Abstract

In order to effectively predict the sieving efficiency of a vibrating screen, experiments to investigate the sieving efficiency were carried out. Relation between sieving efficiency and other working parameters in a vibrating screen such as mesh aperture size, screen length, inclination angle, vibration amplitude, and vibration frequency was analyzed. Based on the experiments, least square support vector machine (LS-SVM) was established to predict the sieving efficiency, and adaptive genetic algorithm and cross-validation algorithm were used to optimize the parameters in LS-SVM. By the examination of testing points, the prediction performance of least square support vector machine is better than that of the existing formula and neural network, and its average relative error is only 4.2%.

1. Introduction

Sieving is one of the oldest physical size separation methods and has been widely used both in industries and in laboratories. Vibrating screens which include a number of types are the main sieving tool for large-scale separation and classification of solid particles by size, and they are widely used in some practical engineering such as mining, metallurgy, dry mortar, artificial sand, and agriculture production. Probability screen is a special vibrating screen for the separation and classification of fine particulate material, which exhibits problems of plugging holes and low sieving efficiency when the particle size is below 0.6 mm. Sieving efficiency is an essential evaluation indicator of sieving performance, and it is hard to be predicted based on the existing sieving design parameters in the design process of vibrating screens due to the comprehensive effect of complex particle sieving process under multiple factors, which will influence the selection or determination of these parameters. Therefore, an understanding of predicting sieving efficiency has a great practical significance.

At present, the research on the sieving efficiency of vibrating screens has also made some progress. There are lots of researchers studying the sieving process by DEM simulations like Li et al. [1], Dong et al. [2], Liu [3], Delaney et al. [4], Jiao and Zhao [5], and Li et al. [6], and qualitative relation between sieving efficiency and sieving parameters in a vibrating screen such as amplitude, vibration frequency, screen mesh size, particle size, and vibration direction angle has been analyzed, which provides references for in-depth study. But the results of DEM simulations need to be further explored and improved since particulate materials and boundary conditions of simulation are difficult to coincide with the actual conditions. Some scholars have studied the real-time monitoring of sieving efficiency in the working course of a vibrating screen by gathering its vibration signals, but their research achievements only play the role of real-time monitoring and have little effect on the design of a vibrating screen [7]. In terms of sieving efficiency fitting, Grozubinsky et al. [8] and Chen and Tong [9] have, respectively, established formulas between the sieving efficiency and sieving parameters such as amplitude, vibration frequency, vibration direction angle, particle size, and screen mesh size based on a probabilistic model and a discrete element model, but these formulas only reflect the relationship between the single parameter and sieving efficiency. Jiao et al. [10] found the mathematical formula between sieving efficiency and parameters including screen deck angle and screen mesh size based on statistical analysis of experimental data, which provides a theoretical basis for the design of vibrating screens but ignores the impact of screen length. Although some fitting function formulas of sieving efficiency have been studied, there is still no widely accepted formula to predict sieving efficiency on the basis of sieving parameters. The introduction of artificial intelligence may provide a good path to the solution of this problem [11].

Support vector machine (SVM) and neural network both can fit the nonlinear relations [1214], whereas SVM is more suitable when the sample size is relatively small and can solve “curse of dimensionality” problems. The solution of “curse of dimensionality” can make the complexity of algorithm and the dimension of sample independent. At present, SVM has been widely and effectively used in the pattern recognition, intelligent fitting, and prediction [1518]. However, the application of SVM to predict the sieving efficiency has not been reported in the literatures yet.

In this paper, the experimental system and results were firstly introduced and analyzed, and then intelligent fitting model of least square support vector machine (LS-SVM) and adaptive genetic algorithm were provided; finally, the contrast between the performance of the LS-SVM model, the existing formula, and the neural network was carried out.

