fallen below the imaging position of the imaging device different from the imaging trajectory of the ore based on the discrimination result by the discrimination device. An air blowing device that blows air from the direction;
An ore sorting apparatus comprising: The ore sorting apparatus according to claim 2,
The supply device is wound around a plurality of stretching rolls, circulates and transports the rock crushed material, and the stretching roll located at the downstream end in the transport direction of the belt-shaped transporting body In the portion stretched over the belt, the rock crushed material is transported without slipping on the belt-like transport body while drawing a fall trajectory having a curvature close to the curvature of the peripheral surface of the portion spanned over the stretch roll. As described above, an ore sorting device comprising: a driving device that drives the belt-like carrier at a predetermined conveyance speed. The ore sorting apparatus according to claim 2,
The discriminating apparatus extracts density information resulting from ore from the imaging result of the rock pulverized material, and discriminates that the ore is a good product when the ratio of the density information is equal to or greater than a predetermined threshold. Ore sorting device. The ore sorting apparatus according to claim 2,
The discriminating device calculates the projection start time of the air blowing object and the projected area facing the direction of gravity of the air blowing object based on the imaging result of the imaging tool, so that the air blowing by the air blowing object is performed. Ore sorter characterized by adjusting time. The ore sorting apparatus according to claim 2,
When the size of the rock pulverized material is within the range between the predetermined minimum dimension and the maximum dimension,
The ore-spraying apparatus is characterized in that air can be individually blown and nozzles having a diameter smaller than the minimum dimension are arranged in parallel in a horizontal direction at a pitch less than the minimum dimension. The ore sorting apparatus according to claim 2,
The ore-spraying apparatus is characterized in that nozzles capable of individually blowing air are juxtaposed in the horizontal direction and have a plurality of stages in the direction of gravity. The ore sorting apparatus according to claim 2,
When the air blowing device blows air onto one of the non-defective or defective ore objects, it blows air so as to generate an upward blowing force component on the air blowing object. A featured ore sorter. The ore sorting apparatus according to claim 2,
The air blowing device blows air over a majority area of the projection surface facing the gravity direction of the air blowing target object when blowing air to one of the non-defective or defective ore objects. Ore sorting device.

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