Carnot-Like Heat Engines Versus Low-Dissipation Models

González-Ayala, Julián; Roco, J. M. M.; Medina, A.; Hernández, A. Calvo

doi:10.3390/e19040182

Cited by 21 publications

(24 citation statements)

References 42 publications

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“…We noted in the above that the bounds on EMEP have also been obtained with other models such as the endoreversible model. The similarities and differences between endoreversible and LD models have been discussed recently [23][24][25][26]. While different such models assume a particular functional form or a mechanism for irreversible entropy generation, we discuss in the following a different formulation that has been recently proposed by one of the authors [43] and show that the same lower and upper bounds as obtained in Eq.…”

Section: Global Linear-irreversible Principlementioning

confidence: 66%

Low-dissipation Carnot-like heat engines at maximum efficient power

Singh

Johal

2018

Phys. Rev. E

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We study the optimal performance of Carnot-like heat engines working in low dissipation regime using the product of the efficiency and the power output, also known as the efficient power, as our objective function. Efficient power function represents the best trade-off between power and efficiency of a heat engine. We find lower and upper bounds on the efficiency in case of extreme asymmetric dissipation when the ratio of dissipation coefficients at the cold and the hot contacts approaches, respectively, zero or infinity. In addition, we obtain the form of efficiency for the case of symmetric dissipation. We also discuss the universal features of efficiency at maximum efficient power and derive the bounds on the efficiency using global linear-irreversible framework introduced recently by one of the authors. * varindersingh@iisermohali.ac.in † rsjohal@iisermohali.ac.in arXiv:1806.10581v1 [cond-mat.stat-mech]

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Section: Global Linear-irreversible Principlementioning

confidence: 66%

Low-dissipation Carnot-like heat engines at maximum efficient power

Singh

Johal

2018

Phys. Rev. E

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“…These two behaviors appear from the constraint of fixed α (being equivalent to the endoreversible hypothesis [70]) and from fixing t (i.e., fixing the irreversibility of the system). From now on, the two cases will be denoted as the endoreversible and irreversible limits, respectively.…”

Section: A Maximum Power and Maximum Regimesmentioning

confidence: 99%

“…Insights on these behaviors from time constraints in the stability and optimization are also discussed for HE's in Ref. [70] and for RE's in Ref. [78].…”

Section: A Maximum Power and Maximum Regimesmentioning

confidence: 99%

“…In previous works the Otto and Brayton cycles have been related with the irreversible Carnot cycle [13], where the linking of both models depends on the heat capacity of the working fluid. Furthermore, the irreversible Carnot model has been linked to the low-dissipation model, where the mapping between these two models is constrained to a certain family of heat capacities [70]. Thus, it is expected that the Otto and Brayton heat engines can be mapped into the low-dissipation model.…”

Section: Concluding Remarks and Perspectivesmentioning

confidence: 99%

“…This model constitutes a suitable way to explore general behaviors not linked with particularities in the heat transfer mechanism, with validity in a broad temperature range and including valuable information about possible symmetries [59][60][61][62][63]. An advantage of this model is the capability to reproduce results from a variety of models in the macroscopic and microscopic regime [15,61,[63][64][65][66][67][68][69][70][71][72].…”

Section: Introductionmentioning

confidence: 99%

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Optimization induced by stability and the role of limited control near a steady state

et al. 2019

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A relationship between stability and self-optimization is found for weakly dissipative heat devices. The effect of limited control on operation variables around an steady state is such that, after instabilities, the paths toward relaxation are given by trajectories stemming from restitution forces which improve the system thermodynamic performance (power output, efficiency, and entropy generation). Statistics over random trajectories for many cycles shows this behavior as well. Two types of dynamics are analyzed, one where an stability basin appears and another one where the system is globally stable. Under both dynamics there is an induced trend in the control variables space due to stability. In the energetic space this behavior translates into a preference for better thermodynamic states, and thus stability could favor self-optimization under limited control. This is analyzed from the multiobjective optimization perspective. As a result, the statistical behavior of the system is strongly influenced by the Pareto front (the set of points with the best compromise between several objective functions) and the stability basin. Additionally, endoreversible and irreversible behaviors appear as very relevant limits: The first one is an upper bound in energetic performance, connected with the Pareto front, and the second one represents an attractor for the stochastic trajectories.

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Optimal analyses and performance bounds of the low-dissipation three-terminal heat transformer: The roles of the parameter constraints and optimization criteria

Cao

Peng

et al. 2023

Energy

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Carnot-Like Heat Engines Versus Low-Dissipation Models

Cited by 21 publications

References 42 publications

Low-dissipation Carnot-like heat engines at maximum efficient power

Low-dissipation Carnot-like heat engines at maximum efficient power

Optimization induced by stability and the role of limited control near a steady state

Optimal analyses and performance bounds of the low-dissipation three-terminal heat transformer: The roles of the parameter constraints and optimization criteria

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