still air range

简明释义

无风航程

英英释义

例句

1.We measured the still air range of the model rocket during the test launch.

在测试发射期间，我们测量了模型火箭的静止空气射程。

2.The engineer calculated the still air range of the new drone to ensure it meets performance standards.

工程师计算了新无人机的静止空气射程以确保其符合性能标准。

3.Understanding the still air range is crucial for optimizing fuel efficiency in aircraft design.

理解静止空气射程对于优化飞机设计中的燃油效率至关重要。

4.The still air range can be affected by the weight and aerodynamics of the vehicle.

车辆的重量和空气动力学会影响其静止空气射程。

5.The pilot was briefed on the still air range before the flight to plan the route effectively.

飞行前，飞行员被告知静止空气射程以有效规划航线。

作文

Understanding the concept of still air range is crucial for anyone interested in aviation, aerodynamics, or even physics. The term refers to the maximum distance an aircraft can travel in still air conditions without any wind interference. This concept is not only applicable to airplanes but also to various other flying objects such as drones and rockets. To grasp the significance of still air range, we need to explore its implications on flight performance, fuel efficiency, and the overall design of aircraft.In aviation, the still air range is a critical factor that influences how far an aircraft can fly on a given amount of fuel. For example, commercial airlines carefully calculate the still air range of their aircraft to ensure they can reach their destinations without running out of fuel. This calculation takes into account many variables, including the weight of the aircraft, the efficiency of the engines, and the aerodynamic design of the plane. Moreover, understanding the still air range helps pilots make informed decisions during flights. For instance, if a pilot knows that their aircraft has a specific still air range, they can plan their route accordingly, taking into consideration factors such as weather conditions, altitude, and air traffic. This knowledge is particularly important when flying over long distances or in areas where fuel stops are limited.The still air range is also essential for aircraft manufacturers. Engineers must design planes that not only meet safety standards but also maximize their still air range. This involves extensive testing and simulations to find the optimal balance between weight, engine power, and aerodynamic efficiency. The goal is to create aircraft that can cover longer distances while consuming less fuel, thereby reducing operational costs for airlines and minimizing environmental impact.In addition to its practical applications, the concept of still air range can be appreciated from a theoretical standpoint. In physics, it serves as an excellent example of how different forces interact to affect motion. By studying the still air range, students can learn about principles such as lift, drag, thrust, and weight. These fundamental concepts are vital for anyone pursuing a career in aviation or aerospace engineering.Furthermore, the still air range can also be related to advancements in technology. With the rise of electric and hybrid aircraft, engineers are now exploring new ways to extend the still air range of these innovative machines. Battery technology and energy management systems play a significant role in determining how far these aircraft can travel before needing to recharge. As technology continues to evolve, the potential for increasing the still air range of various flying vehicles becomes more promising.In conclusion, the concept of still air range is multifaceted, impacting everything from flight planning and aircraft design to educational pursuits in physics and engineering. By understanding this term, individuals can gain insights into the complexities of flight and the continuous efforts to improve aviation technology. Whether one is a student, a pilot, or simply an aviation enthusiast, appreciating the significance of still air range enhances our comprehension of how aircraft operate and the challenges faced in the field of aviation. The journey of learning about still air range is not just about numbers; it is about understanding the principles that allow us to soar through the skies.

理解静止空气距离的概念对于任何对航空、空气动力学甚至物理感兴趣的人来说都是至关重要的。这个术语指的是在静止空气条件下，飞机在没有风干扰的情况下可以飞行的最大距离。这个概念不仅适用于飞机，还适用于各种其他飞行物体，如无人机和火箭。要掌握静止空气距离的重要性，我们需要探讨其对飞行性能、燃油效率和飞机整体设计的影响。在航空领域，静止空气距离是影响飞机在给定燃料量下能飞多远的关键因素。例如，商业航空公司会仔细计算其飞机的静止空气距离，以确保它们能够在不耗尽燃料的情况下到达目的地。这种计算考虑了许多变量，包括飞机的重量、发动机的效率和飞机的空气动力设计。此外，了解静止空气距离帮助飞行员在飞行中做出明智的决策。例如，如果飞行员知道他们的飞机具有特定的静止空气距离，他们就可以相应地规划航线，考虑天气条件、高度和空中交通等因素。这种知识在长途飞行或在燃料补给有限的地区飞行时尤为重要。静止空气距离对飞机制造商也至关重要。工程师必须设计出不仅符合安全标准而且最大化其静止空气距离的飞机。这涉及广泛的测试和模拟，以找到重量、发动机功率和空气动力效率之间的最佳平衡。目标是创造能够在消耗更少燃料的情况下覆盖更长距离的飞机，从而降低航空公司的运营成本并减少环境影响。除了其实际应用外，静止空气距离的概念从理论角度来看也值得欣赏。在物理学中，它是一个很好的例子，展示了不同力量如何相互作用以影响运动。通过研究静止空气距离，学生可以学习诸如升力、阻力、推力和重量等原理。这些基本概念对于任何追求航空或航天工程职业的人都是至关重要的。此外，静止空气距离还可以与技术进步相关联。随着电动和混合动力飞机的兴起，工程师们正在探索延长这些创新机器的静止空气距离的新方法。电池技术和能源管理系统在决定这些飞机在需要充电之前可以飞行多远方面发挥着重要作用。随着技术的不断发展，各种飞行器的静止空气距离增加的潜力变得更加可期。总之，静止空气距离的概念是多方面的，影响着从飞行规划和飞机设计到物理和工程教育的方方面面。通过理解这个术语，个人可以深入了解飞行的复杂性以及在航空领域面临的挑战。无论是学生、飞行员，还是单纯的航空爱好者，欣赏静止空气距离的重要性都增强了我们对飞机如何运作的理解，以及在航空领域所面临的挑战。学习静止空气距离的旅程不仅仅关乎数字；它关乎理解让我们能够翱翔天空的原理。