考虑电力系统灵活爬坡需求的火电厂碳捕集改造方案优化方法

邬凯浪; 单兰晴; 薄利明; 程雪婷; 刘新元; 蔡帜; 郭鸿业; 李寅晓

doi:10.12204/j.issn.1000-7229.2025.09.003

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电力建设 ›› 2025, Vol. 46 ›› Issue (9) : 27-41. DOI: 10.12204/j.issn.1000-7229.2025.09.003

新型电力系统平衡决策智能分析与灵活性资源综合规划·栏目主持王建学、张耀·

考虑电力系统灵活爬坡需求的火电厂碳捕集改造方案优化方法

邬凯浪 ¹ ,
单兰晴 ¹ ,
薄利明 ² ,
程雪婷 ² ,
刘新元 ² ,
蔡帜 ³ ,
郭鸿业 ¹ ,
李寅晓 ¹

作者信息 +

Optimization Methodology for Carbon Capture Reformation Schemes in Thermal Power Plants Considering the Power Flexible Ramping Demand

Author information +

文章历史 +

摘要

【目的】在高比例可再生能源接入背景下，为满足电力系统灵活性和低碳需求，提出了考虑电力系统灵活爬坡需求的火电厂碳捕集改造方案优化方法。【方法】首先，针对大规模风电和光伏接入引发的电力系统爬坡需求攀升现象，建立电力系统灵活性需求计算模型。其次，建立考虑碳捕集改造的火电机组灵活运行模型并量化其灵活爬坡供应能力。然后，考虑负荷、新能源的不确定性，引入灵活爬坡需求约束，建立基于模糊机会约束的火电厂碳捕集改造规划模型，对火电机组碳捕集改造规划问题和火电机组运行优化问题进行联合求解，得到火电最优碳捕集改造方案。最后，结合算例验证了碳捕集改造方案优化方法的有效性，并分析不同单位碳排放惩罚成本、新能源接入比例及置信水平对碳捕集改造方案的影响。【结果】仿真结果表明，在对火电机组进行最优碳捕集改造之后，电力系统的碳排放显著降低，可再生能源弃电率显著减少，系统的总运行成本降低了9.44%。【结论】通过对火电机组进行最优碳捕集改造，能够提升火电机组的出力下调空间和爬坡能力，在降低电力系统碳排放的同时促进可再生能源的消纳，提升系统运行的经济性。

Abstract

[Objective] In the context of high-percentage renewable energy integration， to satisfy the system flexibility and low-carbon demand， we propose an optimization method for the carbon capture reformation of thermal power plants considering the flexible power ramping demand. [Methods] First， a calculation model for the power system flexibility demand is established to address the ramping demand surge caused by large-scale wind and photovoltaic power integration. Second， a flexible operation model of thermal power units considering carbon capture reformation is established， and the flexible ramping supply capacity is quantified. Subsequently， considering the uncertainty of the load and renewable energy， a flexible ramping demand constraint and a fuzzy opportunity-constrained model are introduced to establish a carbon capture reformation planning model for thermal power plants. This model jointly solves the carbon capture reformation planning and operation optimization problems of thermal power units to obtain an optimal carbon capture reformation solution. Finally， the effectiveness of the planning model is verified using examples， and the impacts of different unit carbon penalties， renewable energy integration ratios， and confidence levels on the carbon capture reformation results are analyzed. [Results] Simulation results showed that after the optimal carbon capture reformation of thermal power plants， the carbon emissions of the power system were significantly reduced， the renewable energy curtailment rate was significantly reduced， and the total operating cost of the system was reduced by 9.44%. [Conclusions] Through optimal carbon capture reformation of thermal power plants， the output downward regulation space and ramping capability of thermal power plants can be improved， which can promote the accommodation of renewable energy while reducing the carbon emissions of the power system， thus enhancing the economic efficiency of system operation.

