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Enhancing Benefits by Rectification in the Absorption Refrigeration Systems

Year 2022, , 29 - 37, 01.03.2022
https://doi.org/10.5541/ijot.927046

Abstract

The main objective of this article aims to enhance a single stage absorption refrigeration machine, using the ammonia-water pair as working fluid, and this from the improvement of its exergetic performances by means of a vapor rectification system. The rectifier makes it possible to emit a vapor enriched in pure fluid (ammonia) with a high flow rate; this one is thus transformed into condensate after condensation; as it also allows evacuating a liquid (water) in the form of reflux. Moreover, in order to show the role of the rectifier and to highlight its impact on the operation of the proposed installation, the methodology adopted in this work aims to develop a thermodynamic model of numerical simulation using the FORTRAN language according to two approaches. An energetic analysis approach which aims to assess, in a first time, the performance of the studied refrigeration installation. However, the exergetic approach tries to calculate the exergy efficiency, and thus to evaluate the losses of exergies of the refrigeration installation in a second time. Therefore, the obtained results showed a clear improvement in the exergetic efficiency, accompanied against by an optimization of the losses of exergies which are due to the irreversibility of the studied thermodynamic system. The novelty brought by the present study encourages the engineers and manufacturers to realize the future absorption refrigeration machines integrating rectifier systems.

