基于声发射技术的连续重整反应器故障诊断

doi:10.3969/j.issn.1006-8805.2024.05.002

Petro-chemical Equipment Technology ›› 2024, Vol. 45 ›› Issue (5): 6-10.doi: 10.3969/j.issn.1006-8805.2024.05.002

• CONDITION MONITORING AND ANALYSIS • Previous Articles

Fault Diagnosis of Continuous Reforming Reactor Based on Acoustic Emission Technology

Mo Yajing, Bao Wenjun, Chen Jianfei

SINOPEC Engineering Group Luoyang R&D Center of Technology, Luoyang, Henan, 471003

Received:2024-06-01 Accepted:2024-08-30 Online:2024-09-15 Published:2024-11-08

Abstract

Abstract: Reforming reactor is the key equipment of continuous reforming unit. In the reactor, the contact between the gas and solid phases is a cross flow contact. The abnormal phenomena cavity and pinning could occur if the gas flow is large enough, which may greatly restrict the operating flexibility and affect the safe and stable operation of the reactor. Acoustic emission technology was used to detect the reactor under cold operation. The acoustic emission data of different operation states of the reactor were compared and analyzedso as to determine in time whether the above-mentioned abnormal phenomena occurred or not.The experimental results showed that the waveform was stable during normal operation of the reactor and the average signal level was 20 dB; the amplitude was 35~45 dB. The waveform displayed pulse shape when the reactor was abnormal. When cavity appeared, the average signal level was 20~35 dB; the amplitude was 35~55 dB and the characteristic frequency was 25~150 kHz. When pinning appeared, the average signal level was 30~60 dB; the amplitude was 35~75 dB and the characteristic frequency was 25~250 kHz. The waveform, characteristic parameters and power spectrum of the signal changed obviously when the flow state of the catalyst changed. By using multiple sensors, the fault could be located and the fault type could be identified. The above results indicate that as a non-invasive measurement technology, acoustic emission technology can effectively detect the operation state of the continuous reforming reactor and can provide technical support for the long-term safe and stable operation of the device.

Key words: reforming reactor, gas-solid flow, acoustic emission, cavity, pinning, fault diagnosis

Mo Yajing, Bao Wenjun, Chen Jianfei. Fault Diagnosis of Continuous Reforming Reactor Based on Acoustic Emission Technology[J].Petro-chemical Equipment Technology, 2024, 45(5): 6-10.

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Fault Diagnosis of Continuous Reforming Reactor Based on Acoustic Emission Technology

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