脉冲性负荷下储能系统直流惯性增强控制方法OA
DC Inertia Enhancement Control Method for Energy Storage System under Pulsed Load
针对偏远地区高可靠性供电需求,以柴油发电机与储能单元为核心构建的柴-储并联系统已成为关键解决方案.然而,高能脉冲性负荷的间歇性接入(表现为反复瞬态投切)会导致两级式储能变换系统中间直流母线电压剧烈波动,严重威胁系统稳定运行及负载供电质量.对此,该文提出了一种基于状态观测电流前馈的直流惯性增强控制方法,一方面通过虚拟惯性增强方法,增强储能系统直流侧的惯性,提升系统的稳定性;另一方面通过电流状态观测器预测直流侧负载电流,并将其作为前馈指令快速补偿脉冲性负荷消耗的瞬时能量,从而抑制直流母线的电压波动.该文建立了脉冲性负荷下的储能系统数学模型,并揭示了脉冲性负荷下的直流电压波动机理,同时根据所提的惯性增强控制策略,建立了系统小信号模型,分析了直流母线电压波动的抑制机理,并设计了系统的控制参数.最后通过实验验证了该文所提控制方法的正确性和有效性.
To address the growing demand for highly reliable power supply in remote areas,hybrid power systems that integrate diesel generators with energy storage units have been widely recognized as a promising solution.These systems combine the long-term energy capacity of diesel generation with the fast-response and dynamic support capability of energy storage,thereby ensuring both reliability and flexibility.Nevertheless,in practical operation,the intermittent connection of high-power pulsed loads—characterized by frequent and repetitive transient switching—introduces severe challenges.In particular,such pulsed loads impose instantaneous power shocks on the system,which cause pronounced voltage fluctuations in the intermediate DC bus of the two-stage energy storage converter.These fluctuations not only jeopardize the stable operation of the hybrid system but also significantly deteriorate the quality of power supply delivered to sensitive loads. To overcome this issue,this paper proposes a novel DC-side inertia enhancement control strategy that incorporates state-observer-based current compensation.The core idea of the method is twofold.First,a virtual inertia control mechanism is introduced to increase the effective inertia of the DC link within the energy storage system,thereby enhancing its ability to resist disturbances and stabilize the bus voltage.Second,a current state observer is designed to predict the dynamic behavior of the DC-side load current in real time.The predicted current is then utilized as a feedforward signal to rapidly offset the instantaneous energy drawn by pulsed loads.Through the coordinated action of virtual inertia support and feedforward energy compensation,the proposed strategy is able to effectively suppress voltage fluctuations on the DC bus,thus significantly improving system stability and power quality. The research is carried out in several stages.First,the supply architecture of a diesel-storage hybrid system with pulsed loads is presented.A detailed mathematical model of the energy storage subsystem under pulsed load conditions is then established,which reveals the inherent mechanism of DC voltage fluctuations and clarifies the relationship between load characteristics and bus voltage dynamics.Based on these insights,a composite control framework combining inertia enhancement and current-feedforward compensation is formulated.A small-signal state-space model of the controlled system is further developed to support theoretical analysis.Within this framework,both frequency-domain and time-domain analyses are conducted to verify the suppression mechanism of voltage oscillations and to characterize the dynamic response of the proposed method.Moreover,parameter design procedures for the inertia enhancement controller and current observer are derived based on the small-signal model,ensuring that the control strategy is not only theoretically sound but also practically implementable. Finally,to validate the proposed approach,both simulation and experimental studies are performed.A Matlab/Simulink simulation platform is first constructed to compare the performance of conventional control,inertia enhancement alone,and the full proposed strategy.The results demonstrate that the proposed control provides superior suppression of voltage fluctuations compared with traditional methods.In addition,a laboratory-scale prototype of the energy storage converter system is developed to experimentally verify the feasibility and effectiveness of the proposed scheme.Experimental results confirm the simulation findings:the system under the proposed control strategy exhibits enhanced stability,faster transient response,and significantly improved suppression of DC bus voltage oscillations.Particularly,the introduction of state-observer current compensation is shown to further optimize the fluctuation suppression performance. In summary,this work establishes a systematic framework for enhancing the inertia and dynamic performance of diesel–storage hybrid systems subjected to pulsed loads.The proposed strategy combines the advantages of inertia support and feedforward compensation,offering a robust and effective solution to mitigate voltage fluctuations and improve overall power supply quality in remote-area applications.
易伟浪;余佩倡;陈强;周乐明;顾世杰;李杰
中国人民解放军国防科技大学智能科学学院 长沙 410003中国人民解放军国防科技大学智能科学学院 长沙 410003中国人民解放军国防科技大学智能科学学院 长沙 410003湖南大学电气与信息工程学院 长沙 410082中国人民解放军国防科技大学智能科学学院 长沙 410003中国人民解放军国防科技大学智能科学学院 长沙 410003
信息技术与安全科学
直流电压波动前馈控制状态观测器两级式储能变换脉冲性负荷虚拟直流发电机控制惯性增强
DC voltage fluctuationfeedforward controlstate observertwo-stage energy storage converterpulsed power loadvirtual DC generatorinertia enhancement
《电工技术学报》 2026 (11)
3909-3920,3936,13
国防科技大学自主科研基金资助项目(ZK24-23).
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