Ball mill load status identification method based on the convolutional neural network, optimized support vector machine model, and intelligent grinding media
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摘要: 當前球磨機負荷檢測方法難以準確評估磨機內部變化,給磨機綜合運行狀態的控制和優化帶來較大難度。本文設計了一款內嵌加速度傳感器且與鋼球介質物理性質相一致的智能磨礦介質用于識別磨機負荷,開展了不同充填率等磨礦條件下的磨礦試驗,設計磨礦效果系數劃分磨機負荷狀態;分別采用了卷積神經網絡方法(CNN)和優化的支持向量機(SVM)模型對智能磨礦介質獲取的加速度信號進行球磨機負荷識別。基于優化的SVM模型將獲取的一維加速度信號進行互補集合經驗模態分解算法(CEEMD)去噪、時域特征值和樣本熵提取等預處理,將上述磨機負荷的特征向量分別輸入GA?SVM、GS?SVM、PSO?SVM分類模型進行訓練,研究表明,PSO?SVM模型的識別準確率可達98.33%,但存在訓練過程繁瑣,耗費時間長的問題。在圖像識別領域具有優秀應用能力的CNN模型是把智能磨礦介質檢測加速度信號數據轉換為二維圖片后直接輸入基于VGG19網絡的CNN模型進行分類識別,磨機負荷分類識別準確率高于優化的SVM模型,可達98.89%,在保證識別準確率的同時有效節約了計算時間。基于CNN的智能磨礦介質球磨機負荷識別方法可為實現球磨機負荷檢測與在線評估提供重要解決方案與技術保障。Abstract: A ball mill is important grinding equipment in a concentrator, and the accurate detection of the load status ensures that the ball mill runs in the best state, which helps optimize the grinding process, ensure the stable operation of the ball mill equipment, and save energy. The current mainstream detection methods cannot easily detect the movement inside the ball mill. Mill load requires a more efficient and direct detection method. In this study, the SM ?500 mm×500 mm ball mill was taken as the research object. Through theoretical analysis and simulation, intelligent grinding media with an embedded triaxial acceleration sensor and physical properties similar to that of ordinary steel ball media were designed to identify the mill load, and grinding experiments with different filling rates and other grinding conditions were conducted. Results revealed that the filling rate and the material to ball ratio are the important factors affecting the ?0.074 mm size products. Taking the grinding effect coefficient as an index to distinguish different load states and grinding effects, the best load state can be achieved under the conditions of 40% filling rate, 1∶37 material to ball ratio, and ~6 kg sample weight. The ball mill load was evaluated using the convolutional neural network (CNN) method and optimized support vector machine (SVM) models from the acceleration signal obtained by the intelligent grinding media. For the optimized SVM models, preprocessing of the acquired one-dimensional acceleration signal, including complementary ensemble empirical mode decomposition algorithm denoising, time-domain eigenvalue extraction, and sample entropy, was conducted. The feature vectors of mill load were included in the genetic algorithm and SVM (GA?SVM), grid search and SVM (GS?SVM), and partial swarm optimization and SVM (PSO?SVM) classification models for training. The research results revealed that the recognition accuracy of the PSO?SVM algorithm reaches 98.33%, but the training process tends to be tedious and time-consuming. For the CNN algorithm with excellent applicability in the field of image recognition, the detected acceleration signal data were converted into two-dimensional pictures and directly inputted into the CNN model based on the VGG19 network for classification and recognition. The classification and recognition accuracy of the mill load of the CNN method (i.e., 98.89%) was higher than that of the optimized SVM algorithm. Moreover, the calculation time of the CNN method was shorter than that of the optimized SVM algorithm. The ball mill load status identification method using the intelligent grinding media and CNN method could provide critical solutions and technical support for load detection and online evaluation.
