4E: Energy,effective,exergy and economic based performance investigation for rectangular pyramid shaped roughened solar collectors

Abstract

The present experimental investigation is aimed at determining 4E: Energy, Effective, exergy and economic based performance investigation for rectangular pyramid shaped roughened solar absorbers. The investigation was conducted outdoors at the rooftop of mechanical engineering department, MANIT Bhopal during February to June 2023. Data for air and absorber’s temperatures were measured at different locations using k-type thermocouples. Roughness in form of rectangular pyramid was imparted on flow side of absorber. Rise in heat transfer for rough plates compared to smooth were more than that of heat transfer obtained for rhombus and sinusoidal roughness. Roughness geometric parameters were varied and tested to determine Nusselt number, friction factor and THPP. Investigation covered relative rectangular pyramid height (e/D_h), relative rectangular pyramid pitch (p/e), relative base length to width ratio (b_L/b_W), roughness height to base length ratio (e/b_L) and Reynolds number (Re) varied respectively as 0.033–0.054, 8–20, 1.25–2, 0.35–0.63 and 3350–13350. The outcome of paper focusses on determination of maximum rise in friction and Nusselt number for varying p/e, e/D_h, e/b_L and b_L/b_W. Rise in friction and heat transfer for the proposed roughness system lie in range of 4.66–5.6 and 4.58–6.09 times respectively. The maximum effective efficiency achieved was 76.5%, maximum exergy efficiency reached 33.4% under optimized conditions and thermohydraulic performance was found to be as 3.9, 3.8, 4.1 and 4.0 at p/e = 16, e/D_h = 0.054, e/b_L = 0.58 and b_L/b_W = 2, respectively.

Keywords

RPR shaped element Nusselt number friction factor relative rectangular pyramid pitch relative rectangular pyramid height relative base length to width ratio

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References

Mekhilef

Saidur

Safari

A review on solar energy use in industries. Renew Sustain Energy Rev 2011; 15: 1777–1790.

Joule

JP.

On the surface condensation of steam. J Franklin Inst 1862; 73: 136–137.

Dutt

Hedau

Kumar

, et al. Thermo-hydraulic performance of solar air heater having discrete D-shaped ribs as artificial roughness. Environ Sci Pollut Res. Epub ahead of print 5 July 2023. DOI: 10.1007/s11356-023-28247-9.

Faujdar

Agrawal

Computational fluid dynamics based numerical study to determine the performance of triangular solar air heater duct having perforated baffles in V-down pattern mounted underneath absorber plate. Solar Energy 2021; 228: 235–252.

Bai

Xie

Farid

, et al. Analytical model to study the heat storage of phase change material envelopes in lightweight passive buildings. Build Environ 2020; 169: 106531.

Yadav

Thapak

MK.

Artificially roughened solar air heater: experimental investigations. Renew Sustain Energy Rev 2014; 36: 370–411.

Şevik

Özdilli

Abuşka

. Experimental investigation of relative roughness height effect in solar air collector with convex dimples. Renew Energy 2022; 194: 100–116.

El Khadraoui

Bouadila

Kooli

, et al. Thermal behavior of indirect solar dryer: Nocturnal usage of solar air collector with PCM. J Clean Prod 2017; 148: 37–48.

Abhay

Chandramohan

Raju

VRK

. Numerical analysis on solar air collector provided with artificial square shaped roughness for indirect type solar dryer. J Clean Prod 2018; 190: 353–367.

10.

Bezbaruah

Das

Sarkar

BK.

Thermo-hydraulic performance augmentation of solar air duct using modified forms of conical vortex generators. Heat Mass Transf 2019; 55: 1387–1403.

11.

Saravanan

Murugan

Reddy

, et al. Thermo-hydraulic performance of a solar air heater with staggered C-shape finned absorber plate. Int J Therm Sci 2021; 168: 107068.

12.

Singh

Chander

Saini

JS.

Thermal and effective efficiency-based analysis of discrete V-down rib-roughened solar air heaters. J Renew Sustain Energy 2011; 3(2): 3574430.

13.

Kumar

Heat transfer, friction factor and thermal efficiency results of air flowing through three sides concave dimple roughened duct. Int J Ambient Energy 2022; 43(1), 5405–5419.

14.

Hedau

Singal

SK.

Thermo-hydraulic performance investigation of double pass solar air heater integrated with PCM-based thermal energy storage. J Energy Storage 2024; 79: 110202.

