azimuth handwheel
简明释义
方位操纵轮
英英释义
A hand-operated wheel used to adjust the azimuth angle in navigation or positioning systems. | 用于在导航或定位系统中调整方位角的手动操作轮。 |
例句
1.During the calibration process, ensure the azimuth handwheel is functioning correctly.
在校准过程中,确保方位手轮正常工作。
2.To get a clearer signal, turn the azimuth handwheel slowly until you find the optimal angle.
为了获得更清晰的信号,慢慢转动方位手轮,直到找到最佳角度。
3.The operator adjusted the position of the satellite dish using the azimuth handwheel.
操作员使用方位手轮调整卫星天线的位置。
4.He turned the azimuth handwheel to align the radar system with the incoming aircraft.
他转动方位手轮,将雷达系统与来袭的飞机对齐。
5.The azimuth handwheel allows for precise directional adjustments in the telescope.
在望远镜中,方位手轮允许进行精确的方向调整。
作文
In the world of navigation and engineering, precision is paramount. One of the key components that facilitate this precision in various applications, such as in ships, aircraft, and even telescopes, is the azimuth handwheel. The azimuth handwheel is a mechanical device that allows operators to adjust the direction of an object with great accuracy. By rotating the handwheel, users can change the azimuth angle, which is crucial for determining the position of an object relative to a reference point, often true north.The concept of azimuth originates from astronomy and navigation, where it refers to the angle between a reference direction (usually north) and the line of sight to an object. In practical terms, when an operator turns the azimuth handwheel, they are effectively altering the azimuth angle, enabling them to track moving objects or aim devices accurately. This is especially important in fields such as maritime navigation, where the ability to pinpoint a vessel's heading can mean the difference between safe passage and disaster.The design of the azimuth handwheel is typically ergonomic, allowing for easy manipulation even in challenging environments. It is often marked with gradations or indicators that provide visual feedback to the operator about the current azimuth setting. This feature is critical because it enhances situational awareness, allowing users to make informed decisions based on real-time data.In addition to its use in navigation, the azimuth handwheel plays a vital role in various scientific and industrial applications. For instance, astronomers utilize this device to align telescopes with celestial bodies. By adjusting the azimuth, they can ensure that the telescope is pointed accurately at stars or planets they wish to observe. Similarly, in the field of geodesy, surveyors use the azimuth handwheel to measure angles between landmarks, contributing to the accurate mapping of geographical areas.Moreover, technology has advanced the functionality of the azimuth handwheel. In modern applications, these handwheels can be integrated with digital displays and electronic controls, providing enhanced features such as automatic tracking and remote operation. This integration not only improves accuracy but also increases efficiency, making it easier for operators to manage complex tasks.Despite the advancements in technology, the fundamental importance of the azimuth handwheel remains unchanged. It serves as a reminder of the balance between traditional techniques and modern innovations. Operators who understand how to use this tool effectively can navigate challenges with confidence, ensuring that they maintain control over their equipment and achieve their objectives.In conclusion, the azimuth handwheel is more than just a mechanical component; it is a crucial tool that embodies the principles of precision and control in navigation and engineering. Whether in the hands of a sailor, an astronomer, or an engineer, the ability to manipulate azimuth angles with the azimuth handwheel is essential for success in various fields. As technology continues to evolve, the significance of this simple yet effective device will undoubtedly endure, proving that sometimes, the simplest tools can have the most profound impact on our ability to explore and understand the world around us.
在导航和工程的世界中,精确性至关重要。促进这种精确性的关键组件之一是方位手轮,它在船舶、飞机甚至望远镜等各种应用中发挥着重要作用。方位手轮是一种机械装置,使操作员能够以极高的精度调整物体的方向。通过旋转手轮,用户可以改变方位角,这对于确定物体相对于参考点(通常是真北)的位置至关重要。方位的概念源于天文学和导航,它指的是参考方向(通常是北)与观察对象之间的角度。在实际操作中,当操作员转动方位手轮时,他们实际上是在改变方位角,从而使他们能够准确跟踪移动物体或瞄准设备。这在海洋导航等领域尤其重要,因为能够精确定位船只的航向可能意味着安全通行与灾难之间的区别。方位手轮的设计通常符合人体工程学,即使在恶劣环境中也便于操作。它通常带有刻度或指示器,为操作员提供有关当前方位设置的视觉反馈。这一特性至关重要,因为它增强了情境意识,使用户能够根据实时数据做出明智的决策。除了在导航中的应用,方位手轮在各种科学和工业应用中也发挥着重要作用。例如,天文学家利用该装置将望远镜与天体对齐。通过调整方位,他们可以确保望远镜准确指向他们希望观察的星星或行星。同样,在测绘学领域,测量员使用方位手轮测量地标之间的角度,有助于准确绘制地理区域。此外,技术的发展提升了方位手轮的功能。在现代应用中,这些手轮可以与数字显示屏和电子控制集成,提供自动跟踪和远程操作等增强功能。这种集成不仅提高了准确性,还增加了效率,使操作员更容易管理复杂任务。尽管技术不断进步,但方位手轮的基本重要性仍然没有改变。它提醒我们传统技术与现代创新之间的平衡。了解如何有效使用这一工具的操作员可以自信地应对挑战,确保他们掌控设备,达到目标。总之,方位手轮不仅仅是一个机械组件;它是导航和工程中体现精确性和控制原则的重要工具。无论是在水手、天文学家还是工程师的手中,使用方位手轮操控方位角的能力对于各个领域的成功至关重要。随着技术的不断发展,这一简单但有效的设备的重要性无疑将持续存在,证明有时,最简单的工具可以对我们探索和理解周围世界的能力产生深远的影响。
相关单词
