- Infrastructure Engineering - Research Publications
Infrastructure Engineering - Research Publications
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ItemNo Preview AvailableExploring policy mixes for low-carbon and just energy transitions systems: An Australian caseRojas Arevalo, A ; de Haan, F ; Candy, S ; Foliente, G ; Aye, L (DUMU, 2022-11-09)
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ItemNo Preview AvailableA multi-layered energy resilience framework and metrics for energy master planning of communities: A university campus case studyCharani Shandiz, S ; Rismanchi, B ; Foliente, G ; Aye, L (Society of Risk Analysis, 2021-12-05)
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ItemNo Preview AvailableThermal comfort simulation for cold air distribution systems by a user defined Predictive Mean Vote IndexWahba, N ; Rismanchi, B ; Pu, Y ; Aye, L (Elsevier, 2021)
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ItemAn innovative cost-effective floating solar still with integrated condensation coilsMohsenzadeh, M ; Aye, L ; Christopher, P (Australian PV Institute, 2021-12-16)
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ItemAn update on Activity C1 Design Tools and Models, Task 65 Solar Cooling Sunbelt RegionsAye, L ; Daborer-Prado, N ; Neyer, D ; Jakob, U (Australian PV Institute, 2021-12-16)
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ItemEffects of substrate depth and native plants on green roof thermal performance in South-East AustraliaPianella, A ; Aye, L ; Chen, Z ; Williams, N (IOP Publishing, 2020-11-20)Three experimental green roofs in Melbourne with depth of 100, 150 and 300 mm have been assessed to quantify their thermal performance. To evaluate the benefit of substrate depth, temperature was recorded every 50 mm along a vertical profile. Green roofs consisted of scoria substrate and a mix of three species of plants: Lomandra longifolia, Dianella dmixta and Stypandra glauca. Statistical analyses applying the hierarchical partitioning technique showed that solar radiation is the main driver affecting the green roof surface temperature, air temperature has strong correlations with the variations of the temperatures recorded below the surface, while moisture content has the least influence. Temperature profiles of the green roof show that the first 50 mm do reduce the heat flowing through the green roof substrate regardless the total green roof substrate depth. Differences in thermal performance arise at deeper points, where thicker green roofs are able to delay the change of substrate temperatures. Similar effects were found for the heat fluxes measured at the interface between the green roof and building roof. These results confirmed that green roofs may be used as a sustainable passive technology to reduce building energy consumptions for South-East Australia climate.