WO2020038992A1 - Method and device for operating a crushing plant - Google Patents

Abstract

The invention relates to a method and a device for operating a processing plant for crushing substantially rock-type material, wherein the processing plant comprises at least one crushing stage (420, 455, 487) and at least one screening stage (405, 445, 485, 497), and wherein processing operations of the processing plant are calculated, in particular, on the basis of a simulation involving discrete elements of the material (430 - 440, 470 - 480, 491 - 495), wherein individual material particles are used as a basis, the material particles are taken into account as a substitution model during the simulation (430, 470, 491), and the results of the simulation are taken into account during the operation stage or planning stage of the processing plant (420, 455, 487).

Description

 description

Method and device for operating a crushing plant

The invention relates to a method for operating a processing or crushing system for comminuting stone-shaped material, according to the preamble of claim 1. The present invention also relates to a computer program, a machine-readable data carrier for storing the computer program and a device, by means of which the method according to the invention can be carried out.

State of the art

Materials affected here, e.g. Stones or ores are usually extracted from a quarry. There, the material is loosened either by blasting or with heavy machinery and then transported to a crushing plant by wheel shovel loaders and heavy goods vehicles and crushed there. In the case of cement production, the material can be crushed together with additives to crushed stone. The material shredded in this way is then brought to an interim storage facility via conveyor belts.

Crushing plants affected here generally consist of several crushing, sieving and transport stages. The design of the individual stages of the crushing plant during its planning is mostly carried out on the basis of model calculations based on so-called “continuum” models. These models are mostly based on empirical empirical values or empirical formulas, in which influencing factors such as the fineness, moisture or hardness of the material are included with correction factors.

With these known model calculations of a crushing plant affected here, however, no individual units of the plant, e.g. using a discrete element method (DEM) simulation. Until now, such calculations have only been carried out on such individual units, i.e. separately from a crushing plant. In addition, these calculation methods often reach their limits in the case of complex project requirements of the processing plants affected here.

In many areas of material processing in opencast mining, mechanical disintegration of solid rock is an essential part of the processing chain. It is therefore of great importance to realistically forecast the loads occurring in the fracture process. The Ab- However, the formation of the fracture process in a simulation model is very complex, which is mainly due to the mostly highly inhomogeneous material. A promising approach to consider the material behavior in the load forecast is the numerical simulation of the material fracture behavior with the help of the DEM simulation mentioned.

A DEM simulation is known to map a real, irregular rock geometry using discrete particles. A sphere with a defined radius and density is preferred because it is the easiest way to detect contact in space. In addition, inhomogeneities occurring in a real aggregate are simulated. This is achieved by assembling the contact model from a model for material deformation, sliding friction, rolling resistance and cohesion. In this way, the behavior of the round particles can be adapted to that of bulk materials with an irregular geometry.

For the simulation of solid bodies affected here, the so-called contact model is additionally extended according to the superposition principle by a so-called “bond” model (usually a bar with a circular cross section). In accordance with the behavior of the solid, the bonds implemented between the particles are able to absorb forces and moments. In addition, the bonds can "break" if a defined load is exceeded. Based on the basic models, a breakable DEM rock body is built up from a large number of particles and bonds. The parameters of the contact and bond model are also calibrated so that the macroscopic rock features, such as breaking force, rigidity, toughness, grain size effects and the fracture pattern, are realistically reproduced.

As an alternative to this, there is also a model approach in which a DEM rock body is formed monolithically and this rock body breaks as a whole when deformed in accordance with a corresponding fracture function.

Disclosure of the invention

The invention is based on the idea of feeding individual material particles present in a processing or crushing plant concerned here for comminuting essentially stone-shaped material to a discrete consideration (DEM simulation).

It should be noted here that such a processing system comprises not only crushing tools but also other units or machines, for example sorting machines. The material part kel are simulated as a replacement model in a process and are subject to the applicable physical laws for transport, sorting and shredding.

It should also be noted that in the present case the DEM simulation depicts a real irregular rock geometry using discrete particles, it being possible to use other geometrical body shapes instead of a sphere. For example, an ellipsoid, an octahedron or preferably even irregular particle shapes or spatially arbitrarily shaped particles can be used. In this way, inhomogeneities occurring in a real aggregate can be reproduced even more precisely.

In the method proposed according to the invention for operating a processing plant for crushing essentially stone-shaped material, the processing plant having at least one comminution stage and at least one sorting stage, processing processes of the processing plant are calculated using a simulation based on discrete elements of the material, whereby individual material particles are taken as a basis, the material particles being taken into account as a substitute model in the simulation, and the results of the simulation being taken into account when operating or optimizing an existing processing plant or when planning a new processing plant.

