Research Article
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Year 2024, Volume: 10 Issue: 3, 722 - 736, 21.05.2024

Abstract

References

  • [1] EIA. EIA projects 28% increase in world energy use by 2040. Available at: https://www.eia.gov/todayinenergy/detail.php?id=32912. Accessed May 8, 2024.
  • [2] Naukkarinen P. Solar air conditioning and its role in alleviating the energy crisis of the Mediterranean hotels. Int J Sustain Energy 2009;28:93–100. [CrossRef]
  • [3] Harby K, Fahad A. An investigation of energy savings in a split air-conditioner using commercial cooling pads with different thicknesses and wide range of climatic conditions. Energy 2019;182:321–336. [CrossRef]
  • [4] Ziegler F. Recent developments and future prospects of sorption heat pump systems. Int J Therm Sci 1999;38:191–208. [CrossRef]
  • [5] Perez-Blanco H. Absorption heat pump performance for different types of solutions. Int J Refrigeration 1984;7:115–122. [CrossRef]
  • [6] Ali A, Zamri N, Ahmed A. Solar absorption cooling systems: A review. J Therm Engineer 2021;7:970–983. [CrossRef]
  • [7] Harby K, Ehab SA, Almohammadi KM. A novel combined reverse osmosis and hybrid absorption desalination-cooling system to increase overall water recovery and energy efficiency. J Clean Prod 2021;287:125014. [CrossRef]
  • [8] Stephan K. History of absorption heat pumps and working pair developments in Europe. Int J Refrigeration 1983;6:160–166. [CrossRef]
  • [9] Sumathy K, Yeung KH, Yong L. Technology development in the solar adsorption refrigeration systems. Prog Energy Combust Sci 2003;29:301–327. [CrossRef]
  • [10] Wang R, Wang L. Adsorption refrigeration-green cooling driven by low grade thermal energy. Chin Sci Bull 1993;50:204. [CrossRef]
  • [11] Ziegler F. State of the art in sorption heat pumping and cooling technologies. Int J Refrigeration 2002;25:450–459. [CrossRef]
  • [12] Sun J, Fu L, Zhang S. A review of working fluids of absorption cycles. Renew Sustain Energy Rev 2012;16:1899–1906. [CrossRef]
  • [13] Jawahar C, Saravanan R. Generator absorber heat exchange-based absorption cycle-a review. Renew Sustain Energy Rev 2010;14:2372–2382. [CrossRef]
  • [14] Alka S, Yash P. Evaluation and optimization of single-effect vapour absorption system for the dairy industry using design of experiment approach. J Therm Engineer 2022;8:619–631. [CrossRef]
  • [15] Kamel A, Khalil KMS, Askalany A, Ali ES, Harby K, Ghazy M. Improving adsorption materials properties for renewable energy-driven cooling systems, Therm Sci Engineer Prog 2024;50:102551. [CrossRef]
  • [16] Ibarra-Bahena J, Romero RJ. Performance of different experimental absorber designs in absorption heat pump cycle technologies: A review. Energies 2014;7:751–766. [CrossRef]
  • [17] Wang X, Chua HT. Absorption cooling: a review of lithium bromide-water chiller technologies. Recent Pat Mech Engineer 2009;2:193–213. [CrossRef]
  • [18] Zhai X, Qu M, Li Y, Wang R. A review for research and new design options of solar absorption cooling systems. Renew Sustain Energy Rev 2011;15:4416–4423. [CrossRef]
  • [19] Siddiqui M, Said S. A review of solar powered absorption systems. Renew Sustain Energy Rev 2015;42:93–115. [CrossRef]
  • [20] Wang X, Bierwirth A, Christ A, Whittaker P, Regenauer-Lieb K, Chua HT. Application of geothermal absorption air-conditioning system: A case study. Appl Therm Engineer 2013;50:71–80. [CrossRef]
  • [21] Tugcu A, Arslan O. Optimization of geothermal energy aided absorption refrigeration system-GAARS: A novel ANN-based approach. Geothermics 2017;65:210–221. [CrossRef]
  • [22] Seyfouri Z, Ameri M. Analysis of integrated compression–absorption refrigeration systems powered by a microturbine. Int J Refrig 2012;35:1639–1646. [CrossRef]
  • [23] Bruno JC, Ortega-López V, Coronas A. Integration of absorption cooling systems into micro gas turbine trigeneration systems using biogas: case study of a sewage treatment plant. Appl Energy 2009;86:837–847. [CrossRef]
  • [24] Sira S, Somchai W. A critical review of recent investigations on two-phase pressure drop in flow boiling micro-channels. Front Heat Mass Transf 2012;3:013007. [CrossRef]
  • [25] Awad M, Dalkılıç AS, Wongwises S. A critical review on condensation heat transfer in microchannels and minichannels. J Nanotechnol Engineer Med 2014;5:0108011. [CrossRef]
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  • [27] Boer D, Valles M, Coronas A. Performance of double effect absorption compression cycles for air-conditioning using methanol-TEGDME and TFE-TEGDME systems as working pairs. Int J Refrig 1998;21:542–555. [CrossRef]
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  • [29] Medrano M, Bourouis M, Coronas A. Double-lift absorption refrigeration cycles driven by low-temperature heat sources using organic fluid mixtures as working pairs. Appl Energy 2001;68:173–185. [CrossRef]
  • [30] Izquierdo M, Venegas M, García N, Palacios E. Exergetic analysis of a double stage LiBr-H2O thermal compressor cooled by air/water and driven by low grade heat. Energy Conver Manage 2005;46:1029–1042. [CrossRef]
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  • [32] Kairouani L, Nehdi E. Cooling performance and energy saving of a compression-absorption refrigeration system assisted by geothermal energy. Appl Therm Engineer 2006;26:288–294. [CrossRef]
  • [33] Seyfouri Z, Ameri M. Analysis of integrated compression–absorption refrigeration systems powered by a microturbine. Int J Refrig 2012;35:1639–1646. [CrossRef]
  • [34] Fernández-Seara J, Sieres J, Vázquez M. Compression-absorption cascade refrigeration system. Appl Therm Engineer 2005;26:502–512. [CrossRef]
  • [35] Jain V, Sachdeva G, Singh Kachhwaha S, Patel B. Thermo-economic and environmental analyses based multi-objective optimization of vapor compression-absorption cascaded refrigeration system using NSGA-II technique. Energy Conver Manage 2016;113:230–242. [CrossRef]
