Full-band vibration isolation and energy absorption via cuttlebone-inspired lattice structures

Abstract

In diverse engineering disciplines, vibration isolation technology is indispensable for ensuring stability, accuracy, and safety. Traditional vibration isolation methods often compromise structural rigidity, particularly at ultra-low frequencies, presenting a significant challenge. To solve this issue, this study introduces cuttlebone-inspired lattice structures (CILS), which are fabricated using selective laser sintering (SLS) 3D printing and have an excellent energy absorption capacity as well as enhanced vibration isolation. This innovation enables effective low-frequency, full-band vibration isolation while preserving structural stiffness. CILS have an excellent energy absorption capacity of 1.411 J/mm3, which is due to the maintenance of a zero Poisson's ratio even under significant deformation (a strain of 0.5). Vibration isolation tests revealed that CILS provide comprehensive isolation across the frequency spectrum of 5–36.77 Hz. Furthermore, CILS effectively extends full-band vibration isolation to medium and high-frequency bands encompassing 56.01 Hz to 2000 Hz. The proposed design strategy offers a novel approach by integrating high energy absorption with extensive isolation capabilities, effectively overcoming traditional limitations to enhance engineering stability and safety.