Hydro power flexibility for power systems with variable renewable energy sources: an IEA Task 25 collaboration

Huertas‐Hernando, Daniel; Farahmand, Hossein; Holttinen, Hannele; Kiviluoma, Juha; Rinne, Erkka; Söder, Lennart; Milligan, Michael; Ibáñez, Eduardo; Martín-Martínez, Sergio; Gómez‐Lázaro, Emilio; Estanqueiro, Ana; Rodrigues, Luís; Carr, Luis; Roon, Serafin van; Orths, Antje; Eriksen, Peter Børre; Forcione, Alain; Menemenlis, Nickie

doi:10.1002/wene.220

Cited by 53 publications

(40 citation statements)

References 32 publications

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“…Hydro power, in particular through reservoir-based power plants, plays a critical role in providing flexibility to the European power systems. With the EU renewable energy target of 32% by 2030 [2], the role of hydro power will be even more important in a low-carbon scenario, where the capacity of non-dispatchable electricity sources (mostly wind and solar) will be much higher than today [3].…”

Section: Introductionmentioning

confidence: 99%

Reconstruction of Multidecadal Country-Aggregated Hydro Power Generation in Europe Based on a Random Forest Model

Dubus

Felice

et al. 2020

Energies

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Hydro power can provide a source of dispatchable low-carbon electricity and a storage solution in a climate-dependent energy mix with high shares of wind and solar production. Therefore, understanding the effect climate has on hydro power generation is critical to ensure a stable energy supply, particularly at a continental scale. Here, we introduce a framework using climate data to model hydro power generation at the country level based on a machine learning method, the random forest model, to produce a publicly accessible hydro power dataset from 1979 to present for twelve European countries. In addition to producing a consistent European hydro power generation dataset covering the past 40 years, the specific novelty of this approach is to focus on the lagged effect of climate variability on hydro power. Specifically, multiple lagged values of temperature and precipitation are used. Overall, the model shows promising results, with the correlation values ranging between 0.85 and 0.98 for run-of-river and between 0.73 and 0.90 for reservoir-based generation. Compared to the more standard optimal lag approach the normalised mean absolute error reduces by an average of 10.23% and 5.99%, respectively. The model was also implemented over six Italian bidding zones to also test its skill at the sub-country scale. The model performance is only slightly degraded at the bidding zone level, but this also depends on the actual installed capacity, with higher capacities displaying higher performance. The framework and results presented could provide a useful reference for applications such as pan-European (continental) hydro power planning and for system adequacy and extreme events assessments.Energies 2020, 13, 1786 2 of 17 for individual power plants. There are several explanations for this approach: (i) modelling tends to be thought of as a bottom-up approach, therefore starting from individual power plants (to e.g., assist with their operations) rather than at the entire country or pan-European level; (ii) the impacts of climate variables on hydro power are varied and complex, and many factors contribute to these impacts such as watershed characteristics, the river flow rate, the evaporation process, and human factors, and hence, using only climate data is not sufficient to predict hydro power generation at the desired accuracy for plant-level operational purposes; (iii) hydro power generation at the European level has only recently started to become publicly available (as further discussed below); (iv) the quality of climate data as provided by reanalysis (i.e., climate reconstructions), and particularly precipitation, has been improving significantly only in recent years.Wind and solar power play an increasingly important role in a low-carbon energy plan. However, their weather-dependent nature requires a more stable energy source, together with storage solutions, to cope with climate variability. Hydro power is a good candidate with its ability to dispatch or store electricity according to demand. For example, [4] sho...

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Section: Introductionmentioning

confidence: 99%

Reconstruction of Multidecadal Country-Aggregated Hydro Power Generation in Europe Based on a Random Forest Model

Dubus

Felice

et al. 2020

Energies

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“…Pumped hydro systems have been applied to a range of system types, including: (1) off-grid and distributed electricity generation (Pali and Vadhera 2018), (2) smaller or islanded grid systems (Norconsult 2013;Coburn et al 2014), or even (3) very large utility-scale systems (MWH 2009;Huertas-Hernando et al 2017). The objectives of pumped hydro differ, depending on the type of system of interest.…”

Section: Hybrid Power Plant Technology Selectionmentioning

confidence: 99%

Opportunities for Research and Development of Hybrid Power Plants

Dykes

King

DiOrio

et al. 2020

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“…The 41 selected hydro stations' annual generation explains over 80% of the national hydroelectricity production, and in the model, their capacities are assumed to be fixed, even though a long list of major dams are currently in plan or under construction [44]. Indeed, the technically exploitable hydro power capacity is estimated to be 542 GW [45], and only 341 GW were put to use until 2017 [46]. The location of planned hydro stations may be known, but we are not able to validate the inflow or approximate the head heights until dam discharge measurement recorded.…”

Section: Hydroelectricity Time Seriesmentioning

confidence: 99%

The role of hydro power, storage and transmission in the decarbonization of the Chinese power system

et al. 2019

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Deep decarbonization of the electricity sector can be provided by a high penetration of renewable sources such as wind, solar PV and hydro power. Flexibility from hydro and storage complements the high temporal variability of wind and solar, and transmission infrastructure helps the power balancing by moving electricity in the spatial dimension. We study cost-optimal highly-renewable Chinese power systems under ambitious CO 2 emission reduction targets, by deploying a 31-node hourly-resolved technoeconomic optimization model supported by a validated weather-converted 38-year-long renewable power generation and electricity demand dataset. With a new realistic reservoir hydro model, we find that if CO 2 emission reduction goes beyond 70%, storage facilities such as hydro, battery and hydrogen become necessary for a moderate system cost. Numerical results show that these flexibility components can lower renewable curtailment by two thirds, allow higher solar PV share by a factor of two and contribute to covering summer cooling demand. We show that expanding unidirectional high-voltage DC lines on top of the regional inter-connections is technically sufficient and more economical than ultra-high-voltage-AC-connected "One-Net" grid. Finally, constraining transmission volume from the optimum by up to 25% does not push total costs much higher, while the significant need for battery storage remains even with abundant interconnectivity.

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Hydro power flexibility for power systems with variable renewable energy sources: an IEA Task 25 collaboration

Cited by 53 publications

References 32 publications

Reconstruction of Multidecadal Country-Aggregated Hydro Power Generation in Europe Based on a Random Forest Model

Reconstruction of Multidecadal Country-Aggregated Hydro Power Generation in Europe Based on a Random Forest Model

Opportunities for Research and Development of Hybrid Power Plants

The role of hydro power, storage and transmission in the decarbonization of the Chinese power system

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