RU2151643C1 - Method of concentration of mineralized mining mass and device for realization of this method - Google Patents

Abstract

FIELD: concentration of minerals in mining industry; separation of minerals into valuable component and gangue. SUBSTANCE: sorting technological type of one is determined at stage of batch concentration by classification criterion according to preset algorithm taking into account technological type, degree of crushing and mixing; according to the data thus obtained, ores are separated into concentrate, gangue which is removed from process and class being separated. This class is subjected to lump separation making use of present lump identification algorithm which belongs to given sorting technological type. In case of change of sorting technological type of ores at batch concentration batch, present lump identification algorithm is corrected in synchronism. Device used for realization of proposed method includes conveyers for delivery of raw material to monitoring zones, three roentgenoradiometric meters; one meter is located above first conveyer and other two are shifted relative to each other in way of motion of belt for lump sorting; device is also provided with three-position selector switch "concentrate - rock - class sorted" which is mounted between conveyers. Switch and meters are connected with control unit. EFFECT: enhanced efficiency. 6 cl, 2 dwg

Description

 The invention relates to methods and devices for preliminary mechanical enrichment of minerals and can be used in the mining and processing industry for dividing the rock mass into grades according to the content of the useful component and separating waste rock.

 In geotechnology, there are known methods of batch sorting and lump separation of rock using x-ray radiometric means (V.I. Revnivtsev, T.G. Rybakova, E.P. Leman. X-ray radiometric concentration of complex ores of non-ferrous and rare metals. - M .: Nedra, 1990 ) [1]. They contribute to the development of rational and economically viable ore dressing schemes that provide certain technological indicators for the extraction, productivity and quality of the final products of enterprises. In this case, special attention is paid to the search for separation features and the algorithms by which the secondary radiation spectra recorded by the detectors are processed in order to determine the technological types and types of ores.

 So, there is a known method of x-ray radiometric sorting when solving the problem of averaging ore quality, according to which an express analysis of ore portions is carried out, the boundary content of the useful component is determined. Next, carry out piecewise ore separation, while the boundary content is regulated depending on the content of the useful component in the concentrate and dumps, which is also measured in the process of averaging (SU 1802130 A1, E 21 C 41/26, op. 1993) [2]. However, the sorting process has features associated with combining averaging and piecewise separation operations with controlled boundary contents in one process, as well as the specifics of multiple recirculation and ore separation in the process of quality averaging.

 In the method of batch sorting of rock mass according to the invention (RU 2101095 C1, B 03 B 13/00, 06/03/96 - the closest analogue) [3] it is proposed to determine the content of rock-forming elements and gold satellite elements, as well as to conduct a phase-rational analysis of ore, which determine the technological type of rock mass. According to the dependence "element content - technological type of rock mass", the classification rule is corrected when portions are addressed. The above allows sorting by technological types of rock mass.

 A device for x-ray batch and piece sorting of ores using several meters controlled by microprocessors and means for moving ores (RU 2066569 C1, B 03 B 13/06, 1996) [4]. A device for X-ray radiometric separation of mineral raw materials is also known, including a feeder, conveyors for supplying raw materials to the control and piece sorting zones, installed in series, two X-ray radiometric meters placed on both sides of the conveyor for supplying raw materials to the piece-sorting zone and, an actuator with a drive connected to the control unit, storage capacities (RU 2069100 C1, B 03 B 13/06, op. 20.11.96 - the closest analogue) [5].

 The disadvantage of this method [3] is the sorting of mineralized rock mass, focused on the separation of portions of raw materials into technological types of ores, and not including the stage of lump sorting. Moreover, the mentioned phase-rational analysis of ore is carried out only periodically, and in view of the fact that it takes considerable time, it is rarely carried out. In this regard, this method cannot be combined with lump separation, and therefore is less effective than patented. The disadvantage of the device [5] is the lack of tools that allow for batch sorting and carry out the assignment of ores to technological types.

 The objective of the patented group of inventions is to eliminate these drawbacks, namely, the possibility of efficient lump separation of rock using synchronously performed batch sorting by sorting and technological types of ores.

 The technical result of the invention is ensured by the fact that the method of enrichment of mineralized rock mass includes the formation of portions of rock mass, assessing the quality of these portions by analyzing the spectra of characteristic x-ray radiation during movement through the control zone, and separating them according to types in accordance with established classification criteria. The batch classification algorithm is preliminarily determined taking into account the technological type, the degree of crushing and mixing of the ore, which determines the sorting and technological type of ore in the portion, and if this type is a concentrate or rock, the portion is removed from the process. In addition, enrichment is carried out for pieces of the remaining sorting and technological types of ores of a given portion, for which, by recording the spectrum of characteristic x-ray radiation, they determine their belonging to a concentrate or rock according to the current algorithm for identifying pieces related to this sorting and technological type, and separate them, moreover, changing the sorting-technological type of ores at the stage of batch dressing synchronously adjusts the current algorithm for identifying pieces.

