Flexibility Modeling, Management, and Trading in Bottom-up Cellular Energy Systems

Accelerated local deployments of renewable energy sources and energy storage units, as well as increased overall flexibility in local demand and supply through active user involvement and smart energy solutions, open up new opportunities (e.g., self-sufficiency and CO2 neutrality through local renewables) and yet pose new challenges (e.g., how to maintain the security of supply and get the best yield) to market players in the lower parts of the energy system (including prosumers, energy communities, aggregators, and distribution system operators (DSOs)). One way to cope with the challenges requires "logical" reorganization of the energy system bottom-up as a number of nested (maximally) self-sufficient and interacting cells with their own local (i.e. within a cell) energy management and trading capabilities. This change necessitates effective IT-based solutions. Towards this goal, we propose a unified Flexibility Modeling, Management, and Trading System (FMTS) that generalizes flexibility modeling, management, and intra-cell trading in such cellular energy systems. Our system offers different flexibility provisioning options (Machine Learning based, and Model Predictive Control based), activation mechanisms (indirect and direct device-control), and trading schemes (e.g. flexibility contracts, market-based trading) and suits different cellular system use-cases. In this paper, we introduce the FMTS, overview its core functionality and components, and explain how it practically manages, prices, and trades flexibility from a diverse variety of loads. We then introduce the real-world FMTS instances developed in the GOFLEX project1 and present experimental results that demonstrate significantly increased flexibility capacities, user gains, and balance between demand and supply when an FMTS instance is used in the simulated cellular energy system setting.

[1]  Torben Bach Pedersen,et al.  Modeling and Managing Energy Flexibility Using FlexOffers , 2018, 2018 IEEE International Conference on Communications, Control, and Computing Technologies for Smart Grids (SmartGridComm).

[2]  Andrey Bernstein,et al.  Autonomous Energy Grids , 2018, HICSS.

[3]  Torben Bach Pedersen,et al.  Data management in the MIRABEL smart grid system , 2012, EDBT-ICDT '12.

[4]  Bo Thiesson,et al.  Towards Flexibility Detection in Device-Level Energy Consumption , 2014, DARE.

[5]  Torben Bach Pedersen,et al.  Aggregating energy flexibilities under constraints , 2016, 2016 IEEE International Conference on Smart Grid Communications (SmartGridComm).

[6]  Dorothea Wagner,et al.  How much demand side flexibility do we need?: Analyzing where to exploit flexibility in industrial processes , 2018, e-Energy.

[7]  De-Nian Yang,et al.  Relay Selection for Heterogeneous Cellular Networks with Renewable Green Energy Sources , 2018, IEEE Transactions on Mobile Computing.

[8]  Henrik Madsen,et al.  Optimal coordinated bidding of a profit-maximizing EV aggregator under uncertainty , 2018, 2018 IEEE International Energy Conference (ENERGYCON).

[9]  Torben Bach Pedersen,et al.  Arrowhead compliant virtual market of energy , 2014, Proceedings of the 2014 IEEE Emerging Technology and Factory Automation (ETFA).

[10]  Torben Bach Pedersen,et al.  Adaptive User-Oriented Direct Load-Control of Residential Flexible Devices , 2018, e-Energy.

[11]  Torben Bach Pedersen,et al.  Measuring and Comparing Energy Flexibilities , 2015, EDBT/ICDT Workshops.

[12]  Anzar Mahmood,et al.  Prosumer based energy management and sharing in smart grid , 2018 .

[13]  Torben Bach Pedersen,et al.  Day-ahead Trading of Aggregated Energy Flexibility , 2018, e-Energy.

[14]  Geert Deconinck,et al.  Battery Scheduling in a Residential Multi-Carrier Energy System Using Reinforcement Learning , 2018, 2018 IEEE International Conference on Communications, Control, and Computing Technologies for Smart Grids (SmartGridComm).

[15]  George B. Dantzig,et al.  Fourier-Motzkin Elimination and Its Dual , 1973, J. Comb. Theory, Ser. A.

[16]  P. Klemperer The Product-Mix Auction: A New Auction Design for Differentiated Goods , 2010 .

[17]  Tom Holvoet,et al.  Who gets my flex? An evolutionary game theory analysis of flexibility market dynamics , 2018 .

[18]  Bo Thiesson,et al.  Utilizing Device-level Demand Forecasting for Flexibility Markets , 2018, e-Energy.

[19]  D. Greene,et al.  Energy efficiency and consumption — the rebound effect — a survey , 2000 .

[20]  Laurynas Siksnys,et al.  Towards the automated extraction of flexibilities from electricity time series , 2013, EDBT '13.

[21]  Jakob Stoustrup,et al.  Simple flexibility factor to facilitate the design of energy-flex-buildings , 2017 .

[22]  Torben Bach Pedersen,et al.  Generation and Evaluation of Flex-Offers from Flexible Electrical Devices , 2017, e-Energy.

[23]  Jan Dimon Bendtsen,et al.  Energy Flexibility for Systems with large Thermal Masses with Applications to Shopping Centers , 2018, 2018 IEEE International Conference on Communications, Control, and Computing Technologies for Smart Grids (SmartGridComm).

[24]  Chi-Kin Chau,et al.  Smart Power Plugs for Efficient Online Classification and Tracking of Appliance Behavior , 2017, APSys.

[25]  Masood Parvania,et al.  Optimal Coordination of Water Distribution Energy Flexibility With Power Systems Operation , 2019, IEEE Transactions on Smart Grid.

[26]  Peter Fritzson,et al.  Modelica - A Unified Object-Oriented Language for System Modelling and Simulation , 1998, ECOOP.

[27]  Torben Bach Pedersen,et al.  An Energy Flexibility Framework on The Internet of Things , 2015 .

[28]  Henrik Madsen,et al.  Characterizing the energy flexibility of buildings and districts , 2018, Applied Energy.

[29]  Torben Bach Pedersen,et al.  Balancing Energy Flexibilities Through Aggregation , 2014, DARE.

[30]  Rolf Wüstenhagen,et al.  The flexible prosumer: Measuring the willingness to co-create distributed flexibility , 2018 .

[31]  Torben Bach Pedersen,et al.  Dependency-based FlexOffers: scalable management of flexible loads with dependencies , 2016, e-Energy.

[32]  Torben Bach Pedersen,et al.  Using Aggregation to Improve the Scheduling of Flexible Energy Offers , 2012 .

[33]  Torben Bach Pedersen,et al.  Aggregating and Disaggregating Flexibility Objects , 2012, IEEE Transactions on Knowledge and Data Engineering.