| Review on using microencapsulated phase change materials (PCM) in building applications Y Konuklu, M Ostry, HO Paksoy, P Charvat Energy and Buildings 106, 134-155, 2015 | 387 | 2015 |
| Numerical and experimental investigation of a PCM-based thermal storage unit for solar air systems P Charvát, L Klimeš, M Ostrý Energy and Buildings 68, 488-497, 2014 | 151 | 2014 |
| Energy demand of liquefaction and regasification of natural gas and the potential of LNG for operative thermal energy storage J Pospíšil, P Charvát, O Arsenyeva, L Klimeš, M Špiláček, JJ Klemeš Renewable and Sustainable Energy Reviews 99, 1-15, 2019 | 123 | 2019 |
| Computer modelling and experimental investigation of phase change hysteresis of PCMs: The state-of-the-art review L Klimeš, P Charvát, MM Joybari, M Zálešák, F Haghighat, ... Applied Energy 263, 114572, 2020 | 87 | 2020 |
| PCM thermal energy storage in solar heating of ventilation air—Experimental and numerical investigations U Stritih, P Charvat, L Klimes, E Osterman, M Ostry, V Butala Sustainable cities and society 37, 104-115, 2018 | 65 | 2018 |
| An overview of mercury emissions in the energy industry-A step to mercury footprint assessment P Charvát, L Klimeš, J Pospíšil, JJ Klemeš, PS Varbanov Journal of cleaner production 267, 122087, 2020 | 55 | 2020 |
| Solar air collector with the solar absorber plate containing a PCM–Environmental chamber experiments and computer simulations P Charvát, L Klimeš, O Pech, J Hejčík Renewable Energy 143, 731-740, 2019 | 54 | 2019 |
| Materials for advanced heat storage in buildings M Ostry, P Charvat Procedia Engineering 57, 837-843, 2013 | 37 | 2013 |
| CHALLENGES IN THE COMPUTER MODELING OF PHASE CHANGE MATERIALS L Klimes, P Charvat, M Ostry Materiali in tehnologije 46 (4), 335-338, 2012 | 25* | 2012 |
| Solar chimneys for ventilation and passive cooling P Charvat, M Jicah, J Stetina World Renewable Energy Congress, Denver, USA, 2004 | 23 | 2004 |
| Identification of the effective heat capacity–temperature relationship and the phase change hysteresis in PCMs by means of an inverse heat transfer problem solved with … M Zálešák, P Charvát, L Klimeš Applied Thermal Engineering 197, 117392, 2021 | 20 | 2021 |
| SIMULATION OF LATENT-HEAT THERMAL STORAGE INTEGRATED WITH ROOM STRUCTURES P Charvat, T Mauder, M Ostry Materiali in tehnologije 46 (3), 239-242, 2012 | 14* | 2012 |
| A solar air collector with integrated latent heat thermal storage P Charvat, M Ostry, T Mauder, L Klimes EPJ Web of Conferences 25, 01028, 2012 | 13 | 2012 |
| Front tracking in modelling of latent heat thermal energy storage: Assessment of accuracy and efficiency, benchmarking and GPU-based acceleration L Klimeš, T Mauder, P Charvát, J Štětina Energy 155, 297-311, 2018 | 12 | 2018 |
| Simulation of the performance of a hybrid ventilation system in different climates P Charvat, M Jicha, A Niachou, M Santamouris | 12 | 2005 |
| Dry cooling as a way toward minimisation of water consumption in the steel industry: A case study for continuous steel casting L Klimeš, M Březina, T Mauder, P Charvát, JJ Klemeš, J Štětina Journal of cleaner production 275, 123109, 2020 | 11 | 2020 |
| Thermally activated wall panels with microencapsulated PCM: comparison of 1D and 3D models L Klimeš, P Charvát, M Ostrý Journal of Building Performance Simulation 12 (4), 404-419, 2019 | 11 | 2019 |
| Assessment of basic approaches to numerical modeling of phase change problems—Accuracy, efficiency, and parallel decomposition T Mauder, P Charvat, J Stetina, L Klimes Journal of Heat Transfer 139 (8), 084502, 2017 | 11 | 2017 |
| Design Optimization of a Solar Air Collector Integrating a Phase Change Material. M Zálešák, L Klimeš, P Charvát CET Journal-Chemical Engineering Transactions 81, 2020 | 9 | 2020 |
| Melting front propagation in a paraffin-based phase change material: Lab-scale experiment and simulations J Stetina, T Mauder, L Klimes, P Charvat Thermal Science 22 (6 Part B), 2723-2732, 2018 | 9 | 2018 |
