posted on 2024-04-10, 14:56authored byFuping Chen, Xuewei Wu, Guoqiang Lu, Jun Nie, Xiaoqun Zhu
With the fast economic development
and accelerating urbanization,
more and more skyscrapers made entirely of concrete and glass are
being constructed. To keep a comfortable indoor environment, massive
energy for air conditioning or heating appliances is consumed. A huge
amount of heat (>30%) is gained or released through glass windows.
Using smart windows with the capability to modulate light is an effective
way to reduce building energy consumption. Thermochromic hydrogel
is one of the potential smart window materials due to its excellent
thermal response, high radiation-blocking efficiency, cost-effectiveness,
biocompatibility, and good uniformity. In this work, polyhydroxypropyl
acrylate (PHPA) hydrogels with controllable lower critical solution
temperature (LCST) were prepared by photopolymerization. The transition
temperature and transition rate under “static transition”
conditions were investigated. Unlike “static” conditions
in which the transition temperature was not affected by the initial
and final temperature and heating/cooling ramp, the transition temperature
varied with the rate of temperature change under dynamic conditions.
The “dynamic” transition temperature of the PHPA hydrogel
gradually increased with the increase of the heating rate. It was
the result of the movement of the molecular chains lagging behind
the temperature change when the temperature change was too fast. The
results of the solar irradiation experiment by filling PHPA hydrogels
into double glazing windows showed that the indoor temperature was
about 15 °C lower than that of ordinary glass windows, indicating
that it can significantly reduce the energy consumption of air conditioning.
In addition, a wide range of adjustable transition temperatures and
fast optical response make PHPA hydrogels potentially applicable to
smart windows.