Research Article
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Year 2024, Volume: 10 Issue: 5, 1292 - 1305, 10.09.2024

Abstract

References

  • [1] Raitila J, Tsupari E. Feasibility of solar-enhanced drying of woody biomass. Bioenerg Res 2019;13:210–221. [CrossRef]
  • [2] Chemkhi S, Zagrouba F, Bellagi A. Drying of agricultural crops by solar energy. Desalination 2004;168:101–109. [CrossRef]
  • [3] Jamali B, Rasekh M, Jamadi F, Gandomkar R, Makiabadi F. Using PSO-GA algorithm for training artificial neural network to forecast solar space heating system parameters. Appl Therm Engineer 2019;147:647–660. [CrossRef]
  • [4] Taslim ME, Li T, Kercher DM. Experimental heat transfer and friction in channels roughened with angled, V-shaped, and discrete ribs on two opposite walls. ASME J Turbomach 1996;118:20–28. [CrossRef]
  • [5] Thianpong C, Chompookham T, Skullong S, Promvonge P. Thermal characterization of turbulent flow in a channel with isosceles triangular ribs. Int Comm Heat Mass Transf 2009;36:712–717. [CrossRef]
  • [6] Nidhul K, Yadav AK, Anish S, Kumar S. Critical review of ribbed solar air heater and performance evaluation of various V-rib configuration. Renew Sustain Energy Rev 2021;142:110871. [CrossRef]
  • [7] Bezbaruah PJ, Das RS, Sarkar BK. Experimental and numerical analysis of solar air heater accoutered with modified conical vortex generators in a staggered fashion. Renew Energy 2021;180:109–131. [CrossRef]
  • [8] Mushatet K, Nashee S. Experimental and computational investigation for 3-D duct flow with modified arrangement ribs turbulators. Therm Sci 2021;25:1653–1663. [CrossRef]
  • [9] Nashee SR, Mushatet KS. 3D numerical and experimental analysis for turbulent flow and heat transfer in a duct integrated with ribs turbulators. TEST Engineer Manage 2020;83:21810–21821.
  • [10] Mushatet KS, Edan IL. Effect of winglet vortex generators orientation on heat transfer enhancement. Int J Mech Mechatron Engineer 2018;18:8–24.
  • [11] Kumar A, Layek A. Evaluation of the performance analysis of an improved solar air heater with Winglet shaped ribs. Exp Heat Transf 2022;35:239–257. [CrossRef]
  • [12] Rajendran V, Singaraj K, Rajarathinam J. Environmental, economic, and performance assessment of solar air heater with inclined and winglet baffle. Environ Sci Pollut Res Int 2023;30:14337–14352. [CrossRef]
  • [13] Bader NM, Mushatet KS. Thermal performance improvement of artificially roughened solar air heater. Engineer Rev 2022;43:66–81. [CrossRef]
  • [14] Mushatet KS, Bader NM. Experimental investigation for the performance of the solar air dryer with vortex generator. Defect Diffus Forum 2022;419:57–67. [CrossRef]
  • [15] Hajabdollahi H. Thermoeconomic assessment of integrated solar flat plate collector with cross flow heat exchanger as solar air heater using numerical analysis. Renew Energy 2021;168:491–504. [CrossRef]
  • [16] Chamoli S, Lu R, Xu D, Yu P. Thermal performance improvement of a solar air heater fitted with winglet vortex generators. Sol Energy 2018;159:966–983. [CrossRef]
  • [17] Zhao Z, Luo L, Qiu D, Wang Z, Sunden B. On the solar air heater thermal enhancement and flow topology using differently shaped ribs combined with delta-winglet vortex generators. Energy 2021;224:119944. [CrossRef]
  • [18] Rout SK, Mishra DP, Thatoi DN, Acharya AK. Numerical analysis of mixed convection through an internally finned tube. Adv Mech Engineer 2012;4:918342. [CrossRef]
  • [19] Rout SK, Thatoi DN, Acharya AK, Mishra DP. CFD supported performance estimation of an internally finned tube heat exchanger under mixed convection flow. Procedia Engineer 2012;38:585–597. [CrossRef]
  • [20] Rout SK, Pulagam MKR, Sarangi SK. Prospect of a fully solar energy-driven compact cold store for low income farming communities. In: Ramgopal M, Rout SK, Sarangi SK, eds. Advances Air Conditioning and Refrigeration Singapore: Springer; 2021. pp. 13–21. [CrossRef]
  • [21] Rout SK, Mohapatra T, Mohanty CP, Mishra P. Experimental investigation of thermal performance of solar air heater having hemispherical fins on absorber plates. In: Ramgopal M, Rout SK, Sarangi SK, editors. Advances Air Conditioning and Refrigeration Singapore: Springer; 2021. pp. 337–343. [CrossRef]
  • [22] Hannun RM, Hamoud MA. Comparison study for the utilization of solar power with different positions lie in Iraq and on the equator and northern region. Thesis, University of Thi-Qar, Iraq; 2021.
  • [23] Ekechukwu O, Norton B. Review of solar-energy drying systems II: An overview solar drying technology. Energy Conver Manage 1999;40:615–655. [CrossRef]
  • [24] Joudi KA. Some aspects of solar irradiance calculations. In: Proceedings of the 3rd Arab International Solar Energy Conference; Feb 1988; Baghdad.
  • [25] Ekechukwu OV, Norton B. Review of solar-energy drying systems III: Low temperature air-heating solar collectors for crop drying applications. Energy Conver Manage 1999;40:657–667. [CrossRef]
  • [26] Ebrahim MA, Saini JS, Solanki SC. Heat transfer and friction in solar air heater duct with V-shaped rib roughness on absorber plate. Int J Heat Mass Transf 2002;45:3383–3396. [CrossRef]
  • [27] Sivakandhan C, Arjunan TV, Matheswaran MM. Thermohydraulic performance enhancement of a new hybrid duct solar air heater with inclined rib roughness. Renew Energy 2020;147:2345–2357. [CrossRef]

