Energy Harvesting: Efficient Mechanical Energy Conversion

Energy harvesting aims to convert ambient mechanical excitations—like vibration, motion, and structural responses—into usable electrical energy. Traditional systems often struggle with narrow operating bandwidths, rigid configurations, or material-dependent limitations. MetaDyna tackles these challenges with a fundamentally different approach: metamaterial based and mechanical conversion mechanisms, allowing mechanical energy to be captured far more effectively under diverse, real-world conditions.

Instead of fixed designs, MetaDyna develops tunable and application-adaptive energy harvesting structures. These structures are engineered to respond precisely to the characteristics of the excitation source, optimizing harvesting performance for low-frequency, broadband, or variable-input environments—all without increasing system size or complexity. The result is compact, lightweight, and seamlessly compatible energy harvesting solutions.

Our technology development is powered by proprietary computational design and optimization tools. These advanced tools provide systematic control over resonance behavior, coupling efficiency, and structural integration, ensuring our energy harvesting systems are tailored for specific use cases while remaining scalable and manufacturable.

Key Capabilities:

• Adaptability: Efficiently harvests energy from low-frequency components by converting them into high frequencies and broadband mechanical excitations.
• Tunable Response: Optimizes performance for changing operational conditions.
• Compact & Lightweight: Seamless structural integration without adding bulk.
• Compatibility: Works with existing materials and manufacturing processes.
• Scalability: Architectures suitable for both prototype and series production.

Application Impact:

MetaDyna’s energy harvesting solutions are designed to create self-powered sensing, monitoring, and autonomous systems. By converting otherwise unused mechanical energy into a continuous power source, we enable reduced maintenance, extended operational lifetimes, and significantly improved system reliability across industrial, mobility, aerospace, and infrastructure applications.