Exergy Flows Inside Expansion and Compression Devices Operating below and across Ambient Temperature Exergy Flows Inside Expansion and Compression Devices Operating below and across Ambient Temperature

The various definitions of the coefficient of exergy efficiency (CEE), which have been pro- posed in the past for the thermodynamic evaluation of compression and expansion devices, operating below and across ambient temperature as well as under vacuum conditions, are examined. The shortcomings of those coefficients are illustrated. An expression for the CEE based on the concept of transiting exergy is presented. This concept permits the quantitative and non-ambiguous definition of two thermodynamic metrics: exergy produced and exergy consumed. The development of these CEEs in the cases of an expansion valve, a cryo- expander, a vortex tube, an adiabatic compressor and a monophasic ejector operating below or across ambient temperature is presented. Computation methods for the transiting exergy are outlined. The analysis based on the above metrics, combined with the traditional analysis of exergy losses, allows pinpointing the most important factors affecting the thermody- namic performance of sub-ambient compression and expansion.


Introduction
Cooling is part of twenty-first century life. Air conditioning, food conservation, industries such as steel, chemicals, and plastics depend on cooling. By mid-century people will use more energy for cooling than heating [1]. Almost all cold is produced by vapor-compression refrigeration and requires large amounts of electricity for its production. And since electricity is still overwhelmingly produced by burning fossil fuels, the rise in cold production will inevitably increase both fuels consumption and power plant emissions. A climate-change irony is that cooling makes the planet hotter. Besides the development of new cooling devices using renewable energy, an important way to reduce refrigeration power consumption is through the energy efficiency improvement of vapor-compression cycles and their associated elementary processes. The processes of compression and expansion play a central role in air-conditioning, refrigeration and cryogenics. An important question still remains: How to define the efficiency of these processes by taking into account the constraints of the first and second laws of thermodynamics? The answer will be discussed in this paper.
The introduction of exergy, the thermodynamic function that takes into account the quality as well as the quantity of energy, has paved the way for a unified approach to the concept of efficiency, a subject pioneered by Grassmann [2]. Serious difficulties concerning the practical application of this concept to sub-ambient systems, however, retarded the acceptance of exergy analysis by the air-conditioning and refrigeration engineering profession. One can mention, in particular, the difficulty of formulating a coefficient of exergy efficiency (CEE) for elementary processes such as compression and expansion. The coefficient should evaluate the exergy losses, quantify the extent to which the technical purpose of an elementary process is achieved, as well as quantify the exergy consumption within the process. Finally, a uniquely determined value (not several) should be assigned to the coefficient. This paper examines some important points pertinent to these issues and presents a definition of the CEE for the thermodynamic evaluation of expansion and compression devices operating below and across ambient conditions. The definition is based on the concept of transiting exergy, introduced by Brodyansky et al. [3], that allows non-ambiguous computation of two metrics: exergy produced and exergy consumed.

Basic concepts of exergy analysis of sub-ambient systems
The maximum amount of work obtained from a given form of energy or a material stream, using the environment as the reference state, is called exergy [4,5]. Three different types of exergy are important for thermodynamic analysis of the sub-ambient processes: exergy of heat flow, exergy of work (equivalent to work) and thermo-mechanical exergy, also known as physical exergy by some authors [4,6]. Chemical exergy [7], important for some refrigeration systems based on the mixing of streams of different composition, is not considered in the present paper.

Exergy of heat flow at the sub-ambient conditions
The exergy of heat flow _ Q [4] is defined as: where Θ = 1 À T 0 /T is the Carnot factor determined by the temperature T of heat flow, and the ambient temperature T 0 . Contrary to conditions above ambient, Θ is negative for sub-ambient temperatures. However, according to Eq. (1), _ E Q is positive due to the fact that heat is removed from a cooled object, and thus _ Q has a negative sign in Eq. (1). The energy and exergy balances of a reversible refrigerator (RR) are presented in Figure 1. One can notice that the directions of energy and exergy flows are opposite below T 0 . This means that the exergy of a heat flow at T < T 0 is looked upon as a product of the refrigeration system rather than as feed. The exergy transfer of a RR characterizes the rate of transformation of power _ W to exergy of heat flow _ Q (exergy of produced cold). Given that the system presented in Figure 1 is reversible, the minimum power _ W min necessary to maintain a cooling rate _ Q equals _ E Q . Obviously it is not the case for a real (non-reversible) refrigerator, where _ E Q is lower than _ W by the value of exergy losses _ D.

