| 81 |
Innovative design of superhydrophobic thermal energy-storage materials by microencapsulation of n-docosane with nanostructured ZnO/SiO2 shell
Sun K, Liu H, Wang XD, Wu DZ
Applied Energy, 237, 549, 2019 |
| 82 |
Thermal energy storage for waste heat recovery in the steelworks: The case study of the REslag project
Ortega-Fernandez I, Rodriguez-Aseguinolaza J
Applied Energy, 237, 708, 2019 |
| 83 |
Techno-economic analysis of a solar district heating system with seasonal thermal storage in the UK
Renaldi R, Friedrich D
Applied Energy, 236, 388, 2019 |
| 84 |
Improving the load flexibility of coal-fired power plants by the integration of a thermal energy storage
Richter M, Oeljeklaus G, Gorner K
Applied Energy, 236, 607, 2019 |
| 85 |
The impact of concentrated solar power in electric power systems: A Chilean case study
Mena R, Escobar R, Lorca A, Negrete-Pincetic M, Olivares D
Applied Energy, 235, 258, 2019 |
| 86 |
Novel strategies and supporting materials applied to shape-stabilize organic phase change materials for thermal energy storage-A review
Umair MM, Zhang Y, Iqbal K, Zhang SF, Tang BT
Applied Energy, 235, 846, 2019 |
| 87 |
Evaluation of energy density as performance indicator for thermal energy storage at material and system levels
Romani J, Gasia J, Sole A, Takasu H, Kato Y, Cabeza LF
Applied Energy, 235, 954, 2019 |
| 88 |
Influence of the storage period between charge and discharge in a latent heat thermal energy storage system working under partial load operating conditions
Gasia J, de Gracia A, Zsembinszki G, Cabeza LF
Applied Energy, 235, 1389, 2019 |
| 89 |
Modelling a molten salt thermal energy system - A validation study
Lappalainen J, Hakkarainen E, Sihvonen T, Rodriguez-Garcia MM, Alopaeus V
Applied Energy, 233, 126, 2019 |
| 90 |
Thermal conductivity enhancement of phase change materials with 3D porous diamond foam for thermal energy storage
Zhang L, Zhou KC, Wei QP, Ma L, Ye WT, Li HC, Zhou B, Yu ZM, Lin CT, Luo JT, Gan XP
Applied Energy, 233, 208, 2019 |
