CN110763830B - Method for predicting content of free calcium oxide in cement clinker - Google Patents

Abstract

The invention discloses a method for predicting the content of free calcium oxide in cement clinker, which comprises the following steps: s1: collecting a cement clinker sample; s2: constructing a time sequence of free calcium oxide content of cement clinker; s3: performing time sequence decomposition on the time sequence of the content of free calcium oxide in the mud clinker based on an empirical mode decomposition method; s4: constructing input and output sample pairs required by a training feature extraction module; s5: training the feature extraction submodule, namely a modularized echo state neural network, and learning the multi-time scale features of the time sequence: s6: training the prediction module-echo state neural network: s7: and predicting the content of free calcium oxide in the clinker. The method predicts the content of free calcium oxide at the next moment based on off-line experimental data, and solves the problem of lag of laboratory measurement results; compared with the measurement method of an on-line analyzer, the method has low cost, and the measurement accuracy is less influenced by on-site smoke dust and actual working conditions.

Description

Method for predicting content of free calcium oxide in cement clinker

Technical Field

The invention relates to a method for predicting the content of free calcium oxide in cement clinker, and belongs to the technical field of cement production control.

Background

The content of clinker free calcium oxide in the cement calcination process is an important standard for measuring the cement quality, and the content of clinker free calcium oxide represents the residual degree after calcium oxide is combined with silicon oxide, aluminum oxide and iron oxide in the calcination of raw materials, and the strength of the cement clinker is directly influenced by the content of the calcium oxide. Free calcium oxide of cement clinker is one of important indexes for reflecting the quality of the cement clinker, and the content of the free calcium oxide in the clinker during the calcination process of the cement clinker needs to be controlled within a reasonable range. The real-time prediction of the content of free calcium oxide in clinker is crucial to the guarantee of the calcination quality of cement clinker and the optimization of the calcination process.

At present, most laboratories of cement factories manually measure the content of free calcium oxide in cement clinker, adopt a glycerol-mango alcohol system as an extraction solvent, generate alkaline glycerol with the free calcium, and titrate with a hexanol benzoate standard solution. The on-line analyzer measuring method utilizes the fact that after ethylene glycol reacts with free calcium oxide in cement clinker, the conductivity of a solution and the content of the free calcium oxide form a certain proportional relation, and the content of the free calcium oxide is indirectly obtained through conductivity measurement.

The chemical test method has large delay and cannot truly reflect the production condition in the rotary kiln, so that the quality of the clinker is difficult to be effectively controlled. The online analyzer measurement method has the advantages of high equipment cost and high maintenance cost, and the measurement accuracy is easily influenced by site smoke dust and actual working conditions.

Disclosure of Invention

Aiming at the defects of the method, the invention provides a method for predicting the content of free calcium oxide in cement clinker, which can accurately predict the free calcium oxide in cement clinker in real time.

The technical scheme adopted for solving the technical problems is as follows:

the embodiment of the invention provides a method for predicting the content of free calcium oxide in cement clinker, which comprises the following steps:

s1: collecting a cement clinker sample;

s2: constructing a time sequence of free calcium oxide content of cement clinker;

s3: performing time sequence decomposition on the time sequence of the content of free calcium oxide in the mud clinker based on an empirical mode decomposition method:

s4: constructing input and output sample pairs required by a training feature extraction module;

s5: training the feature extraction submodule, namely a modularized echo state neural network, and learning the multi-time scale features of the time sequence:

s6: training the prediction module-echo state neural network:

s7: and predicting the content of free calcium oxide in the clinker.

