Citation (APA): Østergaard, J. (Author). (2013). Bornholm Test Island. Sound/Visual production (digital)

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1 Downloaded from orbit.dtu.dk on: Dec 13, 2018 Bornholm Test Island Østergaard, Jacob Publication date: 2013 Link back to DTU Orbit Citation (APA): Østergaard, J. (Author). (2013). Bornholm Test Island. Sound/Visual production (digital) General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. Users may download and print one copy of any publication from the public portal for the purpose of private study or research. You may not further distribute the material or use it for any profit-making activity or commercial gain You may freely distribute the URL identifying the publication in the public portal If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim.

2 Bornholm Test Island Jacob Østergaard Professor, Head of Center Center for Electric Power and Energy, DTU Electrical Engineering 4 th IEEE Innovative Smart Grid Technologies Europe 2013 Panel session 10 Smart Grid Demonstration

3 Bornholm Island as Full-Scale Laboratory 1% of Denmark Area: 589 m2 Population: ( in Rønne) Largest company: Jensen Group, industrial layndry technology Strong political vision & public commitment Energy strategy 2008 Tradition within energy since 1980 s Ref: K. Jørgensen et al., Energy Plan for a Green Island: Project for Renewable Energy at Bornholm, Borgen, ISBN , 1986 (in Danish) 2 DTU Electrical Engineering, Technical University of Denmark

4 Bornholm Energy System >30% wind power penetration 3 DTU Electrical Engineering, Technical University of Denmark Electricity demand, ~28,000 cust., 55 MW peak Heat pumps roll-out Electric vehicles Power generation 29 MW wind power (modern/conventional) 5 MW Solar PV (>1,000 units) 2 MW biogas plant 16 MW CHP plant (wood chips + coal), 35 MJ/s 25 MW peak thermal power (fuel oil) 10x MW backup units (diesel) Distribution grid 60 kv / 10 kv / 0.4 kv 16 main substations / 1,006 secondary subst. Part of the Nordic system 60 kv under sea cable to Sweden, islanding Nord Pool market (DK2) District heating 5 systems, 560 GWh/year CHP + straw-fired boilers

5 Bornholm Smart Grid Activities Active distribution networks - More Micro Grids (EU FP6) - IDE4L (EU FP7) Solar PV integration - PV Island Bornholm I+II+III - PV Net Customers and demand flexibility - Smart Grid customer information - Demand as frequency controlled demand Electricity market designs - EcoGrid EU (EU FP7) - Flex Power Wind power integration - Coordinated Frequency Control of Wind Turbines in Power Systems Electric Vehicle Integration - EDISOIN 4 DTU Electrical Engineering, Technical University of Denmark

6 Strong National and International Collaboration Examples of partners Energy companes: (PT) (BE) Industrial partners etc.: (BE) (CH) (DE) (CH) Academic Partners: (NO) (NL) (AT) 5 DTU Electrical Engineering, Technical University of Denmark (GE) (NL)

7 Flexible multi-purpose laboratories Lyngby & Ballerup Campus Risø Campus 27,000 Customers 33% Wind Power 50% Renewable Energy Islanding capability Full-scale Realistic Power System Bornholm Power System 6 DTU Electrical Engineering, Technical University of Denmark

8 7 DTU Electrical Engineering, Technical University of Denmark

9 Autonomous V- and f-services from demand 8 DTU Electrical Engineering, Technical University of Denmark

10 System Reserves Provided by Frequency Responsive Electricity Demand Field test with 200 residential, commercial and industrial demand units Frequency reserves costs /MW/year in DK Pay pack time: 1-2½ year w/ 1 kw unit T high T normal high kf ( f f 0 ) T low T normal low kf ( f f 0 ) Field test at Bornholm 9 DTU Electrical Engineering, Technical University of Denmark

11 Power wo. DFCR Frequency System Reserves Provided by Frequency Responsive Electricity Demand Field measurements Operation of a single bottle cooler Power Delivery of normal reserve ( Hz) Freqency Power w. DFCR Delivery of disturbance reserve (<49.9 Hz) Demand can with maintained energy service deliver reserves which today are delivered by large power plants Power Easy implementation supporting commercialization Freqency 10 DTU Electrical Engineering, Technical University of Denmark

12 11 DTU Electrical Engineering, Technical University of Denmark

13 Island Operation of Bornholm Experiment 17 September 2009 Wind Power 0.0% 7.5% 10% 15% Penetration (restricted) (available) Average Total Active Power, 20.8 MW 20 MW 19.2 MW Electric Power output Conventional Plant 18.4 MW 17.6 MW 16.8 MW 16 MW Average Hz Frequency, 50.1 Hz System Electric Frequency 50 Hz 49.9 Hz 49.8 Hz 32 AM 11:20:08 AM 11:26:44 AM 11:33:20 AM 11:39:56 AM 11:46:32 AM 11:53:07 AM 11:11AM Monday 17 August 11: : 11:13:32 AM - 11:57:311:25 AM 11:32 AM 11:39 AM 11:46 AM 11:53 AM 12 DTU Electrical Engineering, Technical University of Denmark

14 Coordinated Frequency Control by Wind Turbines a) Fluctuation limiter b) Transient static Frequency [Hz] Wind power [MW] Pavailable Pelectric Frequency [Hz] DTU Electrical Engineering, Technical University of Denmark Ref: IEEE PES General Meeting, Calgary, Alberta, Canada, Power BLok 5 [MW] Power BLok 5 [MW] Time [s]

15 EcoGrid EU Large-scale demonstration of the future intelligent distribution system EU FP7 ENERGY Budget: 21 million Euro DENMARK Energinet.dk Østkraft Technical University of Denmark (DTU) NORWAY SINTEF ER (Coordinator) Integrated research and demonstration ~2,000 active customers BELGIUM ELIA EANDIS (+ORES) Bornholm ESTONIA Tallin University of Technology (TUT) EU fast-track to Smart Grids GERMANY Siemens EnCT THE NETHERLANDS ECN + TNO IBM Benelux SPAIN Tecnalia AUSTRIA Austrian Institute of Technology (AIT) PORTUGAL EDP SWITZERLAND IBM Research Landis+Gyr 14 DTU Electrical Engineering, Technical University of Denmark

16 Extention of the Market Solutions True Market Integration of Smaller Units Shorter Time Constants 15 DTU Electrical Engineering, Technical University of Denmark

17 The Fundamendal Idea of the EcoGrid EU Concept The market concept allows regulation of DER through price signal without direct measurement of the individual DER response * 16 DTU Electrical Engineering, Technical University of Denmark * Includes flexible demand

18 Bornholm as Smart Green Test Island Perspectives Test solutions in a real large-scale system with high share of RE Part of the interconnected system enables replication Isolated operation possible (a true high RE case) Typical system with its own characteristics Energy companies Industry Synergy among multiple activities Measurements and models Cost efficient development and test Universities A platform for collaboration Solve real problems together International collaboration and solutions Education of new generation of engineers Student projects A role model for a future smart grid Showroom Telling the story 17 DTU Electrical Engineering, Technical University of Denmark

19 Thank you! Jacob Østergaard Professor, Head of Center 18 DTU Electrical Engineering, Technical University of Denmark Center for Electric Power and Energy (CEE) Department of Electrical Engineering Technical University of Denmark Tel: