| 1 |
Optimal design of energy conversion units and envelopes for residential building retrofits using a comprehensive MILP model
Schutz T, Schiffer L, Harb H, Fuchs M, Muller D
Applied Energy, 185, 1, 2017 |
| 2 |
The development and validation of the linear time varying Simulink-based model for the dynamic simulation of the thermal performance of buildings
Michalak P
Energy and Buildings, 141, 333, 2017 |
| 3 |
An evaluation of the suitability of lumped-capacitance models in calculating energy needs and thermal behaviour of buildings
Vivian J, Zarrella A, Emmi G, De Carli M
Energy and Buildings, 150, 447, 2017 |
| 4 |
The simple hourly method of EN ISO 13790 standard in Matlab/Simulink: A comparative study for the climatic conditions of Poland
Michalak P
Energy, 75, 568, 2014 |
| 5 |
Heating and cooling energy demand in underground buildings: Potential for saving in various climates and functions
van Dronkelaar C, Costola D, Mangkuto RA, Hensen JLM
Energy and Buildings, 71, 129, 2014 |
| 6 |
Solar Load Ratio and ISO 13790 methodologies: Indirect gains from sunspaces
Panao MJNO, Camelo SML, Goncalves HJP
Energy and Buildings, 51, 212, 2012 |
| 7 |
Assessment of the Portuguese building thermal code: Newly revised requirements for cooling energy needs used to prevent the overheating of buildings in the summer
Panao MJNO, Camelo SML, Goncalves HJP
Energy, 36(5), 3262, 2011 |
| 8 |
Revision of the Trombe wall calculation method proposed by UNE-EN ISO 13790
Ruiz-Pardo A, Dominguez SA, Fernandez JAS
Energy and Buildings, 42(6), 763, 2010 |