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  • [37] Ehab SA, Ahmed AA, Harby K, Mohamed RD, Bahgat RM, Ahmed A. Experimental adsorption water desalination system utilizing activated clay for low grade heat source applications. J Energy Storage 2021;43:103219. [CrossRef]
  • [38] Verde M, Harby K, Robert B, Corberán JM. Performance evaluation of a waste-heat driven adsorption system for automotive air-conditioning: Part I- Modeling and experimental validation. Energy 2016;116:526–538. [CrossRef]
  • [39] Verde M, Harby K, Robert B, Corberán JM. Performance evaluation of a waste-heat driven adsorption system for automotive air-conditioning: Part II- performance optimization under different real driving conditions. Energy 2016;115:996–1009. [CrossRef]
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  • [41] Restuccia G, Freni A, Maggio G. A zeolite-coated bed for air conditioning adsorption systems: parametric study of heat and mass transfer by dynamic simulation. Appl Therm Engineer 2002;22:619–630. [CrossRef]
  • [42] Mohamed G, Askalany A, Harby K, Ahmed MS. Adsorption isotherms and kinetics of HFC-404A onto bituminous based granular activated carbon for storage and cooling applications. Appl Therm Engineer 2016;105:639–645. [CrossRef]
  • [43] Ahmed S, Ahmed A, Harby K, Mahmoud S. Performance evaluation of a solar driven adsorption desalination cooling system. Energy 2017;128:196–207. [CrossRef]
  • [44] Zhang LZ, Wang L. Performance estimation of an adsorption cooling system for automobile waste heat recovery. Appl Therm Engineer 1997;17:1127–1139. [CrossRef]
  • [45] Alam K, Saha B, Kang Y, Akisawa A, Kashiwagi T. Heat design effect on the performance of silica gel adsorption refrigeration systems. Int J Heat Mass Transf 2000;43:4419–4431. [CrossRef]
  • [46] Tamainot-Telto Z, Metcalf SJ, Critoph RE. Novel compact sorption generators for car air conditioning. Int J Refrig 2009;32:727–733. [CrossRef]
  • [47] Liu Y, Leong KC. Numerical study of a novel cascading adsorption cycle. Int J Refrig 2006;29:250–259. [CrossRef]
  • [48] Meunier F. Theoretical performances of solid adsorbent cascading cycles using the zeolite-water and active carbon-methanol pairs: four case studies. Heat Recov Sys 1986;6:491–498. [CrossRef]
  • [49] Khairul H, Bidyut BS, Anutosh C, Shigeru K, Kandadai S. Performance evaluation of combined adsorption refrigeration cycles. Int J Refrigeration 2011;34:129–137. [CrossRef]
  • [50] Saha BB, El-Sharkawy II, Chakraborty A, Koyama S. Study on an activated carbon fiber–ethanol adsorption chiller: Part I - system description and modelling. Int J Refrigeration 2007;30:86–95. [CrossRef]
  • [51] Banker ND, Dutta P, Prasad M, Srinivasan K. Performance studies on mechanical-adsorption combined compression refrigeration cycles with HFC 134a. Int J Refrigeration 2008;31:1398–1406. [CrossRef]
  • [52] Skander J, Shigeru K, Bidyut BS. Performance Investigation of a novel CO2 compression-adsorption based combined cooling cycle. Eng Sci Rep Kyushu Univ 2010;32:12–18.
  • [53] Salvatore V, Valeria P, Davide LR, Walter M. Adsorption-compression cascade cycles: An experimental study. Energy Conver Manage 2018;156:365–375. [CrossRef]
  • [54] Brian KS, Douglas ML. Examination of the performance of a compression-driven adsorption cooling cycle. Appl Therm Engineer 1999;19:1–0. [CrossRef]
  • [55] Syed MA, Anutosh C, Kai CL. CO2-assisted compression-adsorption combined for cooling and desalination. Energy Conver Manage 2017;143:538–552. [CrossRef]
  • [56] Meunier F. Second law analysis of a solid adsorption heat pump operating on reversible cascade cycles: Application to the zeolite–water pair. Heat Recov Sys 1985;5:133–141. [CrossRef]
  • [57] Akahira A, Alam KCA, Hamamoto Y, Akisawa A, Kashiwagi T. Mass recovery four-bed adsorption refrigeration cycle with energy cascading. Appl Therm Engineer 2005;25:1764–1768. [CrossRef]
  • [58] Deshdeep G, Ahmad FS, Akhilesh A, Ashwni. Parametric optimization of blowdown operated double-effect vapour absorption refrigeration system. J Therm Engineer 2022;8:78–89. [CrossRef]
  • [59] Touaibi R, Hasan K, Boudjema F, Selmane S, Hemis M. Energy and exergy analysis of a combined system: Cascade organic Rankine cycle and cascade refrigeration cycle. J Therm Engineer 2021;7:1139–1149. [CrossRef]
  • [60] Saha BB, El-Sharkawy II, Chakraborty A, Koyama S. Study on an activated carbon fiber–ethanol adsorption chiller: Part I - system description and modelling. Int J Refrigeration 2007;30:86–95. [CrossRef]
  • [61] Saha BB, El-Sharkawy II, Chakraborty A, Koyama S. Study on an activated carbon fiber-ethanol adsorption chiller: Part II - performance evaluation. Int J Refrigeration 2007;30:96–102. [CrossRef]
  • [62] Chua HT, Ng KC, Malek A, Kashiwagi T, Akisawa BB, Saha. Modeling the performance of two-bed, silica gel-water adsorption chillers. Int J Refrigeration 1999;22:194–204. [CrossRef]
  • [63] Balghouthi M, Chahbani MH, Guizani A. Feasibility of solar absorption air conditioning in Tunisia. Build Environ 2008;43:1459–1470. [CrossRef]
  • [64] Almohammadi KM, Harby K. Operational conditions optimization of a proposed solar-powered adsorption cooling system: Experimental, modeling, and optimization algorithm techniques. Energy 2020;206:118007. [CrossRef]
  • [65] Herold KE, Radermacher R, Klein SA. Absorption Chillers and Heat Pumps. Florida: CRC Press; 2016. [CrossRef]
  • [66] Kaynakli O, Kilic M. Theoretical study on the effect of operating conditions on performance of absorption refrigeration system. Energy Conver Manage 2007;48:599–607. [CrossRef]
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  • [68] Gonzales-Gil A, Izquierdo M, Marcos JD, Palacios E. Experimental evaluation of a direct air-cooled lithium bromide-water absorption prototype for solar air conditioning. Appl Therm Engineer 2011;31:3358–3368. [CrossRef]
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Performance analysis of a new combined absorption-adsorption refrigeration system to improve energy performance

