The expansion of the use of renewable sources for electricity generation in recent years is a result of the increase of fossil fuels costs and the growing concern with climate change and the impacts on the environment, as well as technological advances and the reduction in their implementation costs. However, the availability of some natural resources for renewable energy matrices, such as wind and solar irradiation, has an intermittent and seasonal nature, which may affect the electrical system operation (CANALES et al., 2015; KELMAN & HARRISON, 2019). One of the alternatives to balance the system load is energy storage, which offers benefits to the electricity provision (ancillary services, for example) and regulates the frequency in times of high demand with low energy supply from renewables, contributing with the necessary inertia so that demand does not change instantly (BARBOUR et al., 2016). The most widely large-scale technology used for storage in the world is hydraulic pumping through pumped storage hydropower – PSH (GUITTET et al., 2016; IHA, 2018). Compared to other technologies, it provides a solution with high efficiency, faster response time and longer useful life (REHMAN et al., 2015). The operation of the plants is characterized by the pumping of water from a lower reservoir for its accumulation in an upper reservoir for energy generation in periods of high demand (BARBOUR et al., 2016). Energy storage alternatives are already on the agenda in the Brazilian energy sector as an option to ensure the system development in an economic and sustainable manner. In the 2030 Ten-Year Energy Expansion Plan (EPE, 2021b), PSH is highlighted as one of the resources to expand the offer for rush hour demand response. EPE understands that preliminary studies are an important step to support the sector s planning and guide the definition of regulatory aspects, which do not yet exist, related to the systemic benefits of this type of solution.