thrust increment

简明释义

推力增量

英英释义

例句

1.The rocket's design includes a significant thrust increment 推力增量 during the second stage of launch.

火箭的设计在发射的第二阶段包含了显著的推力增量。

2.The team analyzed the thrust increment 推力增量 data from the last flight test.

团队分析了上次飞行测试中的推力增量数据。

3.A reliable thrust increment 推力增量 is crucial for achieving orbit.

可靠的推力增量对于达到轨道至关重要。

4.Engineers are testing the thrust increment 推力增量 to ensure it meets safety standards.

工程师正在测试推力增量以确保其符合安全标准。

5.The new engine model promises a higher thrust increment 推力增量 for improved performance.

新的发动机模型承诺提供更高的推力增量以改善性能。

作文

In the field of aerospace engineering, understanding the principles of propulsion is essential for the design and optimization of aircraft and spacecraft. One crucial concept that comes into play is the thrust increment, which refers to the increase in thrust produced by an engine when certain parameters are adjusted. This can occur due to changes in fuel flow, engine speed, or even environmental conditions. The ability to manipulate the thrust increment effectively allows engineers to enhance performance, improve fuel efficiency, and ensure safety during flight.To illustrate, consider a scenario where an aircraft is ascending. During takeoff, the engines must provide a significant amount of power to overcome gravity and achieve lift. Here, the thrust increment becomes particularly important. By adjusting the engine's throttle settings, engineers can achieve a higher thrust increment, allowing the aircraft to climb more rapidly and efficiently. This is vital not only for performance but also for meeting regulatory requirements regarding ascent rates.Moreover, the thrust increment plays a critical role in maneuverability. When an aircraft needs to change its trajectory—whether to avoid obstacles or to follow a specific flight path—engineers rely on precise calculations of thrust increment. A well-timed increase in thrust can significantly alter the aircraft's direction and speed, providing pilots with the necessary control to navigate safely.In addition to commercial aviation, the concept of thrust increment is equally important in the realm of space exploration. Rockets, for instance, depend on high thrust increments to escape Earth's gravitational pull. Engineers meticulously plan the stages of a rocket launch, ensuring that each phase provides the necessary thrust to propel the vehicle into orbit. Any miscalculation in the thrust increment could jeopardize the mission, making it imperative for engineers to have a deep understanding of this concept.Furthermore, advancements in technology have led to the development of more sophisticated engines capable of producing greater thrust increments while minimizing fuel consumption. This not only benefits the environment by reducing emissions but also enhances the economic viability of air travel and space missions. As the industry moves towards sustainable practices, the optimization of thrust increment will continue to be a focal point for research and development.In conclusion, the concept of thrust increment is fundamental in aerospace engineering, influencing everything from takeoff procedures to complex maneuvers in flight. A comprehensive understanding of how to achieve and optimize thrust increment is crucial for engineers tasked with designing efficient and safe aircraft and spacecraft. As technology evolves, the significance of thrust increment will only grow, paving the way for innovations that could redefine the limits of aviation and space exploration.

在航空航天工程领域，理解推进原理对于飞机和航天器的设计与优化至关重要。其中一个关键概念是推力增量，指的是当某些参数调整时，发动机产生的推力增加。这可能由于燃料流量、发动机转速甚至环境条件的变化而发生。有效地操控推力增量使工程师能够提升性能、改善燃油效率，并确保飞行安全。例如，考虑一个飞机正在上升的场景。在起飞过程中，发动机必须提供大量动力以克服重力并实现升力。在这里，推力增量显得尤为重要。通过调整发动机的油门设置，工程师可以实现更高的推力增量，使飞机能够更快速、更高效地爬升。这不仅对性能至关重要，还满足了关于上升率的监管要求。此外，推力增量在机动性方面也发挥着关键作用。当飞机需要改变轨迹时——无论是为了避开障碍物还是遵循特定飞行路径——工程师依赖于对推力增量的精确计算。适时增加推力可以显著改变飞机的方向和速度，为飞行员提供必要的控制，确保安全飞行。除了商业航空之外，推力增量的概念在太空探索领域同样重要。例如，火箭依赖于高推力增量来逃离地球的引力。工程师精心规划火箭发射的各个阶段，确保每个阶段提供必要的推力将飞行器推进到轨道。任何对推力增量的误算都可能危及任务，因此工程师深入理解这一概念至关重要。此外，技术的进步导致开发出能够在最小化燃料消耗的同时产生更大推力增量的更复杂的发动机。这不仅通过减少排放有利于环境，还增强了航空旅行和太空任务的经济可行性。随着行业向可持续实践迈进，优化推力增量将继续成为研究和发展的重点。总之，推力增量的概念在航空航天工程中是基础性的，影响着从起飞程序到飞行中的复杂机动等方方面面。全面理解如何实现和优化推力增量对于负责设计高效且安全的飞机和航天器的工程师至关重要。随着技术的发展，推力增量的重要性只会增加，为重新定义航空和太空探索的界限铺平道路。