Year 2024, Volume: 10 Issue: 3, 722 - 736, 21.05.2024

Abstract

In this study, a new cascaded absorption-adsorption refrigeration cycle (ABS-ADS) is investigated under a variety of various operating conditions. Combined both absorption and adsorption refrigeration cycles can increase the overall energy performance. The condenser of the ABS cycle is cooled down by the evaporator of the ADS cycle. In this way, low-temperature cooling at low-grade heat source temperatures may be provided, and the benefit of each cycle can be utilized. Additionally, a comparison is also made between the performance of the proposed ABS-ADS and that of the standalone ABS and ADS cycles, as well as with other studies taken from the literature. Results demonstrated that, at heat source temperatures of 75oC, the cooling capacity of the proposed cascade ABS-ADS (25.5 kW) is greater than that of ABS and ADS by 16.8 and 177% with 0.644, 0.69, and 0.36 systems COP, respectively. In addition, it is superior to that of the ABS and ADS by 8.39% and 44%, respectively. The influence of mass flowrate of the heat source is high in the range lower than 1.0 kg/s; however, when the mass flowrate is more than 1.0 kg/s, the impact on the cooling effect and the COP is only marginal. When the flow rate of the solution pump is increased from 0.06 to 0.16 kg/s, the cooling capacity grows linearly from 16 to 44 kW, and the COP increases from 0.61 to 0.63. Increasing the temperature of the chilled water from 8 to 16oC raises the cooling capacity linearly from 20.6-36 kW and the COP from 0.58 to 0.622. In conclusion, the performance of the suggested cascade ABS-ADS cycle can operate effectively at low-grade heat sources and produce good thermal performance in comparison to other former studies.