As a possible implementation manner of this embodiment, in step S1, the sampling period is 1 hour, n times of continuous sampling are performed to obtain cement clinker samples online, and laboratory offline detection is performed manually, and the content u of free calcium oxide in cement clinker is recorded₁,u₂,……,u_n。

As a possible implementation manner of this embodiment, in step S3, the process of performing time-series decomposition on the time series of the free calcium oxide content of the clinker includes the following steps:

s3.1: setting an initial characteristic sequence number p to be 0; let h₀(t) U (t), U (t) is cement clinker free calcium oxide content time sequence, U (t) u_t，t＝1,2,……,n；

S3.2: setting the initial cycle number q to be 0;

s3.3: updating the cycle number q to q + 1;

s3.4: finding out all extreme points of the time sequence U (t) of the content of free calcium oxide of the cement clinker;

s3.5: forming a lower envelope e for the minimum points by cubic spline interpolation_min(t) forming an upper envelope e for the maxima_max(t)；

S3.6: calculating the mean of the extreme points:

s3.7: details of extraction:

d_q(t)＝h_p(t)-m(t)； (2)

s3.8: for detail signal d_q(t) repeating steps S3.3 to S3.7 until a detail signal d_q(t) has a mean value of 0;

s3.9: updating the characteristic sequence number p to p + 1;

s3.10: recording a feature sequence IMF_p(t)；

S3.11: calculating a residual sequence:

h_p(t)＝h_p-1(t)-IMF_p(t)； (3)

s3.12: to h_p(t) repeating S3.2 to S3.11 until h_p(t) is a monotonic function;

s3.13: let IMF_p(t)＝h_p(t)。

As a possible implementation manner of this embodiment, in step S4, the input/output sample pairs required for constructing the training feature extraction module are:

Ω_i＝(U(t),IMF_i(t)) (4)

wherein i is 1,2, …, p + 1; t is 1,2, …, n.

As a possible implementation manner of this embodiment, the step S5 specifically includes the following steps:

s5.1: setting an initial module number k to be 0;

s5.2: updating the number k of the modules to k + 1;

s5.3: setting module parameters: number of input neurons 1, number of output neurons 1, number of hidden layer neurons n_kSpectral radius ρ_kDegree of sparsity sp_k；

S5.4: randomly generating a network input weight matrix with uniform distribution over an interval (-0.1,0.1)

S5.5: randomly generating sparsity sp with uniform distribution over the interval (-1,1)_kOf (2) matrix

S5.6: computing matrices

Maximum eigenvalue of

S5.7: calculating hidden layer weight W_k：

S5.8: computing hidden layer neuron states:

where t is 1,2, L L, n, s_k(0)＝0；

S5.9: constructing a hidden layer state matrix:

s5.10: calculating a network output weight matrix:

wherein

For the hidden layer state matrix H_kThe transposed matrix of (2);

s5.11: and (3) calculating network output:

s5.12: repeating steps S5.2 to S5.11 until k ═ p + 1;

s5.13: collecting submodule output:

as a possible implementation manner of this embodiment, the step S6 includes the following steps:

s6.1: constructing network input I and reference output

S6.2: setting module parameters: number of input neurons p +1, number of output neurons 1, number of hidden layer neurons n_RSpectral radius ρ_RDegree of sparsity sp_R；

S6.3: randomly generating a network input weight matrix with uniform distribution over an interval (-0.1,0.1)

S6.4: randomly generating sparsity sp with uniform distribution over the interval (-1,1)_ROf (2) matrix

S6.5: computing matrices

Maximum eigenvalue of

S6.6: calculating hidden layer weight W_R

S6.7: computing hidden layer neuron states s_R(t)：

Wherein s is_R(0)＝0；

S6.8: constructing a hidden layer state matrix H_R：

S6.9: computing network output weight matrix

Wherein

For the hidden layer state matrix H_RThe transposed matrix of (2).

As a possible implementation manner of this embodiment, the step S7 specifically includes: inputting the test sample into the trained feature extraction module, and outputting by the prediction module to obtain the free calcium oxide content of the cement clinker at the next moment.