Supporting Institution

Faculty of science and technology Settat, Hassan first University

References

  • Rasoul Nikbakhti et al., “Absorption cooling systems – Review of various techniques for energy performance enhancement,” Alexandria Engineering Journal, 59, 707–738, 2020.
  • Tuğba Kovacı and Arzu Şencan Şahin, “Energy and exergy analysis of a double-effect LiBr H2O absorption refrigeration system,” International Journal of Energy and Environment, Volume 9, Issue 1, pp.37-48, 2018.
  • Jatin Patel et al., “Exergy Based Analysis of LiCl-H2O Absorption Cooling System,” Energy Procedia 109, 261–269, 2017.
  • Ana CarolinaRosa et al., “Quantitative risk analysis applied to refrigeration’s industry using computational modeling,” Results in Engineering, Volume 9, 100202, 2021.
  • Abid Ustaoglu, “Parametric study of absorption refrigeration with vapor compression refrigeration cycle using wet, isentropic and azeotropic working fluids: Conventional and advanced exergy approach,” Energy, Vol. 201, 117491, 2020.
  • Sahraoui Kherris et al., “Contribution study of the thermodynamics properties of the ammonia-water mixtures,” Thermal Science, Vol. 17, n° 3, pp. 891-902, 2013.
  • João M. Garcia and Armando Rosa, “Theoretical Study of an IntermittentWater-Ammonia Absorption Solar System for Small Power Ice Production,” Sustainability, 11 (12), 3346, 2019.
  • Mohamed Charia et al., “Machine frigorifique à absorption (eau-ammoniac) fonctionnant avec des capteurs plans sur le site de Rabat,” Rev. Int. Froid, Vol 14, 297-303, 1991.
  • Bahram Ghorbani and Mehdi Mehrpooya, “Concentrated solar energy system and cold thermal energy storage (process development and energy analysis),” Sustainable Energy Technologies and Assessments, 37, 100607, 2020.
  • Li Jianbo et al., “A novel absorption–compression combined refrigeration cycle activated by engine waste heat,” Energy Conversion and Management, 205, 112420, 2020.
  • Xiangyang Liu et al., “Performance comparison of two absorption-compression hybrid refrigeration systems using R1234yf/ionic liquid as working pair,” Energy Conversion and Management, 181, 319–330, 2019.
  • Massamba Thioye, “Amé1ioration de la performance des machines frigorifiques à absorption par l'utilisation de cycles à absorption et désorption étagés,” Int J. Ref., Vol. 20, n° 2, pp. 136-145, 1997.
  • J. Dardouch, M. Charia, A. Bernatchou, A. Dardouch, S. Malaine, F. Jeffali, “Study of solar absorption refrigeration Machine in the Moroccan climate,” in (ICMES 2018) Materials Today: Proceeding, 13, 1197-1204, 2019.
  • M. Ahachad, M. Charia and A. Bernatchou, “study of improved NH3-H2O solar absorption refrigerating machine in Rabat (Morocco),” Solar Energy Materials and Solar Cells, 28, 71-79, (1992).
  • A. ŞENCAN et al., “Prediction of Liquid and Vapor Enthalpies of Ammonia-water Mixture,” Energy Sources, Part A, 33:1463–1473, 2011.
  • Gurjeet Singh, P. J. Singh, V. V. Tyagi, P. Barnwal and A. K. Pandey, “Exergy and thermoeconomic analysis of cream pasteurisation plant,” Journal of Thermal Analysis and Calorimetry (Springer), 137 (4), 1381-1400, 2019.
  • MA Javadi et al., “Optimization and analysis of exergy, economic, and environmental of a combined cycle power plant,” a ̃dhana ̃ , 44 (5), 1-11, 2019.
  • Charia Mohamed. (1990). Contribution à l’étude des machines frigorifiques à absorption mono-étagées et biétagées (Doctoral dissertation), FSR, Mohammed V in Rabat University.
  • Silvio de Oliveira Junior, Exergy: Production Cost and Renewability, 1st Ed. Springer Science & Business Media, 2013.
  • V. Vikul and S. D. Raja, “Experimenta and Exergy Analysis of Ammonia/Water Absorption System using Ethylene Glycol [C2H4(OH)2] in the Evaporator,” Energy Procedia, 109, 401-408, 2017.
  • Peizhe Cui et al., “Energy, exergy, and economic (3E) analyses and multi-objective optimization of a cascade absorption refrigeration system for low-grade waste heat recovery,” Energy Conversion and Management, 184, 249–261, 2019.
  • Ayad Khudhair Al-Nadawi, “Irreversibility Analysis of R407C, R404A, and R134A as an Alternatives of R22 in Vapor Compression Chiller under Cycling Conditions,” International Journal of Thermodynamics, Vol. 24, n° 1, pp. 24-29, 2021.
  • Sandro Nizetic, Agis Papadopoulos, The Role of Exergy in Energy and the Environment, 1st Ed. Springer International Publishing, 2018.
