| 1 |
ExRET-Opt: An automated exergy/exergoeconomic simulation framework for building energy retrofit analysis and design optimisation
Kerdan IG, Raslan R, Ruyssevelt P, Galvez DM
Applied Energy, 192, 33, 2017 |
| 2 |
A comparison of an energy/economic-based against an exergoeconomic-based multi-objective optimisation for low carbon building energy design
Kerdan IG, Raslan R, Ruyssevelt P, Galvez DM
Energy, 128, 244, 2017 |
| 3 |
Using epidemiological methods in energy and buildings research to achieve carbon emission targets
Hamilton I, Summerfield A, Oreszczyn T, Ruyssevelt P
Energy and Buildings, 154, 188, 2017 |
| 4 |
The role of an exergy-based building stock model for exploration of future decarbonisation scenarios and policy making
Kerdan IG, Raslan R, Ruyssevelt P, Galvez DM
Energy Policy, 105, 467, 2017 |
| 5 |
An exergy-based multi-objective optimisation model for energy retrofit strategies in non-domestic buildings
Kerdan IG, Raslan R, Ruyssevelt P
Energy, 117, 506, 2016 |
| 6 |
Benchmarking acute hospitals: Composite electricity targets based on departmental consumption intensities?
Morgenstern P, Li M, Raslan R, Ruyssevelt P, Wright A
Energy and Buildings, 118, 277, 2016 |
| 7 |
An exergoeconomic-based parametric study to examine the effects of active and passive energy retrofit strategies for buildings
Kerdan IG, Raslan R, Ruyssevelt P, Galvez DM
Energy and Buildings, 133, 155, 2016 |
| 8 |
Empirical variation in 24-h profiles of delivered power for a sample of UK dwellings: Implications for evaluating energy savings
Summerfield AJ, Oreszczyn T, Hamilton IG, Shipworth D, Huebner GM, Lowe RJ, Ruyssevelt P
Energy and Buildings, 88, 193, 2015 |
| 9 |
Modelling the energy and exergy utilisation of the Mexican non-domestic sector: A study by climatic regions
Kerdan IG, Galvez DM, Raslan R, Ruyssevelt P
Energy Policy, 77, 191, 2015 |
| 10 |
Assessing the overall performance of advanced glazing systems
Clarke JA, Janak M, Ruyssevelt P
Solar Energy, 63(4), 231, 1998 |
