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A LSTM Model with Attention Mechanism for Soft Sensor of SO2 Conversion Rate in Flue Gas Acid Production Process

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Abstract:

The sulfur dioxide (SO2) concentration of flue gas in metal smelting industry is high and difficult to recycle. The commonly used SO2 desulfurization treatment is acid pr...Show More

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Abstract:

The sulfur dioxide (SO2) concentration of flue gas in metal smelting industry is high and difficult to recycle. The commonly used SO2 desulfurization treatment is acid production from flue gas, however, it is difficult to directly measure the conversion rate of SO2. In this paper, we present a soft sensor method based on Long Short-Term Memory (LSTM) which integrates the attention mechanism for predicting SO2 conversion rate to tackle such problem. Considering that the change of SO2 conversion rate is affected by many external factors, the attention mechanism is used to quickly and accurately predict the change results by considering the system data of several past moments. The proposed attention mechanism uses LSTM units to encode the hidden state of the look back time data, obtains different attention weights, and then decodes and predicts SO2 conversion rate according to the hidden state. The experimental results indicate that LSTM model with attention mechanism has lower training cost compared with LSTM model. The training accuracy and soft sensor accuracy are also improved owing to the attention mechanism. It is instructive for SO2 conversion rate soft sensor in acid production from flue gas.

Published in: 2023 IEEE 12th Data Driven Control and Learning Systems Conference (DDCLS)

Date of Conference: 12-14 May 2023

Date Added to IEEE Xplore: 07 July 2023

ISBN Information:

ISSN Information:

DOI: 10.1109/DDCLS58216.2023.10166479

Conference Location: Xiangtan, China

Funding Agency:

References is not available for this document.

Contents

1 Introduction

With the increasing production scale of the smelting industry, the atmospheric pollution caused by sulfur dioxide (SO2) in smelting flue gas is becoming increasingly serious. Smelting flue gas desulfurization has been the focal crux part of air pollution prevention and control for a long time. Smelting flue gas is usually treatment by acid production from flue gas. The acid production method can effectively reduce the sulfur content of smelting flue gas, generate high concentration sulfuric acid, improve air pollution and soil acidification, and reduce the cost of sulfuric acid production and energy consumption. The key link of desulfurization and acid production from flue gas is the process that sulfur trioxide (SO3) converted from SO2 dissolves in water to produce sulfuric acid. The quality and yield of sulfuric acid depend on the SO2 conversion rate, the higher the conversion rate, the higher the quality of sulfuric acid generated. Therefore, the level of SO2 conversion rate reflects the performance of the smelting production system and provides guidance for the system control [1].

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A LSTM Model with Attention Mechanism for Soft Sensor of SO2 Conversion Rate in Flue Gas Acid Production Process

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A LSTM Model with Attention Mechanism for Soft Sensor of SO2 Conversion Rate in Flue Gas Acid Production Process

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Abstract:

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Abstract:

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1 Introduction

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