The Role of Storage in Smart Energy Systems | Henrik Lund
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The Role of Storage in Smart Energy Systems | Henrik Lund
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The Role of Storage in Smart Energy Systems | Henrik Lund
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The Role of Storage in Smart Energy Systems | Henrik Lund
- The role of Storage in Smart Energy Systems Henrik Lund Professor in Energy Planning Aalborg University ICARB Workshop: Energy Storage for the Built Environment 21 October 2014, ECCI, Edinburg, Scottland
- Renewable Energy Systems A Smart Energy Systems Approach to the Choice and Modeling of 100% Renewable Solutions 1. Edition in 2010 2. Edition in 2014 New Chapter on Smart Energy Systems and Infrastructures
- The long-term Objective of Danish Energy Policy Expressed by former Prime Minister Anders Fogh Rasmussen in his opening speech to the Parliament in 2006 and in several political agreements since then: To convert to 100% Renewable Energy Prime minister 16 November 2008: ”We will free Denmark totally from fossil fuels like oil, coal and gas” Prime minister 16 November 2008: ”… position Denmark in the heart of green growth”
- 100% Renewable Energy 2050 …… but how…???!!
- Smart Energy Systems The key to cost-efficient 100% Renewable Energy • A sole focus on renewable electricity (smart grid) production leads to electricity storage and flexible demand solutions! • Looking at renewable electricity as a part smart energy systems including heating, industry, gas and transportation opens for cheaper and better solutions… Power-to-Heat Power-to-Gas Power-to-Transport
- Energy Storage Pump Hydro Storage 175 €/kWh (Source: Electricity Energy Storage Technology Options: A White Paper Primer on Applications, Costs, and Benefits. Electric Power Research Institute, 2010) Natural Gas Underground Storage 0.05 €/kWh (Source: Current State Of and Issues Concerning Underground Natural Gas Storage. Federal Energy Regulatory Commission, 2004) Oil Tank 0.02 €/kWh (Source: Dahl KH, Oil tanking Copenhagen A/S, 2013: Oil Storage Tank. 2013) Thermal Storage 1-4 €/kWh (Source: Danish Technology Catalogue, 2012)
- 100% Renewable Energy 2050 Power-to-Heat
- Four different technologies Power Station 40 units of electrcity 80 Elec. Electric heating 80 units of heat 300 units of fuel Electric heating Power Station 40 units of electricity Boiler 80 units of heat 100 units of fuel Traditional System 100 units of fuel 200 units of fuel CHP plant 40 units of electricity 80 units of heat 135 units of fuel CHP System CHP unit 40 units of electricity Heat Pump 80 units of heat Integrated System with renewable energy 85 units of fuel Wind turbine 20 elec. 10 elec. 45 heat
- Domestic heating
- Heat Roadmap Europe
- 100% Renewable Energy 2050 Wind integration….!!
- Danish electricity production Big power stations Small CHP plants Wind turbines
- Backside of the medal 0 20 40 60 80 100 120 0 24 48 72 96 120 144 168 192 216 240 264 288 312 336 Hour %
- Wind energy Input: • Data from total productions of wind turbines in the TSO Eltra area (West Denmark). Wind production Eltra 1996 (2042 MWh pr MW) 0 100 200 300 400 500 0 1098 2196 3294 4392 5490 6588 7686 8784 Hours MWh/h Wind production Eltra 2000 (2083 MWh pr MW) 0 500 1000 1500 2000 0 1098 2196 3294 4392 5490 6588 7686 8784 Hours MWh/h Wind production Eltra 2001 (1964 MWh pr MW) 0 500 1000 1500 2000 0 1098 2196 3294 4392 5490 6588 7686 8784 Hours MWh/h
- Energi System Analyse Model CHP Boiler Electro- lyser Heat pump and electric boiler PP RES electricity Fuel RES heat Hydro water Hydro storage Hydro power plant H2 storage Electricity storage system Import/ Export fixed and variable Electricity demand Cooling device Cooling demand Transport demand Process heat demand Industry Cars Heat storage Heat demand www.EnergyPLAN.eu
- A palette of solutions • Flexible consumption • Electricity storage • CAES systems • Regulation of CHP plants • Electric heating • Heat pumps • Electric cars • Stopping of wind turbines • Production of hydrogen • Transmission abroad • V2G
- Conclusions: • Regulation of CHP and heat storage (implemented in DK in 2004): Makes possible to integrate 20% Wind Power (and 50% CHP) • Adding large heat pumps and heat storage capacity to existing CHP plants: Makes possible to integrate 40% Wind Power (and 50% CHP) • Electricity for transportation (integrate approx. 60% wind power) • Important to involve the new flexible technologies in the grid stabilisation task
- 100% Renewable Energy 2050 … the overall system..
