4.7 Article

Numerical evaluation of an optically switchable photovoltaic glazing system for passive daylighting control and energy-efficient building design

Journal

BUILDING AND ENVIRONMENT
Volume 219, Issue -, Pages -

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.buildenv.2022.109170

Keywords

Photovoltaic; Thermotropic layer; Solar concentration ratio; Solar heat gain; Useful daylight illuminance (UDI); Transition temperature

Funding

  1. Faculty of Engineering, University of Nottingham
  2. China Scholarship Council
  3. Engineering and Physical Sciences Research Council, UK [EP/S030786/1]

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This study proposed a versatile window called Building Integrated Photovoltaic (BIPV) smart window, which combines an optically switchable thermotropic layer, photovoltaic cells, and different types of glass covers to improve daylighting control, on-site electricity generation, and building energy efficiency. Numerical simulations showed that installing the BIPV smart window in a south-oriented office can achieve significant annual energy savings and provide a more comfortable indoor luminous environment.
Adaptive control of solar heat gain and visible light transmission through windows is perceived to be a potential measure for enhancing energy conservation and visual comfort in buildings. In this study, a novel versatile window, named Building Integrated Photovoltaic (BIPV) smart window, was proposed to offer simultaneous improvement of daylighting control, on-site electricity generation and building energy efficiency, compared to traditional BIPV windows with static optical properties. The key components of the proposed system include an optically switchable thermotropic layer made of Hydroxypropyl Cellulose (HPC) hydrogel, crystalline-silicon photovoltaic cells, clear glass and low-emissivity (low-e) glass covers. The thermotropic layer can respond to heat by autonomously changing its visible and near-infrared optical properties, with which the amount of solar radiation into building spaces can be manipulated and thus the risks of excessive solar heating and illumination can be prevented. Apart from excellent solar modulation, the BIPV smart window can collect a proportion of the light scattered from the thermotropic layer and concentrate it onto the integrated PV cells for extra electricity generation. An innovative methodology has been proposed to predict the optical, thermal and electrical properties of the BIPV smart window under varying ambient conditions. Numerical simulations have been carried out in EnergyPlus to predict the window's performance when it is applied to an office-type environment in the climate of Nottingham, the UK. The influence of different window design scenarios, in terms of Window-to-Wall Ratio (WWR), orientation and transition temperature, has been investigated. It was found that using the BIPV smart window can achieve an annual energy saving of 36.6% but also a more comfortable indoor luminous environment, compared to the counterpart BIPV window (with no thermotropic layer integrated), when installed in the south-oriented office with a WWR of 25%.

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