Optimization Analysis of Various Parameters Based on Response Surface Methodology for Enhancing NOx Catalytic Reduction Performance of Urea Selective Catalytic Reduction on Cu-ZSM-13 Catalyst

Processes Pub Date : 2024-07-19 DOI:10.3390/pr12071519

Weiqi Li, Jie Wu, Dongwei Yao, Feng Wu, Lei Wang, Hua Lou, Haibin He, Jingyi Hu

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Abstract

While selective catalytic reduction (SCR) has long been indispensable for nitrogen oxide (NOx) removal, optimizing its performance remains a significant challenge. This study investigates the combined effects of structural and intake parameters on SCR performance, an aspect often overlooked in previous research. This paper innovatively developed a three-dimensional SCR channel model and employed response surface methodology to conduct an in-depth analysis of multiple key factors. This multidimensional, multi-method approach enables a more comprehensive understanding of SCR system mechanics. Through target optimization, we achieved a simultaneous improvement in three critical indicators: the NOx conversion rate, pressure drop, and ammonia slip. It is worth noting that the NOx conversion rate has been optimized from 17.07% to 98.25%, the pressure drop has been increased from 3454.62 Pa to 2558.74 Pa, and the NH3 slip has been transformed from 122.26 ppm to 17.49 ppm. These results not only advance the theoretical understanding of SCR technology but also provide valuable design insights for practical applications. Our findings pave the way for the development of more efficient and environmentally friendly SCR systems, potentially revolutionizing NOx control in various industries.

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基于响应面方法的各种参数优化分析，以提高 Cu-ZSM-13 催化剂上尿素选择性催化还原法的氮氧化物催化还原性能

长期以来，选择性催化还原（SCR）一直是去除氮氧化物（NOx）不可或缺的方法，但优化其性能仍是一项重大挑战。本研究探讨了结构参数和进气参数对 SCR 性能的综合影响，这也是以往研究中经常忽略的一个方面。本文创新性地建立了一个三维 SCR 通道模型，并采用响应面方法对多个关键因素进行了深入分析。这种多维度、多方法的研究方法能够更全面地了解 SCR 系统的力学特性。通过目标优化，我们实现了氮氧化物转化率、压降和氨滑移三个关键指标的同步改善。值得注意的是，氮氧化物转化率从 17.07% 优化到 98.25%，压降从 3454.62 Pa 提高到 2558.74 Pa，NH3 滑移从 122.26 ppm 转化到 17.49 ppm。这些结果不仅推进了对选择性催化还原技术的理论理解，还为实际应用提供了宝贵的设计见解。我们的研究结果为开发更高效、更环保的选择性催化还原系统铺平了道路，有可能为各行各业的氮氧化物控制带来革命性的变化。

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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