15.

Dhamudia

Senapati

. A computational study for enhancement in thermal performance of plus (+)-shaped ribbed solar air heater duct. Int Commun Heat Mass Transf 2025; 161: 108411.

16.

Kumar

Murmu

Performance based investigation of inclined spherical ball roughened solar air heater. Appl Therm Eng 2023; 224: 120033.

17.

Alam

Kim

MH.

Heat transfer enhancement in solar air heater duct with conical protrusion roughness ribs. Appl Therm Eng 2017; 126: 458–469.

18.

Kumar

Layek

Thermo-hydraulic performance of solar air heater having twisted rib over the absorber plate. Int J Therm Sci 2018; 133: 181–195.

19.

Sureandhar

Srinivasan

Muthukumar

, et al. Performance analysis of arc rib fin embedded in a solar air heater. Therm Sci Eng Prog 2021; 23: 100891.

20.

Mund

Rathore

Sahoo

RK.

Experimental investigation of heat transfer augmentation of impinging jet solar air heater with stepped transverse ribs. Therm Sci Eng Prog 2024; 56: 103020.

21.

Chaudhri

Bhagoria

Kumar

Thermal performance investigation of rhombus shape roughened solar air collector – a novel approach. Renew Energy 2024; 235: 121305.

22.

Skullong

Promvonge

Thianpong

, et al. Thermal performance in solar air heater channel with combined wavy-groove and perforated-delta wing vortex generators. Appl Therm Eng 2016; 100: 611–620.

23.

Singh

Kumar

Thermohydraulic performance parameter based experimental investigation of frustum shaped roughened solar air heater. Proc Inst Mech Eng A J Power Energy 2024; 238(4): 705–722.

24.

Yadav

Kaushal

Nusselt number and friction factor correlations for solar air heater duct having protrusions as roughness elements on absorber plate. Exp Therm Fluid Sci 2013; 44: 34–41.

25.

Patel

Jain

Lakhera

VJ.

Thermo-hydraulic performance analysis of a solar air heater roughened with discrete reverse NACA profile ribs. Int J Therm Sci 2021; 167: 107026.

26.

Chompookham

Eiamsa–ard

Buanak

, et al. Thermal performance augmentation in a solar air heater with twisted multiple V–baffles. Int J Therm Sci 2024; 205: 109295.

27.

Jin

Zuo

Quan

, et al. Thermohydraulic performance of solar air heater with staggered multiple V-shaped ribs on the absorber plate. Energy 2017; 127: 68–77.

28.

ASHRAE Standard. 93 ‘Method of testing to determine the thermal of solar collector’. ASHRAE, 2003.

29.

Kumar

Thermal and thermohydraulic performance analysis of three sides artificially roughened solar collectors. Solar Energy 2019; 190: 212–227.

30.

Hai

Mansir

I B

Alshuraiaan

, et al. (2023). Numerical investigation on the performance of a solar air heater using inclined impinging jets on absorber plate with parallel and crossing orientation of nozzles. Case Studies in Thermal Engineering 2023; 45: Article 102913.

31.

Kline

McClintock

. Describing uncertainties in single-sample Experiments. Mech Eng 1953;75: 3–8.

32.

Kumar

Verma

SK.

Heat transfer and fluid flow analysis of sinusoidal protrusion rib in solar air heater. Int J Therm Sci 2022; 172: 107323.

33.

Bhatti

MS.

Turbulent and transition flow convective heat transfer in ducts. In: Handbook of single-phase convective heat transfer. 1987.

34.

Edalatpour

Kianifar

Aryana

, et al. Energy, exergy, and cost analyses of a double-glazed solar air heater using phase change material. J Renewable Sustain Energy 2016; 8(1): 015101.

35.

Altfeld

Leiner

Fiebig

Second law optimization of flat-plate SAHs part I: The concept of net exergy flow and the modeling of SAHs. Solar Energy 1988; 41: 127–132.

36.

Duffie

Beckman

. Solar engineering of thermal processes. Wiley, 1980.

37.

Sami

Etesami

Rahimi

. Energy and exergy analysis of an indirect solar cabinet dryer based on mathematical modeling results. Energy 2011; 36: 2847–2855.

38.

Kurtbas

Durmus

. Efficiency and exergy analysis of a new SAH. Renew Energy 2004; 29: 1489–1501