In the proposed method, physical laws applicable to the material particles during transport and / or during sorting and / or during comminution can be taken into account.

A so-called break function can be set up in particular when simulating the comminution. The fracture function determines the behavior of the rock particles under the respective stress in the area of the machine and, as a result, provides the respective reaction forces, the fracture energy and the distribution of the respective fragments after stressing the rock particles. As a result, the throughput of the respective broken material and the energy absorbed by the respective rock particle during the refraction can be determined for each predetermined machine.

For the necessary parameterization or calibration of DEM models, it is known that simulation results can be compared with measured values, which were previously determined in real experiments, and a measure for the deviation of the results can be calculated. The model parameters are then varied using an optimization process until they match as closely as possible.

Overall, the throughput and the energy consumption for an entire processing or crushing plant can also be determined with the proposed method. Because the method according to the invention enables DEM modeling of an entire processing or crushing plant. Thus, the planning and design e.g. a correspondingly large ore processing plant, but also crushing plants used in the natural stone industry, can be simplified and carried out more precisely or precisely.

In the proposed method, it can be provided that, in the calculation of the preparation process, blasted material in a deposit is fed to at least one preparation stage, substitutes for the blasted material for the discrete calculation of the simulation, in particular on the basis of a real blasting distribution - particles are formed.

In the proposed method, it can further be provided that parameters are taken into account in the calculation of the preparation process, which parameters are determined in a separate calculation loop. With the separate calculation loop, the grain size of the replacement particles can be calculated, a mechanical load test can be calculated on the basis of the calculated grain size, and a fracture function can be calculated on the basis of the results of the mechanical load test.

It should be noted that the proposed method can also be used to subsequently adapt or improve existing crushing plants using the simulation mentioned, the simulation being able to be carried out in parallel with a crushing process. The adjustment mentioned can be carried out by changing a break function mentioned until the simulation corresponds as closely as possible to the real process.

By coupling the above-mentioned simulation with a constantly changing task composition of a crushing plant affected here, the simulation can be carried out dynamically accordingly. As a result, anomalies occurring in the area, transport and / or sorting process can also be precisely detected.

The proposed method can also be used to control a crushing plant, the simulation being used to determine whether, for example, a changing material rial task the speed of the transport, classification and shredding processes has to be changed or adapted. This is because a relatively coarse feed material slows down the comminution process, whereas a relatively fine feed material can overwhelm the crushing plant with material due to the slow speeds of the aggregates of the crushing plant. In today's crushing plants, such material fluctuations are compensated for by means of an intermediate material warehouse or an intermediate bunker. With the proposed method, such an intermediate material store can thus be dispensed with at least partially or even entirely, as a result of which the entire crushing plant can be manufactured more cost-effectively and can also be operated more cost-effectively.

The device also proposed according to the invention is in particular set up to control a crushing plant affected here by means of the proposed method.

The invention can be used in particular in a crushing plant which can be used for ore extraction or stone extraction.

The computer program according to the invention is set up to carry out every step of the method, in particular if it runs on a computing device or a control device. It enables the method according to the invention to be implemented on an electronic control device without having to make structural changes to it. For this purpose, the machine-readable data carrier is provided, on which the computer program according to the invention is stored. By installing the computer program according to the invention on a device or a corresponding electronic control device, the device according to the invention is obtained, which is set up to operate a crushing plant affected here by means of the method according to the invention or to control the corresponding crushing operation.

Further advantages and refinements of the invention result from the description and the accompanying drawings.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the respectively specified combination but also in other combinations or on their own without departing from the scope of the present invention.

Brief description of the drawings Figures 1a, b show known calculation methods based on a fractional function according to a continuum model (a.) And a discrete DEM model (b.).

FIGS. 2a, b show typical deformations of an irregular material sample by means of crushing tools known per se, namely a flat tool (a.) And a pointed tool (b.).

Figure 3 shows a method for operating a crushing plant, according to the state of the

 Technology, based on a block or flow chart.

Figure 4 shows an embodiment of the inventive method using a

 Block / flow diagram.

Description of exemplary embodiments

The method according to the invention for operating a crushing plant concerned here or a corresponding crushing process is described below using the exemplary embodiment of a crushing plant used in ore extraction. However, the method and the setup can also be used in other crushing plants, e.g. be used accordingly in crushing plants for stone / natural stone extraction or in cement production.

