What does this research mean for the field?

Implementing multi-objective collaborative optimization strategies, such as fine control, equipment upgrades, and intelligent operation, in thermal power plant ash and sulfur systems can reduce comprehensive energy consumption by 10% to 15% while maintaining ultra-low emission standards. Novelty: ClaimNovelty.INCREMENTAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This study aims to address the energy efficiency challenges in the ultra-low emission transformation of thermal power plants.

May 29, 2026Open Access

新形势下火电厂灰硫系统超低排放改造的能效优化与实践研究

Key Points

This study aims to address the energy efficiency challenges in the ultra-low emission transformation of thermal power plants.
Systematic analysis of current ultra-low emission technology pathways in desulfurization, dust removal, and ash handling systems.
Empirical analysis of typical power plant transformation cases to verify optimization proposals.
Development of multi-objective collaborative optimization strategies for energy efficiency improvement.
Achieved a 10%-15% reduction in comprehensive energy consumption while meeting ultra-low emission standards.
Demonstrated that refined control and equipment upgrades effectively enhance resource utilization efficiency.
Validated strategies for achieving SO₂ ≤ 35mg/m³ and dust ≤ 5mg/m³ while lowering operational costs.

Abstract

随着“双碳”战略目标的深入推进与生态环境保护要求的日益严格，火电行业面临着前所未有的转型压力。作为火电厂污染物控制的核心环节，灰硫系统的超低排放改造已成为行业发展的必然趋势。然而，传统改造路径往往侧重于排放指标的达标，忽视了系统能效的协同优化，导致运行成本攀升、能耗增加，甚至影响机组的整体经济性。本文立足于“减污降碳协同增效”的新发展理念，系统梳理了当前火电厂灰硫系统（主要包括脱硫、除尘及灰渣处理系统）超低排放改造的技术路线，深入剖析了其在运行过程中存在的能效瓶颈，并提出了基于多目标协同优化的能效提升策略。通过对典型电厂改造案例的实证分析，验证了所提优化方案在实现超低排放的同时，能够显著降低系统能耗、提升资源利用效率。研究结果表明，通过精细化控制、设备升级、系统集成及智能化运维等手段，可在满足超低排放标准（SO₂ ≤ 35mg/m³、烟尘 ≤ 5mg/m³）的前提下，实现灰硫系统综合能耗降低10%~15%，为火电行业的绿色低碳转型提供了有力的技术支撑与实践参考。

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新形势下火电厂灰硫系统超低排放改造的能效优化与实践研究

Key Points

Abstract

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