Abstract
In power systems, high renewable energy penetration generally results in conventional synchronous generators being displaced. Hence, the power system inertia reduces, thus causing a larger frequency deviation when an imbalance between load and generation occurs, and thus potential system instability. The problem associated with this increase in the system’s dynamic response can be addressed by various means, for example, flywheels, supercapacitors, and battery energy storage systems (BESSs). This paper investigates the application of BESSs for primary frequency control in power systems with very high penetration of renewable energy, and consequently, low levels of synchronous generation. By re-creating a major Australian power system separation event and then subsequently simulating the event under low inertia conditions but with BESSs providing frequency support, it has been demonstrated that a droop-controlled BESS can greatly improve frequency response, producing both faster reaction and smaller frequency deviation. Furthermore, it is shown via detailed investigation how factors such as available battery capacity and droop coefficient impact the system frequency response characteristics, providing guidance on how best to mitigate the impact of future synchronous generator retirements. It is intended that this analysis could be beneficial in determining the optimal BESS capacity and droop value to manage the potential frequency stability risks for a future power system with high renewable energy penetrations.
Highlights
The deployment of power generation sourced from Renewable Energy (RE) is growing steadily, as power systems around the world transition to being based around low-carbon technologies
Group A demonstrates the impact of RE non-synchronous generating sources (NSGSs) penetration on primary frequency control (PFC), when RE replaces conventional SGs; Group B investigates the effect of utilising a single battery energy storage systems (BESSs) with different droop coefficients, along with SGs, for PFC response; Group C shows the impact of utilising a fixed droop coefficient with different BESS
The power system model used in Groups B–D case studies is shown in Figure 6, with SG
Summary
The deployment of power generation sourced from Renewable Energy (RE) is growing steadily, as power systems around the world transition to being based around low-carbon technologies. This deployment generally occurs via the replacement of conventional. In Australia, for example, the Integrated System Plan (ISP) published by the Australian. Energy Market Operator (AEMO) provides a roadmap for eastern Australia’s power system to optimise consumer benefits through a transition period of great complexity and uncertainty [2,3]. ISP findings highlighted the anticipated transformation of the generation mix in the National Electricity Market (NEM) of Australia by 2040. A substantial closure of coal-fired generation fleets is expected, with the future NEM generation mix driven by factors such as the withdrawal of ageing generation assets, reduced carbon emission policies, and changing demand patterns [2,3].
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