- IDA Energiplan 2030
- 100% Renewable Energy in 2050 Primær energiforsyning 100% VE i år 2050, PJ 0 100 200 300 400 500 600 700 800 900 1,000 Ref 2030 IDA 2030 IDA 2050 Bio IDA 2050 Vind IDA 2050 Eksport VE-el Solvarme Biomasse Naturgas Olie Kul Biomass potentials and consumtion in IDA 2030, PJ 0 50 100 150 200 250 300 350 400 DEA potential IDA 2030 Max potential Waste Energy crops Slurry fibre fraction Slurry biogas Wood Straw
- CEESA Project 2011/2012
- TransportPLAN modeling and profiling in CEESA • Particular focus due to large challenges: – >95% reliant on oil – High increase historically – Large potential for electric cars and direct electricity but.. – Specific challenges in bringing in electricity in sea, aviation and good transport
- CEESA Project 2011/2012 Transport: Electric vehicles is best from an energy efficient point of view. But gas and/or liquid fuels is needed to transform to 100%. Biomass: .. is a limited resource and can not satisfy all the transportation needs. Consequence … Electricity from Wind (and similar resources) needs to be converted to gas and liquied fuels in the long-term perspective…
- 100% Renewable Energy 2050 Power-to-Transportation
- Electricity (111 PJ) Conversion Process││ │ │Transport Fuel Electric Grid1 Electricity (100 PJ) │Transport Demand 294 Gpkm 323 Gtkm OR Resource Resource Electricity (111 PJ) Conversion Process││ │ │ Electricity (100 PJ) │ Transport Demand 313 Gpkm Freight is not applicable Transport Fuel ORElectric Grid1 Electrolyser1 Biomass [Cellulose] (65 PJ) Electricity (83.5 PJ) Methane (100 PJ2 ) H2 (60.5 PJ) Steam Gasifier Chemical Synthesis Hydrogenation 1.9 Mt Syngas Resource Conversion Process││ │ ││ Transport Demand 61 Gpkm 36 Gtkm Transport Fuel OR H2 O (2.6 Mt) 4.5Mt Marginal Heat 3 (7.6 PJ) Power Plant 6 PJ 3 0.6 PJ 83 PJ 59 PJ Electrolyser1 Biomass [Glucose] (60 PJ) Electricity (83 PJ) Methane (100 PJ2 ) H2 (60.5 PJ) Anaerobic Digester Chemical Synthesis CO2 Hydrogenation 4.5 Mt Resource Conversion Process││ │ ││ Transport Demand 61 Gpkm 36 Gtkm Transport Fuel OR H2 O (2.3 Mt) Biogas (50 GJ) 2.3 Mt OR Biomass1 (77 PJ) Methanol/DME (100 PJ5 ) Electricity (178 PJ) CO2 (7 Mt) Co-electrolysis4 Carbon Sequestration & Recycling3Electricity2 (7.3 PJ) Chemical Synthesis Syngas (139 PJ) H2 O (5.7 Mt) Resource Conversion Process││ │ ││ Transport Demand or 50 Gtkm 83 Gpkm Transport Fuel Electricity HeatPower Plant Electrolyser6 Chemical Synthesis Fermenter Hydrogenation Chemical Synthesis Electricity (307 PJ) H2 (149.4 PJ) Straw (401.7 PJ) H2 (72.2 PJ) Methanol/DME (62.6 PJ2 ) Ethanol (100 PJ) Methanol/DME (337.5 PJ2 ) CO2 (4.4 Mt) H2O (15.5 Mt) Hydrogenation Low & High Temperature Gasification7 Resource Conversion Process││ │ │Transport Fuel OR Transport Demand │ 52 Gpkm 67 Gpkm 31 Gtkm 39 Gtkm4 279 Gpkm 169 Gtkm OR OR Lignin (197.7 PJ) C5 Sugars (92.8 PJ) Biomass (40.2 PJ) Power Plant 115 Mt 1 Mt Marginal Heat1 (50.2 PJ) 303.6 PJ 3.4 PJ3 3.5 Mt
- Smart Energy Systems The key to cost-efficient 100% Renewable Energy • A sole focus on renewable electricity (smart grid) production leads to electricity storage and flexible demand solutions! • Looking at renewable electricity as a part smart energy systems including heating, industry, gas and transportation opens for cheaper and better solutions… Power-to-Heat Power-to-Gas Power-to-Transport
- Smart Grid (2005) No definition. However it can be understood from the context that a smart grid is a power network using modern computer and communication technology to achieve a network which can better deal with potential failures.