 The method may be characterized in that the construction of batch classification algorithms for rock mass and piece identification algorithms for analyzing the characteristic x-ray spectra of various sorting and technological types of ores is carried out using pattern recognition methods.

 The method can also be characterized by the fact that the spectra of characteristic x-ray radiation are recorded at different portions of the portions and pieces during their movement, and as criteria for the portions to belong to one of the sorting and technological types or to identify pieces, the differences in the mentioned spectra are used, mainly, the dispersion indicators and variations.

 The X-ray radiometric enrichment device includes sequentially installed conveyors for supplying raw materials to the control zones, two X-ray radiometric meters and a switch for unloading portions with a drive connected to the control unit with means for analyzing and processing the spectra of X-ray radiometric meters, storage tanks installed in the place of unloading of raw materials. It is equipped with a third X-ray radiometric meter installed above the first conveyor to supply portions of raw materials to the control zone, and the switch for the port unloading address is made with a three-position "concentrate - breed - sortable class" and is installed between the conveyors. Two other X-ray radiometric meters are placed on both sides of the conveyor to feed the raw materials into the piecewise sorting zone and are installed offset from each other in the direction of movement of the conveyor belt.

 The device can be characterized in that the conveyor for feeding portions of raw materials to the control zone is equipped with means for controlling the flow of mineral raw materials connected to the control unit.

 The device may also be characterized in that the control unit is based on at least one microprocessor.

The invention is illustrated in the drawings, where:
in FIG. 1 is a block diagram of a batch sorting device using a patented method;
in FIG. 2 - the algorithm of the unit for analysis and control of the device.

 The patented method of batch sorting and device for its implementation are based on the following prerequisites.

 It is known that the separation efficiency based on the X-ray radiometric method substantially depends on the technological type of ores. This concept is traditionally associated with the process of enrichment and processing. At the same time, the main features determining this type are the composition of ores and host rocks. Ores of technological types can be delineated in the bowels in the process of geotechnological mapping.

 In contrast, the concept of sorting and technological type (hereinafter referred to as STT) is associated with the efficiency of the process of their mechanical enrichment as a result of ore sorting. CTT of ore is determined not only by its properties in the natural occurrence, but also by the degree of its crushing and mixing. In this case, the main feature for isolating CTT is the degree of difference between the properties of individual pieces of rock mass. By properties, in particular, it is possible to understand the content of the useful component, crystallophysical features, etc. In turn, this depends both on the initial features of the distribution of ore mineralization in the subsoil, and on the degree of crushing of the ores and their mixing during delivery to the sorting place. So, if the average size of pieces of mineralized mass arriving for sorting is close to the average size of ore mineralization nests in their natural occurrence, then such a CTT will be quite efficiently divided into ore and waste rock in the process of x-ray radiometric sorting according to a certain classification criterion. If the sizes of the pieces of the mineralized mass do not coincide (for example, the mineralized mass is strongly crushed and mixed), then sorting by real methods is impossible. Likewise, CTT of a combination of pieces of rock mass in which pieces of different composition containing ore mineralization and pieces of waste rock differing in composition are mixed will be ineffective. Thus, the concept of CTT ore differs significantly from the concept of its technological type or grade [1].

 The essence of this invention is that at the first stage, in the process of fine-graded sorting, the CTT of the sorted rock mass is determined, and at the second stage of piecewise sorting, ore pieces (the content of the useful component is above a certain level) are separated from pieces of the host rocks. This operation is carried out using classification criteria that differ for each CTT identified in the first stage.

So, for example, it is known that for gold-bearing ore deposits, gold may contain:
- in quartz veins without sulfides,
- in sulfides in shales,
- in sulfides in dyke rocks.

 At the same time, two technological types of ores are distinguished on the spot: a) gold-quartz, b) gold-sulfide. Accordingly, they are processed according to various technological schemes.

 At the same time, we found that for the rock mass in this field several CTTs will be allocated: a) gold-quartz; b) gold sulfide in shales, c) gold sulfide in dyke rocks, d) non-sortable classes, which are finely divided and highly mixed rock mass. Belonging to the above CTT of individual portions of ore is determined at the first stage of batch sorting.

The general scheme of preparatory work for the implementation of the patented portion-piece sorting method contains three main operations:
1. The study of the characteristics of CTT ores and the construction of an algorithm for their classification based on pattern recognition methods (see Vasiliev V. I. Recognizing systems, - Kiev: Naukova Dumka, 1983) [6].

