Your search keyword '"Efficient Management"' showing total 4 results

1. Model Predictive Control for Efficient Management of Energy Resources in Smart Buildings

Author

Francesco Simmini, Tommaso Caldognetto, Mattia Bruschetta, Enrico Mion, and Ruggero Carli

Subjects

efficient management, energy resources, heuristic approach, model predictive control, nanogrid, smart buildings, Technology

Abstract

Efficient management of energy resources is crucial in smart buildings. In this work, model predictive control (MPC) is used to minimize the economic costs of prosumers equipped with production units, energy storage systems, and electric vehicles. To this purpose, the predictive control manages the available energy resources by exploiting future information about energy prices, absorption and production power profiles, and electric vehicle (EV) usage, such as times of departure and arrival and predicted energy consumption. The predictive control is compared with a rule-based technique, herein referred to as a heuristic approach, that acts in an instant-by-instant fashion without considering any future information. The reported results show that the studied predictive approach allows one to achieve charging profiles that adapt to variable operating conditions, aiming at optimal performances in terms of economic cost minimization in time-varying price scenarios, reduction of rms current stresses, and recharging capability of EV batteries. Specifically, unlike the heuristic method, the MPC approach is proven to be capable of efficiently managing the available energy resources to ensure a full recharge of the EV battery during nighttime while always respecting all system constraints. In addition, the proposed control is shown to be capable of keeping the peak power absorption from the grid constrained within set limits, which is a valuable feature in scenarios with widespread adoption of EVs in order to limit the stress on the electrical system.

Published

2021

2. Energy Management Systems for Optimal Operation of Electrical Micro/Nanogrids.

Author

Di Piazza, Maria Carmela and Di Piazza, Maria Carmela

Subjects

Technology: general issues, battery energy storage, battery impedance model, black-start, cold load pickup, demand uncertainty, demand-response, distributed electronic power converters, distribution systems, efficient management, electrical vehicles, energy forecasting, energy management system, energy resources, energy storage, equivalent circuit model, flexible programming, forecasting error, fractional-order model, heuristic approach, islanding, master-slave control approach, micro-grid planning, microgrid, microgrids, model predictive control, nanogrid, optimal power sharing, power flow control, real-time control, real-time simulations, rolling horizon, smart buildings, smart home, time- domain implementation

Abstract

Summary: Energy management systems (EMSs) are nowadays considered one of the most relevant technical solutions for enhancing the efficiency, reliability, and economy of smart micro/nanogrids, both in terrestrial and vehicular applications. For this reason, the recent technical literature includes numerous technical contributions on EMSs for residential/commercial/vehicular micro/nanogrids that encompass renewable generators and battery storage systems (BSS) The volume "Energy Management Systems for Optimal Operation of Electrical Micro/Nanogrids", was released as a Special Issue of the journal Energies, published by MDPI, with the aim of expanding the knowledge on EMSs for the optimal operation of electrical micro/nanogrids by presenting topical and high-quality research papers that address open issues in the identified technical field. The volume is a collection of seven research papers authored by research teams from several countries, where different hot topics are accurately explored. The reader will have the possibility to benefit from original scientific results concerning, in particular, the following key topics: distribution systems; smart home/building; battery energy storage; demand uncertainty; energy forecasting; model predictive control; real-time control, microgrid planning; and electrical vehicles.

3. Model Predictive Control for Efficient Management of Energy Resources in Smart Buildings

Author

Tommaso Caldognetto, Enrico Mion, Francesco Simmini, Mattia Bruschetta, and Ruggero Carli

Subjects

Technology, Control and Optimization, business.product_category, model predictive control, Computer science, energy resources, Energy Engineering and Power Technology, efficient management, Energy storage, Electric power system, Electric vehicle, heuristic approach, Electrical and Electronic Engineering, Engineering (miscellaneous), Building automation, nanogrid, smart buildings, Renewable Energy, Sustainability and the Environment, business.industry, Heuristic, Energy consumption, Reliability engineering, Model predictive control, Available energy, business, Energy (miscellaneous)

Abstract

Efficient management of energy resources is crucial in smart buildings. In this work, model predictive control (MPC) is used to minimize the economic costs of prosumers equipped with production units, energy storage systems, and electric vehicles. To this purpose, the predictive control manages the available energy resources by exploiting future information about energy prices, absorption and production power profiles, and electric vehicle (EV) usage, such as times of departure and arrival and predicted energy consumption. The predictive control is compared with a rule-based technique, herein referred to as a heuristic approach, that acts in an instant-by-instant fashion without considering any future information. The reported results show that the studied predictive approach allows one to achieve charging profiles that adapt to variable operating conditions, aiming at optimal performances in terms of economic cost minimization in time-varying price scenarios, reduction of rms current stresses, and recharging capability of EV batteries. Specifically, unlike the heuristic method, the MPC approach is proven to be capable of efficiently managing the available energy resources to ensure a full recharge of the EV battery during nighttime while always respecting all system constraints. In addition, the proposed control is shown to be capable of keeping the peak power absorption from the grid constrained within set limits, which is a valuable feature in scenarios with widespread adoption of EVs in order to limit the stress on the electrical system.

Published

2021

4. Model Predictive Control for Efficient Management of Energy Resources in Smart Buildings.

Author

Simmini, Francesco, Caldognetto, Tommaso, Bruschetta, Mattia, Mion, Enrico, and Carli, Ruggero

Subjects

*POWER resources, *ENERGY management, *INTELLIGENT buildings, *PREDICTION models, *MANAGEMENT controls, *ENERGY storage

Abstract

Efficient management of energy resources is crucial in smart buildings. In this work, model predictive control (MPC) is used to minimize the economic costs of prosumers equipped with production units, energy storage systems, and electric vehicles. To this purpose, the predictive control manages the available energy resources by exploiting future information about energy prices, absorption and production power profiles, and electric vehicle (EV) usage, such as times of departure and arrival and predicted energy consumption. The predictive control is compared with a rule-based technique, herein referred to as a heuristic approach, that acts in an instant-by-instant fashion without considering any future information. The reported results show that the studied predictive approach allows one to achieve charging profiles that adapt to variable operating conditions, aiming at optimal performances in terms of economic cost minimization in time-varying price scenarios, reduction of rms current stresses, and recharging capability of EV batteries. Specifically, unlike the heuristic method, the MPC approach is proven to be capable of efficiently managing the available energy resources to ensure a full recharge of the EV battery during nighttime while always respecting all system constraints. In addition, the proposed control is shown to be capable of keeping the peak power absorption from the grid constrained within set limits, which is a valuable feature in scenarios with widespread adoption of EVs in order to limit the stress on the electrical system. [ABSTRACT FROM AUTHOR]

Published

2021