This work presents a day-ahead demand response (DR) scheduling framework that quantifies the flexibility in non-residential buildings by using thermodynamic modeling, and assesses the benefits of DR in terms of three separate optimization variants: net payment minimization, energy self-sufficiency, and peak power reduction. We test the framework in a case study of a medical research facility located in a business park with local solar power generation. The flexible loads are four groups of independently-controlled medical freezers. Our DR framework generates optimal freezer operation and solar power production/curtailment schedules that are compared against a business-as-usual scenario with no DR. We perform simulations for cases with and w...
Peak demands have a disproportionate effect on grid capital, operational cost, and environment as ca...
The addition of storage technologies such as flow batteries, conventional batteries, and heat storag...
Power demand response is considered as one of the most promising solutions in relieving the power im...
This work presents a day-ahead demand response (DR) scheduling framework that quantifies the flexibi...
This work presents a day-ahead demand response (DR) scheduling framework that quantifies the flexibi...
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 ...
This paper presents a demand response (DR) framework that intertwines thermodynamic building models ...
This paper optimizes the thermodynamic behavior of buildings through demand response (DR) by operati...
The penetration rates of intermittent renewable energies such as wind and solar energy have been inc...
In recent deregulated power systems, demand response (DR) has become one of the most cost-effective ...
While the traditional goal of an electric power system has been to control supply to fulfill demand,...
This paper introduces a two-stage two-level optimization method for optimal day-ahead and real-time ...
Peak demands have a disproportionate effect on grid capital, operational cost, and environment as ca...
The addition of storage technologies such as flow batteries, conventional batteries, and heat storag...
Power demand response is considered as one of the most promising solutions in relieving the power im...
This work presents a day-ahead demand response (DR) scheduling framework that quantifies the flexibi...
This work presents a day-ahead demand response (DR) scheduling framework that quantifies the flexibi...
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 ...
This paper presents a demand response (DR) framework that intertwines thermodynamic building models ...
This paper optimizes the thermodynamic behavior of buildings through demand response (DR) by operati...
The penetration rates of intermittent renewable energies such as wind and solar energy have been inc...
In recent deregulated power systems, demand response (DR) has become one of the most cost-effective ...
While the traditional goal of an electric power system has been to control supply to fulfill demand,...
This paper introduces a two-stage two-level optimization method for optimal day-ahead and real-time ...
Peak demands have a disproportionate effect on grid capital, operational cost, and environment as ca...
The addition of storage technologies such as flow batteries, conventional batteries, and heat storag...
Power demand response is considered as one of the most promising solutions in relieving the power im...