References

Alkan, M.A., A. Kecebas and N. Yamankaradeniz, 2013. Exergoeconomic analysis of a district heating system for geothermal energy using specific exergy cost method. Energy, 60: 426-434.
CrossRef  |  Direct Link  |  

Farshi, L.G., S.M.S. Mahmoudi and M.A. Rosen, 2013. Exergoeconomic comparison of double effect and combined ejector-double effect absorption refrigeration systems. Appl. Energy, 103: 700-711.
CrossRef  |  

Gutierreza, A.S. and C. Vandecasteele, 2011. Exergy-based indicators to evaluate the possibilities to reduce fuel consumption in lime production. Energy, 36: 2820-2827.
CrossRef  |  Direct Link  |  

Jodat, A., 2016. Exergoeconomic analysis of gas turbines cogeneration systems. J. Eng. Appl. Sci., 11: 2545-2550.
Direct Link  |  

Kutas, T.J., 1995. The Exergy Method of Thermal Plant Analysis, Florida. Krieger Publishing, Malabar, Florida,.

Lazzaretto, A. and G. Tsatsaronis, 2006. SPECO: A systematic and general methodology for calculating efficiencies and costs in thermal systems. Energy, 31: 1257-1289.
Direct Link  |  

Lourenco, A.B., S.A. Nebra, J.J.C. Santos and J.L.M. Donatelli, 2015. Application of an alternative thermoeconomic approach to a two-stage vapour compression refrigeration cascade cycle. J. Braz. Soc. Mech. Sci. Eng., 37: 903-913.
CrossRef  |  Direct Link  |  

Lozano, M., A. Valero and L. Serra, 1993. Theory of Exergetic Cost and Thermoeconomic Optimization. In: Energy System and Ecology, Szargut, J. (Ed.). University of Zaragoza, Zaragoza, Spain, pp: 339-350.

Lozano, M.A. and A. Valero, 1993. Thermoeconomic Analysis of Gas Turbine Cogeneration Systems. In: Thermodynamics and the Design, Analysis and Improvement of Energy Systems, Richter, H.J. (Ed.). ASME, New York, USA., pp: 311-320.

Luo, X., J. Hu, J. Zhao, B. Zhang and Y. Chen et al., 2014. Improved exergoeconomic analysis of a retrofitted natural gas-based cogeneration system. Energy, 72: 459-475.
Direct Link  |  

Piacentino, A. and E. Cardona, 2010. Scope oriented Thermoeconomic analysis of energy systems, Part II: Formation structure of optimality for robust design. Appl. Energy, 87: 957-970.
Direct Link  |  

Piacentino, A. and F. Cardona, 2010. Scope-oriented thermoeconomic analysis of energy systems Part I: Looking for a non-postulated cost accounting for the dissipative devices of a vapour compression chiller; Is it feasible?. Appl. Energy, 87: 943-956.
Direct Link  |  

Piacentino, A., 2015. Application of advanced thermodynamics, thermoeconomics and exergy costing to a multiple effect distillation plant: In-depth analysis of cost formation process. Desalin., 371: 88-103.
Direct Link  |  

Santos, D.R.G.D., P.R. Faria, J.J. Santos, D.J.A. Silva and O.D. Florez, 2016. Thermoeconomic modeling for CO₂ allocation in steam and gas turbine cogeneration systems. Energy, 117: 590-603.
Direct Link  |  

Santos, J., M. Nascimento, E. Lora and A.M. Reyes, 2009. On the negentropy application in thermoeconomics: A fictitious or an exergy component flow?. Intl. J. Thermodyn., 12: 163-176.
Direct Link  |  

Sharifi, M. and S. Khalilarya, 2016. Exergoeconomic evaluation and optimisation of a novel combined power and absorption-ejector refrigeration cycle driven by natural gas. Intl. J. Exergy, 19: 232-258.

Teixeira, D.S.M. and D.O.S. Junior, 2001. Thermoeconomic evaluation of cogeneration systems for a chemical plant. Intl. J. Thermodyn., 4: 157-163.
Direct Link  |  

Torres, C., A. Valero, V. Rangel and A. Zaleta, 2008. On the cost formation process of the residues. Energy, 33: 144-152.
Direct Link  |  

Valero, A., 2006. Exergy accounting: Capabilities and drawbacks. Energy, 31: 164-180.
Direct Link  |  

Valero, A., F. Lerch, L. Serra and J. Royo, 2002. Structural theory and thermoeconomic diagnosis: Part II: Application to an actual power plant. Energy Convers. Manage., 43: 1519-1535.
Direct Link  |  

Valero, A., M.A. Lozano, L. Serra and C. Torres, 1994. Application of the exergetic cost theory to the CGAM problem. Energy, 19: 365-381.
Direct Link  |  

Yao, H., D. Sheng, J. Chen, W. Li, A. Wan and H. Chen, 2012. Exergoeconomic analysis of a combined cycle system utilizing associated gases from steel production process based on structural theory of thermoeconomics. Applied Therm. Eng., 51: 476-489.
CrossRef  |