References

  • [1] EIA. EIA projects 28% increase in world energy use by 2040. Available at: https://www.eia.gov/todayinenergy/detail.php?id=32912. Accessed May 8, 2024.
  • [2] Naukkarinen P. Solar air conditioning and its role in alleviating the energy crisis of the Mediterranean hotels. Int J Sustain Energy 2009;28:93–100. [CrossRef]
  • [3] Harby K, Fahad A. An investigation of energy savings in a split air-conditioner using commercial cooling pads with different thicknesses and wide range of climatic conditions. Energy 2019;182:321–336. [CrossRef]
  • [4] Ziegler F. Recent developments and future prospects of sorption heat pump systems. Int J Therm Sci 1999;38:191–208. [CrossRef]
  • [5] Perez-Blanco H. Absorption heat pump performance for different types of solutions. Int J Refrigeration 1984;7:115–122. [CrossRef]
  • [6] Ali A, Zamri N, Ahmed A. Solar absorption cooling systems: A review. J Therm Engineer 2021;7:970–983. [CrossRef]
  • [7] Harby K, Ehab SA, Almohammadi KM. A novel combined reverse osmosis and hybrid absorption desalination-cooling system to increase overall water recovery and energy efficiency. J Clean Prod 2021;287:125014. [CrossRef]
  • [8] Stephan K. History of absorption heat pumps and working pair developments in Europe. Int J Refrigeration 1983;6:160–166. [CrossRef]
  • [9] Sumathy K, Yeung KH, Yong L. Technology development in the solar adsorption refrigeration systems. Prog Energy Combust Sci 2003;29:301–327. [CrossRef]
  • [10] Wang R, Wang L. Adsorption refrigeration-green cooling driven by low grade thermal energy. Chin Sci Bull 1993;50:204. [CrossRef]
  • [11] Ziegler F. State of the art in sorption heat pumping and cooling technologies. Int J Refrigeration 2002;25:450–459. [CrossRef]
  • [12] Sun J, Fu L, Zhang S. A review of working fluids of absorption cycles. Renew Sustain Energy Rev 2012;16:1899–1906. [CrossRef]
  • [13] Jawahar C, Saravanan R. Generator absorber heat exchange-based absorption cycle-a review. Renew Sustain Energy Rev 2010;14:2372–2382. [CrossRef]
  • [14] Alka S, Yash P. Evaluation and optimization of single-effect vapour absorption system for the dairy industry using design of experiment approach. J Therm Engineer 2022;8:619–631. [CrossRef]
  • [15] Kamel A, Khalil KMS, Askalany A, Ali ES, Harby K, Ghazy M. Improving adsorption materials properties for renewable energy-driven cooling systems, Therm Sci Engineer Prog 2024;50:102551. [CrossRef]
  • [16] Ibarra-Bahena J, Romero RJ. Performance of different experimental absorber designs in absorption heat pump cycle technologies: A review. Energies 2014;7:751–766. [CrossRef]
  • [17] Wang X, Chua HT. Absorption cooling: a review of lithium bromide-water chiller technologies. Recent Pat Mech Engineer 2009;2:193–213. [CrossRef]
  • [18] Zhai X, Qu M, Li Y, Wang R. A review for research and new design options of solar absorption cooling systems. Renew Sustain Energy Rev 2011;15:4416–4423. [CrossRef]
  • [19] Siddiqui M, Said S. A review of solar powered absorption systems. Renew Sustain Energy Rev 2015;42:93–115. [CrossRef]
  • [20] Wang X, Bierwirth A, Christ A, Whittaker P, Regenauer-Lieb K, Chua HT. Application of geothermal absorption air-conditioning system: A case study. Appl Therm Engineer 2013;50:71–80. [CrossRef]
  • [21] Tugcu A, Arslan O. Optimization of geothermal energy aided absorption refrigeration system-GAARS: A novel ANN-based approach. Geothermics 2017;65:210–221. [CrossRef]
  • [22] Seyfouri Z, Ameri M. Analysis of integrated compression–absorption refrigeration systems powered by a microturbine. Int J Refrig 2012;35:1639–1646. [CrossRef]
  • [23] Bruno JC, Ortega-López V, Coronas A. Integration of absorption cooling systems into micro gas turbine trigeneration systems using biogas: case study of a sewage treatment plant. Appl Energy 2009;86:837–847. [CrossRef]