2. The study of each CTT and the construction of algorithms A ₁ , A ₂ ... A _{N for} identifying pieces for each type of CCT _i , where i = 1,2, ... N, based on regression analysis methods. At the same time, when constructing algorithms, as the criteria for the portions to belong to one of the sorting-technological types or for identifying pieces, the differences in spectra are used for both the entire portion (piece) and the portions of a given portion (piece), mainly dispersion and variation indicators. Creating a bank of algorithms.

 3. Carrying out technological tests and estimating the time of moving a single stone from a portioned sorting unit to a piece sorting unit in order to programmatically ensure synchronization of the operation of measuring and analysis tools (see below).

 The essence and principles underlying the group of inventions are explained on the block diagram of the device (see Fig. 1).

 The device comprises a hopper 10 for sortable rock mass 11, an adjustable feeder 12, which is, for example, a conveyor. There is a means 14 for determining the flow of rock mass and a means 16 of its regulation. As a means of 14 can be applied strain gauge conveyor scales, as a means of 16 - controlled vibrator.

 At the output of the adjustable feeder 12 through an intermediate element 21, for example, a chute, a three-position switch 22 for unloading portions of the concentrate - rock - sortable class is equipped with a drive 24 that provides ore supply either to the concentrate accumulator 26 or to the waste rock dump 27 or to the pickup 28, depending on the CTT characteristics established as a result of X-ray radiometric measurements and processing of the spectra. The function of the spreader 28 is to organize a piecewise ore supply to the main separator conveyor 30. The spreader 28 can be made in the form of, for example, an inclined groove provided with a vibrator. The principle of the layout is based on the organization of different speeds of the pieces on various transporting elements of the sorting device.

 At the output of the main conveyor 30, a means 32 is installed for removing pieces of waste rock in the dump 37 with a drive 34 and collecting pieces of rich ore 36 in the hopper 38.

 To carry out separation control, the system comprises x-ray radiometers 50, 61 and 62 connected to the control unit 70. In the particular case, block 70 can be implemented on the basis of microprocessors and built into blocks 50, 61 and 62. An X-ray radiometer 50 is designed to record the spectrum of characteristic x-ray radiation from a layer of sorted rock mass 11 transported in the stream by means of a feeder 12. Meters 61 and 62 , similar in principle to the operation of the characteristics of the meter 50, are displaced relative to each other in the direction of movement of the belt of the main conveyor 30 and are installed counter on both sides tera without overlapping diagrams of their orientation.

 Patented method of portion-piece sorting is as follows.

 By means of the unit 70 for controlling the parameters of the feeder 12, a portion is formed - a layer of rock mass 11 on the belt of a moving conveyor. The parameters of the movement and the thickness of the rock mass layer are controlled using the elements 14, 16 in such a way as to equalize the performance of the feeder 12 with the productivity of the conveyor 30. The portion sizes are determined during preliminary studies and the time interval t of the passage of rock mass under the meter 50 on the measuring base L. Spectra can be recorded in the accumulation mode both for the whole portion as a whole and for its individual sections or pieces, and the sizes of these sections depend on the characteristics meter IR 50, 61 and 62. The accumulation of information on meter 50 when passing a portion should be synchronized with the passage of pieces through the control zone of meters 61, 62, using, for example, benchmarks on conveying surfaces, and the layer thickness should provide the necessary representativeness of the measurements. To level the surface of the rock mass layer 11, additional devices can be used: restrictive plates, rolls, etc. (not shown in FIG.).

 The functioning algorithm of the analysis and control unit of the device is shown in FIG. 2.

With the beginning of work (p.100), the system parameters are tuned, the corresponding algorithms are sent (for example, Algorithm A ₁ to the block (p. 109), and the current number i = 1 for CCT _i is assigned to the block (p. 106)).

 Next, the registration of the characteristic x-ray spectra begins (paragraph 101) (hereinafter referred to as the “spectrum”) for a portion of the rock mass. The measurement is carried out by means of an x-ray meter 50, and the accumulation of information is carried out during the mentioned duration t. Next, the characteristics of the CTT are calculated using the classification algorithm for ore grades (paragraph 102) and the decision operation (paragraph 103).

 In the event that the rock mass of the portion is recognized as satisfying the conditions of the further redistribution, then block 70 instructs the drive 24 to direct the portion of the rock mass 11 to the concentrate storage device 26 (paragraph 104). In the case of a negative result, i.e. if the rock mass of the batch is deemed unsuitable for further redistribution, then block 70 instructs the drive 24 to direct the batch of rock 11 to the waste rock storage 27 (p. 105).

