基于氢能设备多状态模型的电氢区域综合能源系统可靠性评估

doi:10.19595/j.cnki.1000-6753.tces.221459

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摘要针对现有电氢区域综合能源系统（EH-RIESs）可靠性评估方法未充分考虑氢能设备故障机理及其多状态运行特性、缺乏供氢可靠性水平量化评估指标及方法等问题,本文提出了基于氢能设备多状态模型的EH-RIESs可靠性评估方法。首先,剖析了氢能设备运行特性与故障机理,建立了考虑降额运行状态的碱性电解槽多状态可靠性评估模型、计及热电联产模式的燃料电池多状态可靠性评估模型以及加氢机组的多状态可靠性评估模型,为准确模拟EH-RIESs运行状态奠定坚实基础。其次,以弃风光成本和异质能源负荷削减成本之和最小为目标,建立了考虑电氢异质能量系统耦合的最优负荷削减模型。然后,从供氢可靠性水平、设备对氢负荷缺供能量的贡献程度以及系统经济损失等方面,构建了供氢可靠性评估指标体系。最后,结合氢能设备多状态模型和马尔科夫链蒙特卡洛法,建立了EH-RIESs可靠性评估方法,实现了对EH-RIESs内氢能等异质能源供给可靠性水平的准确量化。采用两个不同规模的EH-RIESs进行仿真分析,验证了本文所提模型及评估方法的有效性和适应性。

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关键词 ：电氢区域综合能源系统, 电解槽, 燃料电池, 马尔科夫链蒙特卡洛, 供氢可靠性

Abstract：Electricity-hydrogen regional integrated energy systems (EH-RIESs) are considered as one of the key paths to realize the green and low-carbon transformation of power and energy systems. However, the fault mechanism of hydrogen energy equipment hasn’t been considered by the existing reliability evaluation methods of EH-RIESs, as well as the multi-state characteristics of hydrogen energy equipment. There is no efficient reliability evaluation indexes and methods to quantify the reliability level of hydrogen supply. It means the reasonable decision-making basis for the planning and construction of EH-RIESs cannot be provided. A reliability evaluation method of EH-RIESs based on the multi-state models of hydrogen energy equipment is proposed in this paper. By accurately simulating the operation states of EH-RIESs, the reliability levels of heterogeneous energy supply are effectively quantified.
Firstly, the operation characteristics and fault mechanisms of hydrogen energy equipment are analyzed. A multi-state reliability model of alkaline electrolyzers considering de-rated operation state, a multi-state reliability model of fuel cells considering cogeneration mode and a multi-state reliability model of hydrogen dispenser units are established, which provide the basic models for the operation state simulation of EH-RIESs. Secondly, an optimal load shedding model considering the coupling relationship of electricity-hydrogen heterogeneous energy systems is established to minimize the wind power and photovoltaic power curtailment costs and heterogeneous energy load reduction costs. Then, an evaluation index system of hydrogen supply reliability is constructed from the aspects of hydrogen supply reliability level, the contribution of equipment to expected hydrogen not supply and system economic loss. Finally, based on the multi-state models of hydrogen energy equipment and a Markov Chain Monte Carlo method, a reliability evaluation method is developed for EH-RIESs to quantify the reliability levels of heterogeneous energy supply.
Two EH-RIESs with different scales were used to validate the effectiveness and the advantages of the proposed method. The simulation results show that after considering the de-rated operation state of hydrogenation dispenser units, the expected hydrogen not supply (EHNS) of two EH-RIESs increases by 11.82% and 17.52%, respectively. After considering the de-rated operation state of alkaline electrolyzers, the EHNS of two EH-RIESs increase by 11.44% and 5.40%, respectively. After considering the cogeneration mode of fuel cells, the expected thermal energy not supply of two EH-RIESs decrease by 81.83% and 81.01%, respectively. The hydrogen supply contribution index of electrical equipment and electrolyzers in the first EH-RIES reach 32.61% and 53.72%, respectively, which are the key factors affecting the reliability levels of hydrogen supply. In addition, with the increase of penalty cost of unit hydrogen load shedding, the economic loss of the first EH-RIES caused by electricity shortage is gradually increasing, and the comprehensive loss of energy not supply is also increasing.
The following conclusions can be drawn from the simulation results. (1) The hydrogen supply reliability levels of EH-RIESs will be overestimated if the de-rated states of alkaline electrolyzers and hydrogen dispenser units are ignored. The proposed multi-state model of fuel cells considering the cogeneration mode is helpful to accurately evaluate the thermal energy supply reliability levels of EH-RIESs. (2) The proposed reliability evaluation index system and evaluation method of EH-RIESs can quantify the hydrogen supply reliability level, economic loss and the contribution of equipment failures to the hydrogen energy shortage. (3) With the increase of penalty cost of unit hydrogen load shedding, the reliability level of hydrogen supply is improved, but the reliability level of electricity supply is gradually reduced. A reasonable penalty cost of unit hydrogen load shedding is essential to balance the energy supply reliability and economic levels of systems.

Key words： Electricity-hydrogen regional integrated energy systems electrolyzer fuel cell Markov Chain Monte Carlo hydrogen supply reliability

收稿日期: 2022-07-28

PACS:

TM732

基金资助:国家自然科学基金资助项目（52277080）

通讯作者: 任洲洋男,1986年生,副教授,博士生导师,研究方向为电力能源系统低碳运行及规划、人工智能等。E-mail：rzhouyang1108@163.com

作者简介: 王皓男,1998年生,硕士研究生,研究方向为配电网运行与规划、电氢区域综合能源系统可靠性评估等。E-mail：wh19980913@163.com

引用本文:

任洲洋, 王皓, 李文沅, 姜云鹏. 基于氢能设备多状态模型的电氢区域综合能源系统可靠性评估[J]. 电工技术学报, 0, (): 61-61. Ren Zhouyang, Wang Hao, Li Wenyuan, Jiang Yunpeng. Reliability Evaluation of Electricity-Hydrogen Regional Integrated Energy Systems Based on the Multi-State Models of Hydrogen Energy Equipment. Transactions of China Electrotechnical Society, 0, (): 61-61.

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