SHM系统的新激励(多宽脉冲激励(mwpe))方法。第1部分:时频域特性的可视化

Proceedings of the 13th International Workshop on Structural Health Monitoring Pub Date : 2022-03-15 DOI:10.12783/shm2021/36341

I. Tansel, Alireza Modir

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引用次数: 0

摘要

由于表面波的衰减非常强，增材制造聚合物部件的结构健康监测(SHM)具有挑战性。为了在极短的时间内对零件表面进行极宽频带的激励，引入了多宽脉冲激励(MWPE)信号。利用MPWE对结构表面进行激励，实现表面激励响应(surface Response to Excitation, SuRE)方法。为了识别填充物的隐藏几何形状，采用增材制造了十字形聚合物零件。该部件有四个具有相同几何形状但内部设计不同的扩展部分。其中两个扩展部分是交叉填充，另外两个是方形填充。对于每种类型的填充物，一个延伸有1毫米厚，另一个延伸有2毫米厚的皮肤。采用WMPE励磁法对中间部分进行激励，并在每次延伸结束时监测其动态响应。采用短时快速傅立叶变换(STFFT)对信号进行时频分析。采用二维差分平方和(2DSSD)对信号进行分类。所有试验用例的压缩力和填充物类型都得到了准确的识别。

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NEW EXCITATION (MULTIPLE WIDTH PULSE EXCITATION (MWPE)) METHOD FOR SHM SYSTEMS—PART 1: VISUALIZATION OF TIME- FREQUENCY DOMAIN CHARACTERISTICS

Structural health monitoring (SHM) of additively manufactured polymer parts is challenging due to the very strong attenuation of the surface waves. To excite the part surface at a very wide frequency band in a very short time, Multiple Width Pulse Excitation (MWPE) signal was introduced. MPWE was used to excite the surface of the structure for the implementation of the Surface Response to Excitation (SuRE) method. A cross-shaped polymer part was fabricated additively for the identification of the hidden geometry of the infill. The part had four extensions with identical geometry but different internal designs. Two of the extensions had cross infills and the other two had square infills. For each type of infill, one extension had 1 mm and the other extension had 2 mm thick skin. The part was excited at the middle with WMPE excitation and the dynamic response was monitored at the end of each extension. The Short-Time Fast Fourier Transform (STFFT) was used for the analysis of the signal in the time-frequency domain. The two dimentional sum of the squares of the differences (2DSSD) was used for the classification of the signal. Compressive force and type of infill was identified accurately for all the test cases.

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Proceedings of the 13th International Workshop on Structural Health Monitoring

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