This algorithm calculates a building’s energetic quality, its material resource use, and its environmental impact over its life cycle. Building construction and operations make up 36 percent of global energy end-use and 40 percent of energy-related carbon dioxide emissions. Reducing the energy consumption and emissions of buildings through informed decision-making in the blueprinting phase is therefore a focus in preserving environmental health. Contractors commonly perform a Life Cycle Assessment (LCA) to measure the environmental impacts of building designs, but these assessments do not accurately account for resource depletion, plus lack standardization and have the potential for subjectivity.
Researchers at the University of Florida have developed an algorithm to improve LCA that measures the “exergy,” or energetic quality, of resources used and emissions produced in constructing and operating a building. Exergy-based LCA more accurately calculates a building’s energy-related environmental impacts, reduces subjectivity, and allows for easier comparison between LCAs of different buildings.
Exergy-based life cycle assessment of building resource use and emissions to help builders make more sustainable designs
The algorithm uses data from the conventional life cycle assessment (LCA) of a building to determine more accurately its environmental impact based on the energetic quality of the building’s emissions and depleted resources. The automated computation tool employs life cycle inventory (LCI) data to perform a holistic exergy-based LCA to determine the primary exergy demand, material exergy demand, and exergy loss of emissions. The final comprehensive assessment of resource use and emissions can better inform decisions concerning social and economic sustainability factors such as labor and capital.