Thermo-mechanical exergy
The thermo-mechanical exergy equals the maximum amount of work obtainable when the stream of substance is brought from its initial state to the environmental state, defined by pressure P 0 and temperature T 0 , by physical processes involving only thermal interaction with the environment [3,4]. The specific thermo-mechanical exergy e P,T is calculated according to: The value of e P,T may be divided by two components: thermal exergy e T due to the temperature difference between T and T 0 , and mechanical exergy e P due to the pressure difference between P and P 0 . It is important to emphasize that this division is not unique, because e T depends on pressure conditions and e P in its turn depends on temperature conditions. As a result, the division has no fundamental meaning and leads, as will be illustrated further, to ambiguities for the exergy efficiency definition. By conventional agreement [4], e T and e P are defined as: The contribution of e T and e P to the value of e P,T can be clearly visualized on the exergyenthalpy diagram presented in Figure 2. For instance, the thermal exergy for point 1 is illustrated as the segment (e T ) 1 defined by the intersections of two isotherms T 1 and T 0 with the isobar P 1 . The mechanical exergy for point 1 is illustrated as the segment (e P ) 1 defined by the intersections of two isobars P 1 and P 0 with the isotherm T 0 . Whatever the temperature conditions are (T < T 0 or T > T 0 ), the thermal exergy is always positive [3], as clearly presented on the e-h diagram. In this sense the e T behavior is similar to that of the exergy of heat flow, that is always positive, as has been discussed. Meanwhile, e P is only positive for conditions P > P 0 (see for example point 1), but it is negative for P < P 0 , as illustrated by point 2 in Figure 2.

Exergy efficiency of processes operating below and across the ambient temperature
The exergy balance around any process under steady state conditions and without external irreversibilities (the case considered in this paper) may be written as [4]: Here _ E in and _ E out are the inlet and outlet exergy flows; _ D int is the rate of internal exergy losses. There is abundant scientific literature [3][4][5][6][7][8][9] on the subject of the exergy performance criteria definition based on Eq. (5). However, there are only a few definitions of this criteria applied to the processes of expansion and compression operating below and across ambient temperature. Among them, three exergy efficiency definitions may be distinguished: input-output efficiency, products-fuel efficiency, and efficiency that accounts for the transiting exergy.
The input-output efficiency η in-out , first proposed by Grassmann [2], is computed according to Eq. (6): The shortcomings of this definition, particularly for its application to sub-ambient problems, are well documented [3][4][5][6][7][8][9]. The main one is the fact that often η in-out does not evaluate the degree to which the technical purpose of a process is realized; the subject will be illustrated in Section 3. The products-fuel efficiency η pr-f proposed by Tsatsaronis [10] and Bejan et al. [6] in the context of expansion and compression processes is computed as: Under the terms "products" and "fuel" the authors meant either the differences in exergies of the streams at the inlet and outlet of a process, or the exergies of streams themselves. For example, while evaluating the efficiency of an adiabatic compression operating above ambient conditions, the "fuel" is the supplied work, and the "product" is the increment of thermomechanical exergy. The problem with this approach is that it is possible to obtain different values of η pr-f of the sub-ambient expansion and compression processes due to the fact that different things can be understood under the notions "products" and "fuel". It should be also mentioned that some authors used a different terminology to express the numerator and denominator of Eq. (7). For example, Kotas [4] used "desired output" vs. "necessary input"; Szargut et al. [5] used "exergy of useful products" vs. "feeding exergy".

Transiting thermo-mechanical exergy and its link to the thermal and mechanical components
Following the equations proposed by Brodyansky et al. [3], the specific transiting thermomechanical exergy e tr of an analyzed system is defined as the minimum exergy value that can be assigned to a material stream, considering the pressure P and temperature T at the inlet and outlet, as well as the ambient temperature T 0 . With this definition, there are three possible combinations of P in , T in , P out , T out and T 0 that determine the value of e tr : Inspection of these equations shows that for all three cases e tr is determined by using the lowest pressure P min among the inlet and outlet values. The situation is different for temperature, where the minimum exergy value is determined using the lowest temperature T min for processes above ambient, the highest temperature T max for sub-ambient processes, and by using T 0 for the case of processes operating across ambient temperature. In order to understand the physical meaning of the transiting exergy, let us analyze the throttling process of a real gas taking place under these three different temperature conditions.