A crushing plant affected here usually consists of several crushing, screening and transport stages. All of these process stages can be modeled together using a discrete element method (DEM). The part of the process that can be most influenced for modeling is the breaking of the material and, above all, the breaking function of the stones on which it is based. The breaking function must therefore be determined separately for each breaking step and for each material.

After the respective break function has been correctly determined and after the break function has been read into a DEM simulation program, the breaking process can be precisely mapped in a known manner with material throughputs, product distributions and with loads present on the respective units of the processing plant.

The fraction function mentioned can be determined as follows: In the case of crushing plants in which the respective materials for crushing are essentially loaded by pressure, the breaking function is known to be based on so-called “point load tests” (PLT) and pressure resistance tests, in which, for example, a mobile one is essentially used pointed breaking tool is pressed onto a respective, mostly irregular, material sample. The respective material samples, ie individual stones, are loaded or pressed with different intensities as in a crushing room of a crushing plant. These tests provide corresponding parameters, for example the force and the energy up to a break. In addition, these tests also provide information about the fragments generated.

In these strength tests, there is also the possibility of changing or scaling the pressure values used in accordance with the different grain sizes of the material samples. The parameters mentioned are determined individually for each crushing stage, as follows:

1. In the event of a pile being blasted off at the respective break-off edge of a mine, i.e. natural, not yet processed so-called “ROM” material, the fracture function for a first crushing stage is determined using a PLT compressive strength test.

2. For a pile of ROM material broken in the first crushing stage, the fracture function for the subsequent second crushing stage is also determined using a PLT compressive strength test.

3. For a heap broken in the second crushing stage, the fracture function for the subsequent third crushing stage is also determined from the PLT compressive strength test.

4. If necessary, further fraction functions, e.g. for grinding stages for the production of grain sizes smaller than 10 mm, however, cannot be determined on the basis of the PLT compressive strength tests mentioned. Loads and product distributions, e.g. required from a model good-bed roller mill.

It should be noted here that, alternatively, the fractional function can be determined for a first crushing stage as described and can only be extrapolated accordingly for at least a second crushing stage, for example by means of a linear or non-linear extrapolation or the like. Figures 1 a and 1 b show two different calculation methods with the underlying fractional functions in comparison, namely those based on so-called “continuum models” and based on so-called DEM simulations. For the design of the aggregates located in the processing plants concerned here, continuum models illustrated in the prior art in FIG. 1 a are used, material particles being represented as a continuum in the processing process. FIG. 1 a shows schematically a breaking tool 100 with material 105 to be machined continuously arranged therein. The continuum models provide empirical calculation formulas based on practical experience. Individual units of the processing plant are not calculated using discrete methods.

As is known, the calculation method based on continuum models is mostly based on stochastic structural models. In these, discrete elements are generated and networked using point processes or so-called “Varonoi structures” based on structural analyzes with regard to the discrete material structure, in particular the grain structure of the material, and possibly taking binders between these grains into account.

The mechanical behavior of these structural elements, i.e. Mineral grains and binders are known to be mapped using contact and volume laws. Using a numerical DEM simulation of mechanical high pressure loads, the fracture behavior of the rock structure under various high pressure loads can be mapped realistically. The simulation results are validated by laboratory experiments, in which special strength tests in the high-pressure range are carried out in a rock mechanical laboratory.

In the DEM simulation shown schematically in FIG. 1 b, a discrete consideration of replacement material particles takes place in the preparation process. In the present example, three replacement material particles 1 15, 120, 125, each of a different size and shape, are taken into account in the simulation in a breaking tool 110.

A so-called “point load test” (PLT) and a pressure test are shown in comparison in FIGS. 2a and 2b.

In the pressure test illustrated in FIG. 2a, a movable, flat crushing tool 200 is used, which is pressed onto an irregularly shaped material sample 205 arranged on a solid base 205. This application with a pre- given stroke deformation h (reference numeral 215) results in a corresponding pressure p on or in the material sample 205.

In the PLT test illustrated in FIG. 2 b, a movable, pointed breaking tool 220 is used, which is pressed onto a material sample 230, which is again irregularly shaped and is arranged on a base 225 corresponding to the breaking tool 220. The stroke deformation h that occurs in this case (reference numeral 235) also results in a corresponding pressure p on or in the material sample 230.

The break function for a DEM simulation is known to include at least the following three physical quantities or functional relationships:

1. The reaction energy E (h) depending on the deformation h;

2. the reaction force F (h) of the material as a function of the deformation h; and

3. the distribution P (h) of the grain size of the material as a function of the deformation h.