2. Sieving Experimental System

Sieving is a process in which a certain size range of materials is separated into several products with different size through one-deck or multideck screens that have sieving mesh with uniform apertures. Theoretically, the particles whose size is larger than the mesh aperture remain on the screen surface and leave the screen surface when they pass the end of the screen, and these particles are called overflow particles; however, other smaller particles penetrate the sieving mesh through the mesh aperture and are called undersize particles. Sieving efficiency is the ratio between actual mass of undersize particles and the mass of the particles in raw materials whose size is smaller than the mesh aperture. Compared with the mesh aperture size, the smaller the particles are, the easier the penetration is, but the particles whose size is close to the mesh aperture size penetrate the screen mesh with difficulty. Probability screens have some advantages in all vibrating screens such as large sieving capacity and easy penetration because of their unique characteristics of the large mesh aperture and large inclination angle.

The repeated sieving tests are finished in an experimental system, which is illustrated in Figure 1. Sieving parameters such as inclination angle, screen length, mesh aperture size, amplitude, and vibration frequency are adjustable in this vibration sieving test bench, which is a circular experimental system and includes the multideck probability screen, storage bin of raw materials, vibrating feeder, and automatic feeding system. Samples used for measuring the sieving efficiency by Hancock’s total efficiency formula are gotten when the screen is in steady working condition. The “steady working condition” means that the screen works steadily after starting the screen on the sieving test bench; meanwhile, raw materials cover the whole screen mesh surface and the feed rate of raw materials from vibrating feeder reaches a stable state. Total efficiency is the difference between the penetration probability of the particles whose size is smaller than separation size and the penetration probability of the particles whose size is larger than separation size. The schematic diagram of total efficiency calculation is shown in Figure 2.

In Figure 2, is the total mass of raw materials into the screen, is the mass of overflow particles, is the mass of undersize particles, is the percentage of the particles whose size is smaller than separation size in raw materials, is the percentage of the particles whose size is smaller than separation size in overflow particles, is the percentage of the particles whose size is smaller than separation size in undersize particles, is mesh aperture size of the screen mesh, is screen length, and is inclination angle of the screen surface. Total efficiency is calculated as follows [10]:

In test process, the screen mesh with rectangular apertures which is woven by steel wire is selected, and the common II area sands in construction industry whose particle diameter is between thick sands and fine sands are selected as raw materials. Sand properties and operating conditions are shown in Table 1, and grading curves of sands are shown in Figure 3.

As is shown in Figure 3, the particle diameter corresponding to the 6 data points is 0.15 mm, 0.3 mm, 0.6 mm, 1.18 mm, 2.36 mm, and 4.75 mm; the grading curve of the sand sample is almost in the middle position between the upper and lower limits of the common sand. Since the raw sands are shifted with this multideck probability screen whose separation size is 2.36 mm, 1.18 mm, and 0.6 mm, respectively, from top to bottom, and, generally, the 0.6 mm layer of this probability screen has a smallest sieving efficiency, which sieves finest materials with the particle diameter below 0.6 mm, the sieving efficiency of the 0.6 mm layer is viewed as the probability screen’s one.

3. Experimental Results

According to experimental results, the sieving efficiency    first increases with the increase of vibration amplitude and screen length and then decreases with the increase of vibration frequency , mesh aperture size , and inclination angle . This paper focuses on detailed analysis of , , and , and the effect of and on the sieving efficiency is detailed in literature [7].

3.1. Effect of Mesh Aperture Size on the Sieving Efficiency

The mesh aperture size can also be characterized by the ratio between mesh aperture size and separation size . is greater than 1 in probability screens. Figure 4 shows the effect of mesh aperture size on the sieving efficiency when is equal to 3.5 mm, is equal to 960 r/min, and is equal to 2.4 m. first increases and then decreases with the increase of . When the mesh aperture size is small, the sieving efficiency is low due to the approximate size between and and the lower penetration probability of the fine particles and a greater proportion of fine particles remained in overflow particles. When the mesh aperture size is larger, the sieving efficiency is higher due to the larger penetration probability of the fine particles. When the mesh aperture size is too large, the sieving efficiency becomes lower due to the higher penetration probability of the particles whose size is larger than separation size and undersize particles mixed with a greater proportion of larger particles. The optimum mesh aperture size is between 0.8 mm and 1.1 mm, and the maximum efficiency can reach above 80% when is 25°.

