Islands challenges and R&D activities funded by HEDNO Nikos Hatziargyriou Chairman of the Board and CEO of HEDNO ETIP SNET Vice-Chair
Clean Energy for All Europeans-Clean energy for EU Islands More than 2200 inhabited islands in the EU. Despite access to renewable sources of energy, they mainlydepend on expensive fossil fuel imports for their energy supply. As part of the Clean Energy for All Europeans package, the EU's Clean Energy for EU Islands initiative provides a long term framework to help islands generate their own sustainable, low-cost energy, resulting in: Reduced energy costs and greatly increased production of renewable energy and construction of energy storage facilities and demand response systems Better energy security for islands, less reliance on imports Improved air quality, lower greenhouse gas emissions, less impact on islands' natural environment New jobs and business opportunities, boosting islands' economic self-sufficiency. The Clean Energy for EU Islands initiative was launched in May 2017 in Malta, when the European Commission and 14 EU countries (Croatia, Cyprus, Denmark, Estonia, Finland, France, Germany, Greece, Ireland, Italy, Malta, Portugal, Spain, and Sweden) signed a Political Declaration followed by Clean Energy for EU Islands-Inaugural Forum (Chania, Crete 22 September 2017)
Greek Non Interconnected (NII) Islands 32 Electrical Systems (ES) Categorized by Average Peak Demand (last 5 years) Large (>100 MW):2 ES
Non Interconnected Islands (NII) 32 Electrical Systems (ES) Categorized by Average Peak Demand (last 5 years) Large (>100 MW):2ES Medium (>5 100 MW): 14 ES
Non Interconnected Islands (NII) 32 Electrical Systems (ES) Categorized by Average Peak Demand (last 5 years) Large (>100 MW):2ES Medium (>5 100 MW): 14 ES Small( 5 MW): 16 ES St.Efstratios Agathonisi Amorgos Anafi Antikythira Arkioi Astypalaia Gavdos Donousa Ereikousa Kythnos Megisti Othonoi Serifos Skyros Symi
HEDNO s role as NII s Electrical System Operator Market Operator Distribution System Operator HEDNO Operator of NII Manager and Operator of NIIs Energy Control Centers Transmission System Operator Our MISSION - Increase RES penetration in each ES of NII - Reduce the operational cost of NII s ES - Ensure uninterruptible electricity supply of prosumers Our GOAL Develop all the necessary infrastructure for the 32 ES of NII, covering the emerging needs of all Participants in the NII s Market
Strategic Plan for NIIPs 130 million 0.5 million 49 million 0.5 million Market Smart Island NII s Infrastructure HEDNO s Core Infrastructure HEDNO s Core Infrastructure Further implementation of Smart Metering Digitalization and Data Management through smart and integrated systems NII s Infrastructure Metering Infrastructure for producers Development of the IT System for NII Energy Control Centers (ECC) in Athens, Grete and Rhodes Energy Control Centers (ECC) in the rest ES Market NII s market Infrastructure Smart Island increase of RES penetration reduction of the operational cost contribution to environmental protection saving of resources ensure reliable and uninterrupted supply of electricity
R&I is a key activity in our business
Research, Development and Innovation HEDNO S main objective is the continuous modernization through research and development, with emphasis on innovation Active member of: Smart grids create new opportunities for HEDNO s contribution to the country s productive reconstruction. HEDNO participates in various research projects through European and national partnerships, and with a particular focus on fields such as the optimal integration of RES into the Network, the production and load forecasting, the Network development and upgrading, the remote metering of electricity consumption etc.
