Forecasting of Fouling in Air Pre-Heaters Through Deep Learning

ASME 2021 Power Conference Pub Date : 2021-07-20 DOI:10.1115/power2021-64665

Ashit Gupta, Vishal Jadhav, Mukul Patil, A. Deodhar, V. Runkana

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引用次数: 6

Abstract

Thermal power plants employ regenerative type air pre-heaters (APH) for recovering heat from the boiler flue gases. APH fouling occurs due to deposition of ash particles and products formed by reactions between leaked ammonia from the upstream selective catalytic reduction (SCR) unit and sulphur oxides (SOx) present in the flue gases. Fouling is strongly influenced by concentrations of ammonia and sulphur oxide as well as the flue gas temperature within APH. It increases the differential pressure across APH over time, ultimately leading to forced outages. Owing to lack of sensors within APH and the complex thermo-chemical phenomena, fouling is quite unpredictable. We present a deep learning based model for forecasting the gas differential pressure across the APH using the Long Short Term Memory (LSTM) networks. The model is trained and tested with data generated by a plant model, validated against an industrial scale APH. The model forecasts the gas differential pressure across APH within an accuracy band of 5–10% up to 3 months in advance, as a function of operating conditions. We also propose a digital twin of APH that can provide real-time insights into progression of fouling and preempt the forced outages.

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基于深度学习的空气预热器结垢预测

火力发电厂采用蓄热式空气预热器(APH)从锅炉烟气中回收热量。APH污染的发生是由于上游选择性催化还原(SCR)装置泄漏的氨与烟气中存在的硫氧化物(SOx)反应形成的灰颗粒和产物的沉积。结垢受氨和硫氧化物浓度以及APH内烟气温度的强烈影响。随着时间的推移，它会增加APH之间的压差，最终导致强制停机。由于APH内部缺乏传感器和复杂的热化学现象，污垢是非常不可预测的。我们提出了一个基于深度学习的模型，用于使用长短期记忆(LSTM)网络预测APH上的气差压。该模型使用工厂模型生成的数据进行训练和测试，并针对工业规模的APH进行验证。该模型可以根据工况提前3个月预测APH上的气压差，预测精度在5-10%之间。我们还提出了一个APH的数字孪生体，可以提供对污垢进展的实时洞察，并先发制人地进行强制停机。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ASME 2021 Power Conference

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