Multipurpose control and planning method for battery energy storage systems in distribution network with photovoltaic plant

Akagi, Satoru; Yoshizawa, Shinya; Ito, Masakazu; Fujimoto, Yu; Miyazaki, Teru; Hayashi, Yasuhiro; Tawa, Katsuhisa; Toshiya, Hisada; Yano, Takashi

doi:10.1016/j.ijepes.2019.105485

Cited by 34 publications

(19 citation statements)

References 28 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…There are two main types of energy storage system operation: island operation and grid connection operation (Ge et al., 2019). Some researchers have established multi-energy complementary systems with complementary energy, such as wind, solar, electricity, and hydrogen (Akagi et al., 2020; Chen et al., 2019; Georgios and Stavros, 2020; Wang et al., 2020). Aiming at the wind power model, photovoltaic power model, and energy storage system power model in island mode, the power, the goal is to predict loads and reduce operating costs.…”

Section: Research On Key Technologies Of Multi-energy Complementary Hmentioning

confidence: 99%

Development of renewable energy multi-energy complementary hydrogen energy system (A Case Study in China): A review

Zhang

et al. 2020

Energy Exploration & Exploitation

110

View full text Add to dashboard Cite

The hydrogen energy system based on the multi-energy complementary of renewable energy can improve the consumption of renewable energy, reduce the adverse impact on the power grid system, and has the characteristics of green, low carbon, sustainable, etc., which is currently a global research hotspot. Based on the basic principles of hydrogen production technology, this paper introduces the current hydrogen energy system topology, and summarizes the technical advantages of renewable energy complementary hydrogen production and the complementary system energy coordination forms. The problems that have been solved or reached consensus are summarized, and the current status of hydrogen energy system research at home and abroad is introduced in detail. On this basis, the key technologies of multi-energy complementation of hydrogen energy system are elaborated, especially in-depth research and discussion on coordinated control strategies, energy storage and capacity allocation, energy management, and electrolysis water hydrogen production technology. The development trend of the multi-energy complementary system and the hydrogen energy industry chain is also presented, which provides a reference for the development of hydrogen production technology and hydrogen energy utilization of the renewable energy complementary system.

show abstract

Section: Research On Key Technologies Of Multi-energy Complementary Hmentioning

confidence: 99%

Development of renewable energy multi-energy complementary hydrogen energy system (A Case Study in China): A review

Zhang

et al. 2020

Energy Exploration & Exploitation

110

View full text Add to dashboard Cite

show abstract

“…Typical equipment to be controlled in city-level distribution systems include load-ratio control transformers (LRTs), step voltage regulators (SVRs) and low-voltage regulators (LVRs) [145,144]. The large-scale BESSs attached to substations [146,147] would be another possible control target for supply-side energy management. The idea of a control scheme based on monitored/forecasted results have been recognized as a powerful approach to achieve the objectives of EMSs considering uncertainties in power fluctuation.…”

Section: Control Targets Of Emss An Objective Of Emssmentioning

confidence: 99%

Designing Sustainable Smart Cities: Cooperative Energy Management Systems and Applications

Fujimoto

Ishii

Hayashi

2020

IEEJ Transactions Elec Engng

Self Cite

View full text Add to dashboard Cite

Smart cities will be an important component for the construction of a sustainable future society. This paper focuses on the functionalities of smart cities from the perspective of electric power systems and reviews recent works on the various types of energy management systems (EMSs), particularly those focusing on the interaction among systems distributed in a city. Furthermore, this paper describes the idea of a platform for evaluating cooperative EMS technologies distributed in a city. The related research and demonstration of the EMS technology in real cities that were evaluated using the proposed platform are presented. © 2020 Institute of Electrical Engineers of Japan. Published by Wiley Periodicals LLC.

show abstract

“…BESSs play a major role as flexible energy source (FES) in ANM schemes by bridging gaps between non-concurrent renewable energy sources (RES)-based power generation and demand in the MV and low-voltage (LV) distribution networks. Ability of the BESS to provide both active power and reactive power flexibility services makes them a multipurpose FES for ANM needs [12][13][14]. With current technological maturity, Li-ion BESSs are capable of acting as a cost-efficient FESs and provide multiple technical ancillary/flexibility services like frequency control by controlling active power injection and voltage control by active/ reactive power management [15,16].…”

Section: Introductionmentioning

confidence: 99%

Integration and control of lithium-ion BESSs for active network management in smart grids: Sundom smart grid backup feeding case

2021

View full text Add to dashboard Cite

Lithium-ion battery energy storage systems (Li-ion BESS), due to their capability in providing both active and reactive power services, act as a bridging technology for efficient implementation of active network management (ANM) schemes for land-based grid applications. Due to higher integration of intermittent renewable energy sources in the distribution system, transient instability may induce power quality issues, mainly in terms of voltage fluctuations. In such situations, ANM schemes in the power network are a possible solution to maintain operation limits defined by grid codes. However, to implement ANM schemes effectively, integration and control of highly flexible Li-ion BESS play an important role, considering their performance characteristics and economics. Hence, in this paper, an energy management system (EMS) has been developed for implementing the ANM scheme, particularly focusing on the integration design of Li-ion BESS and the controllers managing them. Developed ANM scheme has been utilized to mitigate MV network issues (i.e. voltage stability and adherence to reactive power window). The efficiency of Li-ion BESS integration methodology, performance of the EMS controllers to implement ANM scheme and the effect of such ANM schemes on integration of Li-ion BESS, i.e. control of its grid-side converter (considering operation states and characteristics of the Li-ion BESS) and their coordination with the grid side controllers have been validated by means of simulation studies in the Sundom smart grid network, Vaasa, Finland.

show abstract

Multipurpose control and planning method for battery energy storage systems in distribution network with photovoltaic plant

Cited by 34 publications

References 28 publications

Development of renewable energy multi-energy complementary hydrogen energy system (A Case Study in China): A review

Development of renewable energy multi-energy complementary hydrogen energy system (A Case Study in China): A review

Designing Sustainable Smart Cities: Cooperative Energy Management Systems and Applications

Integration and control of lithium-ion BESSs for active network management in smart grids: Sundom smart grid backup feeding case

Contact Info

Product

Resources

About