基于EMD的螺旋输送机叶片运动速度静电检测方法

doi:10.16085/j.issn.1000-6613.2023-1380

化工进展 ›› 2024, Vol. 43 ›› Issue (2): 752-759.DOI: 10.16085/j.issn.1000-6613.2023-1380

基于EMD的螺旋输送机叶片运动速度静电检测方法

王超¹(), 曹辉², 马国纪², 叶佳敏¹(), 纪学玲¹

^1.天津大学电气自动化与信息工程学院，天津 30072
^2.天津大学未来技术学院，天津 30072

收稿日期:2023-08-11 修回日期:2023-10-23 出版日期:2024-02-25 发布日期:2024-03-07
通讯作者: 叶佳敏
作者简介:王超（1973—），男，博士，教授，研究方向为多相流测量。E-mail：wangchao@tju.edu.cn。

EMD-based electrostatic detection of screw conveyor blade motion

WANG Chao¹(), CAO Hui², MA Guoji², YE Jiamin¹(), JI Xueling¹

^1.School of Electrical and Information Engineering, Tianjin University, Tianjin 30072, China
^2.School of Future Technology, Tianjin University, Tianjin 30072, China

Received:2023-08-11 Revised:2023-10-23 Online:2024-02-25 Published:2024-03-07
Contact: YE Jiamin

摘要/Abstract

摘要：

螺旋输送机广泛应用于化工、冶金、粮食和运输等领域，其螺旋叶片的运动对输送状态有直接的影响。多采用封闭运输，且运行环境恶劣，经过较长时间工作后，易出现螺旋叶片变形甚至断轴等事故。通过实时检测螺旋叶片的运动速度，可及时获得螺旋输送机的运行状态。针对缺少有效的螺旋叶片运动速度检测手段的问题，本文设计了静电传感器，针对静电信号噪声干扰严重的问题，提出了基于经验模态分解（empirical mode decomposition，EMD）的静电信号滤波处理方法，对滤波处理后的信号通过互相关计算，可以获得螺旋叶片的上升速度。实验结果表明：螺旋输送过程中，管壁处检测到的静电信号具有周期性，且与螺旋叶片经过电极的频次一致，经基于EMD的滤波处理和螺旋转速修正，螺旋转速测量相对误差为0.67%。

关键词: 螺旋输送机, 静电传感器, 经验模态分解, 测量, 颗粒物料, 多相流

Abstract:

Screw conveyor is widely used in chemical industry, metallurgy, grain and transport and other fields, and the movement of its screw blade has a direct impact on the conveying state. Most of the closed transport, and harsh operating environment, after a long time of work, easy to deformation of the spiral blade, or even broken shafts and other accidents, through real-time detection of the movement speed of the spiral blade, can be timely access to the operating status of the screw conveyor. For the lack of effective means of detecting the movement speed of the spiral blade, an electrostatic sensor was designed, and the problem of serious noise interference of the electrostatic signal was proposed based on the empirical mode decomposition (empirical mode decomposition, EMD) of the electrostatic signal filtering method, and the filtered signals could be obtained through the mutual correlation calculation of the rising speed of the spiral blade. The rising speed of the spiral blade could be obtained by the cross-correlation calculation of the filtered signal. The experimental results showed that the electrostatic signal detected at the pipe wall during the spiral conveying process was periodic and consistent with the frequency of the spiral blade passing through the electrodes, and the relative error of the spiral speed measurement was 0.67% after the filtering process based on EMD and the correction of the spiral speed.

Key words: crew conveyor, electrostatic sensor, empirical mode decomposition, measurement, particulate material, multiphase flow

中图分类号:

TP212.9

王超, 曹辉, 马国纪, 叶佳敏, 纪学玲. 基于EMD的螺旋输送机叶片运动速度静电检测方法[J]. 化工进展, 2024, 43(2): 752-759.

WANG Chao, CAO Hui, MA Guoji, YE Jiamin, JI Xueling. EMD-based electrostatic detection of screw conveyor blade motion[J]. Chemical Industry and Engineering Progress, 2024, 43(2): 752-759.

图/表 16

图1 螺旋输送实验装置

图2 螺旋叶片与静电传感器的结构尺寸

图3 静电检测系统

图4 螺旋叶片运动过程

表1 实验条件

参数	数据1	数据2	数据3	数据4	数据5	数据6
转速/r·min^-1	215	230	245	260	275	289

图5 原始静电信号

表2 信号周期关系

转速/r·min^-1	叶片经过电极次数	周期个数
215	14.3	14
230	15.3	15
245	16.3	16
260	17.3	17
275	18.3	18
289	19.3	19

图6 两个电极原始静电信号

图7 EMD分解结果

图8 IMF傅里叶频谱图

图9 IMF能量分数以及相关系数

图10 IMF1互相关函数

图11 相关系数

图12 静电检测的叶片上升速度

图13 螺旋测量转速与误差

图14 螺旋修正转速与误差

参考文献 9

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基于EMD的螺旋输送机叶片运动速度静电检测方法

EMD-based electrostatic detection of screw conveyor blade motion

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