Abstract
Kinetic shading devices have recently been introduced for energy-saving and for their innovative appearance. Quantifiable research on kinetic operation systems is necessary to evaluate their applicability in a specific region. This study developed a theoretical methodology for producing an optimal positioning algorithm targeting minimizing total energy demands of kinetic shading devices; the control algorithms for hourly operation were tested through a combined analysis framework of energy performance simulations and spreadsheet analysis. Two common types of external shading devices, vertical-folding and horizontal-rotating types, were simulated in three Asian cities with different climate conditions. Automatic kinetic operation with a consequential dimming control was simulated on the east, south and west facade of an office building, selecting the optimal position every hour based on total energy demand for heating, cooling, and lighting. Comparative simulation analyses for kinetic operation and fixed shading demonstrated that the energy saving potential of fixed shading was greater than that of kinetic operation shading. Kinetic operation was the most applicable in Seoul, where seasonal optimal operation was required for both types of kinetic shadings. In Abu Dhabi and Hanoi, cooling and lighting energy demands were balanced every hour through kinetic operation. Rotating-type kinetic operation in these two regions resulted in better energy-saving performance. The operation frequency pattern of rotating-type kinetic shading provided more active operation and consequent outperformance over the folding-type.
Highlights
The amount of greenhouse gas emissions is rapidly increasing globally, contributing to global climate change
The United Nations Framework Convention on Climate Change (UNFCCC) recognized that the reduction of building energy consumption is essential for reducing overall energy consumption, organizing the Global Alliance for Buildings and Construction and launching a roadmap for buildings [3]
Kinetic shading devices have been developed to maximize the performance of traditional shading devices to cope with the ever-changing outdoor environment, by adjusting the form of external shading devices according to the position of the sun or climate conditions to minimize the disadvantages of conventional fixed shading devices [6]
Summary
The amount of greenhouse gas emissions is rapidly increasing globally, contributing to global climate change. The International Energy Agency (IEA) reported that building energy consumption in urban areas accounts for the most significant portion (40%) of total global energy consumption. This is predicted to increase by 30% by 2035 [2]. The energy-saving potential of optimal kinetic operation was analyzed for three Asian cities (Seoul, Abu Dhabi, and Hanoi), with different climate conditions, to determine the applicability of kinetic shading devices. Total energy consumption (i.e., for heating, cooling, and lighting) of the different types of kinetic shading devices was comprehensively evaluated for each city, and the applicability of each device was analyzed
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