propulsive output

简明释义

推进功率

英英释义

例句

1.The propulsive output of the new electric motor is significantly higher than its predecessor, making it more effective for electric vehicles.

新型电动机的推进输出明显高于其前身，使其在电动车中更有效。

2.The propulsive output of the underwater drone was tested in various conditions to ensure reliability.

水下无人机的推进输出在各种条件下进行了测试，以确保可靠性。

3.Engineers are constantly looking for ways to improve the propulsive output of jet engines to enhance fuel efficiency.

工程师们不断寻找提高喷气发动机的推进输出的方法，以增强燃油效率。

4.In naval architecture, understanding the propulsive output of a vessel is crucial for optimizing its performance.

在船舶设计中，理解船只的推进输出对优化其性能至关重要。

5.The rocket's engines were designed to maximize propulsive output, ensuring it could escape the Earth's atmosphere.

火箭的发动机旨在最大化推进输出，确保它能够逃离地球大气层。

作文

In the realm of physics and engineering, the concept of propulsive output refers to the amount of thrust or force produced by a propulsion system to move an object through a medium, such as air or water. This term is particularly significant in fields like aerospace engineering, marine engineering, and automotive design, where understanding the efficiency and effectiveness of propulsion systems is crucial for performance optimization. Propulsive output can be influenced by various factors, including the design of the engine, the type of fuel used, and the environmental conditions in which the vehicle operates.For instance, in aviation, the propulsive output of an aircraft's engines determines its ability to ascend, cruise, and maneuver effectively. A higher propulsive output typically translates to better performance, enabling the aircraft to carry heavier loads or travel longer distances. Engineers strive to maximize this output while minimizing fuel consumption, which is essential for both economic and environmental reasons. The development of more efficient engines and alternative fuels is a direct response to the need for improved propulsive output in modern aircraft.In marine applications, the propulsive output of a ship's engine affects its speed and maneuverability in water. Ships with powerful engines can navigate through rough seas more effectively, ensuring safety and efficiency in transportation. Moreover, advancements in technology have led to the creation of hybrid propulsion systems that enhance the propulsive output while reducing emissions. Such innovations are vital for meeting global environmental standards and promoting sustainable practices in maritime operations.Automotive engineering also places great emphasis on propulsive output. The performance of a vehicle is often measured by its acceleration and top speed, both of which rely heavily on the propulsive output generated by the engine. As electric vehicles become more prevalent, understanding how to optimize the propulsive output of electric motors is becoming increasingly important. Engineers are exploring ways to enhance the torque and efficiency of these motors to ensure that electric vehicles can compete with traditional gasoline-powered cars in terms of performance.Beyond technical specifications, the implications of propulsive output extend to broader discussions about energy consumption and sustainability. As the world grapples with climate change and the depletion of fossil fuels, the quest for higher propulsive output must be balanced with the need for cleaner energy solutions. This challenge drives innovation in propulsion technologies, leading to breakthroughs that not only improve performance but also reduce the ecological footprint of transport systems.In conclusion, the term propulsive output encompasses a vital aspect of propulsion systems across various modes of transportation. Its significance in engineering cannot be overstated, as it directly impacts performance, efficiency, and environmental considerations. As we continue to advance in technology, the pursuit of enhanced propulsive output will remain a key focus for engineers and researchers alike, shaping the future of transportation in a sustainable direction.

在物理和工程领域，propulsive output（推进输出）的概念指的是推进系统产生的推力或力量，以便通过空气或水等介质移动物体。这个术语在航空航天工程、海洋工程和汽车设计等领域尤为重要，因为了解推进系统的效率和有效性对于性能优化至关重要。propulsive output可能受到多种因素的影响，包括发动机的设计、使用的燃料类型以及车辆运行的环境条件。例如，在航空领域，飞机发动机的propulsive output决定了其上升、巡航和有效机动的能力。更高的propulsive output通常意味着更好的性能，使得飞机能够承载更重的负荷或飞行更长的距离。工程师们努力在最大化这一输出的同时，最小化燃料消耗，这对于经济和环境原因都是至关重要的。更高效的发动机和替代燃料的发展，正是对现代飞机提升propulsive output需求的直接响应。在海洋应用中，船舶发动机的propulsive output影响其在水中的速度和机动性。动力强大的船舶可以更有效地在恶劣海况中航行，确保运输的安全和效率。此外，技术的进步导致混合动力推进系统的创建，这些系统在提高propulsive output的同时降低排放。这类创新对于满足全球环境标准和促进海洋运营的可持续实践至关重要。汽车工程同样非常重视propulsive output。车辆的性能通常通过加速和最高速度来衡量，而这两者都在很大程度上依赖于发动机产生的propulsive output。随着电动汽车的普及，了解如何优化电动机的propulsive output变得越来越重要。工程师们正在探索增强这些电动机扭矩和效率的方法，以确保电动汽车在性能上能够与传统汽油车竞争。除了技术规格，propulsive output的影响还扩展到关于能源消耗和可持续性的更广泛讨论。随着世界面临气候变化和化石燃料枯竭的挑战，提高propulsive output的追求必须与寻求更清洁的能源解决方案相平衡。这一挑战推动了推进技术的创新，带来了不仅提高性能而且减少交通系统生态足迹的突破。总之，术语propulsive output涵盖了各种运输方式推进系统的重要方面。它在工程中的重要性不容小觑，因为它直接影响着性能、效率和环境考虑。随着我们在技术上的不断进步，提升propulsive output的追求将继续成为工程师和研究人员的重点，朝着可持续方向塑造交通的未来。