中科院推進高速無人機研發　攜手碳纖產業強化突防結構設計

隨著無人化與高速化成為現代戰場的重要趨勢，中山科學研究院（中科院）近年持續投入新世代高速無人載具研發，聚焦於高速巡航與末段俯衝等飛行模式，藉此提升突防成功率，強化整體空防突破能力。
As unmanned and high-speed systems become a defining trend in modern warfare, Taiwan’s National Chung-Shan Institute of Science and Technology (NCSIST) has intensified development of next-generation high-speed unmanned platforms, focusing on high-speed cruise and terminal dive flight profiles to enhance penetration success against air defense systems.

在研發與製造層面，中科院同步展開產業合作，結合國內具備航太級製造能量的關鍵廠商。其中，專精航太碳纖複合材料製程的碳基科技，已投入相關製程技術，協助提升高速無人機在高動能飛行環境下的結構強度、耐久性與製造一致性。
On the manufacturing front, NCSIST has partnered with domestic aerospace-capable suppliers. Carbon Base Technology, a specialist in aerospace-grade carbon composite manufacturing, has contributed process expertise to strengthen structural integrity, durability, and production consistency under high-energy flight conditions.

在無人化與高速載具蔚為主流的背景下，中科院持續以系統整合與前瞻設計為研發核心，規劃打造具備高機動性、長航程與多任務彈性的高速無人機，定位為不對稱作戰體系中的關鍵戰力節點。整體設計理念強調多功能、高彈性與可規模化部署，以支援精準打擊、戰場消耗、誘敵與戰術塑形等多重任務需求。
Against the backdrop of accelerating unmanned and high-speed system adoption, NCSIST is emphasizing system integration and forward-looking design to field high-mobility, long-range, multi-mission UAVs. These platforms are envisioned as key elements within Taiwan’s asymmetric warfare framework, designed for scalable deployment and capable of supporting precision strike, attrition, deception, and battlespace shaping roles.

碳基科技指出，高速無人載具可在高度防空威脅環境中，透過高速巡航與末段俯衝等多樣化飛行模式靈活運用，不僅能提高突防效率，也可與現有高價值打擊系統形成高低搭配，透過數量與節奏優勢消耗對手防空資源，放大整體作戰效益。
According to Carbon Base Technology, high-speed unmanned platforms can operate flexibly in dense air defense environments by combining sustained high-speed flight with terminal dive profiles. When paired with higher-value strike assets, such systems can exploit numerical and tempo advantages to exhaust enemy air defenses and amplify overall combat effectiveness.

在研發過程中，中科院特別重視高速、高機動飛行條件所帶來的結構挑戰，將機體完整性、耐熱能力與長時間可靠度列為核心技術指標，並同步納入製造一致性與未來量產可行性的評估。為此，團隊導入國內航太級複合材料製程，針對機殼、承力結構與關鍵複材組件進行工程驗證與優化。
Throughout development, NCSIST has placed particular emphasis on structural challenges associated with high-speed, high-maneuver flight, prioritizing airframe integrity, thermal resistance, and long-duration reliability. Manufacturing consistency and scalability have also been factored in, with aerospace-grade composite processes applied to validate and optimize load-bearing structures and critical components.

在此合作架構下，碳基科技主要提供航太碳纖複合材料的製程與工程支援，協助中科院在高速無人機結構設計與製造精度上，建立穩定且可複製的技術成果。航太級碳纖複材兼具高強度、輕量化與耐熱優勢，特別適合高速載具應用，但其製程門檻較高，成熟技術的導入有助降低量產風險。
Within this partnership framework, Carbon Base Technology provides aerospace carbon composite process and engineering support, enabling NCSIST to achieve stable and repeatable outcomes in structural design and manufacturing precision. Aerospace-grade carbon composites offer high strength, low weight, and thermal resilience—ideal for high-speed platforms—while mature processes help mitigate mass-production risks.

在無人化、高機動且具可消耗特性的載具逐漸成為各國防衛體系發展重點之際，中科院透過此次合作，展現國防科研體系在系統整合、產業協作與前瞻作戰布局上的成熟度。碳基科技表示，該型高速無人載具未來可望在反登陸、防空消耗與戰場塑形等任務中發揮關鍵作用，進一步強化整體防衛縱深與不對稱作戰效益。
As unmanned, high-mobility, and attritable platforms become central to modern defense planning, this collaboration highlights the maturity of Taiwan’s defense R&D ecosystem in system integration, industrial cooperation, and forward operational planning. Carbon Base Technology noted that such high-speed UAVs are expected to play a critical role in counter-landing operations, air defense attrition, and battlespace shaping, strengthening overall defensive depth and asymmetric warfare effectiveness.