foilborne condition

简明释义

水翼航行状态

英英释义

例句

1.The spacecraft was designed to operate under foilborne condition, which ensures stability during re-entry.

这艘航天器被设计为在箔载条件下操作，以确保在再入过程中的稳定性。

2.Understanding foilborne condition is crucial for developing safer and more efficient flight systems.

理解箔载条件对于开发更安全、更高效的飞行系统至关重要。

3.During the flight test, the pilot had to manage the aircraft under foilborne condition to avoid turbulence.

在飞行测试中，飞行员必须在箔载条件下管理飞机以避免颠簸。

4.Engineers tested the vehicle's performance in a foilborne condition to simulate extreme aerodynamic forces.

工程师们在箔载条件下测试了车辆的性能，以模拟极端的空气动力学力量。

5.The research focused on the effects of foilborne condition on material fatigue in aerospace applications.

这项研究集中于箔载条件对航空航天应用中材料疲劳的影响。

作文

In the realm of engineering and materials science, the term foilborne condition refers to a state where a material or component is supported or constrained by a thin layer or film, commonly referred to as a foil. This concept is critical in various applications, particularly in the aerospace and automotive industries, where weight reduction and efficiency are paramount. The use of foils can significantly enhance the performance characteristics of components, allowing them to withstand greater stresses while maintaining a lightweight profile.Understanding the foilborne condition is essential for engineers who design systems that rely on such materials. For instance, in the aerospace sector, aircraft wings often utilize composite materials that include foil layers to achieve optimal lift-to-drag ratios. The foil acts as a barrier that not only supports the structure but also enhances aerodynamic properties, ensuring that the aircraft can operate efficiently at high speeds.Moreover, the foilborne condition plays a crucial role in thermal management systems. In many electronic devices, heat sinks made from metal foils are employed to dissipate heat effectively. These foils help maintain the temperature of sensitive components, ensuring their longevity and reliability. The ability of a foil to conduct heat while remaining lightweight is a significant advantage in the design of modern electronics.In addition to its applications in aerospace and electronics, the foilborne condition is also relevant in the field of biomedical engineering. For instance, stents and implants often utilize foil-like structures to support biological tissues. These foils can be designed to be biocompatible, allowing them to integrate seamlessly with the body while providing necessary support to organs or blood vessels.The significance of understanding the foilborne condition extends beyond mere material properties; it encompasses the entire lifecycle of a product. Engineers must consider how these foils will behave under various environmental conditions, including temperature fluctuations, humidity, and mechanical stress. This holistic approach ensures that products are safe, reliable, and efficient throughout their intended lifespan.Furthermore, advancements in technology continue to evolve the applications of the foilborne condition. Innovations in manufacturing processes, such as 3D printing and nanotechnology, have opened new avenues for creating complex foil structures that were previously unattainable. These advancements enable engineers to design components with tailored properties, optimizing performance for specific applications.In conclusion, the foilborne condition is a fundamental concept in engineering that highlights the importance of using thin films or layers to enhance the performance of materials and components. Its applications span across various industries, including aerospace, electronics, and biomedical engineering. As technology progresses, the understanding and utilization of this condition will undoubtedly continue to evolve, leading to more efficient and innovative designs. By grasping the implications of the foilborne condition, engineers can create solutions that not only meet current demands but also pave the way for future advancements in material science and engineering practices.

在工程和材料科学领域，术语foilborne condition指的是一种状态，其中材料或组件由一层薄膜或薄层支持或约束，这通常被称为箔。这一概念在航空航天和汽车工业等各种应用中至关重要，因为减轻重量和提高效率是重中之重。箔的使用可以显著增强组件的性能特性，使其在保持轻量级的同时承受更大的应力。理解foilborne condition对于设计依赖于此类材料的系统的工程师至关重要。例如，在航空航天领域，飞机机翼常常利用包含箔层的复合材料以实现最佳的升阻比。箔作为一种屏障，不仅支持结构，还增强了气动特性，确保飞机能够在高速下高效运行。此外，foilborne condition在热管理系统中也发挥着至关重要的作用。在许多电子设备中，采用金属箔制成的散热器有效地散发热量。这些箔有助于维持敏感组件的温度，确保其耐用性和可靠性。箔导热的能力，同时保持轻量，是现代电子设备设计中的一个显著优势。除了在航空航天和电子产品中的应用外，foilborne condition在生物医学工程领域也具有相关性。例如，支架和植入物通常利用箔状结构来支持生物组织。这些箔可以设计为生物相容性，允许它们与身体无缝集成，同时为器官或血管提供必要的支持。理解foilborne condition的重要性超越了单纯的材料特性；它涵盖了产品的整个生命周期。工程师必须考虑这些箔在各种环境条件下的表现，包括温度波动、湿度和机械应力。这种整体方法确保产品在其预期的使用寿命内是安全、可靠且高效的。此外，技术的进步不断推动foilborne condition应用的发展。制造工艺的创新，如3D打印和纳米技术，为创造以前无法实现的复杂箔结构开辟了新的途径。这些进步使工程师能够设计具有定制性能的组件，优化特定应用的性能。总之，foilborne condition是工程中的一个基本概念，强调使用薄膜或薄层增强材料和组件性能的重要性。它的应用跨越多个行业，包括航空航天、电子和生物医学工程。随着技术的进步，对这一条件的理解和利用无疑将继续发展，导致更高效和创新的设计。通过掌握foilborne condition的意义，工程师可以创造出不仅满足当前需求而且为未来材料科学和工程实践的进步铺平道路的解决方案。