Study on Formation, Deposition and Fouling Prediction of Ammonium Bisulfate (ABS) at Air Preheater in Utility Boiler

ASME 2020 Power Conference Pub Date : 2020-08-04 DOI:10.1115/power2020-16708

L. Pang, Q. Liang, Liqiang Duan

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Abstract

The ammonium bisulfate (ABS) widely exists at air preheater. The ABS may deposit and foul at the heating elements of air preheater because of the chemical reaction between SO3 at flue gas side and ammonia slip from SCR excess injection. The heat transfer equation between flue gas side and air side is constructed and simplified using physical and mathematical models accordingly. The finite difference method is applied to solve numerically by means of iterative computation. Based on the NH3 and SO3 concentration data from the real time data in the actual operation and the discrete calculation of the temperature field, the Radian number (Ra) is used to evaluate the possibility of ABS fouling and the developing trend of heating elements at the air preheater. A 1000MW ultra supercritical boiler is selected as example. The ABS deposit area is simulated under different working conditions 100%BMCR, 75% BMCR and 50% BMCR. The possible ABS deposition and fouling is analyzed for operators to evaluate the risk of cold-end and hot-end heating elements plate at air preheater. As the working load decreases lower than 50%BMCR, the deposition and fouling position could extend to the hot-end area of heating elements at air preheater.

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硫酸氢铵(ABS)在锅炉空气预热器中的形成、沉积及污染预测研究

硫酸氢铵广泛存在于空气预热器中。由于烟气侧的SO3与SCR过量喷射产生的氨滑脱发生化学反应，ABS可能在空气预热器的加热元件上沉积并发臭。建立了烟气侧与空气侧的传热方程，并用物理模型和数学模型对其进行了简化。采用有限差分法，通过迭代计算进行数值求解。基于实际运行中实时数据的NH3和SO3浓度数据和温度场的离散计算，采用弧度数(Ra)来评价空气预热器ABS结垢的可能性和加热元件的发展趋势。以某1000MW超超临界锅炉为例。模拟了100%BMCR、75% BMCR和50% BMCR不同工况下ABS沉积区。分析了空气预热器冷端和热端加热元件板可能出现的ABS沉积和结垢情况，以供操作人员评估空气预热器冷端和热端加热元件板的风险。当工作负荷降低到50%BMCR以下时，空气预热器的沉积和结垢位置可能延伸到加热元件的热端区域。

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 2020 Power Conference

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