References
- Scilab 5.5.2. www.scilab.org.
- Akhtar, N., and S. C. Mullick. 1999. “Approximate Method for Computation of Glass Cover Temperature and Top Heat-loss Coefficient of Solar Collectors with Single Glazing.” Solar Energy 66: 349–354.
- Alam, T., R. P. Saini, and J. S. Saini. 2014. “Heat and Flow Characteristics of air Heater Ducts Provided with Turbulators – A Review.” Renewable and Sustainable Energy Reviews 31: 289–304.
- Altfeld, K., W. Leiner, and M. Fiebig. 1988. “Second Law Optimization of Flat-plate Solar Air Heaters Part I: The Concept of Net Exergy Flow and the Modeling of Solar air Heaters.” Solar Energy 41: 127–132.
- Bhushan, B., and R. Singh. 2012. “Thermal and Thermohydraulic Performance of Roughened Solar Air Heater Having Protruded Absorber Plate.” Solar Energy 86: 3388–3396.
- Biondi, P., L. Cicala, and G. Farina. 1988. “Performance Analysis of Solar Air Heaters of Conventional Design.” Solar Energy 41: 101–107.
- Gupta, M. K., and S. C. Kaushik. 2009. “Performance Evaluation of Solar Air Heater for Various Artificial Roughness Geometries Based on Energy, Effective and Exergy Efficiencies.” Renewable Energy 34: 465–476.
- Kalogirou, S. A. 2004. “Solar Thermal Collectors and Applications.” Progress in Energy and Combustion Science 30: 231–295.
- Kumar, A., R. P. Saini, and J. S. Saini. 2012a. “Experimental Investigation on Heat Transfer and Fluid Flow Characteristics of air Flow in a Rectangular Duct with Multi v-Shaped Rib with Gap Roughness on the Heated Plate.” Solar Energy 86: 1733–1749.
- Kumar, A., R. P. Saini, and J. S. Saini. 2012b. “Heat and Fluid Flow Characteristics of Roughened Solar Air Heater Ducts – A Review.” Renewable Energy 47: 77–94.
- Layek, A., J. S. Saini, and S. C. Solanki. 2007. “Second Law Optimization of a Solar Air Heater Having Chamfered Rib-groove Roughness on Absorber Plate.” Renewable Energy 32: 1967–1980.
- Pandey, N. K., and V. K. Bajpai. 2016a. “Experimental Investigation of Heat Transfer and Friction Characteristics of Arc-Shaped Roughness Elements Having Central Gaps on the Absorber Plate of Solar Air Heater.” Journal of Solar Energy Engineering 138: 1–8.
- Pandey, N. K., and V. K. Bajpai. 2016b. “Thermo-hydraulic Performance Enhancement of Solar Air Heater (SAH) Having Multiple Arcs with gap Shaped Roughness Element on Absorber Plate.” International Journal of Engineering, Science and Technology 8 (1): 34–42.
- Pandey, N. K., V. K. Bajpai, and Varun. 2016a. “Experimental Investigation on Heat Transfer Augmentation by Providing Multiple Arcs with Gap as Roughness Element on the Absorber Plate of a Solar air Heater.” Solar Energy 134: 314–326.
- Pandey, N. K., V. K. Bajpai, and Varun. 2016b. “Heat Transfer and Friction Factor Study of a Solar Air Heater Having Multiple Arcs with Gap-shaped Roughness Element on Absorber Plate.” Arabian Journal for Science and Engineering 41: 4517–4530.
- Pandey, N. K., V. K. Bajpai, A. Sharma, and S. Yadav 2020. “CFD and Thermo-Hydraulic Analysis of Multiple Arc Roughened Absorber Plate with Gaps used in Solar Air-Heaters.” International Journal of Ambient Energy. https://doi.org/10.1080/01430750.2020.1824941.
- Sethi, M., Varun, and N. S. Thakur. 2012. “Correlations for Solar Air Heater Duct with Dimpled Shape Roughness Elements on Absorber Plate.” Solar Energy 86: 2852–2861.
- Varun, R. P. Saini, and S. K. Singal. 2007. “A Review on Roughness Geometry Used in Solar air Heaters.” Solar Energy 81: 1340–1350.
- Varun R. P. Saini, and S. K. Singal 2008. “Investigation of Thermal Performance of Solar Air Heater Having Roughness Elements as a Combination of Inclined and Transverse Ribs on the Absorber Plate.” Renewable Energy 33: 1398–1405.
- Yadav, S., M. Kaushal, Varun, and Siddhartha. 2013. “Nusselt Number and Friction Factor Correlations for Solar air Heater Duct Having Protrusions as Roughness Elements on Absorber Plate.” Experimental Thermal Fluid Science 44: 34–41.