The irregular material samples, e.g. Rock samples, positioned on the first fixed tool and deformed and crushed by the movement of the moving tool. The deformation is set to different sizes. In addition, the size of the material samples is varied and the tests repeated with the same / similar material sample size. The reaction force of the material sample is measured during the tests. In addition, the size of the fragments resulting from the deformation is measured.

The fracture function is determined as a result, functions of the reaction energy, reaction force and grain size distribution of the fragments being formed as a function of the deformation and the sample size. These functions are then extrapolated for larger grain sizes.

FIG. 3 shows a typical functional block diagram or flow chart of a calculation of processing processes in a processing or crushing plant concerned using the example of cement production. It should be emphasized that the individual units (ie the blocks shown here) of the system can also be arranged or combined differently in the calculation. So when calculating on the first sorting stage 205 shown there can be dispensed with. The preparation processes are calculated in accordance with the state of the art using a continuum model.

In the processing process shown, material 300 which has been blown up in the respective deposit is first transported 310 to a first sorting stage 305 by means of conveyor technology (not shown) which is known per se. This transportation 310 can thus be carried out by means of a transport motor vehicle or a conveyor belt. In the first sorting stage 305, an empirical calculation of the expected result of the first sorting is based on the continuum model. Depending on the result of the first sorting, the material can then be forwarded to different shredding levels.

In the calculation, the correspondingly pre-sorted material is transported 320 to a first shredding stage 315, preferably by means of a conveyor belt. The first comminution stage 315 has a so-called breaking tool for comminuting the material 300. In the first comminution stage 315, an empirical calculation of the expected result of the comminution or refraction of the material 300 is again based on the continuum model.

In the further calculation, the material which has been comminuted in this way is first transported 325 to a first intermediate store (not shown) and controllably fed from it to a second sorting stage 330. In the second sorting stage 330, too, an empirical calculation based on the continuum model of the expected result of the second sorting takes place. This is followed by a transport 335 of the material sorted in this way to a second crushing stage 340, then to a third sorting stage 345, then to a third crushing stage 350 and then to a fourth sorting stage 355. The then present, crushed and meanwhile sorted fourfold Material is then transported 360 to a second intermediate store (not shown) and controllably fed from it to a first grinding stage 365, in which fine-grained material required for cement production is produced.

It should be emphasized that in the preparation stages 340, 345, 350, 355 and the first grinding stage 365, empirical calculations based on the continuum model are also carried out of the respectively expected result of the crushing or sorting. According to the method according to the invention, a processing process of stone-shaped material affected here is calculated in a processing or crushing plant concerned here on the basis of a discrete consideration or DEM simulation of the material to be processed in each stage of the processing process. This is illustrated in FIG. 4, in which the corresponding additional calculation steps of the respective DEM simulation are shown.

The functional block diagram or flowchart shown in FIG. 4 of a processing / crushing plant concerned here, again using the example of cement production, also includes several assumed machines or units. In the present exemplary embodiment, the following parameters are generated as the results of the respective DEM simulation steps for each machine or each unit of the processing or crushing plant:

Material throughput in the unit [1,000 kg / h],

 Power consumption in the unit [kW],

 Grain size distribution of the feed material and product material in the unit [mm /%],

 Loads or forces in the unit [kNj.

It should also be emphasized in FIG. 4 that the individual units (i.e. the blocks shown here) of the system can also be arranged or combined differently. In this way, the first sorting stage 405 shown can also be omitted in the calculation. In contrast to the prior art, the processing processes in the system shown are calculated using a DEM simulation.

In the discrete calculation of the processing process shown in FIG. 4, material 400 blasted in the respective deposit is first transported 410 to a first sorting stage 405. Here too, the transport 410 can be carried out by means of a transport motor vehicle or a conveyor belt. In contrast to FIG. 3, the material that was blasted off when the material was blown up at the deposit is also defined as part of the DEM simulation as DEM replacement particles to be taken into account there (see FIG. 1b) or educated.

In the present first sorting stage 405, a DEM simulation of the sorting process based on the DEM replacement particles takes place. Depending on the result of this first sorting, the material present in each case can then also be forwarded to different shredding levels. After the first sorting stage 405 has been calculated, the replacement particles are transported 415 to a first crushing stage 420, in which the crushing process of the DEM replacement particles is calculated. This calculation takes place on the basis of parameters which are determined in a separate first process or calculation loop 425. The grain size of the DEM replacement particles is first calculated 430. On the basis of the grain size thus calculated, a pressure and PLT test described with reference to FIGS. 2a and 2b is carried out 435 using simulation technology. On the basis of the results of the mechanical load test carried out in this way a fraction function described is calculated 440.