  • Rupp Carriveau et al., “Transient thermodynamic modeling of an underwater compressed air energy storage plant: Conventional versus advanced exergy analysis,” Sustainable Energy Technologies and Assessments 31 (2019) 146–154. Thamer Khalif Salem, Saad Sami Farhan, Israa Sami Farhan, “Energy and exergy analysis study of heat exchanger in a refrigeration system with different lengths of capillary tube,” International Journal of Thermodynamics, 23 (4), 260-266, 2020.
  • Anarghya Ananda Murthy et al., “A review on expanders and their performance in vapour compression refrigeration systems,” International Journal of Refrigeration 106, 427–446, 2019.
  • Huawei Wu et al., “Heat transfer analysis of energy and exergy improvement in water-tube boiler in steam generation process,” Journal of Thermal Analysis and Calorimetry, 139 (4), 2791-2799, 2020.
  • Zhihua Wang et al., “Exergy analysis of a frost-free air source heat pump system,” Journal of Mechanical Science and Technology, 33 (5), 2439-2450, 2019.
  • N. D. Shikalgar, S.N. Sapali, “Energy and exergy analysis of a domestic refrigerator: approaching a sustainable refrigerator,” Journal of Thermal Engineering, Vol. 5, n° 5, pp. 469-481, 2019.
  • Michel Wakim and Rodrigo Rivera-Tinoco, “Absorption heat transformers: Sensitivity study to answer existing discrepancies,” Renewable Energy, 130, 881-890, 2019.
  • Muhammad Umer Arshad et al., “Thermodynamic analysis and optimization of double effect absorption refrigeration system using genetic algorithm,” Energy Conversion and Management, 192, 292–307, 2019.
  • Hamed Kariman et al., “Energetic and exergetic analysis of evaporation desalination system integrated with mechanical vapor recompression circulation,” Case Studies in Thermal Engineering, Vol. 16, 100548, 2019. Yuan Zhang et al., “Exergy destruction analysis of a low-temperature Compressed Carbon dioxide Energy Storage system based on conventional and advanced exergy methods,” Applied Thermal Engineering, Vol. 185, 116421, 2021.
  • Nelson O. Moraga and Diego R. Rivera, “Advantages in predicting conjugate freezing of meat in a domestic freezer by CFD with turbulence k-ɛ 3D model and a local exergy destruction analysis,” Int. Jour. of Refr., doi.org/10.1016/j.ijrefrig.2021.02.002.
  • Chinedu F. Okwose, Muhammad Abid, Tahir A.H. Ratlamwala., “Performance analysis of compressor-assisted two-stage triple effect absorption refrigeration cycle for power and cooling,” Energy Conversion and Management., Energy Conversion and Management, 227 , 113547, 2021.
  • Ramen Kanti De and Aritra Ganguly., “Energy, Exergy and Economic Analysis of a Solar Hybrid Power System Integrated Double-E®ect Vapor Absorption System-Based Cold Storage,” International Journal of Air-Conditioning and Refrigeration, Vol. 27, n° 2 1950018 (13 pages), 2019.
  • Boris Huirem and Pradeepta Kumar Sahoo, “Thermodynamic Modeling and Performance Optimization of a Solar-Assisted Vapor Absorption Refrigeration System (SAVARS),” International Journal of Air-Conditioning and Refrigeration, Vol. 28, n° 1, 2050006 (18 pages), 2020.
  • Xiao Zhang et al., “Energetic and Exergetic Investigations of Hybrid Configurations in an Absorption Refrigeration Chiller by Aspen Plus,” Processes, 7 (9), 609, 2019.
  • Wei Wu et al., “Comparative analysis of conventional and low-GWP refrigerants with ionic liquid used for compression-assisted absorption cooling cycles,” Applied Thermal Engineering, 172, 115145, 2020.
  • Manel Vallès, M Bourouis, D Boer, “Solar-driven absorption cycle for space heating and cooling,” Applied Thermal Engineering, Vol. 168, 114836, 2020.
  • XuPing et al., “Prediction and optimization of isentropic efficiency of vortex pump under full operating conditions in Organic Rankine Cycle waste heat recovery system based on deep learning and intelligent algorithm,” Sustainable Energy Technologies and Assessments., Vol. 42, , 100898, December 2020.
  • Ahmad Fakheri, “Heat Exchanger Efficiency,” Journal of heat transfer, 129 (9):1268-1276 (9 pages), 2007, https://doi.org/10.1115/1.2739620.
  • B. Ziegler and Ch. Trepp, “Equation of state for ammonia-water mixtures,” Int. Jour. Of Ref., Vol. 7, n° 2, Pages 101-106, March 1984.
  • VijayChauhan et al., “Thermodynamic analysis of a combined cycle for cold storage and power generation using geothermal heat source,” Thermal Science and Engineering Progress, Volume 11, Pages 19-27, June 2019.
Year 2022, , 29 - 37, 01.03.2022
https://doi.org/10.5541/ijot.927046

