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Journal Articles
Journal:
Journal of Solar Energy Engineering
Publisher: ASME
Article Type: Research Papers
J. Sol. Energy Eng. June 2025, 147(3): 031012.
Paper No: SOL-23-1175
Published Online: February 5, 2025
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 1 Particle candidates at 2× magnification: ( a ) HSP, ( b ) CP, ( c ) solar HSP, ( d ) max HD, ( e ) WanLi Diamond Black, ( f ) Solar CP, and ( g ) Solar MAX HD More about this image found in Particle candidates at 2× magnification: ( a ) HSP, ( b ) CP, ( c ) solar H...
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 2 Tube furnace sample tray containing five particle candidates in crucibles More about this image found in Tube furnace sample tray containing five particle candidates in crucibles
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 3 ET 100 Emissometer (left) and Solar 410 reflectometer (right) More about this image found in ET 100 Emissometer (left) and Solar 410 reflectometer (right)
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 4 Irradiance cycling experimental setup depicting (1) exposure and (2) shielding of a sample crucible More about this image found in Irradiance cycling experimental setup depicting (1) exposure and (2) shield...
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 5 Article absorptance for a 2.5 × 2.5 cm coupon versus irradiance cycles for ( a ) 775 °C, ( b ) 975 deg C, ( c ) and simulated freefall cases, with a 10 s cooldown between cycles. Uncertainty intervals of 95% are present but not visible due to low instrument measurement error. More about this image found in Article absorptance for a 2.5 × 2.5 cm coupon versus irradiance cycles for ...
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 6 WanLi Diamond Black particles: ( a ) as received and ( b ) after 10,000 cycles with a peak cycle temperature of 975 °C More about this image found in WanLi Diamond Black particles: ( a ) as received and ( b ) after 10,000 cyc...
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 7 HSP particles following 1500 °C, 110 w/cm 2 irradiance cycling More about this image found in HSP particles following 1500 °C, 110 w/cm 2 irradiance cycling
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 8 Particle candidate absorptance for a 2.5 × 2.5 cm coupon versus hours at ( a ) 800 °C, ( b ) 900 °C, and ( c ) 1000 °C ( c ). Uncertainty intervals of 95% are present but not visible due to low instrument measurement error. More about this image found in Particle candidate absorptance for a 2.5 × 2.5 cm coupon versus hours at ( ...
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 9 Model fits (lines) and measurements (markers) of hemispherical total emittance (three lower curves) and hemispherical solar absorptance (three upper curves) after isothermal experiments at 800, 900, and 1000 °C for five materials: ( a ) HSP, ( b ) CP, ( c ) WanLi Diamond Black, ( d ) max HD... More about this image found in Model fits (lines) and measurements (markers) of hemispherical total emitta...
Image
in Assessment of Particle Candidates for Falling Particle Receiver Applications Through Irradiance and Thermal Cycling
> Journal of Solar Energy Engineering
Published Online: February 5, 2025
Fig. 10 Particle bed emittance enhancement for the estimated bed porosity of HSP 40/100 (solid line) as well as a sensitivity range of ±15% (shaded area). A thin dashed line is shown at unity. More about this image found in Particle bed emittance enhancement for the estimated bed porosity of HSP 40...
Journal Articles
Journal:
Journal of Solar Energy Engineering
Publisher: ASME
Article Type: Technical Briefs
J. Sol. Energy Eng. June 2025, 147(3): 034501.
Paper No: SOL-24-1067
Published Online: January 20, 2025
Journal Articles
Mokhtar Ghodbane, Boussad Boumeddane, Fayaz Hussain, Naima El-Amarty, Khadija Lahrech, Arsenio Barbón
Journal:
Journal of Solar Energy Engineering
Publisher: ASME
Article Type: Research Papers
J. Sol. Energy Eng. June 2025, 147(3): 031011.
Paper No: SOL-24-1135
Published Online: January 20, 2025
Journal Articles
Journal:
Journal of Solar Energy Engineering
Publisher: ASME
Article Type: Research Papers
J. Sol. Energy Eng. June 2025, 147(3): 031010.
Paper No: SOL-24-1074
Published Online: January 20, 2025
Image
in Annual Energy Analysis of a Building-Integrated Semitransparent Photovoltaic Thermal Façade
> Journal of Solar Energy Engineering
Published Online: January 20, 2025
Fig. 1 Flowchart for thermal modeling of the BiSPVT system More about this image found in Flowchart for thermal modeling of the BiSPVT system
Image
in Annual Energy Analysis of a Building-Integrated Semitransparent Photovoltaic Thermal Façade
> Journal of Solar Energy Engineering
Published Online: January 20, 2025
Fig. 2 Configuration of the BiSPV façade system More about this image found in Configuration of the BiSPV façade system
Image
in Annual Energy Analysis of a Building-Integrated Semitransparent Photovoltaic Thermal Façade
> Journal of Solar Energy Engineering
Published Online: January 20, 2025
Fig. 3 Heat transfer mechanisms in the BiSPV façade system More about this image found in Heat transfer mechanisms in the BiSPV façade system
Image
in Annual Energy Analysis of a Building-Integrated Semitransparent Photovoltaic Thermal Façade
> Journal of Solar Energy Engineering
Published Online: January 20, 2025
Fig. 4 Schematic representation of the thermal resistance network of the BiSPVT system More about this image found in Schematic representation of the thermal resistance network of the BiSPVT sy...
Image
in Annual Energy Analysis of a Building-Integrated Semitransparent Photovoltaic Thermal Façade
> Journal of Solar Energy Engineering
Published Online: January 20, 2025
Fig. 5 Hourly variation of solar radiation and ambient temperature at façade inclination of 90 deg, azimuthal angle of 0 deg, and reflection coefficient of the ground, ρ = 0.2 for a-type and b-type climatic conditions in the month of October at Srinagar More about this image found in Hourly variation of solar radiation and ambient temperature at façade incli...
Image
in Annual Energy Analysis of a Building-Integrated Semitransparent Photovoltaic Thermal Façade
> Journal of Solar Energy Engineering
Published Online: January 20, 2025
Fig. 6 Hourly variation of different temperatures in the PV façade system versus PV module efficiency and thermal efficiency—a type (October) for constant values of the number of air changes ( N ˙ ) = 10 , the specific heat of air (Ca) = 1005 J/kg/K, the density of air = 1.17 kg/m 3 ... More about this image found in Hourly variation of different temperatures in the PV façade system versus P...
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