An experimental study for a single-pass solar air heater integrated with artificial roughness

Year 2024, Volume: 10 Issue: 5, 1292 - 1305, 10.09.2024

Abstract

The utilization of solar air heaters are significant due to its capacity to diminish the reliance on fossil fuel-based power usage, hence mitigating pollution and conserving energy. The thermal-performance of a solar heater was analyzed using experimental simulations. Different types of artificial roughness, such as delta-winglet-vortex generators, ribs, or a combination of ribs and delta-winglet, were tested in a single-pass solar air heater. The objective of this study is to identify the optimal design that maximizes the thermal efficiency of a solar air heater. The relative roughness height-ratio remains constant at 0.6, although the pitch ratio is fixed at 10 and various attack angles are used. The experimental investigation was conducted within a range of Reynolds numbers (5000-14000). The usual levels of irradiance varied as 330 W/m2 - 850 W/m2. Based on the results, the average bulk temperature of the roughened solar air heater was 37% greater than that of a smooth SAH under peak sun irradiation. The inclined ribs at a 60° angle exhibited superior thermal efficiency compared to the other instances. These ribs covered a greater surface area and greatly enhanced the convective heat-transfer rate.

References

  • [1] Raitila J, Tsupari E. Feasibility of solar-enhanced drying of woody biomass. Bioenerg Res 2019;13:210–221. [CrossRef]
  • [2] Chemkhi S, Zagrouba F, Bellagi A. Drying of agricultural crops by solar energy. Desalination 2004;168:101–109. [CrossRef]
  • [3] Jamali B, Rasekh M, Jamadi F, Gandomkar R, Makiabadi F. Using PSO-GA algorithm for training artificial neural network to forecast solar space heating system parameters. Appl Therm Engineer 2019;147:647–660. [CrossRef]
  • [4] Taslim ME, Li T, Kercher DM. Experimental heat transfer and friction in channels roughened with angled, V-shaped, and discrete ribs on two opposite walls. ASME J Turbomach 1996;118:20–28. [CrossRef]
  • [5] Thianpong C, Chompookham T, Skullong S, Promvonge P. Thermal characterization of turbulent flow in a channel with isosceles triangular ribs. Int Comm Heat Mass Transf 2009;36:712–717. [CrossRef]
  • [6] Nidhul K, Yadav AK, Anish S, Kumar S. Critical review of ribbed solar air heater and performance evaluation of various V-rib configuration. Renew Sustain Energy Rev 2021;142:110871. [CrossRef]
  • [7] Bezbaruah PJ, Das RS, Sarkar BK. Experimental and numerical analysis of solar air heater accoutered with modified conical vortex generators in a staggered fashion. Renew Energy 2021;180:109–131. [CrossRef]
  • [8] Mushatet K, Nashee S. Experimental and computational investigation for 3-D duct flow with modified arrangement ribs turbulators. Therm Sci 2021;25:1653–1663. [CrossRef]
  • [9] Nashee SR, Mushatet KS. 3D numerical and experimental analysis for turbulent flow and heat transfer in a duct integrated with ribs turbulators. TEST Engineer Manage 2020;83:21810–21821.
  • [10] Mushatet KS, Edan IL. Effect of winglet vortex generators orientation on heat transfer enhancement. Int J Mech Mechatron Engineer 2018;18:8–24.
  • [11] Kumar A, Layek A. Evaluation of the performance analysis of an improved solar air heater with Winglet shaped ribs. Exp Heat Transf 2022;35:239–257. [CrossRef]
  • [12] Rajendran V, Singaraj K, Rajarathinam J. Environmental, economic, and performance assessment of solar air heater with inclined and winglet baffle. Environ Sci Pollut Res Int 2023;30:14337–14352. [CrossRef]
  • [13] Bader NM, Mushatet KS. Thermal performance improvement of artificially roughened solar air heater. Engineer Rev 2022;43:66–81. [CrossRef]
  • [14] Mushatet KS, Bader NM. Experimental investigation for the performance of the solar air dryer with vortex generator. Defect Diffus Forum 2022;419:57–67. [CrossRef]
  • [15] Hajabdollahi H. Thermoeconomic assessment of integrated solar flat plate collector with cross flow heat exchanger as solar air heater using numerical analysis. Renew Energy 2021;168:491–504. [CrossRef]
  • [16] Chamoli S, Lu R, Xu D, Yu P. Thermal performance improvement of a solar air heater fitted with winglet vortex generators. Sol Energy 2018;159:966–983. [CrossRef]
  • [17] Zhao Z, Luo L, Qiu D, Wang Z, Sunden B. On the solar air heater thermal enhancement and flow topology using differently shaped ribs combined with delta-winglet vortex generators. Energy 2021;224:119944. [CrossRef]
  • [18] Rout SK, Mishra DP, Thatoi DN, Acharya AK. Numerical analysis of mixed convection through an internally finned tube. Adv Mech Engineer 2012;4:918342. [CrossRef]
  • [19] Rout SK, Thatoi DN, Acharya AK, Mishra DP. CFD supported performance estimation of an internally finned tube heat exchanger under mixed convection flow. Procedia Engineer 2012;38:585–597. [CrossRef]
  • [20] Rout SK, Pulagam MKR, Sarangi SK. Prospect of a fully solar energy-driven compact cold store for low income farming communities. In: Ramgopal M, Rout SK, Sarangi SK, eds. Advances Air Conditioning and Refrigeration Singapore: Springer; 2021. pp. 13–21. [CrossRef]
  • [21] Rout SK, Mohapatra T, Mohanty CP, Mishra P. Experimental investigation of thermal performance of solar air heater having hemispherical fins on absorber plates. In: Ramgopal M, Rout SK, Sarangi SK, editors. Advances Air Conditioning and Refrigeration Singapore: Springer; 2021. pp. 337–343. [CrossRef]
  • [22] Hannun RM, Hamoud MA. Comparison study for the utilization of solar power with different positions lie in Iraq and on the equator and northern region. Thesis, University of Thi-Qar, Iraq; 2021.
  • [23] Ekechukwu O, Norton B. Review of solar-energy drying systems II: An overview solar drying technology. Energy Conver Manage 1999;40:615–655. [CrossRef]
  • [24] Joudi KA. Some aspects of solar irradiance calculations. In: Proceedings of the 3rd Arab International Solar Energy Conference; Feb 1988; Baghdad.
  • [25] Ekechukwu OV, Norton B. Review of solar-energy drying systems III: Low temperature air-heating solar collectors for crop drying applications. Energy Conver Manage 1999;40:657–667. [CrossRef]
  • [26] Ebrahim MA, Saini JS, Solanki SC. Heat transfer and friction in solar air heater duct with V-shaped rib roughness on absorber plate. Int J Heat Mass Transf 2002;45:3383–3396. [CrossRef]
  • [27] Sivakandhan C, Arjunan TV, Matheswaran MM. Thermohydraulic performance enhancement of a new hybrid duct solar air heater with inclined rib roughness. Renew Energy 2020;147:2345–2357. [CrossRef]
There are 27 citations in total.

