不同衰减函数的钢丝绳漏磁信号自适应降噪

doi:10.3969/j.issn.1000-1158.2024.10.16

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摘要讨论了双曲线函数、指数函数、线性函数3种不同衰减函数对钢丝绳漏磁信号降噪效果的影响,对损伤含噪信号进行自适应移位平均降噪,并使用信噪比、互相关系数对降噪效果作了对比分析。结果表明,针对所用的2种漏磁信号,使用双曲线函数的降噪信号信噪比最大可达14.1041dB与10.8349dB,大于指数函数与线性函数所得的对应信噪比值,且得到的输出曲线平滑,具有更好的降噪效果。同时,随着噪声增大,使用双曲线函数的降噪信号互相关系数更快地接近1,具有更好的动态特性。

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	吴东
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关键词 ：漏磁检测, 钢丝绳, 强噪声, 自适应降噪, 双曲线函数, 移位平均法, 衰减函数

Abstract：The effects of three different attenuation functions, namely, hyperbolic function, exponential function and linear function, on the noise reduction effect of wire rope magnetic flux leakage signal are discussed.Adaptive shift average denoising is applied to noisy signals with damage, and the denoising effect is compared and analyzed using signal-to-noise ratio and correlation number.The results show that for the two types of magnetic leakage signals used, the maximum SNR of the denoising signal using hyperbolic functions can reach 14.1041dB and 10.8349dB, which is greater than the corresponding SNR obtained from exponential and linear functions.The output curve obtained is smooth and has better denoising effect.Meanwhile, as the noise increases, the correlation number of denoised signals using hyperbolic functions approaches 1 faster, exhibiting better dynamic characteristics.

Key words： magnetic flux leakage testing steel wire rope strong noise adaptive denoising hyperbolic functions shift average method attenuation function

收稿日期: 2023-09-25 发布日期: 2024-09-30

PACS:

TB972

基金资助:鞍钢集团矿业有限公司科研项目(2020-科A40)

通讯作者: 杨建华(1982-),河北泊头人,中国矿业大学教授,主要研究方向为高端装备智能运维。Email: jianhuayang@cumt.edu.cn E-mail: jianhuayang@cumt.edu.cn

作者简介: 吴东(1982-),宁夏平罗人,鞍钢集团矿业有限公司工程师,主要研究方向为矿山提升系统与安全管理。Email: wudong2005@163.com

引用本文:

吴东,黄升平,周立峰,隋显俊,宋洪志,杨建华. 不同衰减函数的钢丝绳漏磁信号自适应降噪[J]. 计量学报, 2024, 45(10): 1549-1554.
WU Dong,HUANG Shengping,ZHOU Lifeng,SUI Xianjun,SONG Hongzhi,YANG Jianhua. Adaptive Denoising of Magnetic Flux Leakage Signals of Steel Wire Ropes Based on Different Attenuation Functions. Acta Metrologica Sinica, 2024, 45(10): 1549-1554.

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http://jlxb.china-csm.org:81/Jwk_jlxb/CN/10.3969/j.issn.1000-1158.2024.10.16 或 http://jlxb.china-csm.org:81/Jwk_jlxb/CN/Y2024/V45/I10/1549

