Performance analysis of solar assisted multigenerational system using therminol VP1 based nanofluids: A comparative study

Sajid, Muhammad; Amber, Khuram Pervez; Ali, Hafız Muhammad; Abid, Muhammad; Ratlamwala, A H Tahir; Javed, Samina

doi:10.2298/tsci180608062k

Cited by 15 publications

(6 citation statements)

References 34 publications

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“…Many researchers have studied the use of nanofluid as a working fluid in solar cooling systems and several studies [31], [32] show that nanofluid can improve the efficiency of solar collectors. Salem et al [33] and Ande et al [34] studied the behavior of an air conditioning chiller working with water-Al2O3 nanofluid and they observed that less time was taken to obtain desired cooling temperature and also that there was a significant improvement in COP. Colangelo et al [36] and Milanese et al [37], [38] studied the use of nanofluid in solar thermal collectors.…”

Section: Nanofluids As Heat Transfer Fluids In Heating/cooling Systemmentioning

confidence: 99%

Assessment of a desiccant cooling system in a traditional and innovative nanofluid HVAC system

Colangelo

Raho

Milanese

et al. 2022

J. Phys.: Conf. Ser.

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The topic of energy saving is a constant in everyday life, and it is widespread all over the world. Space heating using solar panels is the most used renewable source of energy, but the application of solar energy for cooling the fluids used for refrigeration is growing very fast. Among the techniques used for refrigeration, this work focused on Desiccant Cooling. In particular, with the use of dynamic simulation software, it was possible to study the heat supplied and the energy consumption of a Heating Ventilation Air Conditioning (HVAC) system of a university building and to compare consumption with those of a Desiccant Cooling system applied to the same building. Four different cases were simulated: two related to the HVAC system, one of which operates with water and glycol and the other one with nanofluid, and the other ones to the Desiccant Cooling system with both types of fluids mentioned above. Keeping the same energy demand of the building in all the simulations, it was found that in summer the Desiccant Cooling system had higher performance than the traditional HVAC system and that the use of the nanofluid in both types of conditioning systems further increased the performance of 21%. Simulations were carried out using TRNSYS software.

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Section: Nanofluids As Heat Transfer Fluids In Heating/cooling Systemmentioning

confidence: 99%

Assessment of a desiccant cooling system in a traditional and innovative nanofluid HVAC system

Colangelo

Raho

Milanese

et al. 2022

J. Phys.: Conf. Ser.

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“…Density of hybrid nanofluids is an important parameter that influences the friction factor, pressure drop and Reynolds number of the fluid and it has inverse relation to the volumetric concentration. 60 The specific heat capacity of nanofluids is given by:…”

Section: Heat Transfer Analysismentioning

confidence: 99%

Thermal and thermodynamic comparison of smooth and convergent‐divergent parabolic trough absorber tubes with the application of mono and hybrid nanofluids

et al. 2020

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Summary The utilization of hybrid nanofluids is a promising technique in the high temperature solar applications specially, parabolic trough collector (PTC). The purpose of the current research is to analyze, evaluate and compare the performance of PTC (converging‐diverging absorber tube) using mono and hybrid nanofluids to increase the convective heat transfer coefficient. To obtain this objective, converging‐diverging tube with sine geometry is examined as it enhances the turbulence in the flow due to increase in the inner surface roughness. The performance of the absorber tube is assessed for hybrid nanofluid (1.5% MWCNTs/therminol‐VPI and 1.5% TiO2/therminol‐VPI) as well as mono nanofluids (3% MWCNTs and 3% TiO2)/therminol‐VPI at a wide range of inlet temperature ranges from 350 K to 600 K. In order to compare the results of the converging‐diverging tube, a smooth absorber tube is also investigated at the same design conditions. Furthermore, our study comprises of the overall performance investigation about the exergy analysis, pressure drop, pumping power required and performance evaluation criteria to investigate the comprehensive performance of the absorber tubes. The results of the study reveal that the use of modified geometry with hybrid nanofluids considerably improves the performance of the system due to the presence of swirls and turbulence that will reduce absorber surface temperature and ultimately the heat losses. More specifically, the thermal efficiency enhancement for the converging‐diverging absorber tube with hybrid nanofluids ranges from 3.61% to 5.27%, while it is varied from 1.70% to 1.91% for smooth tube using hybrid nanofluids. Reynolds number ranges from 12 000 to 90 300 for hybrid nanofluid, while it is from 14 000 to 97 600 for pure therminol‐VPI. Furthermore, mean enhancement in the heat transfer coefficient using converging‐diverging tube with hybrid, TiO2 and MWCNTs therminol‐VPI‐based nanofluids are 1.72%, 0.67% and 0.70%, respectively at a mass flow rate of 0.6 kg/s and an ambient temperature of 300 K. The converging‐diverging/hybrid case has the values of 1.47 and 1.33 for performance evaluation criteria I and II, while all other cases has significantly less values compared to hybrid nanofluids. The thermal efficiency enhancement has a pressure‐drop penalty that leads to higher pumping power requirement; however, this requirement is very small as compared to the useful energy gain.

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“…The volume fraction rising led to a reduction in the optimal Reynolds number. Khan et al [17] studied the effect of applying nanofluids in a solar-based cycle from an energy, exergy, and exergo-environmental point of view. The influence of three nanofluids, including Fe2O3/Therminol VP1, SiO2/Therminol VP1, and Cu/Therminol VP1, were compared by considering different parameters.…”

Section: Introductionmentioning

confidence: 99%

Thermodynamic Modeling and Analysis of a Solar and Geothermal-driven Multigeneration System Using TiO2 and SiO2 Nanoparticles

Habibzadeh

Abbasalizadeh

Mirzaee

et al. 2023

IJEE

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Performance analysis of solar assisted multigenerational system using therminol VP1 based nanofluids: A comparative study

Cited by 15 publications

References 34 publications

Assessment of a desiccant cooling system in a traditional and innovative nanofluid HVAC system

Assessment of a desiccant cooling system in a traditional and innovative nanofluid HVAC system

Thermal and thermodynamic comparison of smooth and convergent‐divergent parabolic trough absorber tubes with the application of mono and hybrid nanofluids

Thermodynamic Modeling and Analysis of a Solar and Geothermal-driven Multigeneration System Using TiO2 and SiO2 Nanoparticles

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