swinging radius

简明释义

旋转半径

英英释义

例句

1.It's crucial to mark the area within the swinging radius 摆动半径 of the boom to keep workers safe.

在吊臂的swinging radius 摆动半径内标记区域是至关重要的，以确保工人安全。

2.During the inspection, we found that the swinging radius 摆动半径 was not properly accounted for in the safety plan.

在检查过程中，我们发现安全计划中没有正确考虑到swinging radius 摆动半径。

3.The crane operator must be aware of the swinging radius 摆动半径 to avoid hitting nearby structures.

起重机操作员必须注意swinging radius 摆动半径，以避免撞击附近的建筑物。

4.Before starting the job, we need to measure the swinging radius 摆动半径 of the excavator to ensure safety.

在开始工作之前，我们需要测量挖掘机的swinging radius 摆动半径以确保安全。

5.Always keep a safe distance from the swinging radius 摆动半径 when operating heavy machinery.

在操作重型机械时，始终保持与swinging radius 摆动半径的安全距离。

作文

In the realm of engineering and machinery, the term swinging radius plays a crucial role in understanding the movement and operational capabilities of various equipment. The swinging radius refers to the distance from the pivot point or axis of rotation to the outermost point of an object that swings or rotates. This concept is particularly significant in fields such as construction, where heavy machinery like cranes and excavators are employed. For instance, when planning a construction site, engineers must take into account the swinging radius of a crane to ensure that it can operate safely without colliding with other structures or obstacles.Understanding the swinging radius is essential for several reasons. First and foremost, it helps in optimizing the layout of a worksite. By knowing the swinging radius, operators can determine the best positions for equipment to maximize efficiency and minimize risks. For example, if a crane has a large swinging radius, it may require more space to operate effectively. Therefore, careful planning is necessary to avoid accidents and ensure that the machinery can perform its tasks without hindrance.Moreover, the swinging radius also affects the stability of the machinery. A larger swinging radius can lead to potential tipping hazards, especially if the machine is not properly stabilized. Engineers must calculate the center of gravity and ensure that the equipment is adequately supported to prevent accidents. This is particularly critical in construction zones where multiple machines operate simultaneously, and the risk of collision or tipping increases.In addition to construction, the concept of swinging radius is also applicable in various other industries. For instance, in the automotive sector, the swinging radius can refer to the turning radius of a vehicle, which is vital for maneuverability. Understanding how far a vehicle can turn without hitting obstacles is essential for designing roads and parking lots. Similarly, in aviation, the swinging radius can pertain to the arc that an aircraft’s wings might cover during certain maneuvers, impacting safety protocols and air traffic management.Furthermore, the swinging radius can influence the design and functionality of products. For example, in consumer electronics, devices with moving parts, such as robotic arms or automated tools, must be designed considering their swinging radius to ensure that they can operate effectively within a confined space. This consideration is crucial for enhancing user experience and ensuring safety during operation.In conclusion, the concept of swinging radius is multifaceted and extends beyond just mechanical applications. It encompasses safety, efficiency, and design considerations across various industries. Whether in construction, automotive, or consumer technology, understanding the swinging radius is essential for engineers and designers alike. By taking this parameter into account, we can create safer and more efficient systems that enhance productivity while minimizing risks. As technology continues to advance, the importance of understanding such fundamental concepts will only grow, making it imperative for professionals in all fields to grasp the implications of the swinging radius in their respective domains.

在工程和机械领域，术语摆动半径在理解各种设备的运动和操作能力方面起着至关重要的作用。摆动半径指的是从支点或旋转轴到摆动或旋转物体最外侧点的距离。这个概念在建筑等领域尤为重要，因为重型机械如起重机和挖掘机被广泛使用。例如，在规划施工现场时，工程师必须考虑起重机的摆动半径，以确保它能够安全操作而不会与其他结构或障碍物发生碰撞。理解摆动半径至关重要，原因有很多。首先，它有助于优化工地布局。通过了解摆动半径，操作员可以确定设备的最佳位置，以最大限度地提高效率并降低风险。例如，如果一台起重机的摆动半径很大，它可能需要更多的空间才能有效操作。因此，需要仔细规划，以避免事故并确保机器能够顺利完成任务。此外，摆动半径还会影响机械的稳定性。较大的摆动半径可能导致潜在的倾覆危险，特别是如果机器没有得到适当的稳定。工程师必须计算重心，并确保设备得到足够的支撑，以防止事故发生。这在多个机器同时运行的施工现场尤其关键，因为碰撞或倾覆的风险会增加。除了建筑业，摆动半径的概念在其他许多行业中也适用。例如，在汽车行业，摆动半径可以指车辆的转弯半径，这对机动性至关重要。了解一辆车在不撞到障碍物的情况下可以转动多远，对于设计道路和停车场至关重要。同样，在航空领域，摆动半径可能涉及飞机在某些机动过程中翅膀可能覆盖的弧度，这影响着安全协议和空中交通管理。此外，摆动半径还会影响产品的设计和功能。例如，在消费电子领域，具有活动部件的设备，如机器人手臂或自动工具，必须在设计时考虑其摆动半径，以确保它们能够在有限空间内有效操作。这一考虑对于提升用户体验和确保操作安全至关重要。总之，摆动半径的概念是多方面的，超越了机械应用。它涵盖了各个行业的安全、效率和设计考虑。在建筑、汽车或消费技术领域，理解摆动半径对于工程师和设计师来说都是必不可少的。通过考虑这一参数，我们可以创建更安全、更高效的系统，提升生产力，同时降低风险。随着技术的不断进步，理解这些基本概念的重要性只会增加，因此各个领域的专业人士都必须掌握摆动半径在其各自领域中的影响。