［1］	李玉瑾. 矿井提升系统的装备技术与展望［J］. 煤炭工程, 2014, 46(10): 61-64.
	DAI J W. Discussion on damage detection of hoisting steel wire rope ［J］. China Standardization, 2017 (20): 255-256.
	LIANG H, HONG R Y, YANG G H. Research on wire rope nondestructive testing technology based on the magnetic flux leakage signals ［J］. Piezoelectrics and Acoustooptics, 2008 ( 4): 508-510.
	ZHOU H Y, SUN J, XU H W,et al. Ultrasonic defect echoes identification based on EEMD and low-rank sparse decomposition ［J］. Acta Metrologica Sinica,2022, 43(1): 77-84.
［6］	张楠. 基于小波变换的钢丝绳断丝定量检测技术研究［J］. 煤炭工程, 2013 (2): 129-131.
	ZHAO J, HUA G, YU B. De-noising method of mine wire rope damage signal based on lmproved wavelet threshold algorithm ［J］. Coal Mine Machinery, 2013, 34(1): 284-286.
	ZHANG S X, LI S J, ZHANG Y. Research on acquiring method of characteristics of steel wire rope damage detection signal ［J］. Coal Technology, 2015, 34(3): 271-273.
	DOU L C, ZHAN W X, BAI X R. Damage identification of broken wires inside and outside the wire rope ［J］. Journal of Mine Automation, 2021, 47(3): 83-88.
［11］	Hung N H, Yang Z J, Profitability of applying simple moving average trading rules for the Vietnamese stock market, Journal of Business Management, 2013, 2(3): 22-31.
［13］	胡阳, 康宜华, 卢文祥, 等. 钢丝绳无损检测中的一些算法——信号的预处理和特征提取［J］. 无损检测, 2000 (11): 483-488.
［14］	王龙, 潘存治, 王彦, 等. 钢丝绳缺陷漏磁信号的降噪及波形特征的提取［J］. 矿山机械, 2014, 42(2): 49-53.
［2］	代俊伟. 提升钢丝绳损伤检测问题的探讨［J］. 中国标准化, 2017 (20): 255-256.
［5］	陈剑, 刘圆圆, 黄凯旋, 等. 基于奇异值分解和独立分量分析的滚动轴承故障诊断方法［J］. 计量学报, 2022, 43(6): 777-785.
［7］	赵洁, 华钢, 于博. 基于改进小波阈值算法的矿用钢丝绳损伤检测信号去噪方法［J］. 煤矿机械, 2013, 34(1): 284-286.
［10］	王红尧, 吴佳奇, 李长恒, 等. 矿用钢丝绳损伤检测信号处理方法研究［J］. 工矿自动化, 2021, 47(2): 58-62.
	WU D, ZHANG B J, LIU W X, et al. Noise reduction method for wire rope damage signal under strong noise background ［J］. Journal of Mine Automation, 2022, 48(1): 58-63.
［4］	周航锐, 孙坚, 徐红伟, 等. 基于EEMD和低秩稀疏分解的超声缺陷回波检测方法［J］. 计量学报, 2022, 43(1): 77-84.
［9］	窦连城, 战卫侠, 白晓瑞. 钢丝绳内外部断丝损伤识别［J］. 工矿自动化, 2021, 47(3): 83-88.
	WANG L, PAN C Z, WANG Y, et al. Denoising and waveform feature extraction of magnetic leakage signal due to fault of wire rope ［J］. Mining Machinery, 2014, 42(2): 49-53.
［3］	梁华, 洪汝渝, 杨光祥. 基于漏磁信号的钢丝绳检测技术研究［J］. 压电与声光, 2008 (4): 508-510.
［8］	张守新, 李思嘉, 张瑜. 钢丝绳损伤检测信号的特征量获取方法研究［J］. 煤炭技术, 2015, 34(3): 271-273.
	HU Y, KANG Y H, LU W X, et al. Some algorithms for nondestructive testing of wire ropes—signal pre-processing and character extraction ［J］. Nondestructive Testing, 2000 (11): 483-488.
	LI Y J. Equipment technology and prospects of mine hoisting system ［J］. Coal Engineering, 2014, 46(10): 61-64.
	ZHANG N. Study on Broken Wire Quantitative Detection Technology of Steel Rope Base on Wavelet Transform ［J］. Coal Engineering, 2013 (2): 129-131.
［12］	吴东, 张宝金, 刘伟新, 等. 强噪声背景下钢丝绳损伤信号降噪方法［J］. 工矿自动化, 2022, 48(1): 58-63.
	CHEN J, LIU Y Y, HUANG K X, et al. Rolling bearing fault diagnosis method based on singular value decomposition and independent component analysis ［J］. Acta Metrologica Sinica, 2022, 43(6): 777-785.
	WANG H Y, WU J Q, LI C H, et al. Research on signal processing method of mine wire rope damage detection ［J］. Journal of Mine Automation, 2021, 47(2): 58-62.
［15］	SHAN Z, YANG J H, SANJN M A F, et al. A novel adaptive moving average method for signal denoising in strong noise background ［J］. The European Physical Journal Plus, 2022, 137(1): 50.