thrust horse-power

简明释义

推进马力推力马力

英英释义

Thrust horse-power refers to a measure of the effective power output of an engine or motor, specifically in the context of propulsion systems, where it indicates the thrust produced by the engine multiplied by the velocity at which the thrust is applied.

推力马力是指发动机或电动机的有效功率输出的一个测量,特别是在推进系统的背景下,它表示发动机产生的推力与推力施加的速度的乘积。

例句

1.A higher thrust horse-power 推力马力 rating generally indicates a more powerful engine.

更高的推力马力 推力马力 评级通常表示发动机更强大。

2.To achieve optimal performance, the thrust horse-power 推力马力 must be matched with the weight of the aircraft.

为了实现最佳性能,推力马力 推力马力 必须与飞机的重量相匹配。

3.The aircraft's engine produces a maximum of thrust horse-power 推力马力 to ensure it can take off efficiently.

飞机的发动机产生最大推力马力 推力马力,以确保其能够高效起飞。

4.When calculating performance, engineers often refer to the thrust horse-power 推力马力 generated by the jet engines.

在计算性能时,工程师通常会参考喷气发动机产生的推力马力 推力马力

5.The speed of the boat is directly related to its thrust horse-power 推力马力 output.

船只的速度与其输出的推力马力 推力马力 直接相关。

作文

In the world of engineering and aviation, understanding the concept of thrust horse-power is crucial for both designers and operators of aircraft. Thrust horse-power refers to the measure of the power produced by an engine that is used to generate thrust, which propels an aircraft forward. This term combines two vital concepts in aerodynamics: thrust and horsepower. Thrust is the force that moves an aircraft through the air, while horsepower is a unit of measurement that quantifies the rate at which work is done. When these two elements are combined, we can assess how effectively an engine converts fuel into motion.The significance of thrust horse-power becomes evident when analyzing the performance of different aircraft. For instance, during takeoff, an aircraft requires a substantial amount of thrust to overcome gravitational forces. The engines must produce enough thrust horse-power to ensure that the aircraft can lift off the ground safely. Engineers meticulously calculate the required thrust horse-power based on various factors, including the weight of the aircraft, the altitude at which it will operate, and the desired speed.Moreover, thrust horse-power is not only important for takeoff but also plays a critical role during cruising and landing phases. As an aircraft climbs to cruising altitude, the engines must maintain a specific level of thrust horse-power to counteract drag and maintain speed. Similarly, during descent and landing, pilots must manage the thrust horse-power to ensure a smooth approach and touchdown.In addition to its practical implications, thrust horse-power has become a focal point in discussions about efficiency and environmental impact. Modern aircraft are designed with fuel efficiency in mind, and optimizing thrust horse-power is a key factor in reducing fuel consumption and emissions. Engineers strive to create engines that provide maximum thrust horse-power while minimizing fuel usage, thereby contributing to more sustainable aviation practices.Furthermore, advancements in technology have led to innovations in engine design that enhance thrust horse-power. For example, turbojet and turbofan engines have revolutionized the aviation industry by providing higher levels of thrust horse-power without significantly increasing weight. These developments allow aircraft to achieve better performance metrics, making air travel faster and more efficient.In conclusion, the concept of thrust horse-power is fundamental in the field of aviation, impacting everything from aircraft design to operational efficiency. Understanding this term enables engineers and pilots to make informed decisions that enhance safety and performance. As the aviation industry continues to evolve, the importance of thrust horse-power will remain a pivotal element in the quest for innovation and sustainability in air travel.

在工程和航空的世界中,理解“推力马力”的概念对飞机的设计师和操作员至关重要。“推力马力”指的是发动机产生的用于产生推力的功率测量,这种推力使飞机向前推进。这个术语结合了空气动力学中的两个重要概念:推力和马力。推力是将飞机移动穿过空气的力量,而马力是量化完成工作速率的测量单位。当这两个元素结合时,我们可以评估引擎将燃料转化为运动的有效性。“推力马力”的重要性在于分析不同飞机的性能时变得显而易见。例如,在起飞期间,飞机需要大量的推力来克服重力。发动机必须产生足够的“推力马力”以确保飞机能够安全地离开地面。工程师根据各种因素仔细计算所需的“推力马力”,包括飞机的重量、其将要操作的高度以及所需的速度。此外,“推力马力”不仅对起飞重要,而且在巡航和着陆阶段也发挥着关键作用。当飞机爬升到巡航高度时,发动机必须维持特定水平的“推力马力”以抵消阻力并保持速度。同样,在下降和着陆过程中,飞行员必须管理“推力马力”以确保平稳的接近和着陆。除了实际影响外,“推力马力”已成为关于效率和环境影响讨论的焦点。现代飞机的设计考虑到了燃油效率,优化“推力马力”是减少燃油消耗和排放的关键因素。工程师努力创造出在最小化燃油使用的同时提供最大“推力马力”的引擎,从而为更可持续的航空实践做出贡献。此外,技术的进步导致了增强“推力马力”的发动机设计创新。例如,涡喷和涡扇发动机通过提供更高水平的“推力马力”而没有显著增加重量,彻底改变了航空业。这些发展使飞机能够实现更好的性能指标,使航空旅行变得更快、更高效。总之,“推力马力”的概念在航空领域是基础,对飞机设计到操作效率的各个方面都有影响。理解这一术语使工程师和飞行员能够做出明智的决策,从而提高安全性和性能。随着航空业的不断发展,“推力马力”的重要性将在追求航空旅行创新和可持续性的过程中保持关键元素。