Abstract

References

  • Rasoul Nikbakhti et al., “Absorption cooling systems – Review of various techniques for energy performance enhancement,” Alexandria Engineering Journal, 59, 707–738, 2020.
  • Tuğba Kovacı and Arzu Şencan Şahin, “Energy and exergy analysis of a double-effect LiBr H2O absorption refrigeration system,” International Journal of Energy and Environment, Volume 9, Issue 1, pp.37-48, 2018.
  • Jatin Patel et al., “Exergy Based Analysis of LiCl-H2O Absorption Cooling System,” Energy Procedia 109, 261–269, 2017.
  • Ana CarolinaRosa et al., “Quantitative risk analysis applied to refrigeration’s industry using computational modeling,” Results in Engineering, Volume 9, 100202, 2021.
  • Abid Ustaoglu, “Parametric study of absorption refrigeration with vapor compression refrigeration cycle using wet, isentropic and azeotropic working fluids: Conventional and advanced exergy approach,” Energy, Vol. 201, 117491, 2020.
  • Sahraoui Kherris et al., “Contribution study of the thermodynamics properties of the ammonia-water mixtures,” Thermal Science, Vol. 17, n° 3, pp. 891-902, 2013.
  • João M. Garcia and Armando Rosa, “Theoretical Study of an IntermittentWater-Ammonia Absorption Solar System for Small Power Ice Production,” Sustainability, 11 (12), 3346, 2019.
  • Mohamed Charia et al., “Machine frigorifique à absorption (eau-ammoniac) fonctionnant avec des capteurs plans sur le site de Rabat,” Rev. Int. Froid, Vol 14, 297-303, 1991.
  • Bahram Ghorbani and Mehdi Mehrpooya, “Concentrated solar energy system and cold thermal energy storage (process development and energy analysis),” Sustainable Energy Technologies and Assessments, 37, 100607, 2020.
  • Li Jianbo et al., “A novel absorption–compression combined refrigeration cycle activated by engine waste heat,” Energy Conversion and Management, 205, 112420, 2020.
  • Xiangyang Liu et al., “Performance comparison of two absorption-compression hybrid refrigeration systems using R1234yf/ionic liquid as working pair,” Energy Conversion and Management, 181, 319–330, 2019.
  • Massamba Thioye, “Amé1ioration de la performance des machines frigorifiques à absorption par l'utilisation de cycles à absorption et désorption étagés,” Int J. Ref., Vol. 20, n° 2, pp. 136-145, 1997.
  • J. Dardouch, M. Charia, A. Bernatchou, A. Dardouch, S. Malaine, F. Jeffali, “Study of solar absorption refrigeration Machine in the Moroccan climate,” in (ICMES 2018) Materials Today: Proceeding, 13, 1197-1204, 2019.
  • M. Ahachad, M. Charia and A. Bernatchou, “study of improved NH3-H2O solar absorption refrigerating machine in Rabat (Morocco),” Solar Energy Materials and Solar Cells, 28, 71-79, (1992).
  • A. ŞENCAN et al., “Prediction of Liquid and Vapor Enthalpies of Ammonia-water Mixture,” Energy Sources, Part A, 33:1463–1473, 2011.
  • Gurjeet Singh, P. J. Singh, V. V. Tyagi, P. Barnwal and A. K. Pandey, “Exergy and thermoeconomic analysis of cream pasteurisation plant,” Journal of Thermal Analysis and Calorimetry (Springer), 137 (4), 1381-1400, 2019.
  • MA Javadi et al., “Optimization and analysis of exergy, economic, and environmental of a combined cycle power plant,” a ̃dhana ̃ , 44 (5), 1-11, 2019.
  • Charia Mohamed. (1990). Contribution à l’étude des machines frigorifiques à absorption mono-étagées et biétagées (Doctoral dissertation), FSR, Mohammed V in Rabat University.
  • Silvio de Oliveira Junior, Exergy: Production Cost and Renewability, 1st Ed. Springer Science & Business Media, 2013.
  • V. Vikul and S. D. Raja, “Experimenta and Exergy Analysis of Ammonia/Water Absorption System using Ethylene Glycol [C2H4(OH)2] in the Evaporator,” Energy Procedia, 109, 401-408, 2017.
  • Peizhe Cui et al., “Energy, exergy, and economic (3E) analyses and multi-objective optimization of a cascade absorption refrigeration system for low-grade waste heat recovery,” Energy Conversion and Management, 184, 249–261, 2019.
  • Ayad Khudhair Al-Nadawi, “Irreversibility Analysis of R407C, R404A, and R134A as an Alternatives of R22 in Vapor Compression Chiller under Cycling Conditions,” International Journal of Thermodynamics, Vol. 24, n° 1, pp. 24-29, 2021.
  • Sandro Nizetic, Agis Papadopoulos, The Role of Exergy in Energy and the Environment, 1st Ed. Springer International Publishing, 2018.