The technical scheme of the embodiment of the invention has the following beneficial effects:

aiming at the problem of online prediction of the free calcium oxide content of the cement clinker, the invention designs an intelligent prediction method of the free calcium oxide content of the cement clinker based on time sequence decomposition and a neural network, and realizes accurate prediction of the free calcium oxide content of the cement clinker; the empirical mode decomposition and the modularized echo state are combined, a time series multi-time scale feature learning method is provided, the automatic extraction of the time series multi-time scale features is realized, and the free calcium oxide of the cement clinker can be accurately predicted in real time.

The method predicts the content of free calcium oxide at the next moment based on off-line experimental data, and solves the problem of lag of laboratory measurement results; compared with the measurement method of an on-line analyzer, the method has low cost, and the measurement accuracy is less influenced by on-site smoke dust and actual working conditions.

Description of the drawings:

FIG. 1 is a flow chart illustrating a method for predicting free calcium oxide content of cement clinker in accordance with an exemplary embodiment;

FIG. 2 is a diagram of a predictive model topology;

FIG. 3 is a comparison graph of predicted values and measured values;

fig. 4 is a prediction error map.

Detailed Description

The invention is further illustrated by the following examples in conjunction with the accompanying drawings:

in order to clearly explain the technical features of the present invention, the following detailed description of the present invention is provided with reference to the accompanying drawings. The following disclosure provides many different embodiments, or examples, for implementing different features of the invention. To simplify the disclosure of the present invention, the components and arrangements of specific examples are described below. Furthermore, the present invention may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed. It should be noted that the components illustrated in the figures are not necessarily drawn to scale. Descriptions of well-known components and processing techniques and procedures are omitted so as to not unnecessarily limit the invention.

FIG. 1 is a flow chart illustrating a method for predicting free calcium oxide content of cement clinker according to an exemplary embodiment. As shown in fig. 1, a method for predicting the content of free calcium oxide in cement clinker provided by the embodiment of the present invention includes the following steps:

s1: collecting a cement clinker sample;

s2: constructing a time sequence of free calcium oxide content of cement clinker;

s3: performing time sequence decomposition on the time sequence of the content of free calcium oxide in the mud clinker based on an empirical mode decomposition method:

s4: constructing input and output sample pairs required by a training feature extraction module;

s5: training the feature extraction submodule, namely a modularized echo state neural network, and learning the multi-time scale features of the time sequence:

s6: training the prediction module-echo state neural network:

s7: and predicting the content of free calcium oxide in the clinker.

As a possible implementation manner of this embodiment, in step S1, the sampling period is 1 hour, n times of continuous sampling are performed to obtain cement clinker samples online, and laboratory offline detection is performed manually, and the content u of free calcium oxide in cement clinker is recorded₁,u₂,……,u_n。

As a possible implementation manner of this embodiment, in step S3, the process of performing time-series decomposition on the time series of the free calcium oxide content of the clinker includes the following steps:

s3.1: setting an initial characteristic sequence number p to be 0; let h₀(t) U (t), U (t) is cement clinker free calcium oxide content time sequence, U (t) u_t，t＝1,2,……,n；

S3.2: setting the initial cycle number q to be 0;

s3.3: updating the cycle number q to q + 1;

s3.4: finding out all extreme points of the time sequence U (t) of the content of free calcium oxide of the cement clinker;

s3.5: forming a lower envelope e for the minimum points by cubic spline interpolation_min(t) forming an upper envelope e for the maxima_max(t)；

S3.6: calculating the mean of the extreme points:

s3.7: details of extraction:

d_q(t)＝h_p(t)-m(t)； (2)

s3.8: for detail signal d_q(t) repeating steps S3.3 to S3.7 until a detail signal d_q(t) has a mean value of 0;

s3.9: updating the characteristic sequence number p to p + 1;

s3.10: recording a feature sequence IMF_p(t)；

S3.11: calculating a residual sequence:

h_p(t)＝h_p-1(t)-IMF_p(t)； (3)

s3.12: to h_p(t) repeating S3.2 to S3.11 until h_p(t) is a monotonic function;

s3.13: let IMF_p+1(t)＝h_p(t)。

As a possible implementation manner of this embodiment, in step S4, the input/output sample pairs required for constructing the training feature extraction module are:

Ω_i＝(U(t),IMF_i(t)) (4)

wherein i is 1,2, …, p + 1; t is 1,2, …, n.

