Discrete cogeneration optimization with storage capacity decision support for dynamic hybrid solar combined heat and power systems in isolated rural villages

“…Usually, they are used as a backup energy supply to overcome outage power events or as control sources to regulate frequency and voltage deviations. Common [13], microturbines [14], combustion turbines, biomass generators, and distributed generators.…”

“…Figure 7 shows a general example of such strategies involving three energy supplies: RER as a primary supply, ESS as a second supply, and the utility grid as the backup supply.More complicated strategies can be integrated in the optimal sizing for performing EM. For instance, the authors in [13,26,34] performed a combined sizing and energy scheduling strategy. For a more detailed overview about the optimal sizing/design strategies for μ grids, see [53].…”

“…e resolution of a linear programming system returns the sets of vector x specifying the maximum/minimum value of the objective function. Many papers used linear programming to solve the energy usage optimization problem [13,30,40,42].…”

“…Other costs were introduced in the papers such as the cost of generated energy [15,23,28,38,41], the cost of degradation of ESS [38], the cost of purchased energy from the grid [2,14,15,19,23,28,33,37,38,41], the start-up/ shut-down cost of DER [14,38,41], cost of fuel [13,14,43], and the comfort cost. e comfort cost is the cost related to the nonsupplied energy [9] or to the action of shifting/shedding appliances [38,43].…”

Energy Management Strategies for Smart Green MicroGrid Systems:  A Systematic Literature Review

“…Usually, they are used as a backup energy supply to overcome outage power events or as control sources to regulate frequency and voltage deviations. Common [13], microturbines [14], combustion turbines, biomass generators, and distributed generators.…”

“…Figure 7 shows a general example of such strategies involving three energy supplies: RER as a primary supply, ESS as a second supply, and the utility grid as the backup supply.More complicated strategies can be integrated in the optimal sizing for performing EM. For instance, the authors in [13,26,34] performed a combined sizing and energy scheduling strategy. For a more detailed overview about the optimal sizing/design strategies for μ grids, see [53].…”

“…e resolution of a linear programming system returns the sets of vector x specifying the maximum/minimum value of the objective function. Many papers used linear programming to solve the energy usage optimization problem [13,30,40,42].…”

“…Other costs were introduced in the papers such as the cost of generated energy [15,23,28,38,41], the cost of degradation of ESS [38], the cost of purchased energy from the grid [2,14,15,19,23,28,33,37,38,41], the start-up/ shut-down cost of DER [14,38,41], cost of fuel [13,14,43], and the comfort cost. e comfort cost is the cost related to the nonsupplied energy [9] or to the action of shifting/shedding appliances [38,43].…”

Energy Management Strategies for Smart Green MicroGrid Systems:  A Systematic Literature Review

“…DERs perform twin functions: (1) adaptation and (2) mitigation of climate impacts. For example, combined cooling heat and power (CCHP) and cogeneration systems are a form of an integrated DER energy system, which delivers both heat and electricity, as well as improve system efficiency (Prinsloo et al 2016;Eid et al 2016). Such DER technologies can be paired with information communication technologies (ICTs) in cities to enable communication and control of the DER resource of interest.…”

Smart Energy Frameworks for Smart Cities: The Need for Polycentrism

Smart Energy Frameworks for Smart Cities: The Need for Polycentrism