| 1 |
Experimental testing of a solar air cavity-receiver with reticulated porous ceramic absorbers for thermal processing at above 1000 degrees C
Patil VR, Kiener F, Grylka A, Steinfeld A
Solar Energy, 214, 72, 2021 |
| 2 |
Homogeneous equivalent model coupled with P-1-approximation for dense wire meshes volumetric air receivers
Avila-Marin AL, Caliot C, de Lara MA, Fernandez-Reche J, Montes MJ, Martinez-Tarifa A
Renewable Energy, 135, 908, 2019 |
| 3 |
CFD model for the performance estimation of open volumetric receivers and comparison with experimental data
Stadler H, Maldonado D, Offergeld M, Schwarzbozl P, Trautner J
Solar Energy, 177, 634, 2019 |
| 4 |
Multi-scale modular analysis of open volumetric receivers for central tower CSP systems
Cagnoli M, Froio A, Savoldi L, Zanino R
Solar Energy, 190, 195, 2019 |
| 5 |
Three-dimensional modelling and analysis of solar radiation absorption in porous volumetric receivers
Barreto G, Canhoto P, Collares-Pereira M
Applied Energy, 215, 602, 2018 |
| 6 |
Efficiency improvement of a solar direct volumetric receiver utilizing aqueous suspensions of CuO
Zhang RM, Qu J, Tian M, Han XY, Wang Q
International Journal of Energy Research, 42(7), 2456, 2018 |
| 7 |
Performance comparison between the geometry models of multi-channel absorbers in solar volumetric receivers
Kasaeian A, Barghamadi H, Pourfayaz F
Renewable Energy, 105, 1, 2017 |
| 8 |
Experimental performance of an advanced metal volumetric air receiver for Solar Towers
Pabst C, Feckler G, Schmitz S, Smirnova O, Capuano R, Hirth P, Fend T
Renewable Energy, 106, 91, 2017 |
| 9 |
Coupled optical and CFD parametric analysis of an open volumetric air receiver of honeycomb type for central tower CSP plants
Cagnoli M, Savoldi L, Zanino R, Zaversky F
Solar Energy, 155, 523, 2017 |
| 10 |
Improved performance of open volumetric receivers by employing an external air return system
Stadler H, Tiddens A, Schwarzbozl P, Gohring F, Baumann T, Trautner J
Solar Energy, 155, 1157, 2017 |