As a possible implementation manner of this embodiment, the step S5 specifically includes the following steps:

s5.1: setting an initial module number k to be 0;

s5.2: updating the number k of the modules to k + 1;

s5.3: setting module parameters: number of input neurons 1, number of output neurons 1, number of hidden layer neurons n_kSpectral radius ρ_kDegree of sparsity sp_k；

S5.4: randomly generating a network input weight matrix with uniform distribution over an interval (-0.1,0.1)

S5.5: randomly generating sparsity sp with uniform distribution over the interval (-1,1)_kOf (2) matrix

S5.6: computing matrices

Maximum eigenvalue of

S5.7: calculating hidden layer weight W_k：

S5.8: computing hidden layer neuron states:

wherein t is 1,2, … …, n; s, s_k(0)＝0；

S5.9: constructing a hidden layer state matrix:

s5.10: calculating a network output weight matrix:

wherein

For the hidden layer state matrix H_kThe transposed matrix of (2);

s5.11: and (3) calculating network output:

s5.12: repeating steps S5.2 to S5.11 until k ═ p + 1;

s5.13: collecting submodule output:

as a possible implementation manner of this embodiment, the step S6 includes the following steps:

s6.1: constructing network input I and reference output

S6.2: setting module parameters: number of input neurons p +1, number of output neurons 1, number of hidden layer neurons n_RSpectral radius ρ_RDegree of sparsity sp_R；

S6.3: randomly generating a network input weight matrix with uniform distribution over an interval (-0.1,0.1)

S6.4: randomly generating sparsity sp with uniform distribution over the interval (-1,1)_ROf (2) matrix

S6.5: computing matrices

Maximum eigenvalue of

S6.6: computing hidden layer weightsValue W_R

S6.7: computing hidden layer neuron states s_R(t)：

Wherein s is_R(0)＝0；

S6.8: constructing a hidden layer state matrix H_R：

S6.9: computing network output weight matrix

Wherein

For the hidden layer state matrix H_RThe transposed matrix of (2).

As a possible implementation manner of this embodiment, the step S7 specifically includes: as shown in fig. 2, the test sample is input into the trained feature extraction module, and the output of the prediction module is the free calcium oxide content of the cement clinker at the next moment.

The present example employed 1000 sets of laboratory test data for a cement manufacturing enterprise, with the first 800 sets being used for training and the last 200 sets being used for testing. The test results are shown in fig. 3, X-axis: sample (one/hour), Y-axis: free calcium oxide content (%),. o is the predicted result, is the measured free calcium oxide content; the error between the model prediction result and the actually measured free calcium oxide content is shown in fig. 4, wherein the X axis: sample (one/hour), Y-axis: the difference between the model prediction result and the actually measured content of the free calcium oxide proves the effectiveness of the method.

The foregoing is only a preferred embodiment of the present invention, and it will be apparent to those skilled in the art that various modifications and improvements can be made without departing from the principle of the present invention, and these modifications and improvements are also considered to be within the scope of the present invention.

Claims (2)

1. A method for predicting the content of free calcium oxide in cement clinker is characterized by comprising the following steps:

s1: collecting a cement clinker sample;

s2: constructing a time sequence of free calcium oxide content of cement clinker;

s3: performing time sequence decomposition on the time sequence of the content of free calcium oxide in the cement clinker based on an empirical mode decomposition method:

s4: constructing input and output sample pairs required by a training feature extraction module;

s5: training the feature extraction submodule, namely a modularized echo state neural network, and learning the multi-time scale features of the time sequence:

s6: training the prediction module-echo state neural network:

s7: predicting the content of free calcium oxide in cement clinker;

in step S1, sampling period is 1 hour, continuously sampling n times to obtain cement clinker sample on line, and manually carrying out laboratory off-line detection, and recording cement clinker free calcium oxide content u₁,u₂,……,u_n；

