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dc.contributor.advisorWilliamson, Terence Johnen
dc.contributor.advisorSoebarto, Veronica Irawatien
dc.contributor.authorFreney, Martin Howard Priestmanen
dc.description.abstractMinimising environmental impact from buildings and building construction processes while providing thermal comfort to the occupants are some of the main goals of green building design. Many different approaches exist to achieve these goals, one of which is the “Earthship”, invented by American architect Michael Reynolds. The Earthship is an earth-sheltered autonomous house with walls made substantially from waste products, most notably, discarded car tyres. This thesis presents original research to investigate claims about Earthship performance: that it provides passive thermal comfort in any climate and is the most sustainable green building design in the world. This investigation has been conducted by using Life Cycle Assessment (LCA) to evaluate the overall environmental impact of the Earthship and to compare it to a variety of similar building types characterised by their wall construction materials and other design features. To support assumptions in the LCA, a Post Occupancy Evaluation and a Thermal Performance study were conducted to estimate heating and cooling energy use in a variety of climates. The environmental credentials of the Earthship are then compared to that of other housing types, using both the LCA and thermal modelling approaches. A post occupancy evaluation (POE) of Earthship homes in Taos, New Mexico, USA, was conducted. This included interviews and surveys of the occupants, and monitoring of the indoor thermal environment. Some aspects of the POE were also extended to an international cohort of Earthship occupants to help justify the assumptions that Earthships provide a level of amenity comparable to conventional housing. The indoor monitored data were also used to calibrate a thermal simulation model of an Earthship home in Taos to ensure the accuracy of the model. The tested approach and parameters to model this Earthship were then used in a model to predict the indoor temperature and theoretical heating and cooling energy requirement of an Earthship design in cold climates and in a warm Mediterranean climate of Adelaide, Australia – the particular context of the LCA study. Thermal modelling of other building types, characterised by their wall materials, was conducted for the Adelaide climate, to predict the heating and cooling energy requirement which was needed for the comparative LCA study. The research produced the following results. Firstly, in the extreme climate of Taos, the Earthship is able to provide thermal comfort without active heating and cooling systems, and that people are generally very satisfied with the level of comfort and amenity provided. Secondly, in the Adelaide climate, Earthship performance would be similar to Taos; approaching zero energy use for heating and cooling, while in cold and overcast climates minimal space heating may be required. Finally, in the Adelaide climate and context, of all the house types considered, the Earthship had the least environmental impacts and these were considerably less than conventional grid connected homes. The Earthship’s comparatively low environmental impact arises from the holistic design, in particular the greenhouse and earth-sheltering, which enable occupants to be extremely energy and water efficient, and therefore live within the limits of modestly sized “off-grid” systems (autonomously) while still enjoying a high level of comfort and amenity. The use of tyres to construct the Earthship’s external walls proved to be a low impact method for constructing a retaining wall capable of being earth-sheltered. The study has provided scientific evidence about the thermal performance and environmental credentials of the Earthship and other housing types, supporting claims that Earthships can provide passive thermal comfort in many climates and that it may be the most sustainable green building design compared to the other building types investigated by this study.en
dc.subjectearthship; autonomous house; self sufficient house; off-grid; life cycle assessmenten
dc.titleEarthship architecture: post occupancy evaluation, thermal performance & life cycle assessment.en
dc.contributor.schoolSchool of Architecture and Built Environmenten
dc.provenanceThis electronic version is made publicly available by the University of Adelaide in accordance with its open access policy for student theses. Copyright in this thesis remains with the author. This thesis may incorporate third party material which has been used by the author pursuant to Fair Dealing exceptions. If you are the owner of any included third party copyright material you wish to be removed from this electronic version, please complete the take down form located at:
dc.provenanceCopyright material removed from digital thesis. See print copy in University of Adelaide Library for full text.en
dc.description.dissertationThesis (Ph.D.) -- University of Adelaide, School of Architecture and Built Environment, 2014en
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