  • Rupp Carriveau et al., “Transient thermodynamic modeling of an underwater compressed air energy storage plant: Conventional versus advanced exergy analysis,” Sustainable Energy Technologies and Assessments 31 (2019) 146–154. Thamer Khalif Salem, Saad Sami Farhan, Israa Sami Farhan, “Energy and exergy analysis study of heat exchanger in a refrigeration system with different lengths of capillary tube,” International Journal of Thermodynamics, 23 (4), 260-266, 2020.
  • Anarghya Ananda Murthy et al., “A review on expanders and their performance in vapour compression refrigeration systems,” International Journal of Refrigeration 106, 427–446, 2019.
  • Huawei Wu et al., “Heat transfer analysis of energy and exergy improvement in water-tube boiler in steam generation process,” Journal of Thermal Analysis and Calorimetry, 139 (4), 2791-2799, 2020.
  • Zhihua Wang et al., “Exergy analysis of a frost-free air source heat pump system,” Journal of Mechanical Science and Technology, 33 (5), 2439-2450, 2019.
  • N. D. Shikalgar, S.N. Sapali, “Energy and exergy analysis of a domestic refrigerator: approaching a sustainable refrigerator,” Journal of Thermal Engineering, Vol. 5, n° 5, pp. 469-481, 2019.
  • Michel Wakim and Rodrigo Rivera-Tinoco, “Absorption heat transformers: Sensitivity study to answer existing discrepancies,” Renewable Energy, 130, 881-890, 2019.
  • Muhammad Umer Arshad et al., “Thermodynamic analysis and optimization of double effect absorption refrigeration system using genetic algorithm,” Energy Conversion and Management, 192, 292–307, 2019.
  • Hamed Kariman et al., “Energetic and exergetic analysis of evaporation desalination system integrated with mechanical vapor recompression circulation,” Case Studies in Thermal Engineering, Vol. 16, 100548, 2019. Yuan Zhang et al., “Exergy destruction analysis of a low-temperature Compressed Carbon dioxide Energy Storage system based on conventional and advanced exergy methods,” Applied Thermal Engineering, Vol. 185, 116421, 2021.
  • Nelson O. Moraga and Diego R. Rivera, “Advantages in predicting conjugate freezing of meat in a domestic freezer by CFD with turbulence k-ɛ 3D model and a local exergy destruction analysis,” Int. Jour. of Refr., doi.org/10.1016/j.ijrefrig.2021.02.002.
  • Chinedu F. Okwose, Muhammad Abid, Tahir A.H. Ratlamwala., “Performance analysis of compressor-assisted two-stage triple effect absorption refrigeration cycle for power and cooling,” Energy Conversion and Management., Energy Conversion and Management, 227 , 113547, 2021.
  • Ramen Kanti De and Aritra Ganguly., “Energy, Exergy and Economic Analysis of a Solar Hybrid Power System Integrated Double-E®ect Vapor Absorption System-Based Cold Storage,” International Journal of Air-Conditioning and Refrigeration, Vol. 27, n° 2 1950018 (13 pages), 2019.
  • Boris Huirem and Pradeepta Kumar Sahoo, “Thermodynamic Modeling and Performance Optimization of a Solar-Assisted Vapor Absorption Refrigeration System (SAVARS),” International Journal of Air-Conditioning and Refrigeration, Vol. 28, n° 1, 2050006 (18 pages), 2020.
  • Xiao Zhang et al., “Energetic and Exergetic Investigations of Hybrid Configurations in an Absorption Refrigeration Chiller by Aspen Plus,” Processes, 7 (9), 609, 2019.
  • Wei Wu et al., “Comparative analysis of conventional and low-GWP refrigerants with ionic liquid used for compression-assisted absorption cooling cycles,” Applied Thermal Engineering, 172, 115145, 2020.
  • Manel Vallès, M Bourouis, D Boer, “Solar-driven absorption cycle for space heating and cooling,” Applied Thermal Engineering, Vol. 168, 114836, 2020.
  • XuPing et al., “Prediction and optimization of isentropic efficiency of vortex pump under full operating conditions in Organic Rankine Cycle waste heat recovery system based on deep learning and intelligent algorithm,” Sustainable Energy Technologies and Assessments., Vol. 42, , 100898, December 2020.
  • Ahmad Fakheri, “Heat Exchanger Efficiency,” Journal of heat transfer, 129 (9):1268-1276 (9 pages), 2007, https://doi.org/10.1115/1.2739620.
  • B. Ziegler and Ch. Trepp, “Equation of state for ammonia-water mixtures,” Int. Jour. Of Ref., Vol. 7, n° 2, Pages 101-106, March 1984.
  • VijayChauhan et al., “Thermodynamic analysis of a combined cycle for cold storage and power generation using geothermal heat source,” Thermal Science and Engineering Progress, Volume 11, Pages 19-27, June 2019.
There are 42 citations in total.

