Three-dimensional analysis and numerical optimization of combined natural convection and radiation heat loss in solar cavity receiver with plate fins insert

Ngo, L.C.; Bello‐Ochende, Tunde; Meyer, Josua P.

doi:10.1016/j.enconman.2015.05.061

Cited by 39 publications

(14 citation statements)

References 32 publications

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“…As reported earlier by Ngo et al [8], radiation heat loss remains unaffected by change in inclination angle of a receiver. Therefore, according to them, receiver inclination influences the heat transfer (energy loss) by means of combined conduction and convection.…”

Section: Introductionsupporting

confidence: 73%

“…As discussed earlier, the loss of energy by conduction mode through the insulation is obtained using Eq. (8). During experimentation, it exhibited a rising trend with the surface temperature of cavity.…”

Section: Heat Loss Analysismentioning

confidence: 92%

“…The provision of plate fins significantly reduces the convective heat losses by about 20% from the cavity receiver as well as it reduces the radiative energy losses by about 5% [8]. Radiation energy loss from a cavity receiver is seen to be unchanged for various receiver inclination angles (0°, 90°, and 180°).…”

Section: Introductionmentioning

confidence: 92%

“…At sideways position, a receiver is dominated by the convective zone which diminishes for down-facing receiver due to stagnant fluid zone inside cavity. The provision of fins improves the receiver collection efficiency by about 2% [8]. Similarly, providing fins inside the conical receiver without glazing exhibited collection efficiency improvement of about 10% as compared to conical receiver with no fins [13].…”

Section: Introductionmentioning

confidence: 93%

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Experimental investigations on thermal performance characteristics of a solar cavity receiver

Bopche

Kumar

2019

Int J Energy Environ Eng

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The experimentation is carried out to examine the influence of receiver aperture/opening ratio (receiver's aperture diameter to the maximum diameter ratio, d/D), glass cover thickness and inclination angle of cavity receiver on its collection efficiency for various flow rates of ordinary water as a working fluid. Experimental tests have been conducted at lower incident energy, i.e., at lower cavity wall temperatures (less than 200 °C). The aperture ratio examined encompasses values as 0.46, 0.6, 0.7, and 0.93 for water flowing at flows of 0.8, 0.65, 0.5, and 0.4 LPM that corresponds to Reynolds numbers (Re) of 1880, 1525, 1175, and 938, respectively. The glazing thicknesses of 6, 4, and 2 mm were provided at an aperture. A modified cavity-type receiver is made inclined at angles 90°, 60°, 45°, and 30° (with 90° as down-facing receiver opening and 30° as close to sideway-facing of receiver opening). The tests have been conducted for cavity surface temperatures ranging from 90° to 180 °C. It is observed that an aperture ratio of 0.6 demonstrates maximum receiver performance for the values of Reynolds number studied, while the receiver performance exhibited reducing trend with reduction in receiver tilting angle from 90° to 30°.Keywords Modified cavity receiver · Aperture/opening ratio · Collection efficiency · Inclination Non-dimensional numbers d/D Ratio of receiver's aperture diameter to the receiver maximum diameter ∕D Glazing thickness ratio Gr Grashof number Nu Nusselt number N RC Radiation-conduction number = T 4 w D 2 (Tw−Tamb)kf Re Reynolds number T R Temperature ratio = T amb T w o Angle ratio Symbols Surface absorptivity δ Thickness (m) Emissivity of the surface Receiver collection efficiency or receiver performance parameter

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Section: Introductionsupporting

confidence: 73%

Section: Heat Loss Analysismentioning

confidence: 92%

Section: Introductionmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 93%

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Experimental investigations on thermal performance characteristics of a solar cavity receiver

Bopche

Kumar

2019

Int J Energy Environ Eng

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“…The outlet condition regards the pressure is kept to be at atmospheric pressure and at the relevant suitable conditions with no wind influence was neglected by means of natural convection only will be the convective heat losses [39]. Moreover, the model of the receiver was maintained vertically, 90 o only, as this alignment attains the lowest amount of convective heat losses [25] and [40]. For calculating the radiation losses each model needs the relevant value of view-factor [41] so this was also calculated before computing the radiation heat losses.…”

Section: -mentioning

confidence: 99%

Parametric analysis of small scale cavity receiver with optimum shape for solar powered closed Brayton cycle applications

Daabo

Ahmad

Mahmoud

et al. 2017

Applied Thermal Engineering

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Convective heat loss from a modified solar cavity receiver with vertical plate fins: An experimental assessment

Mobasheri‐Shiri,

Yazdanipour,

Razzaghi

2024

Heat Trans

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Experimental investigations have been conducted to study the convective heat transfer from a cylindrical solar cavity receiver with vertical fins. The experiments were performed under varying surface heat flux levels and at seven inclination angles, ranging from −90° (upward facing) to +90° (downward facing) at 30° intervals. The impact of fins on the heat transfer process was studied by conducting experiments in two scenarios, namely, finned and unfinned cavities. The findings of the study showed that with an increase in cavity inclination, the magnitude of convective heat loss decreased in both finned and unfinned cavities, while the cavity surface temperature increased. At +90° inclination, the convective heat loss and Nusselt number were observed to have the lowest value, while the surface temperature had the highest value. For a downward‐facing cavity, the fins reduced convective heat loss, leading to an increase in cavity surface temperature. The finned cavity performed better for a vertically downward‐facing inclination (+90°) as it had a contribution of only 11% for convection heat loss compared with the unfinned cavity, which had a contribution of 21% for the same. Furthermore, an empirical model was developed based on the experimental results for the Nusselt number, which correlates experimental data with an error margin of ±15%. This model can be used to predict the Nusselt number for different inclination angles and surface heat flux levels. The presence of vertical fins in the cavity was found to be effective in reducing convective heat loss, especially for downward‐facing cavities. Understanding the influence of fin and cavity inclination on convective heat transfer can lead to enhanced efficiency and performance of solar receivers, thereby increasing the overall energy output of the system.

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Three-dimensional analysis and numerical optimization of combined natural convection and radiation heat loss in solar cavity receiver with plate fins insert

Cited by 39 publications

References 32 publications

Experimental investigations on thermal performance characteristics of a solar cavity receiver

Experimental investigations on thermal performance characteristics of a solar cavity receiver

Parametric analysis of small scale cavity receiver with optimum shape for solar powered closed Brayton cycle applications

Convective heat loss from a modified solar cavity receiver with vertical plate fins: An experimental assessment

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