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Container-based lightweight buildings offer a high ecologic and economic potential when they are designed as nearly zero-energy container buildings (NZECBs). Thus, they are relevant to energy transition in achieving an almost climate-neutral building stock. This paper describes and applies design strategies for suitable building concepts and energy systems to be used in NZECBs for different climates. Therefore, different applications in representative climatic zones were selected. Initially, the global climate zones were characterized and analyzed with regard to their potential for self-sufficiency and renewable energies in buildings. The design strategies were further developed and demonstrated for three cases: a single-family house in Sweden, a multi-family house in Germany, and a small school building in rural Ethiopia. For each case, design guidelines were derived and building concepts were developed. On the basis of these input data, various energy concepts were developed in which solar and wind energy, as well as biomass, were integrated as renewable energy sources. All the concepts were simulated and analyzed with the Polysun® software. The various approaches were compared and evaluated, particularly with regard to energy self-sufficiency. Self-sufficiency rates up to 80% were achieved. Finally, the influence of different climate zones on the energy efficiency of the single-family house was studied as well as the influence of the size of battery storage and insulation.
In dieser Arbeit wird untersucht, wie sich ein steigender energetischer Autarkiegrad eines speziellen containerbasierten Einfamilienhauses auf verschiedene ökologische Indikatoren auswirkt. Zur Steigerung des Autarkiegrades wurden folgende Komponenten verbaut und variiert: Photovoltaik (PV) mit und ohne Batteriespeicher sowie Vakuum-Isolations-Paneelen (VIP) und Phasenwechselmaterialien (PCM) in der Gebäudehülle. Bei der Betrachtung der Umweltbelastungen stehen dabei die folgenden Lebenswegphasen im Vordergrund: Herstellung, Nutzung und Verwertung. Das Recycling Potenzial spielt hier eine untergeordnete Rolle. Nach der Definition des Gebäudes und der Ermittlung der Wärme und Strombedarfswerte werden die Ergebnisse für die verschiedenen Umweltindikatoren einzeln errechnet. Das Treibhauspotenzial (GWP), Versauerungspotenzial (AP) und der abiotische Ressourcenverbrauch werden in Abhängigkeit vom Autarkiegrad dargestellt. Die Ergebnisse zeigen, dass die ökologisch günstigste Lösung je nach Umweltindikator sehr unterschiedlich ausgeprägt ist und zwischen 0 bis 75 % Autarkiegrad liegt. Abschließend findet eine kurze ökonomische Betrachtung statt.