- Smart Grid - definitions “A smart grid is an electricity grid that uses information and communications technology to gather and act on information, such as information about the behaviors of suppliers and consumers, in an automated fashion to improve the efficiency, reliability, economics, and sustainability of the production and distribution of electricity.” (U.S. Department of Energy) “Smart Grids … concerns an electricity network that can intelligently integrate the actions of all users connected to it - generators, consumers and those that do both - in order to efficiently deliver sustainable, economic and secure electricity supplies.” (SmartGrids European Technology Platform, 2006). “A Smart Grid is an electricity network that can cost efficiently integrate the behaviour and actions of all users connected to it – generators, consumers and those that do both – in order to ensure economically efficient, sustainable power system with low losses and high levels of quality and security of supply and safety.” (European Commission, 2011) “Smart grids are networks that monitor and manage the transport of electricity from all generation sources to meet the varying electricity demands of end users” …. “The widespread deployment of smart grids is crucial to achieving a more secure and sustainable energy future.” (International Energy Agency 2013).
- Smart heating and cooling grids • In the European Commission’s strategy [7] for a competitive, sustainable and secure “Energy 2020“, the need for “high efficiency cogeneration, district heating and cooling” is highlighted (page 8). The paper launches projects to promote, among others, “smart electricity grids” along with “smart heating and cooling grids” (page 16).
- Smart Energy Systems • Smart Electricity Grids are define as electricity infrastructures that can intelligently integrate the actions of all users connected to it - generators, consumers and those that do both - in order to efficiently deliver sustainable, economic and secure electricity supplies. • Smart Thermal Grids (District Heating and Cooling) is a network of pipes connecting the buildings in a neighbourhood, town centre or whole city, so that they can be served from a centralised plant as well as from a number of distributed heat and/or cooling producing units including individual contributions from the connected buildings. • Gas Smart Grids are defined as gas infrastructures that can intelligent integrate the actions of all users connected to it - supplies, consumers and those that do both - in order to efficiently deliver sustainable, economic and secure gas supplies and storage. Smart Energy Systems is define as an approach in which Smart Electricity, Thermal and Gas Grids are combined and coordinated to identify synergies between them in order to achieve an optimal solution for each individual sector as well as for the overall energy system.
- Energi System Analyse Model CHP Boiler Electro- lyser Heat pump and electric boiler PP RES electricity Fuel RES heat Hydro water Hydro storage Hydro power plant H2 storage Electricity storage system Import/ Export fixed and variable Electricity demand Cooling device Cooling demand Transport demand Process heat demand Industry Cars Heat storage Heat demand www.EnergyPLAN.eu
- Smart Energy Systems: Hourly modelling of all smart grids to identify synergies! … and influence of different types of energy storage..!
- CEESA Project 2011/2012 Smart Energy Systems: Integrated use of Power-To-Heat, Power- To-Transport and Power-To-Gas/Liquid fuel RES integration: Hourly balance of wind etc. by use of thermal and gas/fuel storage. (Least-cost solution) No electricity storage … except from batteries in cars…
- Energy Storage Pump Hydro Storage 175 €/kWh (Source: Electricity Energy Storage Technology Options: A White Paper Primer on Applications, Costs, and Benefits. Electric Power Research Institute, 2010) Natural Gas Underground Storage 0.05 €/kWh (Source: Current State Of and Issues Concerning Underground Natural Gas Storage. Federal Energy Regulatory Commission, 2004) Oil Tank 0.02 €/kWh (Source: Dahl KH, Oil tanking Copenhagen A/S, 2013: Oil Storage Tank. 2013) Thermal Storage 1-4 €/kWh (Source: Danish Technology Catalogue, 2012)
- More information: • http://www.emd.dk/desire/skagen • http://www.emd.dk/el http://energy.plan.aau.dk/book.php www.EnergyPLAN.eu www.heatroadmap.eu www.4DH.dk