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[28] Schuster, A., Karellas, S., Kakaras, E. and Spliethoff, H., Energetic and economic investigation of organic Rankine cycle applications. Applied Thermal Engineering, vol. 29, pp. 1809–1817, 2009. [29] Chen, H., Goswami, Y., Rahman, M. and Stefanakos, E., A supercritical Rankine cycle using zeotropic mixture working fluids for the conversion of low-grade heat into power. Energy, vol. 36, pp. 549-555, 2011. [30] Mikielewicz, D. and Mikielewicz, J., A thermodynamic criterion for selection of working fluid for subcritical and supercritical domestic micro CHP. Applied Thermal Engineering, vol. 30, pp. 2357-2362, 2010. [31] Lakew, A. and Bolland, O., Working fluids for low temperature heat source. Applied Thermal Engineering, vol. 30, pp. 1262–1268, 2010. [32] Lemmon, E.W., Huber, M.L. and Mclinden, M.O., Reference fluid thermodynamic and transport properties (REFPROP). NIST Standard Reference Database, 23, Version 8.0; 2007. Fredy Vélez. Ph.D in Energetic and Fluid-Mechanical Engineering by University of Valladolid (2011). MSc in Engineer -Emphasis in Chemical Engineering- (2007) and Chemical Engineer (2004), both by Colombian National University, where he was also an Associate Professor at the Energy and Process School. He started to work as researcher in the field of renewable energies in 2004. Since 2007 he is actively working in Energy Department of CARTIF in RTD projects about energy efficiency and integration of renewable energy (solar, geothermal, biomass) for the production of heating and cooling and/or electricity generation in buildings (to achieve zero emission buildings and near-zero energy balance) and industrial processes. He has experience in national and international (European and Latin American) projects, and has published many papers in peer review and technical journals and contributions in conferences about these themes. ORCID 0000-0003-0764-1321 Farid Chejne is a post-doctoral researcher at University Libre of Brussels (1997). He earned a PhD in Energy systems at Technical University of Madrid (1991). BSc in Physic (1989) by University of Antioquia and Mechanical Engineer by University Pontificia Bolivariana (1983). From 1983 to 2002, he worked as Full Professor in the Thermodynamical department in the University Pontificia Bolivariana, starting his career in National University of Colombia in 2002 where he currently continues his work as Full Professor. His research interests includes: modeling and simulation of processes, analysis of energy systems, advanced thermodynamic, energy resources, optimization and rational use of the energy, new technologies, combustion and gasification, management and technology. Furthermore, he has carried out projects for different companies within the power and industrial sectors. He has participated in multiple national and international research projects, contributing in addition in the publication of a large number of publications, including papers in peer review and technical journals, contributions in conferences and books about these themes. He has organized several international workshops, scientific sections and panels at international conferences and conducted various theses. Ana Quijano. BSc in Environmental Science (2003) and MSc in Research in Engineering for the Agroforestry Development (2010), by the University of Salamanca and University of Valladolid, respectively. She has been working in the Biofuels Area of CARTIF during 2005-2012, leading and participating in several National and European R&D projects on technologies for energy valorisation of biomass. She was nominated as Member of the Action COST “Innovative applications of regenerated wood cellulose fibres” in 2012 for her trajectory in the field of biorefineries. In 2013, she was incorporated to the Energy Area, specializing the execution of FP7 Projects in the field of efficiency and renewable energy generation systems in buildings. Furthermore, she is co-author of 4 articles in scientific journals, 6 articles in dissemination journals and 12 contributions in conferences. Vélez et al / DYNA 81 (185), pp. 153-159. June, 2014. 159PDF Image | Thermodynamic analysis of R134a in an Organic Rankine Cycle for power generation from low temperature sources Analisis termodinamico del R134a en un Ciclo Rankine Organico para la generacionde energía a partir de fuentes de baja temperatura
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