Stochastic adaptive-service level agreement-based energy management model for smart grid and prosumers

The growing issue of demand-supply management between the prosumers and the local energy market requires an efficient and reliable energy management model. The microlayers, such as prosumers, energy districts, and macro players, namely retail dealers and wholesale dealers play a pivotal role in achieving mutual benefits. The stochastic nature of renewable energy generation in energy districts requires an effective model that can contemplate all stochastic complexities. Therefore, this paper proposes a mutual trade model between energy districts and smart grid to authorize the prosumers for mutual energy transactions under the stochastic adaptive-service level agreement. Moreover, multiple smart contacts are developed between the stakeholders to design adaptability and stochastic behavior of wind speed and solar irradiance. The real-time adaptations of the stochastic adaptive-service level agreement are based on technical beneficial feasibility and achieved through stochastic and adaptive functions. The optimized solution based on a genetic algorithm is proposed for the energy cost and energy surplus of prosumers and output parameters of the mutual trade model (grid revenue). In the context of mutual benefits associated with balanced demand and supply, the economic load dispatch and simplex method maximization are used for optimized demand-supply energy management. Moreover, the effectiveness of the proposed adaptive and stochastic mutual trade model is validated through simulation and statistical analysis.

[1]  M. P. Balcell,et al.  Connecting the grids: A review of blockchain governance in distributed energy transitions , 2022, Energy Research & Social Science.

[2]  Alejandro Navarro-Espinosa,et al.  On the Value of Community Association for Microgrid Development: Learnings from Multiple Deterministic and Stochastic Planning Designs , 2021, Applied Sciences.

[3]  Antonio J. Conejo,et al.  Mixed-integer linear programming models and algorithms for generation and transmission expansion planning of power systems , 2021, Eur. J. Oper. Res..

[4]  Ahmad Alhindi,et al.  Bi-Directional Mutual Energy Trade between Smart Grid and Energy Districts Using Renewable Energy Credits , 2021, Sensors.

[5]  Juan David Mina-Casaran,et al.  Demand response integration in microgrid planning as a strategy for energy transition in power systems , 2021, IET Renewable Power Generation.

[6]  Masoud Dashtdar,et al.  Size Optimization of Distributed Generation Resources in Microgrids with Considering Uncertainty Units Based on Scenario Tree , 2021, Autom. Control. Comput. Sci..

[7]  M. Poblet,et al.  Connecting the Grids: A Review of Blockchain Governance in Distributed Energy Transitions , 2020, SSRN Electronic Journal.

[8]  M. A. Abido,et al.  High-Level Penetration of Renewable Energy Sources Into Grid Utility: Challenges and Solutions , 2020, IEEE Access.

[9]  Andrea Michiorri,et al.  Optimal Participation of Residential Aggregators in Energy and Local Flexibility Markets , 2020, IEEE Transactions on Smart Grid.

[10]  Tariq Kamal,et al.  Grid integrated photovoltaic system with fuzzy based maximum power point tracking control along with harmonic elimination , 2020, Trans. Emerg. Telecommun. Technol..

[11]  Golbon Zakeri,et al.  Multistage stochastic demand-side management for price-making major consumers of electricity in a co-optimized energy and reserve market , 2020, Eur. J. Oper. Res..

[12]  B. Khan,et al.  Smart Grid Block-Chain (BC) Conceptual Framework: Bi-Directional Models for Renewable Energy District and Utility , 2019, 2019 15th International Conference on Emerging Technologies (ICET).

[13]  Saifur Rahman,et al.  Comparative analysis of auction mechanisms and bidding strategies for P2P solar transactive energy markets , 2019 .

[14]  Zahid Ullah,et al.  Smart grid and energy district mutual interactions with demand response programs , 2019, IET Energy Systems Integration.

[15]  Muhammad Baseer,et al.  Planning of HMG with high penetration of renewable energy sources , 2019, IET Renewable Power Generation.

[16]  Izhar Hussain,et al.  Stochastic Wind Energy Management Model within smart grid framework: A joint Bi-directional Service Level Agreement (SLA) between smart grid and Wind Energy District Prosumers , 2019, Renewable Energy.

[17]  Sayyad Nojavan,et al.  Deriving nonlinear models for incentive-based demand response programs , 2019, International Journal of Electrical Power & Energy Systems.

[18]  J. Maděra,et al.  Effect of applied weather data sets in simulation of building energy demands: Comparison of design years with recent weather data , 2019, Renewable and Sustainable Energy Reviews.

[19]  E. Rocco,et al.  Hybrid solar power system versus photovoltaic plant: A comparative analysis through a life cycle approach , 2019, Renewable Energy.

[20]  Robert Shorten,et al.  Distributed Algorithms for Internet-of-Things enabled Prosumer Markets: A Control Theoretic Perspective , 2018, Analytics for the Sharing Economy: Mathematics, Engineering and Business Perspectives.

[21]  Jérôme De Boeck,et al.  Optimizing power generation in the presence of micro-grids , 2018, Eur. J. Oper. Res..

[22]  Anastasios D. Doulamis,et al.  Virtual Associations of Prosumers for Smart Energy Networks Under a Renewable Split Market , 2018, IEEE Transactions on Smart Grid.

[23]  David Allinson,et al.  Seasonal variation in household electricity demand: A comparison of monitored and synthetic daily load profiles , 2018, Energy and Buildings.

[24]  Frank Sehnke,et al.  Wind turbine power curve modeling based on Gaussian Processes and Artificial Neural Networks , 2018, Renewable Energy.

[25]  Thomas Morstyn,et al.  Constructing Prosumer Coalitions for Energy Cost Savings Using Cooperative Game Theory , 2018, 2018 Power Systems Computation Conference (PSCC).

[26]  Daniele Cocco,et al.  Use of weather forecast for increasing the self-consumption rate of home solar systems: An Italian case study , 2018 .

[27]  A. Ożadowicz,et al.  A New Concept of Active Demand Side Management for Energy Efficient Prosumer Microgrids with Smart Building Technologies , 2017 .

[28]  Ganguk Hwang,et al.  Event-Driven Energy Trading System in Microgrids: Aperiodic Market Model Analysis With a Game Theoretic Approach , 2017, IEEE Access.

[29]  Sang-Won Min,et al.  Optimal Scheduling and Operation of the ESS for Prosumer Market Environment in Grid-Connected Industrial Complex , 2017, IEEE Transactions on Industry Applications.

[30]  Ashok M. Jadhav,et al.  Priority-Based Energy Scheduling in a Smart Distributed Network With Multiple Microgrids , 2017, IEEE Transactions on Industrial Informatics.

[31]  R. Madlener,et al.  Are Prosumer Households that Much Different? Evidence from Stated Residential Energy Consumption in Germany , 2016, Ecological Economics.

[32]  Mahmud Fotuhi-Firuzabad,et al.  Decentralized transactive energy management of multi-microgrid distribution systems based on ADMM , 2021 .

[33]  Amjad Ullah,et al.  Machine Learning Based Energy Management Model for Smart Grid and Renewable Energy Districts , 2020, IEEE Access.

[34]  C. Rehtanz,et al.  Self-sustainable Community of Electricity Prosumers in Distribution System , 2019 .