applied thrust

简明释义

1. 施加推力; 2. 外加的推力; 3. 外施推力; 4. 作用推力;

英英释义

例句

1.The engineers calculated the amount of applied thrust to determine the rocket's trajectory.

工程师计算了施加的推力以确定火箭的轨迹。

2.The propulsion system was designed to optimize the applied thrust for maximum efficiency.

推进系统旨在优化施加的推力以实现最大效率。

3.Calculating the applied thrust is crucial for ensuring the spacecraft reaches its intended orbit.

计算施加的推力对于确保航天器达到预定轨道至关重要。

4.During the test flight, the aircraft experienced a significant increase in applied thrust during takeoff.

在试飞过程中，飞机在起飞时经历了施加的推力显著增加。

5.The team analyzed the data to see how variations in applied thrust affected fuel consumption.

团队分析数据，以查看施加的推力变化如何影响燃料消耗。

作文

In the field of engineering and physics, the term applied thrust refers to the force exerted by an engine or a propelling device to move an object forward. This concept is crucial in various applications, ranging from aerospace engineering to automotive design. Understanding applied thrust allows engineers to optimize performance and efficiency in their designs, ensuring that vehicles and aircraft can achieve their intended speeds and maneuvers.For instance, in aviation, the engines of an aircraft generate applied thrust to lift the plane off the ground and propel it through the air. The amount of thrust produced must overcome the weight of the aircraft and the drag created by air resistance. Engineers meticulously calculate the required applied thrust to ensure that the aircraft can take off, cruise, and land safely. This involves considering factors such as the aircraft's weight, wing design, and engine specifications.Similarly, in the automotive industry, applied thrust plays a vital role in vehicle performance. The power generated by the engine translates into thrust that moves the car forward. Factors like tire friction, road conditions, and vehicle aerodynamics all influence how effectively this thrust is utilized. Engineers strive to maximize applied thrust while minimizing fuel consumption, leading to advancements in technology such as hybrid and electric vehicles.Moreover, the concept of applied thrust is not limited to traditional vehicles. In space exploration, rockets rely heavily on the principles of thrust. When a rocket launches, it generates massive amounts of applied thrust to escape Earth's gravitational pull. The thrust must be precisely calculated to ensure that the rocket can reach its destination, whether that be orbiting the Earth or traveling to another planet. The science behind applied thrust in rocketry involves complex calculations and simulations to predict the behavior of the spacecraft under various conditions.Understanding applied thrust also extends to the realm of sports. Athletes often utilize the concept of thrust in their training and performance. For example, a sprinter applies thrust through their legs to propel themselves forward during a race. Coaches analyze the mechanics of this thrust to improve an athlete's speed and efficiency. Techniques such as optimizing stride length and frequency are essential for maximizing applied thrust in sprinting.In conclusion, the term applied thrust encompasses a fundamental principle that impacts numerous fields, including engineering, aerospace, automotive design, and even athletics. By understanding and mastering the concept of applied thrust, professionals can innovate and enhance performance across various domains. As technology continues to evolve, the importance of effectively applying thrust will only increase, paving the way for advancements that could change the way we travel and explore our world.

在工程和物理学领域，术语applied thrust指的是由发动机或推进装置施加的力量，以推动物体向前移动。这个概念在航空航天工程到汽车设计等各种应用中至关重要。理解applied thrust使工程师能够优化设计中的性能和效率，确保车辆和飞机能够达到预期的速度和机动能力。例如，在航空领域，飞机的发动机产生applied thrust以将飞机从地面升起并推动其在空中飞行。产生的推力必须克服飞机的重量以及空气阻力所造成的阻力。工程师精确计算所需的applied thrust，以确保飞机能够安全起飞、巡航和着陆。这需要考虑飞机的重量、机翼设计和发动机规格等因素。同样，在汽车工业中，applied thrust在车辆性能中发挥着重要作用。发动机产生的动力转化为推动汽车向前的推力。轮胎摩擦、路况和车辆空气动力学等因素都会影响这种推力的有效利用。工程师努力在最大化applied thrust的同时，最小化燃料消耗，从而推动混合动力和电动车辆等技术的进步。此外，applied thrust的概念并不仅限于传统车辆。在太空探索中，火箭在很大程度上依赖于推力原理。当火箭发射时，它会产生大量的applied thrust以逃离地球的引力。推力必须精确计算，以确保火箭能够到达目的地，无论是绕地球轨道飞行还是前往其他行星。火箭中的applied thrust科学涉及复杂的计算和模拟，以预测航天器在各种条件下的行为。理解applied thrust还延伸到体育领域。运动员在训练和表现中常常利用推力的概念。例如，短跑运动员通过腿部施加推力，在比赛中向前推进。教练分析这种推力的力学，以提高运动员的速度和效率。优化步幅和频率等技术对于最大化短跑中的applied thrust至关重要。总之，术语applied thrust涵盖了一个基本原则，影响着多个领域，包括工程、航空航天、汽车设计甚至体育。通过理解和掌握applied thrust的概念，专业人士可以在各个领域进行创新和提升性能。随着技术的不断发展，有效应用推力的重要性只会增加，为可能改变我们旅行和探索世界方式的进步铺平道路。