3.2. Effect of Screen Length on the Sieving Efficiency

Figure 5 shows the effect of screen length on the sieving efficiency when is equal to 3 mm, is equal to 960 r/min, and is equal to 25°. increases significantly with the increase of , and the increase of becomes slow after reaches a certain value. However, decreases with the further increase of under the condition of larger value of due to the high penetration probability of the particles whose size is larger than separation size and undersize particles mixed with an increasing number of impurities. If is larger, the optimum is shorter due to the high penetration probability of the particles whose size is smaller than separation size during the beginning time of sieving. The optimum range of screen length is between 2.0 m and 2.6 m.

3.3. Effect of Inclination Angle on the Sieving Efficiency

Inclination angle mainly affects the horizontal projection size of mesh aperture and the moving speed of particles on the screen surface. Figure 6 shows the effect of inclination angle on the sieving efficiency when is equal to 3.5 mm, is equal to 960 r/min, and is equal to 0.9 mm. first increases and then decreases with the increase of , and reaches the maximum value with a certain inclination angle. When the inclination angle increases, the horizontal projection size of mesh aperture decreases and penetration probability of particles in the vertical direction decreases, which results in a lower penetration amount of the particles whose size is larger than separation size. Meanwhile, penetration and stratification capacity of the particles whose size is smaller than separation size is enhanced with increasing moving speed of particles on the screen surface. When the inclination angle increases further, the sieving efficiency becomes low due to sharp decrease of the horizontal projection size of mesh aperture, sharp increase of the moving speed of particles on the screen surface, and shorter stay time of particles on the screen surface. The optimum inclination angle is about 25° and the maximum efficiency can reach above 82% when is equal to 2.4 m.

3.4. Effect of Vibration Amplitude on the Sieving Efficiency

Figure 7 shows the effect of vibration amplitude on the sieving efficiency when is equal to 0.9 mm, is equal to 2.4 m, and is equal to 25°. increases with the increase of , and first increases and then decreases with the increase of . When and increase, the penetration probability of particles whose size is smaller than separation size becomes larger, so the sieving efficiency increases. However, when increases to 1000 r/min, decreases because larger vibration frequency can lead to larger penetration probability of particles whose size is larger than separation size. Optimum vibration amplitude and vibration frequency are 3.5 mm and 960 r/min, respectively.

4. Establishment of the Intelligent Model Based on LS-SVM

It is supposed that there are lots of training points ( is the input value, is the output value, and is the total number of training points) to be fitted; according to the basic theory of SVM, these problems can be converted to the solution of the following equations:where is kernel function, , , and are the parameters which could be obtained by the solution of the optimization problem (such problem is described in the form of (2)), and is the penalty factor.

SVM algorithm is sensitive to noise, and its calculation speed does not depend on the dimensions of input vectors but on the sample size. The large sample size will result in complex quadratic programming problem based on SVM, slow operational speed, and the long time that the calculation will spend. Therefore, LS-SVM is introduced on the basis of the traditional theory of SVM.

According to the theory of LS-SVM, (2) can be converted to the following linear equation:where , , ,   is the unit matrix, and . Here, Gauss function is selected as Kernel function and it meets the following equation:

Accordingly, (3) can be converted into the following equation:

When LS-SVM is applied into the intelligent fitting of sieving efficiency , the five-dimensional input vector is and the one-dimensional output vector is . The 82 training samples come from the experimental results discussed above, and the prediction value of the LS-SVM model can be acquired finally by solving the value of and .

In the theory of LS-SVM, the parameters needed to be optimized are the penalty factor and the kernel parameter , and the fitting performance of LS-SVM depends on the selection of and .

Nowadays, there are many kinds of intelligent algorithm that can be used to optimize and , such as particle swarm optimization algorithm, genetic algorithm, grid search, and chaos optimization algorithm [19, 20]. In these methods, genetic algorithm has been considered with increasing interest in a wide variety of applications, and it is widely used to solve linear and nonlinear problems by exploring all regions of state space and exploiting potential areas through mutation, crossover, and selection operations applied to individuals in the population. In this paper, adaptive genetic algorithm is applied to determine the value of and .

