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- Transmission planning for wind energy in the United States and Europe: status and prospectsPublication . Smith, J. Charles; Osborn, D.; Zavaldi, R.; Lasher, W.; Gomez-Lázaro, E.; Estanqueiro, Ana; Trotscher, Thomas; Tande, J.; Korpås, Magnus; Van Hulle, Frans; Holttinen, Hannele; Orths, Antje; Burke, Daniel; O'Malley, Mark; Dobschinski, Jan; Rawn, B.; Gibescu, Madeline; Dale, L.This paper provides an overview ofmajor transmission planning activities related to wind integration studies in the United States and Europe. Transmission planning for energy resources is different from planning for capacity resources. Those differences are explained, and illustrated with examples from several regions of the United States and Europe. Transmission planning for wind is becoming an iterative process consisting of generation expansion planning, economic-based transmission planning, system reliability analysis, and wind integration studies. A brief look at the policy environment in which this activity is taking place is provided. A set of coherent and collaborative transmission planning, siting, and permitting policies and cost allocation method must be developed to achieve the intended objectives. The scale of transmission development envisioned for this purpose will require unprecedented cooperation across multiple jurisdictional boundaries.
- System impact studies for near 100% renewable energy systems dominated by inverter based variable generationPublication . Holttinen, Hannele; Kiviluoma, Juha; Flynn, Damian; Smith, J. Charles; Orths, Antje; Eriksen, Peter Børre; Cutululis, Nicolaos Antonio; Söder, Lennart; Korpås, Magnus; Estanqueiro, Ana; MacDowell, Jason; Tuohy, Aidan; Vrana, Til Kristian; O'Malley, MarkABSTRACT: The demand for low carbon energy calls for close to 100% renewable power systems, with decarbonization of other energy sectors adding to the anticipated paradigm shift. Rising levels of variable inverter-based renewable energy sources (VIBRES) are prompting questions about how such systems will be planned and operated when variable renewable generation becomes the dominant technology. Here, we examine the implications of this paradigm shift with respect to planning, operation and system stability, also addressing the need for integration with other energy vectors, including heat, transport and Power-to-X. We highlight the knowledge gaps and provide recommendations for improved methods and models needed as power systems transform towards 100% VIBRES.
- Design and operation of energy systems with large amounts of variable generation: Final summary report, IEA Wind TCP Task 25Publication . Holttinen, Hannele; Kiviluoma, Juha; Helistö, Niina; Levy, Thomas; Menemenlis, Nickie; Jun, Liu; Cutululis, Nicolaos Antonio; Koivisto, Matti; Das, Kaushik; Orths, Antje; Eriksen, Peter Børre; Neau, Emmanuel; Bourmaud, Jean-Yves; Dobschinski, Jan; Pellinger, Christoph; von Roon, Serafin; Guminski, Andrej; Flynn, Damian; Carlini, Enrico Maria; Yasuda, Yoh; Tanabe, Ryuya; Watson, Simon; van der Meer, Arjen; Morales-España, Germán; Korpås, Magnus; Vrana, Til Kristian; Estanqueiro, Ana; Couto, António; Silva, Bernardo; Martínez, Sergio Martín; Söder, Lennart; Strbac, Goran; Pudjianto, Danny; Giannelos, Spyros; Frew, Bethany; Hodge, Bri-Mathias; Shah, Shahil; Smith, J. Charles; Lew, Debbie; O'Malley, Mark; Klonari, VasilikiABSTRACT: This report summarises findings on wind integration from the 17 countries or sponsors participating in the International Energy Agency Wind Technology Collaboration Programme (IEA Wind TCP) Task 25 from 2006–2020. Both real experience and studies are reported. Many wind integration studies incorporate solar energy, and most of the results discussed here are valid for other variable renewables in addition to wind. The national case studies address several impacts of wind power on electric power systems. In this report, they are grouped under long-term planning issues and short-term operational impacts. Long-term planning issues include grid planning and capacity adequacy. Short-term operational impacts include reliability, stability, reserves, and maximising the value of wind in operational timescales (balancing related issues). The first section presents the variability and uncertainty of power system-wide wind power, and the last section presents recent studies toward 100% shares of renewables. The appendix provides a summary of ongoing research in the national projects contributing to Task 25 for 2021–2024. The design and operation of power and energy systems is an evolving field. As ambitious targets toward net-zero carbon energy systems are announced globally, many scenarios are being made regarding how to reach these future decarbonized energy systems, most of them involving large amounts of variable renewables, mainly wind and solar energy. The secure operation of power systems is increasingly challenging, and the impacts of variable renewables, new electrification loads together with increased distribution system resources will lead to somewhat different challenges for different systems. Tools and methods to study future power and energy systems also need to evolve, and both short term operational aspects (such as power system stability) and long-term aspects (such as resource adequacy) will probably see new paradigms of operation and design. The experience of operating and planning systems with large amounts of variable generation is accumulating, and research to tackle the challenges of inverter-based, nonsynchronous generation is on the way. Energy transition and digitalization also bring new flexibility opportunities, both short and long term.
- Transmission Planning for Wind Energy: Status and ProspectsPublication . Smith, J. Charles; Osborn, Dale; Zavaldi, Robert; Lasher, Warren; Gómez-Lázaro, E.; Trotscher, Thomas; Tande, John; Korpås, Magnus; Hulle, Frans Van; Estanqueiro, Ana; Dale, Lewis; Holttinen, HanneleThis paper provides an overview of major transmission planning activities related to wind integration studies in the US and Europe. Transmission planning for energy resources is different from planning for capacity resources. Those differences are explained, and illustrated with examples from several regions of the US and Europe. Transmission planning for wind is becoming an interative process consisting of generation expansion planning, economic-based transmission planning, system reliability analysis, and wind integration studies. A brief look at the policy environment in which this activity is taking place is provided.