4.7 Article

Impacts of thermo-optical properties on the seasonal operation of thermochromic smart window

Journal

ENERGY CONVERSION AND MANAGEMENT
Volume 252, Issue -, Pages -

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.enconman.2021.115058

Keywords

Renewable energy; Natural ventilation; Thermochromic glazing; Transition temperature; CFD modelling; Energy saving

Funding

  1. Australian Government through the Australian Research Council [DE200100892]
  2. Australian Research Council [DE200100892] Funding Source: Australian Research Council

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Thermochromic glazing smart windows are a promising technology for green buildings due to their self-regulating feature and low-maintenance need. This paper presents a validated computational fluid dynamics model to simulate the performance of these windows and determine the optimal switching temperatures under different climate conditions.
A type of smart window using thermochromic glazing (TCG) is a promising technology for green buildings owing to the self-regulating feature and low-maintenance need. Its most important feature, thermo-optical properties that regulate the blockage of solar heat, is directly linked to the variation of surface temperatures. However, challenges from the inhomogeneity of thermo-optical properties, the coupled solar radiation and natural convection, and varying outdoor conditions all seriously hinder the understanding of its mechanism. In this paper, a validated Computational Fluid Dynamics (CFD) model achieves the simulation of inhomogeneous tinting of TCG by defining the thermo-optical properties of each finite volume according to the surface temperature. Solar radiation and natural convection at outdoor, indoor and the cavity are solved to reflect glazing temperature more accurately. The case studies compared six different switching temperatures in the range of 20 similar to 42.5 degrees C with a transition gradient of 10 degrees C. Averaged meteorological data for both summer and winter, sunny days and cloudy days are selected to present realistic climate impacts. The result reveals the overall saving in transmitted solar radiation in summer and heating penalties in winter. It suggests the best switching temperatures for each climate condition. With the seasonal operation, the highest saving in solar heat gain is 20.9% when adopting a switching temperature of 25-35 degrees C, while the lowest saving can be negative, meaning TCG is not suitable for those climate zones. The proposed evaluation criteria help to quantify the applicability of TCG with the input of the summer/winter day ratio and sunny/cloudy ratio. The best region to apply TCG is where summer days are longer and winter solar radiation is significantly lower. The in-depth understanding of this temperature-sensitive process benefits the optimization of TCG in buildings, especially for its seasonal operation needs.

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