This paper optimizes the thermodynamic behavior of buildings through demand response (DR) by operating their mechanical heating/cooling systems at 50% or 100% output capacity on a 15-minute basis. The optimization's objective is either minimizing cost or net electricity consumption, considering hourly prices and renewable energy resource availability in the local microgrid. The proposed DR framework combines thermodynamic models with an automated, genetic-algorithm based optimization, resulting in demonstrable benefits in terms of cost and energy efficiency for the end-users. The optimal DR schedule with multiple heating/cooling output capacity is compared against an unoptimized, business-as-usual scenario and against a DR schedule which al...
Although multiple trials have been conducted demonstrating that demand side flexibility works and ev...
Summarization: Demand Response (DR) is a fundamental aspect of the smart grid concept, as it refers ...
© 2019 IEEE. Combined heat and power (CHP) is a typical community owned distributed generation solut...
This paper optimizes the thermodynamic behavior of buildings through demand response (DR) by operati...
This paper presents a demand response (DR) framework that intertwines thermodynamic building models ...
This paper presents a demand response (DR) framework that utilizes the flexibility inherent to the t...
This paper presents a demand response (DR) framework that intertwines thermodynamic building models ...
European Union households account for 26% of the final energy consumption, yet their participation i...
This book represents the Special Issue of Energies, entitled “Demand-Response in Smart Buildings”, t...
Summarization: Demand response offers the possibility of altering the profile of power consumption o...
In this paper, an intelligent multi-objective energy management system (MOEMS) is proposed for appli...
In this article, a new business model comprising multiple stakeholders is proposed to develop a fram...
Recent communication, computation, and technology advances coupled with climate change concerns have...
In this article, a new business model comprising multiple stakeholders is proposed to develop a fram...
Although multiple trials have been conducted demonstrating that demand side flexibility works and ev...
Summarization: Demand Response (DR) is a fundamental aspect of the smart grid concept, as it refers ...
© 2019 IEEE. Combined heat and power (CHP) is a typical community owned distributed generation solut...
This paper optimizes the thermodynamic behavior of buildings through demand response (DR) by operati...
This paper presents a demand response (DR) framework that intertwines thermodynamic building models ...
This paper presents a demand response (DR) framework that utilizes the flexibility inherent to the t...
This paper presents a demand response (DR) framework that intertwines thermodynamic building models ...
European Union households account for 26% of the final energy consumption, yet their participation i...
This book represents the Special Issue of Energies, entitled “Demand-Response in Smart Buildings”, t...
Summarization: Demand response offers the possibility of altering the profile of power consumption o...
In this paper, an intelligent multi-objective energy management system (MOEMS) is proposed for appli...
In this article, a new business model comprising multiple stakeholders is proposed to develop a fram...
Recent communication, computation, and technology advances coupled with climate change concerns have...
In this article, a new business model comprising multiple stakeholders is proposed to develop a fram...
Although multiple trials have been conducted demonstrating that demand side flexibility works and ev...
Summarization: Demand Response (DR) is a fundamental aspect of the smart grid concept, as it refers ...
© 2019 IEEE. Combined heat and power (CHP) is a typical community owned distributed generation solut...