If the CTT characteristic shows that the ore is suitable for further sorting, then pieces of rock 36 of rock 11 are laid out piece by piece on the main conveyor 30 for separation by X-ray radiometers 61, 62. At the same time (step 106), the characteristics of the CTT of a portion of the rock mass are compared ( "prev" portion) which entered the guide support 28 (CTT _i) and portions CTT _{i + 1} at the time-controlled measurement gauge 50 (the "current" portion) and a decision on the nature of the further sorting pieces (p. 107) and Parts Required signal processing correction algorithm installed in the early work.

 In the event that the CTT characteristic has not changed, then for separate portions of a portion the operations similar to those in sections 101 and 102 are carried out: recording the spectrum (section 108) and calculating the characteristics of the piece corresponding to these measurements according to the current algorithm (section 109 ), which provides the identification of the piece. In the event that it is established that the piece has a rich content of the component, it is sent to the concentrate (p. 104), if not, a command is given to drive 34, and the piece is sent to the waste dump (p. 105).

Otherwise, if it is established at operations (p. 107) that the CTT characteristic has changed, then at operations (p. 111) a new algorithm A _{i + 1} is selected from the bank of pre-built algorithms (see above). Then, the program of this algorithm A _{i + 1} is sent (p. 112) simultaneously with the receipt of a piece of ore of a new CTT _{i + 1} (taking into account the delay τ of the time it took for this piece to arrive at the measurement position from the position of portion analysis), and the obtained spectrum is processed by new algorithm. The time delay τ can be introduced both programmatically in the form of coefficients, and by means of hardware solutions, using, for example, television recognition devices known in the art (see Fore A. Perception and pattern recognition. - M.: Engineering, 1989 [7] ) During the functioning of the system, information is accumulated and processed statistically (Section 113), which is used to control the operation of the system. Information about the end of the separation process (verification of the end of the portion and the arrival of a new portion) and the transfer of control is carried out on the operation (paragraph 114). If a decision is made to end the separation of the current portion, then control is transferred to the stage (paragraph 101). Otherwise, control is transferred to the operation (paragraph 108) and the system continues to separate pieces of the current portion.

 To increase the reliability of x-ray radiometric separation at the stage of lump analysis, two meters 61, 62 are used that are installed across the path of moving the pieces counter to each other on the conveyor belt to provide a two-sided view of the analyzed piece [1, p. 74].

Claims (6)

 1. The method of enrichment of mineralized rock mass, including the formation of portions of rock mass, the assessment of the quality of these portions by analyzing the spectra of characteristic x-ray radiation during movement through the control zone, their separation according to types in accordance with established classification criteria, characterized in that the batch algorithm is predefined classification taking into account the technological type, degree of crushing and mixing of ore, which determines the sorting and technological type of ore c. portions, and if this type is a concentrate or rock, the portion is removed from the process, additionally enrichment is carried out for pieces of the remaining sorting and technological types of ores of this portion, for which, by registering the spectrum of characteristic x-ray radiation, their belonging to the concentrate or rock is determined by the current algorithm for identifying pieces related to this sorting-technological type, and separate them, and when changing the sorting-technological type of ores at the stage of portioned ogascheniya synchronously corrected current algorithm identification pieces.  2. The method according to claim 1, characterized in that the construction of batch classification algorithms for rock mass and piece identification algorithms for analyzing the characteristic x-ray spectra of various sorting and technological types of ores is carried out using pattern recognition methods.  3. The method according to claim 1 or 2, characterized in that the spectra of characteristic x-ray radiation are recorded at different portions of the portions and pieces in the process of moving them, and as criteria for the portions to belong to one of the sorting-technological types or to identify the pieces, the differences in the above spectra, mainly indicators of dispersion and variation.  4. An X-ray radiometric enrichment device, including sequentially installed conveyors for supplying raw materials to the control zones, two X-ray radiometric meters and a switch for unloading portions with a drive connected to the control unit with means for analyzing and processing the spectra of X-ray radiometric meters, storage tanks installed in the place of unloading of raw materials characterized in that it is provided with a third x-ray radiometer mounted above the first conveyor for I feed the portions of raw materials to the control zone, and the switch for the address of the unloading of the portions is made with a three-position concentrate - rock - sortable class and is installed between the conveyors, and two other X-ray radiometric meters are placed on both sides of the conveyor to feed the raw materials into the piecewise sorting zone and are installed offset from each other in the direction of movement of the conveyor belt.  5. The device according to claim 4, characterized in that the conveyor for feeding portions of raw materials to the control zone is equipped with means for controlling the flow of mineral raw materials connected to the control unit.  6. The device according to claim 4 or 5, characterized in that the control unit is based on at least one microprocessor.

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