The DEM replacement particles resulting from the comminution process according to the first comminution stage 420 are conveyed 450 with or without intermediate storage to a second sorting stage 445 in terms of transport technology. The DEM simulation of a sorting of the then available DEM replacement particles then takes place.

The two sorted DEM replacement particles thus present are then fed to a second comminution stage 455 460, in which the shredding process of the DEM replacement particles is in turn simulated. Here, too, the required parameters are first calculated using a second calculation loop 465, namely the particle size 470 of the DEM replacement particles that is then present, the simulation of a pressure and PLT test 475, and the determination or determination of a corresponding fracture function 480.

Correspondingly, a subsequent third sorting stage 485 and a third comminution stage 487 are used, and the process parameters required for the DEM simulation are also determined there using a third calculation loop 489 with corresponding calculation steps 491, 493 and 495.

The DEM replacement particles then present are also subjected to a fourth sorting stage 497 in the present exemplary embodiment. Finally, the DEM replacement particles then present are fed to a first grinding stage 499. After that, further process stages can be set up if necessary.

The method described with reference to FIG. 4 can be in the form of a control program for an electronic control unit for operating or controlling a processing or crushing system concerned here, or in the form of one or more corresponding electronic ones Control units (ECUs) can be realized. The described method can also be implemented in the form of a computer program for planning a new processing / crushing plant affected here or for optimizing an existing processing / crushing plant affected here.

Claims

claims

1. A method for operating a processing plant for crushing essentially stone-shaped material, the processing plant having at least one crushing stage (420, 455, 487) and at least one sorting stage (405, 445, 485, 497), characterized in that that processing processes of the processing plant are calculated using a simulation based on discrete elements of the material (430 - 440, 470 - 480, 491 - 495), taking individual material particles as a basis, using the material particles as a substitute model for the simulation are taken into account (430, 470, 491) and the results of the simulation are taken into account when operating the processing plant (420, 455,

487).

2. The method according to claim 1, characterized in that physical laws applicable to the material particles during transport and / or during sorting and / or during comminution are taken into account (420, 455, 487).

3. The method according to claim 1 or 2, characterized in that a break function is used as a basis in the simulation of the comminution, which describes the behavior of the material particles under mechanical stress.

4. The method according to claim 3, characterized in that the fracture function describes the reaction forces present during the mechanical stress, the fracture energy and the distribution of the respective fragments present after a stress.

5. The method according to any one of the preceding claims, characterized in that, for parameterization or calibration, results of the simulation are compared with measured values, which are determined in real experiments, and model parameters are adapted to the measured values.

6. The method according to claim 5, characterized in that the adaptation of the model parameters to the measured values takes place on the basis of an optimization method, the model parameters being varied until they match the measured values as much as possible.

7. The method according to any one of the preceding claims, characterized in that when calculating the processing process in a deposit blasted material (400) is fed to at least one processing stage (405), with the blasted material for discrete calculation based on the simulation a real explosive distribution replacement particles are formed.

8. The method according to any one of the preceding claims, characterized in that parameters are taken into account in the calculation of the preparation process, which are determined in a separate calculation loop (425, 465, 489).

9. The method according to claim 8, characterized in that in the separate calculation loop (425, 465, 489) the grain size of the replacement particles is calculated (430, 470, 491), that on the basis of the calculated grain size a mechanical load test is determined (435, 475, 493) and that a fracture function is calculated based on the results of the mechanical load test (440, 480, 495).

10. The method according to any one of the preceding claims, characterized in that the processing plant is operated in a controlled manner on the basis of the results of the simulation.

1 1. The method according to claim 10, characterized in that the simulation is used to determine whether process parameters have to be changed or adapted in the case of a changing material task.

12. Method for planning a new processing plant or for optimizing an existing processing plant for comminuting essentially stone-shaped material, the processing plant at least one comminution stage (420, 455, 487) and at least one sorting stage (405, 445, 485, 497) , characterized in that processing processes of the processing system are calculated using a simulation based on discrete elements of the material (430-440, 470-480, 491-495), individual material particles being taken as a basis, the material particles are taken into account as a substitute model in the simulation (430, 470, 491) and the results of the simulation are taken into account when planning or optimizing the processing plant (420, 455, 487).

13. Computer program which is set up to carry out each step of a method according to one of claims 1 to 12.

14. Machine-readable data carrier on which a computer program according to claim 13 is stored.

15. Device which is set up to control a processing plant for breaking stone-shaped material by means of a method according to one of claims 1 to 1 1.