Integrating bio-inspired morphologies into porous media burners: Experimental and computational insights on interphase heat exchange

In this study, the influence of bio-inspired triply periodic minimal surface (TPMS) morphology on the behavior of porous media burners (PMBs) was investigated. Experimental testing, volume-averaged modeling, and computational fluid dynamics (CFD) are employed to explore the effects of TPMS morphology on PMB stability, temperature distribution, emissions, and thermal-fluid characteristics. Key findings reveal significant variations instability and temperature profiles among different TPMS morphologies, with the diamond and I-WP demonstrating superior stability compared to the gyroid and primitive. Additionally, CFD analysis uncovers distinct flow characteristics underlying the experimental observations, highlighting the importance of morphology optimization for enhancing interphase heat exchange and thus, burner performance. These findings provide valuable insights into the intricate interplay between TPMS morphology and PMB behavior, guiding future research towards advanced design strategies for combustion technology.