Browsing by Author "Pudjianto, Danny"
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- 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.
- Dynamic Line Rating Models and Their Potential for a Cost-Effective Transition to Carbon-Neutral Power SystemsPublication . Estanqueiro, Ana; Algarvio, Hugo; Couto, António; Michiorri, Andrea; Salas, Sergio; Pudjianto, Danny; Hagglund, Per; Dobschinski, Jan; Bolgaryn, Roman; Kanefendt, Thomas; Gentle, Jake; Alam, S. M. Shafiul; Priest, Zachary M.; Abboud, Alexander W.ABSTRACT: Most transmission system operators (TSOs) currently use seasonally steady-state models considering limiting weather conditions that serve as reference to compute the transmission capacity of overhead power lines. The use of dynamic line rating (DLR) models can avoid the construction of new lines, market splitting, false congestions, and the degradation of lines in a cost-effective way. DLR can also be used in the long run in grid extension and new power capacity planning. In the short run, it should be used to help operate power systems with congested lines. The operation of the power systems is planned to have the market trading into account; thus, it computes transactions hours ahead of real-time operation, using power flow forecasts affected by large errors. In the near future, within a "smart grid" environment, in real-time operation conditions, TSOs should be able to rapidly compute the capacity rating of overhead lines using DLR models and the most reliable weather information, forecasts, and line measurements, avoiding the current steady-state approach that, in many circumstances, assumes ampacities above the thermal limits of the lines. This work presents a review of the line rating methodologies in several European countries and the United States. Furthermore, it presents the results of pilot projects and studies considering the application of DLR in overhead power lines, obtaining significant reductions in the congestion of internal networks and cross-border transmission lines.
- Review of wind generation within adequacy calculations and capacity markets for different power systemsPublication . Soder, Lennart; Tómasson, Egill; Estanqueiro, Ana; Flynn, Damian; Hodge, Bri-Mathias; Kiviluoma, Juha; Korpås, Magnus; Neau, Emmanuel; Couto, António; Pudjianto, Danny; Strbac, Goran; Burke, Daniel; Gomez, Tomas; Das, Kaushik; Cutululis, Nicolaos Antonio; Van Hertem, Dirk; Hoschle, Hanspeter; Matevosyan, Julia; von Roon, Serafin; Carlini, Enrico Maria; Caprabianca, Mauro; Vrie, Laurens deABSTRACT: The integration of renewable energy sources, including wind power, in the adequacy assessment of electricity generation capacity becomes increasingly important as renewable energy generation increases in volume and replaces conventional power plants. The contribution of wind power to cover the electricity demand is less certain than conventional power sources; therefore, the capacity value of wind power is smaller than that of conventional plants. This article presents an overview of the adequacy challenge, how wind power is handled in the regulation of capacity adequacy, and how wind power is treated in a selection of jurisdictions. The jurisdictions included in the overview are Sweden, Great Britain, France, Ireland, United States (PJM and ERCOT), Finland, Portugal, Spain, Norway, Denmark, Belgium, Germany, Italy and the Netherlands.
- Strategies for Continuous Balancing in Future Power Systems with High Wind and Solar SharesPublication . Nordström, Henrik; Söder, Lennart; Flynn, Damian; Matevosyan, Julia; Kiviluoma, Juha; Holttinen, Hannele; Vrana, Til Kristian; van der Welle, Adriaan; Morales-España, Germán; Pudjianto, Danny; Strbac, Goran; Dobschinski, Jan; Estanqueiro, Ana; Algarvio, Hugo; Martinez, Sergio Martin; Lázaro, Emilio Gómez; Hodge, Bri-MathiasABSTRACT: The use of wind power has grown strongly in recent years and is expected to continue to increase in the coming decades. Solar power is also expected to increase significantly. In a power system, a continuous balance is maintained between total production and demand. This balancing is currently mainly managed with conventional power plants, but with larger amounts of wind and solar power, other sources will also be needed. Interesting possibilities include continuous control of wind and solar power, battery storage, electric vehicles, hydrogen production, and other demand resources with flexibility potential. The aim of this article is to describe and compare the different challenges and future possibilities in six systems concerning how to keep a continuous balance in the future with significantly larger amounts of variable renewable power production. A realistic understanding of how these systems plan to handle continuous balancing is central to effectively develop a carbon-dioxide-free electricity system of the future. The systems included in the overview are the Nordic synchronous area, the island of Ireland, the Iberian Peninsula, Texas (ERCOT), the central European system, and Great Britain.