Details

Primary Language English
Subjects Thermodynamics and Statistical Physics
Journal Section Research Articles
Authors

Malaıne Salek This is me

N. Ababssi This is me

M. Charia This is me

A. Boulal This is me

Publication Date March 1, 2022
Published in Issue Year 2022

Cite

APA Salek, M., Ababssi, N., Charia, M., Boulal, A. (2022). Enhancing Benefits by Rectification in the Absorption Refrigeration Systems. International Journal of Thermodynamics, 25(1), 29-37. https://doi.org/10.5541/ijot.927046
AMA Salek M, Ababssi N, Charia M, Boulal A. Enhancing Benefits by Rectification in the Absorption Refrigeration Systems. International Journal of Thermodynamics. March 2022;25(1):29-37. doi:10.5541/ijot.927046
Chicago Salek, Malaıne, N. Ababssi, M. Charia, and A. Boulal. “Enhancing Benefits by Rectification in the Absorption Refrigeration Systems”. International Journal of Thermodynamics 25, no. 1 (March 2022): 29-37. https://doi.org/10.5541/ijot.927046.
EndNote Salek M, Ababssi N, Charia M, Boulal A (March 1, 2022) Enhancing Benefits by Rectification in the Absorption Refrigeration Systems. International Journal of Thermodynamics 25 1 29–37.
IEEE M. Salek, N. Ababssi, M. Charia, and A. Boulal, “Enhancing Benefits by Rectification in the Absorption Refrigeration Systems”, International Journal of Thermodynamics, vol. 25, no. 1, pp. 29–37, 2022, doi: 10.5541/ijot.927046.
ISNAD Salek, Malaıne et al. “Enhancing Benefits by Rectification in the Absorption Refrigeration Systems”. International Journal of Thermodynamics 25/1 (March 2022), 29-37. https://doi.org/10.5541/ijot.927046.
JAMA Salek M, Ababssi N, Charia M, Boulal A. Enhancing Benefits by Rectification in the Absorption Refrigeration Systems. International Journal of Thermodynamics. 2022;25:29–37.
MLA Salek, Malaıne et al. “Enhancing Benefits by Rectification in the Absorption Refrigeration Systems”. International Journal of Thermodynamics, vol. 25, no. 1, 2022, pp. 29-37, doi:10.5541/ijot.927046.
Vancouver Salek M, Ababssi N, Charia M, Boulal A. Enhancing Benefits by Rectification in the Absorption Refrigeration Systems. International Journal of Thermodynamics. 2022;25(1):29-37.