  • [24] Sira S, Somchai W. A critical review of recent investigations on two-phase pressure drop in flow boiling micro-channels. Front Heat Mass Transf 2012;3:013007. [CrossRef]
  • [25] Awad M, Dalkılıç AS, Wongwises S. A critical review on condensation heat transfer in microchannels and minichannels. J Nanotechnol Engineer Med 2014;5:0108011. [CrossRef]
  • [26] Alican Ç, Ali C, Aydın H, Yakup K, Pınar C, Mehmet SC, et al. A review of flow boiling in mini and microchannel for enhanced geometries. J Therm Engineer 2018;4:2037–2074. [CrossRef]
  • [27] Boer D, Valles M, Coronas A. Performance of double effect absorption compression cycles for air-conditioning using methanol-TEGDME and TFE-TEGDME systems as working pairs. Int J Refrig 1998;21:542–555. [CrossRef]
  • [28] Kim JS, Ziegler F, Lee H. Simulation of the compressor-assisted triple-effect H2O/LiBr absorption cooling cycles. Appl Therm Engineer 2002;22:295–308. [CrossRef]
  • [29] Medrano M, Bourouis M, Coronas A. Double-lift absorption refrigeration cycles driven by low-temperature heat sources using organic fluid mixtures as working pairs. Appl Energy 2001;68:173–185. [CrossRef]
  • [30] Izquierdo M, Venegas M, García N, Palacios E. Exergetic analysis of a double stage LiBr-H2O thermal compressor cooled by air/water and driven by low grade heat. Energy Conver Manage 2005;46:1029–1042. [CrossRef]
  • [31] Ahmet SD. Parametric study of energy, exergy, and thermoeconomic analyses on vapor compression system cascaded with LiBr/Water and NH3/Water absorption cascade refrigeration cycle. Anadolu Univ J Sci Technol A - Appl Sci Engineer 2017;18:78–96. [CrossRef]
  • [32] Kairouani L, Nehdi E. Cooling performance and energy saving of a compression-absorption refrigeration system assisted by geothermal energy. Appl Therm Engineer 2006;26:288–294. [CrossRef]
  • [33] Seyfouri Z, Ameri M. Analysis of integrated compression–absorption refrigeration systems powered by a microturbine. Int J Refrig 2012;35:1639–1646. [CrossRef]
  • [34] Fernández-Seara J, Sieres J, Vázquez M. Compression-absorption cascade refrigeration system. Appl Therm Engineer 2005;26:502–512. [CrossRef]
  • [35] Jain V, Sachdeva G, Singh Kachhwaha S, Patel B. Thermo-economic and environmental analyses based multi-objective optimization of vapor compression-absorption cascaded refrigeration system using NSGA-II technique. Energy Conver Manage 2016;113:230–242. [CrossRef]
  • [36] Cimsit C, Ozturk IT, Kincay O. Thermoeconomic optimization of LiBr/H2O-R134a compression-absorption cascade refrigeration cycle. Appl Therm Engineer 2015;76:105–115. [CrossRef]
  • [37] Ehab SA, Ahmed AA, Harby K, Mohamed RD, Bahgat RM, Ahmed A. Experimental adsorption water desalination system utilizing activated clay for low grade heat source applications. J Energy Storage 2021;43:103219. [CrossRef]
  • [38] Verde M, Harby K, Robert B, Corberán JM. Performance evaluation of a waste-heat driven adsorption system for automotive air-conditioning: Part I- Modeling and experimental validation. Energy 2016;116:526–538. [CrossRef]
  • [39] Verde M, Harby K, Robert B, Corberán JM. Performance evaluation of a waste-heat driven adsorption system for automotive air-conditioning: Part II- performance optimization under different real driving conditions. Energy 2016;115:996–1009. [CrossRef]
  • [40] Maggio G, Freni A, Restuccia G. A dynamic model of heat and mass transfer in a double-bed adsorption machine with internal heat recovery. Int J Refrig 2006;29:589–600. [CrossRef]
  • [41] Restuccia G, Freni A, Maggio G. A zeolite-coated bed for air conditioning adsorption systems: parametric study of heat and mass transfer by dynamic simulation. Appl Therm Engineer 2002;22:619–630. [CrossRef]
  • [42] Mohamed G, Askalany A, Harby K, Ahmed MS. Adsorption isotherms and kinetics of HFC-404A onto bituminous based granular activated carbon for storage and cooling applications. Appl Therm Engineer 2016;105:639–645. [CrossRef]