Research and Innovation in the Greek Islands/Success stories Kythnos (1982) Operation of the first Wind Park in Europe (5x20kW) Kythnos(1983) Operation of the first hybrid station comprising a 100 kw PV system with Battery storage Kythnos (2000) Operation of a fully automated power system with 500kW battery storage and a 500kW Wind Turbine Kythnos (2001) Operation of the first Microgrid electrifying 12 houses with intelligent autonomous Load Control Crete (2003) Development of advanced control software system for isolated systems with high RES penetration Ikaria hybrid power station: Consisting of 1.05 MW small hydro, 3MW pumped storage and 2.7MW wind farm (Almost completed) TILOS: Small Hybrid station (Wind Turbine, PV and battery storage) (on-going) Several RD&D projects
Crete Power Production 60% hourly RES penetration 11
http://www.microgrids.eu Kythnos Microgrid of 12 houses comprising PVs and Batteries (52 kwh), 9 kva Diesel (only back-up), flexible loads (1-2 kw irrigation pumps), Intelligent Load Controllers
Decentralized MAS Based Control for Energy Efficiency (Kythnos) Agents embedded in Intelligent Load Controllers identify the status of the environment (available energy) Agents negotiate on how the share the available energy without central coordination PV Diesel Batteries System House Wi-Fi
R&D activities funded by HEDNO
R&D activities funded by HEDNO ENERGY MANAGEMENT The objective of the e-care software is to optimize the overall performance of island systems by increasing the share of RES energy maintaining security. Modular Architecture Load and RES forecast RDAS and ED according to the NII Code Online Security Monitoring Web based environment
R&D activities funded by HEDNO Load and RES Forecasting SCADA Meteo Forecast Advanced Modules Advanced All Technologies Rolling Day Ahead Scheduling/Economic Dispatch Scheduling based on power optimization libraries (CPLEX) Integration of Market Rules Simple Messages to the operator Advanced Modules
R&D activities funded by HEDNO PLANNING AHEAD Cover yearly demand and peak by Thermal Unit and RES Maximize RES Penetration Minimize Fuel Cost Respect Market operation and associated constraints Identify type and size of ICE/Thermal Units (Data Base for all island systems) Identify RES Capacity limits including new technologies : Hybrid (Storage with RES) and CSP Compare interconnections (between islands or with the mainland system) with new Thermal Units Analysis of technical constraints on island operation (reserves, RES penetration limits, etc) Hourly simulation for several years ahead(1 to 10) Online environment to create and store scenarios
Διείσδυση ΑΠΕ (% της ζήτησης) Εγκατεστημένη ισχύς ΑΠΕ (MW) CF Α/Π R&D activities funded by HEDNO RES Hosting Capacity: Island of Rhodes 30.0% 29.8% 29.6% 29.4% 29.2% 29.0% 28.8% 28.6% 28.4% 28.2% 28.0% 24 25 26 27 28 29 30 31 32 33 34 35 Ισχύς Φ/Β (MW) 49 MW Α/Π 51 MW Α/Π 55 MW Α/Π 59 MW Α/Π 61 MW Α/Π 50% 48% 46% 44% 42% 40% 38% 36% 34% 32% 180 160 140 120 100 80 60 40 20 0 ΗΘΣ 85 75 55 25 0 ΥΒΣ 0 20 35 50 55 Φ/Β 24 24 24 24 24 Α/Π 49 49 49 49 49
Ροή ισχύος (MW) Ροή ισχύος (MW) R&D activities funded by HEDNO Impact of a new interconnection 600 0 0 1000 2000 3000 4000 5000 6000 7000 8000 9000 500-20 400 300 200 2020 2025-40 -60 2020 2025 2030 2035 100 0 0 1000 2000 3000 4000 5000 6000 7000 8000 9000 Ώρες -80-100 -120 Ώρες 2040 2045 Duration curve of thermal production in Crete Duration curve in the interconnection between Andros and mainland
R&D activities funded by HEDNO Hybrid station with RES and small size of storage Increase the RES penetration beyond 60% - 70% Sustainable solution Smart Island-The GOAL Does not increase the total cost in the island Should be attractive investment Ensure the power supply in the island Minimize impact on thermal production New experiences for the Island Operator in order to replicate the solution in other islands HEDNO responsible for technical terms, tendering process launched by Regulatory authority for energy within the next months.
R&D activities funded by HEDNO Simulation -Case of Astypalaia Typical NII system, summer peak 5 thermal units with total capacity 4,3 MW Peak Load: 2,3MW Yearly Demand: 6,600MWh 4 PV plants (0.32MW) and 7 roof top PVs (0,035 MW) Hybrid: 0,4MW PV,2MW Wind, Storage 2MW/ 8MWh 8000 7000 6000 5000 4000 3000 2000 1000 0 RES Penetration 6320 480 0 Without Hybrid 1840 480 4480 With Hybrid Thermal Existing RES Hybrid 15,00% 14,50% 14,00% 13,50% 13,00% 12,50% IRR of the investment 14,20% 0MW PV, 2,4MW W/Τ 14,60% 0,4 MW PV, 2MW W/Τ 14,50% 0,8 MW PV, 1,6MW W/Τ 13,30% 1,6MW PV, 0,8MW W/Τ 14,30% 0,4MW PV, 2,4MW W/Τ 21
Thank you very much.