thermal engineering Thermal engineering is a specialized sub-discipline of mechanical engineering that deals with the movement of heat energy and transfer. The energy can be transferred between two mediums or transformed into other forms of energy. A thermal engin ...

, exergy efficiency (also known as the second-law efficiency or rational efficiency) computes the effectiveness of a system relative to its performance in reversible conditions. It is defined as the ratio of the

thermal efficiency In thermodynamics, the thermal efficiency (\eta_) is a dimensionless performance measure of a device that uses thermal energy, such as an internal combustion engine, steam turbine, steam engine, boiler, furnace, refrigerator, ACs etc. For ...

of an actual system compared to an idealized or reversible version of the system for

heat engine A heat engine is a system that transfers thermal energy to do mechanical or electrical work. While originally conceived in the context of mechanical energy, the concept of the heat engine has been applied to various other kinds of energy, pa ...

s. It can also be described as the ratio of the useful work output of the system to the reversible work output for work-consuming systems. For

refrigerator A refrigerator, commonly shortened to fridge, is a commercial and home appliance consisting of a thermal insulation, thermally insulated compartment and a heat pump (mechanical, electronic or chemical) that transfers heat from its inside to ...

s and

heat pump A heat pump is a device that uses electricity to transfer heat from a colder place to a warmer place. Specifically, the heat pump transfers thermal energy using a heat pump and refrigeration cycle, cooling the cool space and warming the warm s ...

s, it is the ratio of the actual

coefficient of performance The coefficient of performance or COP (sometimes CP or CoP) of a heat pump, refrigerator or air conditioning system is a ratio of useful heating or cooling provided to work (energy) required. Higher COPs equate to higher efficiency, lower energy ( ...

(COP) and reversible COP.

Motivation

The reason the second-law efficiency is needed is because the first-law efficiencies fail to take into account an idealized version of the system for comparison. Using first-law efficiencies alone, can lead one to believe a system is more efficient than it is in reality. So, the second-law efficiencies are needed to gain a more realistic picture of a system's effectiveness. From the

second law of thermodynamics The second law of thermodynamics is a physical law based on Universal (metaphysics), universal empirical observation concerning heat and Energy transformation, energy interconversions. A simple statement of the law is that heat always flows spont ...

it can be demonstrated that no system can ever be 100% efficient.

Definition

The

exergy Exergy, often referred to as "available energy" or "useful work potential", is a fundamental concept in the field of thermodynamics and engineering. It plays a crucial role in understanding and quantifying the quality of energy within a system and ...

''B'' balance of a process gives: with exergy efficiency defined as: For many engineering systems this can be rephrased as: Where

\Delta G^_

is the standard Gibbs (free) energy of reaction at temperature

T

and pressure

p_ = 1 \, \mathrm

(also known as the standard

Gibbs function In thermodynamics, the Gibbs free energy (or Gibbs energy as the recommended name; symbol is a thermodynamic potential that can be used to calculate the maximum amount of work, other than pressure–volume work, that may be performed by a ther ...

change),

\dot_\text

is the net work output and

\dot_\text

is the mass flow rate of fuel. In the same way the energy efficiency can be defined as: Where

\Delta H^_

is the standard enthalpy of reaction at temperature

T

and pressure

p_ = 1 \, \mathrm

Application

The destruction of exergy is closely related to the creation of entropy and as such any system containing highly irreversible processes will have a low energy efficiency. As an example the combustion process inside a power stations gas turbine is highly irreversible and approximately 25% of the exergy input will be destroyed here. For fossil fuels the free enthalpy of reaction is usually only slightly less than the enthalpy of reaction so from equations () and () we can see that the energy efficiency will be correspondingly larger than the energy law efficiency. For example, a typical combined cycle power plant burning methane may have an energy efficiency of 55%, while its exergy efficiency will be 57%. A 100% exergy efficient methane fired power station would correspond to an energy efficiency of 98%. This means that for many of the fuels we use, the maximum efficiency that can be achieved is >90%, however we are restricted to the Carnot efficiency in many situations as a heat engine is being used.

Regarding Carnot heat engine

For any heat engine, the exergy efficiency compares a given cycle to a

Carnot heat engine A Carnot heat engine is a theoretical heat engine that operates on the Carnot cycle. The basic model for this engine was developed by Nicolas Léonard Sadi Carnot in 1824. The Carnot engine model was graphically expanded by Benoît Paul Émile ...

with the cold side temperature in equilibrium with the environment. Note that a Carnot engine is the most efficient heat engine possible, but not the most efficient device for creating work.

Fuel cells A fuel cell is an electrochemical cell that converts the chemical energy of a fuel (often hydrogen) and an oxidizing agent (often oxygen) into electricity through a pair of redox reactions. Fuel cells are different from most batteries in req ...

, for instance, can theoretically reach much higher efficiencies than a Carnot engine; their energy source is not thermal energy and so their exergy efficiency does not compare them to a Carnot engine.

Second law efficiency under maximum power

Neither the first nor the second law of thermodynamics includes a measure of the rate of energy transformation. When a measure of the maximal rate of energy transformation is included in the measure of second law efficiency it is known as second law efficiency under maximum power, and directly related to the maximum power principle (Gilliland 1978, p. 101).

Challenges in Calculation

Applications that seek changes in flow streams, like species concentration, require more careful definitions of control volumes and desired end states. For example, for HVAC systems seeking to cool and dehumidify, it is reasonable to define their second law efficiencies for cooling and dehumidification by calculating exergy changes of all incoming and outgoing air and water streams, while assuming a target supply air temperature and humidity. In contrast, in thermal desalination for instance, the temperature of streams in real systems isn't important, so calculations should include control volumes that allow for outgoing brine and pure water streams to reach thermal equilibrium with their environment.

References

{{Reflist * M.W. Gilliland (1978) ''Energy Analysis: A New Public Policy Tool'', Westview Press. * Yunas A. Cengel, Michael A. Boles (2015) ''Thermodynamics: An Engineering Approach'', McGraw-Hill Education. Non-equilibrium thermodynamics