Physical adequacy of a power generation system: The case of Spain in the long term

Generation adequacy is a key ingredient to security of electricity supply. We develop a stochastic model of demand and supply (from different technologies) for measuring it from a physical or technical point of view. We adopt several metrics of supply shortfalls. Next we demonstrate the model by example. Because of limited interconnections with neighboring countries, Spain can be considered an electric island. We get numerical estimates of the parameters underlying the model. We then resort to Monte Carlo simulation to derive the risk profile of the adequacy metrics in the coming decades. We consider up to ten scenarios, with different demand paths and generation parks. The proposed deployment of renewable technologies and the envisaged closure of coal-fired and nuclear stations result in greater risk of shortages. For one, assuming that demand grows at 1.36% per year, from 2020 to 2030 the expected energy not served increases more than 400-fold as coal and nuclear capacities are reduced; the factor runs into the tens of thousands by 2040 and 2050 when those technologies cease to operate. These results are potentially important for policy makers, system operators, and power companies involved in the construction of the European internal electricity market.

[1]  John Foster,et al.  Resilience and electricity systems: A comparative analysis , 2012 .

[2]  Manuel Castro Assessing the risk profile to security of supply in the electricity market of Great Britain , 2017 .

[3]  M. V. Vliet,et al.  Water constraints on European power supply under climate change: impacts on electricity prices , 2013 .

[4]  Tooraj Jamasb,et al.  Security of European electricity systems: Conceptualizing the assessment criteria and core indicators , 2013, Int. J. Crit. Infrastructure Prot..

[5]  Zachary A. Collier,et al.  Metrics for energy resilience , 2014 .

[6]  C. Batlle,et al.  Security of Generation Supply in Electricity Markets , 2013 .

[7]  Wenyuan Li,et al.  Reliability Assessment of Electric Power Systems Using Monte Carlo Methods , 1994 .

[8]  Roy Billinton,et al.  Reliability evaluation of power systems , 1984 .

[9]  J. Martinich,et al.  Projecting future costs to U.S. electric utility customers from power interruptions. , 2017, Energy.

[10]  M. Pahle,et al.  Strategies against shocks in power systems – An analysis for the case of Europe , 2016 .

[11]  Enrico Zio,et al.  Risk assessment of power transmission network failures in a uniform pricing electricity market environment , 2017 .

[12]  Michael D. Sohn,et al.  Improving the estimated cost of sustained power interruptions to electricity customers , 2018, Energy.

[13]  Marko Čepin,et al.  Assessment of Power System Reliability: Methods and Applications , 2011 .

[14]  Pilar Lisbona,et al.  Energy storage in Spain: Forecasting electricity excess and assessment of power-to-gas potential up to 2050 , 2018 .

[15]  A. J. Seebregts,et al.  EU Standards for Energy Security of Supply , 2006 .

[16]  Ignacio J. Pérez-Arriaga,et al.  Enhancing power supply adequacy in Spain: Migrating from capacity payments to reliability options , 2007 .

[17]  Enrico Zio,et al.  Uncertainties in smart grids behavior and modeling: What are the risks and vulnerabilities? How to analyze them? , 2011 .

[18]  Hrvoje Pandžić,et al.  Role of energy storage in ensuring transmission system adequacy and security , 2018, Energy.

[19]  Umberto Desideri,et al.  Power-to-Gas: Analysis of potential decarbonization of Spanish electrical system in long-term prospective , 2018, Energy.

[20]  Anastasios G. Bakirtzis,et al.  Probabilistic evaluation of the long-term power system resource adequacy: The Greek case , 2018, Energy Policy.

[21]  Pedro Linares,et al.  The costs of electricity interruptions in Spain. Are we sending the right signals , 2013 .

[22]  Schuyler Matteson,et al.  Methods for multi-criteria sustainability and reliability assessments of power systems , 2014 .