  • [43] Ahmed S, Ahmed A, Harby K, Mahmoud S. Performance evaluation of a solar driven adsorption desalination cooling system. Energy 2017;128:196–207. [CrossRef]
  • [44] Zhang LZ, Wang L. Performance estimation of an adsorption cooling system for automobile waste heat recovery. Appl Therm Engineer 1997;17:1127–1139. [CrossRef]
  • [45] Alam K, Saha B, Kang Y, Akisawa A, Kashiwagi T. Heat design effect on the performance of silica gel adsorption refrigeration systems. Int J Heat Mass Transf 2000;43:4419–4431. [CrossRef]
  • [46] Tamainot-Telto Z, Metcalf SJ, Critoph RE. Novel compact sorption generators for car air conditioning. Int J Refrig 2009;32:727–733. [CrossRef]
  • [47] Liu Y, Leong KC. Numerical study of a novel cascading adsorption cycle. Int J Refrig 2006;29:250–259. [CrossRef]
  • [48] Meunier F. Theoretical performances of solid adsorbent cascading cycles using the zeolite-water and active carbon-methanol pairs: four case studies. Heat Recov Sys 1986;6:491–498. [CrossRef]
  • [49] Khairul H, Bidyut BS, Anutosh C, Shigeru K, Kandadai S. Performance evaluation of combined adsorption refrigeration cycles. Int J Refrigeration 2011;34:129–137. [CrossRef]
  • [50] Saha BB, El-Sharkawy II, Chakraborty A, Koyama S. Study on an activated carbon fiber–ethanol adsorption chiller: Part I - system description and modelling. Int J Refrigeration 2007;30:86–95. [CrossRef]
  • [51] Banker ND, Dutta P, Prasad M, Srinivasan K. Performance studies on mechanical-adsorption combined compression refrigeration cycles with HFC 134a. Int J Refrigeration 2008;31:1398–1406. [CrossRef]
  • [52] Skander J, Shigeru K, Bidyut BS. Performance Investigation of a novel CO2 compression-adsorption based combined cooling cycle. Eng Sci Rep Kyushu Univ 2010;32:12–18.
  • [53] Salvatore V, Valeria P, Davide LR, Walter M. Adsorption-compression cascade cycles: An experimental study. Energy Conver Manage 2018;156:365–375. [CrossRef]
  • [54] Brian KS, Douglas ML. Examination of the performance of a compression-driven adsorption cooling cycle. Appl Therm Engineer 1999;19:1–0. [CrossRef]
  • [55] Syed MA, Anutosh C, Kai CL. CO2-assisted compression-adsorption combined for cooling and desalination. Energy Conver Manage 2017;143:538–552. [CrossRef]
  • [56] Meunier F. Second law analysis of a solid adsorption heat pump operating on reversible cascade cycles: Application to the zeolite–water pair. Heat Recov Sys 1985;5:133–141. [CrossRef]
  • [57] Akahira A, Alam KCA, Hamamoto Y, Akisawa A, Kashiwagi T. Mass recovery four-bed adsorption refrigeration cycle with energy cascading. Appl Therm Engineer 2005;25:1764–1768. [CrossRef]
  • [58] Deshdeep G, Ahmad FS, Akhilesh A, Ashwni. Parametric optimization of blowdown operated double-effect vapour absorption refrigeration system. J Therm Engineer 2022;8:78–89. [CrossRef]
  • [59] Touaibi R, Hasan K, Boudjema F, Selmane S, Hemis M. Energy and exergy analysis of a combined system: Cascade organic Rankine cycle and cascade refrigeration cycle. J Therm Engineer 2021;7:1139–1149. [CrossRef]
  • [60] Saha BB, El-Sharkawy II, Chakraborty A, Koyama S. Study on an activated carbon fiber–ethanol adsorption chiller: Part I - system description and modelling. Int J Refrigeration 2007;30:86–95. [CrossRef]
  • [61] Saha BB, El-Sharkawy II, Chakraborty A, Koyama S. Study on an activated carbon fiber-ethanol adsorption chiller: Part II - performance evaluation. Int J Refrigeration 2007;30:96–102. [CrossRef]
  • [62] Chua HT, Ng KC, Malek A, Kashiwagi T, Akisawa BB, Saha. Modeling the performance of two-bed, silica gel-water adsorption chillers. Int J Refrigeration 1999;22:194–204. [CrossRef]
  • [63] Balghouthi M, Chahbani MH, Guizani A. Feasibility of solar absorption air conditioning in Tunisia. Build Environ 2008;43:1459–1470. [CrossRef]
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There are 72 citations in total.

