Global performance analysis of a solar-driven indoor CO2/H2O capture system for air quality enhancement and cooling energy saving

A human-eco-friendly building requires high indoor air quality (IAQ) and low carbon emissions. Existing nat-ural/mechanical ventilation methods rely on frequent exchange with fresh ambient air to remove excess respi-ratory CO2 for high IAQ. However, in tropical or subtropical regions, the introduced ambient air features higher humidity and temperature over indoor air, which inevitably increases the energy burden of air conditioning (AC) accompanied with severe CO2 emission. To circumvent this paradox, this study developed a dynamic solar-driven indoor CO2/H2O capture system with selective air recirculation. Rather than simply introducing ambient air to reduce indoor CO2 concentration, this scheme actively captures CO2/H2O and selectively returns post-captured air with sub-ambient temperature, relative humidity and CO2 concentration, thus sustaining high IAQ with reduced AC load and CO2 emission. The system's feasibility and stability are demonstrated through a 20-city global study and a 10-variable sensitivity analysis. Compared to traditional methods, this new system could save up to 64 % of cooling energy while maintaining the indoor CO2 concentration below 1000 ppm and relative humidity within 25 %-55 %. The energy-saving potential of the proposed system increases in regions with larger AC demands, as evidenced by Dakar achieving the highest energy-saving potential and thus decreasing CO2 emission. This system could further reduce CO2 emission by direct capture and storage, whose amount is posi-tively correlated to the amount of solar irradiance in cities. Furthermore, the system demonstrates robustness under off-design conditions and is flexible to be scaled up/down. Overall, this study provides effective-green ventilation strategies and paves the way for developing human-eco-friendly buildings.

Automated summary

This study developed a solar-driven indoor CO2/H2O capture system that effectively reduces energy burden and CO2 emission while maintaining high IAQ. Compared to traditional methods, this system could save up to 64% of cooling energy and control indoor CO2 concentration below 1000 ppm and relative humidity within 25%-55%.