@article {57039, title = {An empirical study of a full-scale polymer thermochromic window and its implications on material science development objectives}, journal = {Solar Energy Materials and Solar Cells}, volume = {116}, year = {2013}, month = {09/2013}, pages = {14-26}, chapter = {14}, abstract = {

Large-area polymer thermochromic (TC) laminated windows were evaluated in a full-scale testbed office. The TC interlayer film exhibited thermochromism through a ligand exchange process, producing a change in solar absorption primarily in the visible range while maintaining transparent, undistorted views through the material. The film had a broad switching temperature range and when combined to make an insulating window unit had center-of-glass properties of Tsol=0.12-0.03, Tvis=0.28-0.03 for a glass temperature range of 24-75{\textdegree}C. Field test measurements enabled characterization of switching as a function of incident solar irradiance and outdoor air temperature, illustrating how radiation influences glass temperature and thus effectively lowers the critical switching temperature of TC devices. This was further supported by EnergyPlus building energy simulations. Both empirical and simulation data were used to illustrate how the ideal critical switching temperature or temperature range for TC devices should be based on zone heat balance, not ambient air temperature. Annual energy use data are given to illustrate the energy savings potential of this type of thermochromic. Based on observations in the field,a broad switching temperature range was found to be useful in ensuring a uniform appearance when incident irradiance is non-uniform across the facade. As indicated in prior research, a high visible transmittance in both the switched and unswitched state is also desirable to enable reduction of lighting energy use and enhance indoor environmental quality.

}, keywords = {buildings energy efficiency, Solar control, Thermochromic, windows}, doi = {10.1016/j.solmat.2013.03.043}, author = {Eleanor S. Lee and Xiufeng Pang and Sabine Hoffmann and Howdy Goudey and Anothai Thanachareonkit} }