Adiabatic throttling process
The case of the throttling process operating above T 0 is presented on an e-h diagram (see Figure 3a). According to Eq. (9a), the value of e tr is: This value coincides with the value e 2 as illustrated in Figure 3a. The specific exergy losses (d) are also presented on the diagram. Following Eq. (8), the values Δ _ E and ∇ _ E are: where _ m is the gas mass flow rate.
As a result, the efficiency η tr = 0, meaning that the exergy consumed is completely lost during the process and there is no produced exergy. It should be mentioned that the input-output efficiency calculated according to Eq. (6) has a negative value in this particular case and has no physical meaning. This is due to the fact that _ E out < 0, because the throttling ended at the vacuum conditions. For this particular case the products-fuel efficiency according to Eq. (7) gives the same value as η tr . Now, let us analyze the case of throttling at sub-ambient conditions presented in Figure 3b. According to Eq. (9b): Thus Δ _ E and ∇ _ E are calculated as: The term (Δe T ) Pout in Eq. (14) is the increase of the specific thermal exergy due to an isobaric temperature drop under sub-ambient conditions at constant pressure P out . The term (∇e P ) Tin in Eq. (15) is the decrease of the specific mechanical exergy due to an isothermal pressure drop at constant temperature T in . Finally, the case presented in Figure 3c illustrates a throttling process started above ambient and ended at sub-ambient conditions. According to Eq. (9c): The values Δ _ E and ∇ _ E are calculated as: Again, the input-output efficiency is not suitable for the evaluation of the processes presented in Figure 3b and c, given that the outlet exergy e 2 = e(P out , T out ) is negative. Another difficulty is linked to the application of the products-fuel efficiency for these cases. The exergy transfer of the throttling process at sub-ambient conditions consists in the partial transformation of mechanical exergy ("fuel") into thermal exergy ("product"). The problem stems from the fact that there are multiple possibilities to define "fuel" and "product" in this case; as a result multiple values of η pr-f may be formulated, leading to the ambiguity in the products-fuel efficiency application. Indeed, the different increments of thermal exergy may be considered as a "product" for the case in Figure 3b, for example, the increase in thermal exergy following the isobar P 1 or the isobar P 2 . In the same way, different decrements of mechanical exergy may be considered as a "fuel" in the same figure, for example, the decrease of mechanical exergy following the isotherms T 1 or T 2 .
Contrary to "products-fuel", the transiting exergy approach does not attempt to individually compute the thermal and mechanical exergy component variations. It relies, rather, on the unaffected part of the thermo-mechanical exergy entering and leaving the system. Figure 3a and c, the transiting exergy may be considered as the introduction of a new reference state to evaluate exergy consumed and produced. Instead of the reference point e = 0 (the intersection of the isobar P 0 and the isotherm T 0 ), the new reference point is presented by e tr : the intersection of the isobar P 2 and the isotherm T 2 for the case 3a; of the isobar P 2 and the isotherm T 1 for the case 3b; and of the isobar P 2 and the isotherm T 0 for the case 3c. Finally, the transiting exergy approach provides the foundation for the non-ambiguous definition of the terms Δ _ E and ∇ _ E, and thus of η tr .

Example 1
The initial parameters of air at the inlet of a throttling valve are: _ m = 1 kg/s, P 1 = 3 MPa, T 1 = 140 K. The ambient temperature T 0 = 283 K. Calculate the variation of _ E tr , Δ _ E and ∇ _ E and η tr as a function of the outlet pressure P 2 in the range 0.1-1 MPa.

Solution
The outlet temperature of the air is calculated by using the software Engineering Equation Solver (EES) [11]. Given that the expansion of air takes place at sub-ambient conditions, Eqs. (13)-(15) are used to evaluate _ E tr , Δ _ E and ∇ _ E. The results are presented in Table 1. One observation is obvious, that the rise in exergy losses as well as the decrease in η tr go along with the decreasing outlet pressure P 2 . Less obvious is that the exergy produced Δ _ E rises with decreasing P 2 , reflecting the production of a more important cooling effect. It can also be noticed that the transiting exergy _ E tr decreases with decreasing outlet pressure P 2 .

Example 2
The expansion valve of a refrigeration mechanical vapor compression cycle is supplied with the subcooled working fluid R152a at the rate _ m = 0.15 kg/s at P 1 = 615.1 kPa. The fluid is expanded to a pressure of P 2 = 142.9 kPa. The ambient temperature T 0 = 278 K. Calculate the variation of _ E tr , Δ _ E and ∇ _ E and η tr as a function of the subcooling ΔT subC in the range 275-281 K.