Details

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

Nabaa M. Bader This is me 0009-0004-7755-8472

Khudheyer S. Mushatet This is me 0000-0001-5371-9914

Publication Date September 10, 2024
Submission Date July 28, 2022
Published in Issue Year 2024 Volume: 10 Issue: 5

Cite

APA Bader, N. M., & Mushatet, K. S. (2024). An experimental study for a single-pass solar air heater integrated with artificial roughness. Journal of Thermal Engineering, 10(5), 1292-1305.
AMA Bader NM, Mushatet KS. An experimental study for a single-pass solar air heater integrated with artificial roughness. Journal of Thermal Engineering. September 2024;10(5):1292-1305.
Chicago Bader, Nabaa M., and Khudheyer S. Mushatet. “An Experimental Study for a Single-Pass Solar Air Heater Integrated With Artificial Roughness”. Journal of Thermal Engineering 10, no. 5 (September 2024): 1292-1305.
EndNote Bader NM, Mushatet KS (September 1, 2024) An experimental study for a single-pass solar air heater integrated with artificial roughness. Journal of Thermal Engineering 10 5 1292–1305.
IEEE N. M. Bader and K. S. Mushatet, “An experimental study for a single-pass solar air heater integrated with artificial roughness”, Journal of Thermal Engineering, vol. 10, no. 5, pp. 1292–1305, 2024.
ISNAD Bader, Nabaa M. - Mushatet, Khudheyer S. “An Experimental Study for a Single-Pass Solar Air Heater Integrated With Artificial Roughness”. Journal of Thermal Engineering 10/5 (September 2024), 1292-1305.
JAMA Bader NM, Mushatet KS. An experimental study for a single-pass solar air heater integrated with artificial roughness. Journal of Thermal Engineering. 2024;10:1292–1305.
MLA Bader, Nabaa M. and Khudheyer S. Mushatet. “An Experimental Study for a Single-Pass Solar Air Heater Integrated With Artificial Roughness”. Journal of Thermal Engineering, vol. 10, no. 5, 2024, pp. 1292-05.
Vancouver Bader NM, Mushatet KS. An experimental study for a single-pass solar air heater integrated with artificial roughness. Journal of Thermal Engineering. 2024;10(5):1292-305.

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