Abstract
Small hydropower (SHP) and pumped hydropower storage (PHS) are ideal members of power systems with regard to integrating intermittent power production from wind and PV facilities in modern power systems using the high penetration of renewable energy. Due to the limited capacity of SHP and the geographic restrictions of PHS, these power sources have not been adequately utilized in multi-energy integration. On the one hand, rapidly increasing wind/PV power is mostly situated in remote areas (i.e., mountain and rural areas) and is delivered to core areas (i.e., manufacturing bases and cities) for environmental protection and economic profit. On the other hand, SHP is commonly dispersed in remote areas and PHS is usually located in core areas. This paper proposes a strategy to take advantage of the distribution and regulation features of these renewable energy sources by presenting two models, which includes a remote power system model to explore the potential of SHP to smooth the short-term fluctuations in wind and PV power by minimizing output fluctuations as well as a core power system model to employ PHS to shift the surplus power to the peak period by maximizing the income from selling regenerated power and minimizing output fluctuations. In the proposed first model, the cooperative regulation not only dispatches SHP with a reciprocal output shape to the wind/PV output to smooth the fluctuations but also operates the reservoir with the scheduled total power production by adjusting its output in parallel. The results of a case study based on a municipal power system in Southwestern China show that, with the proposed method, SHP can successfully smooth the short-term fluctuations in wind and PV power without influencing the daily total power production. Additionally, SHP can replace the thermal power production with renewable power production, smooth the thermal output, and further reduce the operation costs of thermal power. By storing the surplus power in the upper reservoir and regenerating the power during the peak period, PHS can obtain not only the economic benefit of selling the power at high prices but also the environmental benefit of replacing non-renewable power with renewable power. This study provides a feasible approach to explore the potential of SHP and PHS in multi-energy integration applications.
Highlights
To achieve the goal of limiting global warming levels to increase by no more than 1.5 ◦ C, the share of primary energy from Renewable Energy Sources (RES, e.g., hydro, wind, and solar) should account for 49% to 67% of the total energy consumption and, has a conspicuous gap to bridge [1].Hydropower has significant potential for reducing carbon emissions [2] and is one of the viable solutions to integrate intermittent renewable power [3,4] due to its high degree of operational flexibility [5]
Considering that small hydropower (SHP) is commonly dispersed in remote areas and pumped hydropower storage (PHS) is usually located in core areas and, because wind/PV power is mostly situated in remote areas and delivered to core areas for environmental protection and economic profit, we propose a strategy to first explore the potential of SHP to smooth the short-term fluctuating power output from wind/PV by coordinately dispatching the hydropower plant
In Area II, it is assumed that (1) the power system consists of two types of power sources: PHS and non-renewable power, (2) the power production delivered from Area I is consumed in this area, and (3) the surplus power in this area will be curtailed
Summary
To achieve the goal of limiting global warming levels to increase by no more than 1.5 ◦ C, the share of primary energy from Renewable Energy Sources (RES, e.g., hydro, wind, and solar) should account for 49% to 67% of the total energy consumption and, has a conspicuous gap to bridge [1]. We propose a method to explore its flexibility by dispatching SHP in multi-energy integration applications. Research on integrating wind/PV with PHS is commonly focused on employing PHS to shift the surplus RES power to the peak period to mitigate the impacts on the grid and reduce generation costs. Considering that SHP is commonly dispersed in remote areas (i.e., mountains and rural areas) and PHS is usually located in core areas (i.e., manufacturing bases and cities) and, because wind/PV power is mostly situated in remote areas and delivered to core areas for environmental protection and economic profit, we propose a strategy to first explore the potential of SHP to smooth the short-term (based on its finite but considerable flexibility) fluctuating power output from wind/PV by coordinately dispatching the hydropower plant (to mitigate the impacts of intermittent wind/PV power).
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