sample of publications

• articles 

  • Experimental evaluation of the transient and steady state performance of an air-cooled square minichannel heat exchanger.  INTERNATIONAL JOURNAL OF THERMAL SCIENCES.  188:1-26. 2023
  • Experimental evaluation of a new mini square channel air-cooled heat exchanger for an absorption chiller.  INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER.  195. 2022
  • Viability on the desorption and air condensation of water in a compact membrane-based microchannel desorber-condenser for cooling applications.  ENERGY CONVERSION AND MANAGEMENT.  267. 2022
  • Performance assessment of low temperature solar collector with Fullerenes C60 in an emerging country.  Applied Sciences-Basel.  12:1-19. 2022
  • Experimental performance of membrane water absorption in LiBr solution with and without cooling.  APPLIED THERMAL ENGINEERING.  180:1-7. 2020
  • Performance of a solar absorption cooling system using nanofluids and a membrane-based microchannel desorber.  Applied Sciences-Basel.  10:1-16. 2020
  • Experimental evaluation of a membrane-based microchannel desorber operating at low desorption temperatures.  APPLIED THERMAL ENGINEERING.  167:1-10. 2020
  • Experimental performance comparison of three flat sheet membranes operating in an adiabatic microchannel absorber.  APPLIED THERMAL ENGINEERING.  152:835-843. 2019
  • A parametric analysis on the effect of design and operating variables in a membrane-based desorber.  INTERNATIONAL JOURNAL OF REFRIGERATION.  99:47-58. 2019
  • Experimental characterisation of a novel adiabatic membrane-based micro-absorber using H2O-LiBr.  INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER.  129:1136-1143. 2019
  • Modeling and performance analysis of an absorption chiller with a microchannel membrane-based absorber using LiBr-H2O, LiCl-H2O, and LiNO3-NH3.  INTERNATIONAL JOURNAL OF ENERGY RESEARCH.  42:3544-3558. 2018
  • Adiabatic vs non-adiabatic membrane-based rectangular micro-absorbers for H2O-LiBr absorption chillers.  Energy.  134:757-766. 2017
  • Simplified model of a membrane-based rectangular micro-desorber for absorption chillers.  INTERNATIONAL JOURNAL OF REFRIGERATION.  71:108-123. 2016
  • Parametric study of operating and design variables on the performance of a membrane-based absorber.  APPLIED THERMAL ENGINEERING.  98:409-419. 2016
  • A simple model to predict the performance of a H2O-LiBr absorber operating with a microporous membrane.  Energy.  96:383-393. 2016
  • Three-dimensional two-fluid modeling of a cylindrical fluidized bed and validation of the Maximum Entropy method to determine bubble properties.  Chemical Engineering Journal.  262:628-639. 2015
  • Experimental study on the motion of isolated bubbles in a vertically vibrated fluidized bed.  Chemical Engineering Journal.  255:114-125. 2014
  • Energy and exergy analysis of an absorption power cycle.  APPLIED THERMAL ENGINEERING.  55:69-77. 2013
  • A novel methodology for simulating vibrated fluidized beds using two-fluid models.  Chemical Engineering Journal.  198-199:261-274. 2012
  • Experimental and computational study on the bubble behavior in a 3-D fluidized bed.  CHEMICAL ENGINEERING SCIENCE.  66:3499-3512. 2011
  • Energy and exergy analysis in an asphalt plant's rotary dryer.  APPLIED THERMAL ENGINEERING.  31:1039-1049. 2011
  • On the pressure drop in Plate Heat Exchangers used as desorbers in absorption chillers.  ENERGY CONVERSION AND MANAGEMENT.  52:1520-1525. 2011
  • Bubble Characteristics in a Bubbling Fluidized Bed with a Rotating Distributor.  INTERNATIONAL JOURNAL OF MULTIPHASE FLOW.  35:970-976. 2009
  • Maximum Entropy Estimation of the Bubble Size Distribution in Fluidized Beds.  CHEMICAL ENGINEERING SCIENCE.  64:2307-2319. 2009
  • Distributor Effects near the Bottom region of Turbulent Fuidized Beds.  POWDER TECHNOLOGY.  189:25-33. 2009
  • Standard Deviation of Absolute and Differential Pressure Fluctuations in Fluidized Beds of Group B Particles.  CHEMICAL ENGINEERING RESEARCH & DESIGN.  86:1236-1242. 2008
  • Fluidization of Group B Particles with a Rotating Distributor.  POWDER TECHNOLOGY.  181:273-280. 2008

• book chapters 

  • Modelling of membrane-based micro-absorbers for absorption cooling technology. In: Materials and Technologies for Energy Efficiency.  BrownWalker Press. 223-227. 2015

• conference contributions 

  • Simulación de un enfriador híbrido alimentado por energía solar térmica.  451-457. 2020
  • Simulation of a solar cooling system using nanofluids and membrane-based components in the absorption chiller.  1-7. 2020
  • Experimental measurement of mass transfer resistances in a membrane based adiabatic microchannel absorber 2019
  • Performance of a membrane-based microchannel desorber using nanofluids 2019
  • Performance improvement of absorption cooling systems using nanoparticles: A review.  103-107. 2019
  • Performance of a single effect LiBr-water absorption chiller operating with a membrane-based microchannel absorber 2017
  • Thermodynamic design data of a single effect LiBr-H2O absorption chiller provided with a membrane-based microchannel absorber for air conditioning applications.  22-22. 2017
  • Comparison between adiabatic and non-adiabatic H2O-LiBr membrane-based absorbers.  321-326. 2016
  • Comparison of working fluid combinations in a microchannel membrane absorber 2016
  • Micro-absorption chiller components based on membrane technology.  296-296. 2015
  • Modelling of membrane-based micro-absorbers for absorption cooling technology.  223-227. 2015
  • Performance evaluation of H2O-LiBr absorber operating with microporous membrane technology 2015
  • Distributor Effect In The Bottom Region Of Turbulent Fluidized Bed: Implications To Scale-Up 2008