turning thrust vector

简明释义

转动推力矢量

英英释义

例句

1.A precise control of the turning thrust vector is essential for landing on uneven surfaces.

精确控制转向推力矢量对于在不平坦表面着陆至关重要。

2.The fighter jet's agility is enhanced by its advanced turning thrust vector technology.

战斗机的灵活性通过其先进的转向推力矢量技术得到了增强。

3.The engineers tested the turning thrust vector system to ensure it could handle extreme angles.

工程师们测试了转向推力矢量系统，以确保它能够处理极端角度。

4.By adjusting the turning thrust vector, the spacecraft can change its trajectory effectively.

通过调整转向推力矢量，航天器可以有效地改变其轨迹。

5.The rocket's ability to maneuver in space relies heavily on its turning thrust vector.

火箭在太空中机动的能力在很大程度上依赖于其转向推力矢量。

作文

In the realm of aerospace engineering, the concept of turning thrust vector plays a crucial role in enhancing the maneuverability and control of various flying vehicles. The term refers to the ability to change the direction of the thrust produced by an engine, allowing for more agile movements and precise navigation. This technology is particularly significant in the design of modern fighter jets, rockets, and even some commercial aircraft, where agility and responsiveness are paramount.To understand the importance of turning thrust vector, one must first grasp how traditional propulsion systems operate. Most aircraft utilize fixed nozzles that direct exhaust gases in a single direction, providing thrust in a straight line. While this system is effective for cruising and maintaining altitude, it lacks the flexibility needed for complex maneuvers. In contrast, turning thrust vector systems employ adjustable nozzles that can pivot or rotate, redirecting the thrust vector and enabling the aircraft to perform sharp turns and rapid ascents or descents.The implementation of turning thrust vector technology has revolutionized aerial combat. For instance, advanced fighter jets equipped with this capability can outmaneuver opponents in dogfights, making them formidable in air superiority missions. By altering the direction of the thrust during flight, pilots can execute sudden changes in trajectory, evading incoming missiles or gaining advantageous positions against adversaries. This level of control significantly enhances the chances of success in high-stakes military operations.Moreover, turning thrust vector is not limited to military applications. It is also finding its way into the commercial aviation sector. Airlines are increasingly interested in aircraft that can utilize this technology to improve fuel efficiency and reduce travel times. By optimizing flight paths through better maneuverability, airlines can minimize fuel consumption and lower operational costs, which is essential in today’s competitive aviation market.The development of turning thrust vector systems involves intricate engineering challenges. Engineers must ensure that the mechanisms for adjusting the nozzles are reliable and can withstand the extreme conditions of flight. Additionally, the integration of these systems with existing avionics and control systems requires extensive testing and validation. However, advancements in materials science and computer technology are making it increasingly feasible to implement these sophisticated systems in new aircraft designs.In conclusion, the concept of turning thrust vector represents a significant advancement in aerospace technology, offering enhanced maneuverability and control for various types of aircraft. Its application in both military and commercial aviation underscores its versatility and importance in modern flight dynamics. As engineers continue to push the boundaries of what is possible, we can expect to see even more innovative uses of turning thrust vector technology, paving the way for the future of aviation and space exploration.

在航空航天工程领域，转向推力矢量的概念在增强各种飞行器的机动性和控制能力方面发挥着至关重要的作用。这个术语指的是改变发动机产生的推力方向的能力，从而允许更灵活的运动和精确的导航。这项技术在现代战斗机、火箭甚至一些商业飞机的设计中尤为重要，因为机动性和响应性是至关重要的。要理解转向推力矢量的重要性，首先必须掌握传统推进系统的工作原理。大多数飞机使用固定喷嘴，直接将废气朝一个方向排出，从而提供直线推力。虽然这种系统在巡航和维持高度方面有效，但它缺乏进行复杂机动所需的灵活性。相比之下，转向推力矢量系统采用可调喷嘴，可以旋转或转动，重新定向推力矢量，使飞机能够执行急转弯和快速上升或下降。转向推力矢量技术的实施彻底改变了空战。例如，配备此能力的先进战斗机可以在空战中超越对手，使其在空中优势任务中具有强大的优势。通过在飞行过程中改变推力方向，飞行员可以快速改变轨迹，躲避来袭导弹或占据有利位置。这种控制水平显著提高了在高风险军事行动中的成功几率。此外，转向推力矢量不仅限于军事应用。它也逐渐进入商业航空领域。航空公司越来越关注能够利用这项技术来提高燃油效率和缩短旅行时间的飞机。通过更好的机动性优化飞行路径，航空公司可以减少燃料消耗并降低运营成本，这在当今竞争激烈的航空市场中至关重要。转向推力矢量系统的发展涉及复杂的工程挑战。工程师必须确保调整喷嘴的机制可靠，并能承受飞行的极端条件。此外，这些系统与现有航空电子设备和控制系统的集成需要广泛的测试和验证。然而，材料科学和计算机技术的进步使得在新飞机设计中实施这些复杂系统变得越来越可行。总之，转向推力矢量的概念代表了航空航天技术的重大进步，为各种类型的飞机提供了增强的机动性和控制能力。它在军事和商业航空中的应用突显了其多功能性和在现代飞行动态中的重要性。随着工程师不断推动可能性的边界，我们可以期待看到转向推力矢量技术的更多创新应用，为航空和太空探索的未来铺平道路。