integrated lift and propulsion system

简明释义

升力推进综合系统

英英释义

例句

1.The research team is focused on optimizing the integrated lift and propulsion system to improve energy efficiency.

研究团队专注于优化集成升力和推进系统以提高能效。

2.With the integrated lift and propulsion system, the vertical takeoff and landing (VTOL) aircraft can operate in confined spaces.

凭借集成升力和推进系统，垂直起降（VTOL）飞机可以在狭小空间内操作。

3.The new drone features an integrated lift and propulsion system that enhances its flight stability.

这款新无人机配备了一个集成升力和推进系统，增强了其飞行稳定性。

4.Engineers are developing an integrated lift and propulsion system for the next generation of electric aircraft.

工程师们正在为下一代电动飞机开发一个集成升力和推进系统。

5.The integrated lift and propulsion system in this hovercraft allows it to glide over water and land smoothly.

这款气垫船中的集成升力和推进系统使其能够平滑地在水面和陆地上滑行。

作文

In the realm of aerospace engineering, the term integrated lift and propulsion system refers to a sophisticated mechanism that combines both the lifting and propelling functions of an aircraft into a single, cohesive unit. This innovative approach has revolutionized the design and functionality of modern aircraft, enabling them to achieve higher efficiency, reduced weight, and improved performance. The concept of an integrated lift and propulsion system is particularly significant in the development of vertical take-off and landing (VTOL) vehicles, which require a seamless transition between hovering and forward flight. By integrating these two critical functions, engineers can create systems that are not only more efficient but also more reliable and easier to control.One of the key advantages of an integrated lift and propulsion system is its ability to optimize aerodynamic performance. Traditional aircraft often rely on separate mechanisms for lift and propulsion, such as wings for lift and engines for thrust. This separation can lead to inefficiencies, as each component must be designed and optimized independently. In contrast, an integrated system allows for a more holistic approach to design, where the interaction between lift and propulsion can be finely tuned to maximize overall performance.Moreover, the integration of these systems can significantly reduce the overall weight of the aircraft. By eliminating the need for multiple engines or complex mechanical linkages, designers can create lighter and more compact aircraft. This reduction in weight not only enhances fuel efficiency but also improves maneuverability and responsiveness, which are crucial for both military and civilian applications.The use of an integrated lift and propulsion system has also paved the way for new types of aircraft that were previously unfeasible. For instance, hybrid-electric propulsion systems, which combine traditional fuel engines with electric motors, can be seamlessly integrated to provide both lift and thrust. This not only reduces emissions but also opens up possibilities for quieter and more sustainable air travel. As the aviation industry continues to face pressures to reduce its environmental impact, the adoption of integrated systems will play a pivotal role in shaping the future of flight.Furthermore, the advancements in technology, such as computational fluid dynamics and advanced materials, have greatly enhanced the feasibility of implementing integrated lift and propulsion systems. Engineers can now simulate and analyze the performance of these systems under various conditions, leading to more informed design choices and better overall outcomes. As a result, we are witnessing a new era of aircraft design that prioritizes efficiency, sustainability, and performance.In conclusion, the integrated lift and propulsion system represents a significant leap forward in aerospace engineering. By merging the functions of lift and propulsion, this innovative approach not only enhances the performance and efficiency of aircraft but also paves the way for groundbreaking advancements in aviation technology. As we continue to explore the possibilities of flight, the importance of integrated systems will only grow, leading to a future where air travel is more efficient, sustainable, and accessible than ever before.

在航空航天工程领域，术语集成升力和推进系统指的是一种复杂的机制，将飞机的升力和推进功能结合为一个统一的整体。这种创新的方法彻底改变了现代飞机的设计和功能，使其能够实现更高的效率、减轻重量和改善性能。集成升力和推进系统的概念在垂直起降（VTOL）飞行器的发展中尤为重要，这些飞行器需要在悬停和前向飞行之间无缝过渡。通过集成这两个关键功能，工程师可以创建不仅更高效，而且更可靠、更易于控制的系统。集成升力和推进系统的一个主要优点是能够优化气动性能。传统飞机通常依赖于独立的升力和推进机制，例如用于升力的机翼和用于推力的发动机。这种分离可能导致效率低下，因为每个组件必须独立设计和优化。相比之下，集成系统允许采用更全面的设计方法，其中升力和推进之间的相互作用可以精细调节，以最大化整体性能。此外，这些系统的集成可以显著降低飞机的整体重量。通过消除多个发动机或复杂机械连接的需求，设计师可以创建更轻便和紧凑的飞机。这种重量减少不仅提高了燃油效率，还改善了机动性和响应能力，这对于军用和民用应用至关重要。集成升力和推进系统的使用还为新型飞机铺平了道路，这些飞机在以前是不可行的。例如，混合电动推进系统将传统燃料发动机与电动机结合，可以无缝集成以提供升力和推力。这不仅减少了排放，还为更安静和可持续的航空旅行开辟了可能性。随着航空业继续面临减少环境影响的压力，集成系统的采用将在塑造未来飞行中发挥关键作用。此外，计算流体动力学和先进材料等技术的进步大大增强了实施集成升力和推进系统的可行性。工程师现在可以模拟和分析这些系统在各种条件下的性能，从而做出更明智的设计选择和更好的整体结果。因此，我们见证了一个新的飞机设计时代，优先考虑效率、可持续性和性能。总之，集成升力和推进系统代表了航空航天工程的重要飞跃。通过合并升力和推进的功能，这种创新方法不仅增强了飞机的性能和效率，还为航空技术的突破性进展铺平了道路。随着我们继续探索飞行的可能性，集成系统的重要性只会增加，导致一个航空旅行更加高效、可持续和可及的未来。