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Key words:
- mill load /
- intelligent grinding media /
- sample entropy /
- CNN /
- SVM
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圖 2 基于優化SVM分類模型的磨機負荷狀態識別流程
Figure 2. Recognition process of mill load status based on the improved support vector machine classification model
圖 3 正常負荷工況信號波形.(a)源信號;(b)去趨勢結果
Figure 3. Signal waveform under normal load conditions: (a) original signal; (b) detrended results
圖 4 三種優化的SVM模型的負荷狀態分類識別結果.(a)GS?SVM分類結果;(b)GA?SVM分類結果;(c)PSO?SVM分類結果
Figure 4. Results of load status classification and recognition of the three improved support vector machine methods: (a) results of GS?SVM classification model; (b) results of GA?SVM classification model; (c) results of PSO?SVM classification model
圖 5 不同分類模型下的負荷狀態識別準確率及運行時間
Figure 5. Results of load status recognition under different classification models
圖 9 CNN訓練磨機負荷樣本結果
Figure 9. Results of the convolutional neural network training mill load sample
表 1 5種負荷狀態參數劃分結果
Table 1. Five kinds of load state parameter division results
Label Filling rate/% Yield of ?200 mesh/% Power consumption/
(kW·h)Grinding effect coefficient Load state 1 10 22.81 0.221 0.447 Severe underload 2 20 33.44 0.226 0.641 Underload 3 30 52.92 0.233 0.989 Qualified 4 40 68.48 0.236 1.258 Optimal 5 50 70.07 0.244 1.244 Overload 
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表 2 SVM常用核函數
Table 2. Commonly used kernel functions of the support vector machine
Kernel function name Expression Linear kernel function ${ {k} }\left( { { {\boldsymbol{x} }_{{i} } }{{,} }{ {\boldsymbol{x} }_{{j} } } } \right){{ = } }{ {\boldsymbol{x} }_{{i} } }^{\rm T} { {\boldsymbol{x} }_{{j} } }$ Radial basis function (RBF) kernel ${ {k} }\left( { { {\boldsymbol{x} }_{ {i} } },{ {\boldsymbol{x} }_{ {j} } } } \right) = \exp ( - { {g} }\parallel { {\boldsymbol{x} }_{ {i} } },{ {\boldsymbol{x} }_{ {j} } }{\parallel ^2})$ Polynomial kernel function ${ {k} }\left( { { {\boldsymbol{x} }_{{i} } },{ {\boldsymbol{x} }_{{j} } } } \right) = {\left[ { {{g} }({ {\boldsymbol{x} }_{{i} } } \cdot { {\boldsymbol{x} }_{{j} } }) + {{C} } } \right]^{{d} } }$ Sigmoid kernel function ${{k} }\left( { { {\boldsymbol{x} }_{{i} } },{ {\boldsymbol{x} }_{{j} } } } \right) = \tanh \left[ { {{g} }({ {\boldsymbol{x} }_{{i} } } \cdot { {\boldsymbol{x} }_{{j} } }) + {{C} } } \right]$
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表 3 三種典型工況下的樣本熵值
Table 3. Sample entropy values under three typical working conditions
Samples Underload Normal load Overload Original Reconstructed Original Reconstructed Original Reconstructed 1 0.89 0.87 0.48 0.50 0.35 0.38 2 0.84 1.06 0.51 0.47 0.32 0.39 3 0.79 0.99 0.49 0.55 0.31 0.36 4 0.92 1.01 0.43 0.54 0.31 0.39 5 0.77 0.90 0.41 0.48 0.29 0.40 Mean 0.84 0.97 0.46 0.51 0.32 0.38
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表 4 不同負荷狀態下的部分待訓練特征向量
Table 4. Feature vectors to be trained under different load conditions
Serial number Filling rate/ % Peak-to-peak Mean Standard deviation Skewness Kurtosis Sample entropy 1 10 236.91 9.71 10.78 4.45 44.94 1.16 2 10 275.67 7.28 9.46 5.75 78.78 0.90 … … … … … … … … 61 20 306.59 10.35 18.63 5.85 53.51 0.65 62 20 342.41 9.24 17.60 6.21 58.81 0.58 … … … … … … … … 121 30 285.08 8.79 16.17 6.21 61.26 0.63 122 30 265.04 9.34 17.74 5.64 47.87 0.54 … … … … … … … … 181 40 319.24 9.13 19.01 5.60 46.51 0.53 182 40 290.03 9.87 20.76 5.50 44.32 0.48 … … … … … … … … 299 50 284.15 6.47 16.86 7.23 74.09 0.32 300 50 299.88 5.96 15.68 7.80 87.21 0.33
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久色视频表 5 三種優化SVM模型對磨機負荷狀態的識別結果
Table 5. Recognition results of the three improved support vector machine models on the load state of the mill
Classification model Best (C, g) Training accuracy/% Test accuracy/% GS?SVM (64, 2.83) 91.00 91.67 GA?SVM (70.09, 9.44) 94.33 90.00 PSO?SVM (260.94, 2.36) 96.33 98.33
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