The energy performance of energy systems in buildings is commonly studied by applying the First Law of Thermodynamics, which allows to quantify the energy losses and to measure the energy conversion efficiency of the single components. However, different forms of energy have different potential to produce useful work, mainly depending on the temperature at which they are available. For this reason, the Second Law of Thermodynamics should also be considered, leading to the definition of exergy as the maximum amount of work that can be produced, through an ideal reversible process evolving until equilibrium with the environment, by a system or an energy flow available at a certain temperature. Exergy is thus a way to measure the “...
There is an obvious and indisputable need for an increase in the efficiency of energy utilisation in...
Exergy analysis offers the potential of minimizing energy resource depletion, and is useful for assi...
According to the first law of thermodynamics, energy can neither be created nor destroyed; except th...
The energy performance of energy systems in buildings is commonly studied by applying the First Law...
The performance of space heating and cooling systems in buildings is usually measured by applying th...
This doctoral research studied the added value of exergy for the assessment and development of energ...
Though mandatory to be pursued, improved energy efficiency is not the only target to reach. The qual...
Exergy is naturally related to the concept of quality of energy. Therefore, exergy analysis has been...
The law of conservation of energy, stating that energy cannot be created nor destroyed, is inadequat...
The quality of a certain amount of energy is defined as the relative exergy content of this energy. ...
Current analysis and optimization methods of energy use in buildings are based on the assessment of ...
Energy performance of buildings generally assesses the energy consumption of buildings such as heati...
Growing concerns on environmental problems related to current energy use have emphasized the importa...
There is an obvious and indisputable need for an increase in the efficiency of energy utilisation in...
Chapter I describes the characteristics of a thermodynamic concept, exergy, in association with buil...
There is an obvious and indisputable need for an increase in the efficiency of energy utilisation in...
Exergy analysis offers the potential of minimizing energy resource depletion, and is useful for assi...
According to the first law of thermodynamics, energy can neither be created nor destroyed; except th...
The energy performance of energy systems in buildings is commonly studied by applying the First Law...
The performance of space heating and cooling systems in buildings is usually measured by applying th...
This doctoral research studied the added value of exergy for the assessment and development of energ...
Though mandatory to be pursued, improved energy efficiency is not the only target to reach. The qual...
Exergy is naturally related to the concept of quality of energy. Therefore, exergy analysis has been...
The law of conservation of energy, stating that energy cannot be created nor destroyed, is inadequat...
The quality of a certain amount of energy is defined as the relative exergy content of this energy. ...
Current analysis and optimization methods of energy use in buildings are based on the assessment of ...
Energy performance of buildings generally assesses the energy consumption of buildings such as heati...
Growing concerns on environmental problems related to current energy use have emphasized the importa...
There is an obvious and indisputable need for an increase in the efficiency of energy utilisation in...
Chapter I describes the characteristics of a thermodynamic concept, exergy, in association with buil...
There is an obvious and indisputable need for an increase in the efficiency of energy utilisation in...
Exergy analysis offers the potential of minimizing energy resource depletion, and is useful for assi...
According to the first law of thermodynamics, energy can neither be created nor destroyed; except th...