Carnot cycle and heat engine fundamentals and applications /
Carnot cycle and heat engine fundamentals and applications /
edited by Michel Feidt
- Switzerland : MDPI - Multidisciplinary Digital Publishing Institute, c2020
- vii, 129 pages ; 25 cm.
Includes bibliographical references.
Michel Feidt: The Carnot Cycle and Heat Engine Fundamentals and Applications II -- Michel Feidt and Monica Costea: A New Step in the Optimization of the Chambadal Model of the Carnot Engine -- Shuangshuang Shi, Lingen Chen, Yanlin Ge and Huijun Feng Performance Optimizations with Single-, Bi-, Tri-, and Quadru-Objective for Irreversible Diesel Cycle -- Monica Costea, Stoian Petrescu, Michel Feidt, Catalina Dobre and Bogdan Borcila Optimization Modeling of Irreversible Carnot Engine from the Perspective of Combining Finite Speed and Finite Time Analysis -- Ruibo Wang, Yanlin Ge, Lingen Chen, Huijun Feng and Zhixiang Wu Power and Thermal Efficiency Optimization of an Irreversible Steady-Flow Lenoir Cycle -- Chenqi Tang, Lingen Chen, Huijun Feng and Yanlin Ge: Four-Objective Optimizations for an Improved Irreversible Closed Modified Simple Brayton Cycle -- C╦ÿat╦ÿalina Dobre, Lavinia Grosu, Alexandru Dobrovicescu, Georgiana Chi┬╕siu and Mihaela Constantin Stirling Refrigerating Machine Modeling Using Schmidt and Finite Physical Dimensions Thermodynamic Models: A Comparison with Experiments -- Lingen Chen, Huijun Feng and Yanlin Ge: Power and Efficiency Optimization for Open Combined Regenerative Brayton and Inverse Brayton Cycles with Regeneration before the Inverse Cycle -- Pierfrancesco Palazzo Chemical and Mechanical Aspect of Entropy-Exergy Relationship -- Jin-Fu Chen, Ying Li and Hui Dong: Simulating Finite-Time Isothermal Processes with Superconducting Quantum Circuits.
The paper that discusses the Lenoir cycle is from a more conventional point of view. It deals with the steady flow (such as Chambadal's original modeling). Objectives are power and first law efficiency. The corresponding allocation of heat transfer conductance is proposed, due to finite size constraints (i.e., the Utotal imposed).
9783039288458
THERMODYNAMIC
QC 311 .C37 2020
Includes bibliographical references.
Michel Feidt: The Carnot Cycle and Heat Engine Fundamentals and Applications II -- Michel Feidt and Monica Costea: A New Step in the Optimization of the Chambadal Model of the Carnot Engine -- Shuangshuang Shi, Lingen Chen, Yanlin Ge and Huijun Feng Performance Optimizations with Single-, Bi-, Tri-, and Quadru-Objective for Irreversible Diesel Cycle -- Monica Costea, Stoian Petrescu, Michel Feidt, Catalina Dobre and Bogdan Borcila Optimization Modeling of Irreversible Carnot Engine from the Perspective of Combining Finite Speed and Finite Time Analysis -- Ruibo Wang, Yanlin Ge, Lingen Chen, Huijun Feng and Zhixiang Wu Power and Thermal Efficiency Optimization of an Irreversible Steady-Flow Lenoir Cycle -- Chenqi Tang, Lingen Chen, Huijun Feng and Yanlin Ge: Four-Objective Optimizations for an Improved Irreversible Closed Modified Simple Brayton Cycle -- C╦ÿat╦ÿalina Dobre, Lavinia Grosu, Alexandru Dobrovicescu, Georgiana Chi┬╕siu and Mihaela Constantin Stirling Refrigerating Machine Modeling Using Schmidt and Finite Physical Dimensions Thermodynamic Models: A Comparison with Experiments -- Lingen Chen, Huijun Feng and Yanlin Ge: Power and Efficiency Optimization for Open Combined Regenerative Brayton and Inverse Brayton Cycles with Regeneration before the Inverse Cycle -- Pierfrancesco Palazzo Chemical and Mechanical Aspect of Entropy-Exergy Relationship -- Jin-Fu Chen, Ying Li and Hui Dong: Simulating Finite-Time Isothermal Processes with Superconducting Quantum Circuits.
The paper that discusses the Lenoir cycle is from a more conventional point of view. It deals with the steady flow (such as Chambadal's original modeling). Objectives are power and first law efficiency. The corresponding allocation of heat transfer conductance is proposed, due to finite size constraints (i.e., the Utotal imposed).
9783039288458
THERMODYNAMIC
QC 311 .C37 2020