5. Intelligent Prediction of Sieving Efficiency Based on LS-SVM

5.1. Optimization of Parameters by Adaptive Genetic Algorithm

The key of adaptive genetic algorithm [21] is to determine the fitness function. Here, it is described as follows:where is the expected output, is the actual output, and is a small real number, which is to prevent the situation of zero denominator; here .

The initial crossover probability and the initial mutation probability are determined bywhere is the larger fitness function value of the cross two bodies, is the fitness function value of individual, is the average fitness function value in the samples, and is the maximum fitness function value of individual in the samples.

Crossover probability and mutation probability change with the evolutional generation, and their changing rules are as follows: where is the genetic algebra, is the terminated genetic algebra, and is a constant; here .

The basic steps of “adaptive genetic algorithm” are listed as follows.

Step 1. Generate initial population ; algebra is set to 0, and the number of individuals is .

Step 2. Run selection operator, crossover operator, and mutation operator in proper order and calculate the fitness of individuals.

Step 3. Sort individuals by fitness value and run the intelligent fitting model of LS-SVM once for the individual which has highest fitness value.

Step 4. Get a new generation of population , and algebra increases by 1.

Step 5. Judge whether it meets the optimization criterion. If it meets the criteria, the optimization process is over; else, return to Step 2.

There are two factors that may lead to the failure of LS-SVM: (1) “overfitting” issue (the objective function can reduce to a very low value during the training phase, but the testing error is relatively large); (2) “underfitting” issue (the objective function cannot reduce to a low value during the training phase). For solving these issues, “cross-validation” method is introduced [22, 23].

The basic steps of “cross-validation” are listed as follows.

Step 1. Divide the training samples into subsamples and set .

Step 2. Regard the th subsamples as the testing samples and the others as the training samples.

Step 3. Optimize the parameters in LS-SVM based on the new training samples by adaptive genetic algorithm.

Step 4. , and repeat Steps 1–3 till and , .

In this paper, the population size is 40, the dimension of parameters to be optimized is 2, the maximum genetic algebra is 400, and the binary digit of each variable is 20. And after the optimization process, and . Error function is defined as follows:where is the actual output and is the expected output.

5.2. Comparison of the LS-SVM Model, the Existing Formula, and Neural Network

An existing fitting formula of sieving efficiency from literature [10] is shown as follows:where is screen mesh size, is screen deck angle, and is sieving efficiency.

Neural network is also a usual intelligent model to fit the numerical relation besides LS-SVM; the training points in LS-SVM are still selected as training samples to optimize the parameters in neural network. The training methods of neural network have detailed descriptions in literature [24]. The prediction error between LS-SVM, BP neural network, RBF neural network, and the existing fitting formula in literature [10] is shown in Figure 8.

Figure 8 shows that the prediction error of selected 16 testing samples is analyzed; the average relative error of BP neural network is 7.3%, the average relative error of RBF neural network is 6.4%, the average relative error of literature [10] is 16.2%, and the average relative error of LS-SVM model is 4.2%. So the prediction performance of LS-SVM model is better than that of neural network and the existing fitting formula in literature [10].

6. Conclusions

The effects of different factors on sieving efficiency were investigated based on the vibration sieving test bench. According to experimental results, the sieving efficiency increases with the increase of vibration amplitude and screen length , and it first increases and then decreases with the increase of vibration frequency , mesh aperture size , and inclination angle .

The intelligent model to predict the sieving efficiency was established based on the experimental results, LS-SVM theory, and the adaptive genetic algorithm. The average prediction error of the LS-SVM model examined by testing points can be reduced to 4.2%, which is much less than that of neural network and the existing fitting formula. So, the LS-SVM model has a better prediction performance on sieving efficiency, which provides a theoretical basis for the optimal design and parameters selection of sieving screens.

Competing Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.

Acknowledgments

The authors thank the National Science Foundation of China (nos. 51276056 and 51305045) for financial support.