Solution
A vapor compression cycle is presented on a Ts-diagram in Figure 4. The subcooling process is represented by the line 3f-3. Given that the expansion of R152a takes place across ambient temperature, Eqs. (16)-(18) are used to evaluate _ E tr , Δ _ E and ∇ _ E. The results are shown in Table 2.
The transiting exergy does not change with the subcooling, because it is the function of constant parameters T 0 and P 2 , meanwhile the exergy produced increases and exergy consumed decreases. The new result is that η tr is rising with the subcooling. It should be mentioned that increasing the amount of subcooling is well documented as a way to increase the COP (coefficient of performance) of vapor compression cycles [4]. Thus, the rise in η tr of an expansion device guarantees the COP improvement of the overall cycle, a conclusion that may lead to practical recommendations for optimization of refrigeration cycles.

Expansion in low temperature systems with work production and heat transfer
The primary purpose of expansion processes in the sub-ambient region is the production of cooling effect. The power that may be produced can be considered as a useful by-product. This type of expansion takes place in cryo-expanders. There are two types of these devices: adiabatic and non-adiabatic gas expansion machines. The energy and exergy balances around a non-adiabatic expander are presented in Figure 5. It should be emphasized that the directions of heat flow _ Q and exergy _ E Q are opposite. This is due to the fact that heat transfer from a cooled object to the expanding fluid occurs at T < T 0 . As a result _ E Q calculated according to Eq. (1) is presented as the outlet flow in Figure 5b.   Table 2. Variation in exergy metrics with subcooling for the expansion process of R152a. The process of gas expansion in a non-adiabatic cryo-expander is presented on an e-h diagram (see Figure 6). Similar to the case of adiabatic throttling (Figure 3b), the transiting exergy in the gas flow is defined according to Eq. (9b). As a result, the exergy efficiency is calculated as: In the case of an adiabatic cryo-expander η tr is calculated according to Eq. (19), but with the term _ Q:Θ in equals to zero.

Example 3
An adiabatic turbine (η T = 0.80) is supplied with air at the rate _ m = 1 kg/s at P 1 = 6 MPa, T 1 = 320 K. The ambient temperature T 0 = 283 K. Calculate the variation of _ E tr , Δ _ E and ∇ _ E and η tr as a function of the outlet pressure P 2 in the range 0.1-3 MPa.

Solution
Given that the expansion of air takes place across ambient temperature, Eqs. (16) Table 3. It is illustrated that _ E tr decreases with P 2 reduction, and as a result Δ _ E and ∇ _ E and _ W rise, but the increase in Δ _ E and _ W is offset by the greater increase in ∇ _ E causing η tr to decrease. The negative value of _ E tr in the second last row to the right in Table 3, is because the stream at state 2 is under vacuum conditions. It should be emphasized that the increase in the Δ _ E metric reflects the deeper refrigeration of air with increasing pressure drop in the turbine. Figure 7a illustrates a counter flow vortex tube [12]. High pressure gas enters the tube through a tangential nozzle (point 1). Colder low-pressure gas leaves via an orifice near the centerline adjacent to the plane of the nozzle (point 2), and warmer low-pressure gas leaves near the periphery at the end of the tube opposite to the nozzle (point 3). The vortex tube requires no work or heat interaction with the surroundings to operate. The cold mass fraction is μ; the hot gas mass fraction is (1 À μ). The exergy balance around the vortex tube is:

Expansion in a vortex tube
The expansion processes taking place within a vortex tube are presented on an e-h diagram (Figure 7b). The cold stream expands across T 0 , the hot expands at T > T 0 . By applying Eqs. (9a) and (9c) the transiting exergies may be determined for each mass stream, cold (1-2) and hot (1-3).
As a result, the exergy produced and consumed within the cold and hot streams are:  Table 3. Variation in exergy metrics with the outlet pressure for a turbine expansion process.

Energy Systems and Environment
Thus Δ _ E C and Δ _ E H represent the increase in the thermal exergy component due to the cooling of the cold stream and the heating for the hot stream, under conditions of the outlet pressures for each stream. ∇ _ E C represents the decrease in thermo-mechanical exergy of the cold stream due to the partial thermal exergy destruction because of the temperature drop from T 1 to T 0 , and the decrease of mechanical exergy because of pressure drop from P 1 to P 3 . ∇ _ E H is the decrease of mechanical exergy of the hot stream at conditions of constant inlet temperature.
gives the value of η tr .

