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Low-frequency vibration and noise control in sandwiched composite locally resonant metamaterials-embedded plate structures

Jewoo Choi, Byung Wook In, Taehoon Hong, Dong‐Eun Lee, Tongjun Cho, Hyo Seon Park

2024Developments in the Built Environment22 citationsDOIOpen Access PDF

Abstract

This study proposes a sandwiched composite locally resonant metamaterial (SLRM) system and SLRM-embedded plate structure (SLRMeP) to effectively control low-frequency vibrations and sound radiation. The wave control mechanism and configuration of the proposed system are more suitable and realistic to address practical low-frequency vibro-acoustic problems. A numerical model was proposed based on the material properties, unit dimensions, and mass ratios to determine the local resonance characteristics and bandgap formation. The experimental results on a full-scale SLRMeP measuring 3,000 × 4,200 × 210 mm confirmed the efficacy of the local resonance bandgap for controlling vibrations and sound radiation, achieving a 94.08% reduction in the acceleration response and a 15.13 dB reduction in the sound pressure level. Additionally, variations in mass ratio, achieved by altering the mass density or dimensions, yield distinct bandgap behaviors, offering strategies to enhance vibro-acoustic performance.

Topics & Concepts

MetamaterialInfrasoundMaterials scienceAcousticsVibrationFrequency bandReduction (mathematics)Resonance (particle physics)Low frequencyAccelerationBand gapVibration controlNoise controlNoise (video)Sound pressureAcoustic metamaterialsNoise reductionPhysicsOptoelectronicsEngineeringComputer scienceTelecommunicationsGeometryMathematicsImage (mathematics)Bandwidth (computing)Artificial intelligenceParticle physicsClassical mechanicsAcoustic Wave Phenomena ResearchNoise Effects and ManagementVibration Control and Rheological Fluids
Low-frequency vibration and noise control in sandwiched composite locally resonant metamaterials-embedded plate structures | Litcius