Details

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

Majdi T. Amin This is me 0000-0002-3783-4856

Publication Date May 21, 2024
Submission Date March 1, 2023
Published in Issue Year 2024 Volume: 10 Issue: 3

Cite

APA Amin, M. T. (2024). Performance analysis of a new combined absorption-adsorption refrigeration system to improve energy performance. Journal of Thermal Engineering, 10(3), 722-736.
AMA Amin MT. Performance analysis of a new combined absorption-adsorption refrigeration system to improve energy performance. Journal of Thermal Engineering. May 2024;10(3):722-736.
Chicago Amin, Majdi T. “Performance Analysis of a New Combined Absorption-Adsorption Refrigeration System to Improve Energy Performance”. Journal of Thermal Engineering 10, no. 3 (May 2024): 722-36.
EndNote Amin MT (May 1, 2024) Performance analysis of a new combined absorption-adsorption refrigeration system to improve energy performance. Journal of Thermal Engineering 10 3 722–736.
IEEE M. T. Amin, “Performance analysis of a new combined absorption-adsorption refrigeration system to improve energy performance”, Journal of Thermal Engineering, vol. 10, no. 3, pp. 722–736, 2024.
ISNAD Amin, Majdi T. “Performance Analysis of a New Combined Absorption-Adsorption Refrigeration System to Improve Energy Performance”. Journal of Thermal Engineering 10/3 (May 2024), 722-736.
JAMA Amin MT. Performance analysis of a new combined absorption-adsorption refrigeration system to improve energy performance. Journal of Thermal Engineering. 2024;10:722–736.
MLA Amin, Majdi T. “Performance Analysis of a New Combined Absorption-Adsorption Refrigeration System to Improve Energy Performance”. Journal of Thermal Engineering, vol. 10, no. 3, 2024, pp. 722-36.
Vancouver Amin MT. Performance analysis of a new combined absorption-adsorption refrigeration system to improve energy performance. Journal of Thermal Engineering. 2024;10(3):722-36.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering