Experimental investigations of a small‐scale solar‐assisted absorption cooling system

Qadeer, Adil; Hussain, Shafqat; Ali, Muzaffar; Khan, M. Arafat H.

doi:10.1002/htj.22000

Cited by 2 publications

(1 citation statement)

References 16 publications

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“…12 One of the most common heat sources used to drive an AC is solar energy. Qadeer et al 13 presented a solar AC having a capacity of 3.5 kW driven by a flat tube collector. The setup achieved a maximum COP of 0.7 when the fluid flow rate was 0.05 kg/s in the desorber.…”

Section: Introductionmentioning

confidence: 99%

A novel hybrid cooling system combining vortex tube with absorption cooler

Mugdadi

Al‐Nimr

2022

Intl J of Energy Research

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In this study, a novel cooling system that combines a vortex tube with an absorption cooler is presented. The system produces cooling effects from both devices. The compressed air enters the vortex tube to produce a cooling effect, and the hot air escaped from the vortex tube is used to drive the absorption cooler. The theoretical model has been built and employed to study the performance of the hybrid cooling system, in terms of the specific cooling load and the coefficient of performance, under the effect of different parameters (feed air pressure, feed air temperature, and cold/hot mass fractions). Further, the hybrid system performance is compared to the performance of the vortex tube alone. The results showed that the cooling capacity of the system increases with an increase of both the feed air temperature and the feed air pressure. The maximum coefficient of performance of the system under current design points is 29.3% greater than the maximum coefficient of performance of the standalone vortex tube.

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Section: Introductionmentioning

confidence: 99%

A novel hybrid cooling system combining vortex tube with absorption cooler

Mugdadi

Al‐Nimr

2022

Intl J of Energy Research

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Performance Evaluation and Optimal Design Analysis of Continuous-Operation Solar-Driven Cooling Absorption Systems With Thermal Energy Storage

Patiño-Jaramillo,

Rivera-Alvarez,

Osorio

2023

Journal of Thermal Science and Engineering Applications

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A solar absorption cooling system consisting in a flat plate collector, thermal energy storage tank, and absorption chiller is analyzed in this work. A dimensionless model is developed and used to determine the influence of different parameters such as tank size, solar collector area, chiller size, cooling load, cooling temperature, heat loss, and mass flow rates on the performance. From the analysis, smaller solar collector areas are required for lower cooling loads and smaller tank volumes. A specific cooling load of 1E-5 will require a specific solar collector area between two to six times larger, depending on the initial tank temperature, than the area required for a baseline system that considers typical commercial design and operation parameters. A similar behavior was observed for the specific tank volume. For the baseline system, the minimum specific area of the collector of 9.57 is achieved for an initial tank temperature of 1.19. For a cooling load of 1E-5, the optimum initial tank temperature will be 1.11 that results in a minimum specific solar collector area of 25.26. A specific tank volume of 4E-1 will also have an optimum initial tank temperature of 1.11 that minimizes the specific solar collector area to a value of 28.18. The approach and analysis in this work can be used to determine design parameters for solar absorption cooling systems based on a proper relation among system's dimensions to achieve optimum operation.

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Experimental investigations of a small‐scale solar‐assisted absorption cooling system

Cited by 2 publications

References 16 publications

A novel hybrid cooling system combining vortex tube with absorption cooler

A novel hybrid cooling system combining vortex tube with absorption cooler

Performance Evaluation and Optimal Design Analysis of Continuous-Operation Solar-Driven Cooling Absorption Systems With Thermal Energy Storage

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