Example 4
An adiabatic vortex tube is supplied with air as ideal gas at the rate _ m = 1 kg/s and at P 1 = 0.8 MPa, T 1 = 308 K. The air expands at the cold end to pressure P 2 = 0.1 MPa and at the hot end to the pressure P 3 = 0.15 MPa. The ambient temperature T 0 = 298 K. Calculate the variation of _ E tr , Δ _ E and ∇ _ E and η tr as a function of the cold mass fraction μ in the range 0.2-0.9.

Solution
The results are shown in Table 4. It is illustrated that _ E tr, H decreases with the cold mass fraction increase. The _ E tr, C is zero, because it is defined by ambient conditions P 2 = P 0 and T 2 = T 0 . As a result, for the cold stream Δ _ E C decreases but ∇ _ E C increases strongly with μ. An opposite effect is observed for the hot stream, where Δ _ E H increases and ∇ _ E H decreases. As a result, η tr increases, despite the rise in the exergy losses with the increasing cold mass fraction. This can be explained by the fact that the rise in exergy produced in the hot stream surpasses the increase in exergy losses. The exergy efficiency of the vortex tube is relatively low.

Compression across ambient temperature
In most refrigeration plants and heat pumps compression starts at T < T 0 and ends at T > T 0 . The process is presented on an e-h diagram (see Figure 8). According to Eq. (9c), transiting exergy is: The produced and consumed exergies are: Δ _ E represents the increase of thermo-mechanical exergy due to the rise in pressure from P to P 2 and the rise in temperature from T 0 to T 2 . ∇ _ E represents the destruction of thermal exergy due to the rise in temperature from T 1 to T 0 under conditions of constant pressure P 1 , plus the consumed power _ W C . The ratio Δ _ E/(∇ _ E þ _ W C Þ gives the value of exergy efficiency η tr .

Example 5
An adiabatic compressor of a refrigeration plant is supplied with the working fluid R152a at the rate _ m = 1 kg/s at P 1 = 142.9 kPa and T 1 = 263 K (superheated). The fluid is compressed to a pressure of P 2 = 615.1 kPa. The ambient temperature T 0 = 298 K. Calculate the variation of _ E tr , Δ _ E and ∇ _ E and η tr as a function of the isentropic efficiency η C in the range 0.75-0.90.  Table 4. Variation in exergy metrics with the cold mass fraction for a vortex tube expansion process.

Solution
The results are shown in Table 5. The transiting exergy does not change with the isentropic efficiency η C , because is a function of constant parameters T 0 and P 1 . The exergy consumed does not change either. The produced exergy decreases. This drop in Δ _ E is explained by the reduction in "compression reheat". The decrease in Δ _ E is offset by the greater decrease in _ W C , and as a result η tr increases.

Compression and expansion in a one phase ejector
A combination of the processes of vapor expansion and compression takes place within a onephase ejector presented in Figure 9a. A primary (pr) stream at high pressure P 1 and temperature Figure 8. Compression process across ambient temperature (T 0 ) on an exergy-enthalpy diagram. T 1 expands and entrains a secondary stream (s) at low pressure P 2 and temperature T 2 < T 0 . The ratio _ m s / _ m pr gives the value of the entrainment ratio (ω) of the ejector. The mixed stream with the parameters P 2 < P 3 < P 1 and T 2 < T 3 < T 1 leaves the ejector. The exergy balance around the ejector is: The processes of expansion of the primary stream and compression of the secondary stream are presented on an e-h diagram (Figure 9b). The secondary stream is compressed across T 0 , meaning that Eq. (9c) is applied to calculate (e tr ) s . As a result, the transiting exergy for secondary and primary streams are: This means that the exergies produced and consumed may be computed as: Δ _ E s is the increase of thermo-mechanical exergy of the secondary stream due to the compression from P 2 to P 3 and the rise in temperature from T 0 to T 3 . The exergy consumed ∇ _ E s within the secondary stream represents the decrease of thermal exergy component because of the temperature rise from T 2 to T 0 (the partial cold destruction). The exergy consumed within the primary stream ∇ _ E pr is the decrease of thermo-mechanical exergy The ratio Δ _ E s /(∇ _ E s + ∇ _ E pr ) gives the value of exergy efficiency η tr . The detailed analysis of efficiencies for different parts of an ejector is given in [13].