In step S3, the process of performing time-series decomposition on the time series of the content of free calcium oxide in the clinker comprises the following steps:

s3.1: setting an initial characteristic sequence number p to be 0; let h₀(t) U (t), U (t) is cement clinker free calcium oxide content time sequence, U (t) u_t，t＝1,2,……,n；

S3.2: setting the initial cycle number q to be 0;

s3.3: updating the cycle number q to q + 1;

s3.4: finding out all extreme points of the time sequence U (t) of the content of free calcium oxide in the cement clinker;

s3.5: forming a lower envelope e for the minimum points by cubic spline interpolation_min(t) forming an upper envelope e for the maxima_max(t)；

S3.6: calculating the mean of the extreme points:

s3.7: details of extraction:

d_q(t)＝h_p(t)-m(t)； (2)

s3.8: for detail signal d_q(t) repeating steps S3.3 to S3.7 until the detail signal d_q(t) has a mean value of 0;

s3.9: updating the characteristic sequence number p to p + 1;

s3.10: recording a feature sequence IMF_p(t)；

S3.11: calculating a residual sequence:

h_p(t)＝h_p-1(t)-IMF_p(t)； (3)

s3.12: to h_p(t) repeating S3.2 to S3.11 until h_p(t) is a monotonic function;

s3.13: let IMF_p(t)＝h_p(t)；

In step S4, the input/output sample pairs required for constructing the training feature extraction module are:

Ω_i＝(U(t),IMF_i(t)) (4)

wherein U (t) is a time series of the free calcium oxide content of the cement clinker, IMF_i(t) is a signature sequence, i ═ 1,2, …, p + 1; t is 1,2, …, n;

the step S5 specifically includes the following steps:

s5.1: setting an initial module number k to be 0;

s5.2: updating the number k of the modules to k + 1;

s5.3: setting module parameters: number of input neurons 1, number of output neurons 1, number of hidden layer neurons n_kSpectral radius ρ_kDegree of sparsity sp_k；

S5.4: randomly generating a network input weight matrix with uniform distribution over an interval (-0.1,0.1)

S5.5: randomly generating sparsity sp with uniform distribution over the interval (-1,1)_kOf (2) matrix

S5.6: computing matrices

Maximum eigenvalue of

S5.7: calculating hidden layer weight W_k：

S5.8: computing hidden layer neuron states:

where t is 1,2, … …, n, s_k(0)＝0；

S5.9: constructing a hidden layer state matrix:

s5.10: calculating a network output weight matrix:

wherein

For the hidden layer state matrix H_kThe transposed matrix of (2);

s5.11: and (3) calculating network output:

s5.12: repeating steps S5.2 to S5.11 until k ═ p + 1;

s5.13: collecting submodule output:

the step S6 includes the steps of:

s6.1: constructing network input I and reference output

S6.2: setting module parameters: number of input neurons p +1, number of output neurons 1, number of hidden layer neurons n_RSpectral radius ρ_RDegree of sparsity sp_R；

S6.3: in the interval (-0.1,0.1)Randomly generating the network input weight matrix in uniform distribution

S6.4: randomly generating sparsity sp with uniform distribution over the interval (-1,1)_ROf (2) matrix

S6.5: computing matrices

Maximum eigenvalue of

S6.6: calculating hidden layer weight W_R

S6.7: computing hidden layer neuron states s_R(t)：

Wherein s is_R(0)＝0；

S6.8: constructing a hidden layer state matrix H_R：

S6.9: computing network output weight matrix

Wherein

For the hidden layer state matrix H_RThe transposed matrix of (2).

2. The method for predicting the content of free calcium oxide in cement clinker according to claim 1, wherein the step S7 specifically comprises: inputting the test sample into the trained feature extraction module, and outputting by the prediction module to obtain the free calcium oxide content of the cement clinker at the next moment.

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