导出引用

邬凯浪, 单兰晴, 薄利明, 等. 考虑电力系统灵活爬坡需求的火电厂碳捕集改造方案优化方法[J]. 电力建设. 2025, 46(9): 27-41 https://doi.org/10.12204/j.issn.1000-7229.2025.09.003

WU Kailang, SHAN Lanqing, BO Liming, et al. Optimization Methodology for Carbon Capture Reformation Schemes in Thermal Power Plants Considering the Power Flexible Ramping Demand[J]. Electric Power Construction. 2025, 46(9): 27-41 https://doi.org/10.12204/j.issn.1000-7229.2025.09.003

中图分类号： TM74

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摘要

目的分析碳捕集技术对燃煤电厂调峰能力的影响机制，量化碳捕集技术对燃煤电厂发电效率的影响。方法以国内某典型燃煤电厂为例，选取燃烧后碳捕集方案，通过EBSILON软件构建常规燃煤火电机组和碳捕集电厂的模拟模型，得出碳捕集电厂的运行区间，对比分析了碳捕集电厂与常规燃煤电厂的运行结果，对机组的调峰性能的变化展开了研究。结果与常规燃煤电厂相比，碳捕集电厂等效输出功率下降了1%~2%，净输出功率下降了20%~30%，全场净效率下降了8%~10%。结论碳捕集系统的加入会使电厂在效率降低的同时获得更大的下调峰深度和更快的调峰响应速度。

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本文引用 [1] 摘要

Objectives The mechanism of the impact of carbon capture technology on the peaking capacity of coal-fired power plants was analyzed, and the impact of carbon capture technology on the power generation efficiency of coal-fired power plants was quantified. Methods A typical coal-fired power plant was used as an example, and a post-combustion carbon capture scheme was selected. The simulation model of the conventional coal-fired thermal power unit and the carbon capture power plant was constructed by EBSILON software. The operation interval of the carbon capture power plant was derived. A comparative analysis of the operation of a carbon capture power plant and a conventional coal-fired power plant was conducted, and the variation in the peaking performance of the units was investigated. Results The equivalent output power of the carbon capture power plant decreases by 1%-2%, the net output power decreases by 20%-30%, and the net efficiency of the whole field decreases by 8%-10% compared with that of the conventional coal-fired power plant. Conclusions The addition of a carbon capture system would allow the plant to gain greater downward peaking depth and faster peaking response while reducing efficiency.

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Under the background of energy complementarity and low-carbon economy, virtual power plant (VPP) is an effective carrier for achieving optimal allocation of regional resources and new energy consumption. At the technical level,the CO₂ recycling through carbon capture power plant (CCPP) and power-to-gas (P2G) conversion devices was realized, a CCPP-P2G coupling model was established, and a price based demand response model considering user satisfaction on the load side was introduced. In terms of low-carbon policy, the ladder carbon trading mechanism was introduced into VPP to constrain carbon emissions. Then, with the goal of minimizing the total cost, a low-carbon economic dispatch model for VPP was established. By setting different scheduling scenarios for comparison, the effectiveness of the model in low-carbon economy operation of VPP was verified, and the impact of carbon trading parameters on the carbon emissions and costs of VPP was explored through sensitivity analysis. The results show that the model has guiding significance for VPP low-carbon economic scheduling.

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https://doi.org/10.19912/j.0254-0096.tynxb.2022-0840

摘要

在电-气综合能源系统的基础上,加入碳捕集系统以及储碳系统,构建碳捕集-电转气-风电-气电虚拟电厂联合运行模型,分析联合运行模式相较于碳捕集电厂独立运行的优势。其次,考虑风电、负荷的不确定性带来的影响,通过引入模糊参数,建立计及源荷不确定性的模糊机会约束模型,分析不确定性对于碳捕集能力的影响。最后,基于改进的IEEE-39节点系统和天然气20节点算例系统,通过GUROBI求解器验证所提碳捕集虚拟电厂联合运行模型在考虑风电和负荷不确定性下可有效消纳风电、降低系统的碳排放。

CHEN

Jiming

, XU

Qian

, LI

Yong

, et al. Optimal dispatch of electricity-natural gas interconnection system considering source-load uncertainty and virtual power plant with carbon capture[J]. Acta Energiae Solaris Sinica, 2023, 44(10): 9-18.

https://doi.org/10.19912/j.0254-0096.tynxb.2022-0840

本文引用 [1] 摘要

On the basis of the electricity-natural gas interconnection system, the carbon capture system and the carbon storage system are added, and the CCS-P2G-WT-GT combined operation model of virtual power plant is established, and the advantages of the combined operation mode is analyzed. Secondly, the influence of wind power and load uncertainty is considered. By introducing fuzzy parameters, a fuzzy opportunity constraint model is stablished to analyze the influence of uncertainty on carbon capture capacity. Finally, based on the improved IEEE-39 power system and the 20-node natural gas calculation example system, the wind power consumption and the carbon emissions reduction of the proposed combined operation model of carbon capture virtual power plant under the condition of considering the uncertainties of wind power and load are verified by the GUROBI solver.