Example 6
An ejector of a refrigeration plant is supplied with the working fluid R141b. The parameters of the secondary stream are: P 2 = 22.3 kPa, T 2 = 268 K. The pressure of the mixed stream is P 3 = 91 kPa. The ambient temperature T 0 = 289 K. Calculate the variation of ( _ E tr Þ pr , ( _ E tr Þ s , Δ _ E and ∇ _ E and η tr as a function of the entrainment ratio ω = _ m s / _ m pr in the range 0.15-0.25.

Solution
The calculation results are shown in Table 6. The transiting exergy in the secondary flow is negative because the parameters P 2 and T 0 define the state of the flow under vacuum conditions. The exergy produced and exergy consumed increase with the entrainment factor. The increase in Δ _ E s offsets the increase in (∇ _ E s + ∇ _ E pr ), and as a result η tr increases.

Environmental life cycle analysis and exergy efficiency of cooling systems
Life Cycle Analysis (LCA) is an important tool to analyze environmental problems associated with the production, use, and disposal of products or systems [14]. For every product produced within a system the total inflow and outflow of energy and materials are evaluated. The  Table 6. Variation in exergy metrics with the entrainment factor for compression-expansion processes in an ejector. environmental burdens are associated by quantifying the energy and materials used, as well as the wastes released into the environment. The impact of these uses and releases on the environment is assessed. The multidimensional approach of LCA causes some problems when different substances need to be compared and general agreement is required. This problem may be avoided if exergy is used as a common quantity as proposed by Life Cycle Exergy Analysis [15]. The crucial idea behind this method is the distinction between renewable and non-renewable resources. In order to illustrate the method, let us consider three defined time periods within the life cycle of an ejector refrigeration system driven by solar energy [16]. At first, exergy is required during the construction stage to build the plant and put it into operation. During this period the spent exergy is stored in materials, such as metals, glass etc. For the second period, maintenance required for the system's operation takes place. Exergy necessary for this maintenance is evaluated. The third period is the clean-up stage, including the plant demolition and the recycling of materials. Exergy used for the clean-up is assessed. The exergy used for the construction, maintenance, and clean-up is assumed to originate from non-renewable resources and is named indirect exergy, _ E ind . When the ejector refrigeration system driven by solar energy is put into operation, it starts to deliver a product (cold in this case) with exergy, _ E pr . By considering renewable resources (solar in this case) as free, there will be a net exergy output from the plant until the plant is decommissioned. By considering the total life cycle of the plant the net produced exergy becomes _ E net = _ E pr À _ E ind . The higher this value is for the three time periods defined above, the more sustainable the system is, because the input of non-renewable resources will be paid back during the system's lifetime. The rise in exergy efficiency of an ejector calculated according to Eqs. (31) and (32) leads to an increase in efficiency of the solar driven refrigeration system [16].
This in turn means that the net produced exergy _ E net increases too. Thus, the evaluation of η tr of an ejector, as presented in Section 3.5, and its subsequent maximization, may lead to the construction and operation of more sustainable solar driven refrigeration plants.

Conclusion
The common feature of expansion processes operating below or across ambient temperature is the partial transformation of the mechanical exergy component into the thermal exergy component. Sub-ambient compression processes are characterized by the transformation of work into the mechanical exergy component and the partial destruction of the thermal exergy component below T 0 . In order to evaluate the efficiency of these transformations the calculations of the variation in mechanical and thermal exergy components are required. These calculations may be done in many different ways, for example the variation in e P depends on the chosen temperature conditions, while the variation in e T depends on the chosen pressure conditions. This multiplicity in the exergy variation evaluation leads to ambiguity in the exergy efficiency definition. The approach based on the exclusion of the "transiting flow" from thermo-mechanical inlet and outlet exergies of an analyzed process overcomes this difficulty. This improvement is possible because the transiting exergy is uniquely defined by a specific combination of the process intensive parameters, namely the inlet and outlet pressures and temperatures, as well as T 0 . The transiting exergy approach allows non-ambiguous evaluation of two thermodynamic metrics: exergy produced and exergy consumed. Their ratio represents the exergy efficiency; the difference between exergy consumed and exergy produced equals the exergy losses within the process. The phenomenological significance of the transiting exergy and the way in which it can be computed for processes below and across T 0 has been illustrated for the cases of an expansion valve, a cryo-expander, a vortex tube, an adiabatic compressor, and a monophasic ejector. The input-output exergy efficiency is not an appropriate criterion for evaluation of these processes.