邊緣運算減少了數據傳輸到雲端的延遲,特別適用於需要快速反應的場景。將數據處理移至靠近數據生成位置的邊緣運算裝置,例如無人機上的嵌入式系統可以在追蹤或災害救援中,實現即時分析與決策。
對低軌衛星製造商、光學載荷設計團隊,以及航太級電子系統工程師而言,氣體揮發並不只是材料本身的問題,而是直接影響任務可靠性的潛在風險。
在 LEO 低軌衛星系統中,導熱介面材料負責將電子元件、功率模組、感測器、通訊系統與光學載荷所產生的熱量有效傳導至散熱結構。當這些材料長時間暴露於高真空、快速熱循環與嚴苛太空環境時,材料的穩定性就會與導熱係數一樣重要。
傳統矽膠基導熱墊片、導熱膏與間隙填充材料,可能含有低分子量矽氧烷或其他揮發性成分。在真空與高溫條件下,這些物質可能產生氣體揮發,並在衛星內部遷移,最後冷凝附著於敏感表面。這種分子級污染可能導致電氣接點失效、感測器訊號漂移、光學系統衰減,以及長期可靠性下降。
因此,低揮發導熱介面材料已成為 LEO 低軌衛星熱管理、航太電子設備、光學系統與真空敏感應用中越來越重要的材料選項。
As renewable energy rapidly expands, the demand for large-scale lithium battery storage systems continues to grow. However, the California lithium battery storage facility fire has once again exposed the latent safety risks of energy storage systems. This article examines the lithium battery fire health risks in depth, explores the mechanisms behind thermal runaway, and outlines effective prevention and thermal management solutions.
Lithium battery thermal runaway refers to a phenomenon where the battery temperature rises rapidly due to physical damage or short circuits, causing electrolyte decomposition and producing flammable gases. If adjacent battery modules are affected, it can trigger a chain reaction, ultimately leading to fire or explosion. This phenomenon not only threatens equipment safety but may also cause serious harm to personal safety and property.
隨著再生能源快速普及,大型鋰電池儲能系統的建置需求與日俱增。然而,加州鋰電池儲能廠火災事故再次揭示了儲能系統潛在的安全風險。本文將深入探討鋰電池火災的健康危害、熱失控成因,以及有效的預防與熱管理解決方案。
Lightweight thermal materials for drones must satisfy high-efficiency heat dissipation requirements while maintaining lightness and environmental adaptability. From high thermal conductivity resins to aerogel insulation, innovative aerodynamic design technologies are providing diverse solutions for drone performance enhancement.