handling radius

简明释义

悬臂伸距

英英释义

例句

1.We need to adjust the handling radius 操作半径 of the crane for better maneuverability in tight spaces.

我们需要调整起重机的handling radius 操作半径以便在狭小空间内更好地操作。

2.The handling radius 操作半径 of our robotic arm is crucial for assembly tasks.

我们机器人手臂的handling radius 操作半径对装配任务至关重要。

3.A larger handling radius 操作半径 can improve the efficiency of material handling systems.

更大的handling radius 操作半径可以提高物料搬运系统的效率。

4.The robot's handling radius 操作半径 allows it to reach all corners of the workspace efficiently.

机器人的handling radius 操作半径使其能够高效地到达工作空间的所有角落。

5.The design team is considering the handling radius 操作半径 when creating new industrial machines.

设计团队在创建新工业机器时考虑handling radius 操作半径。

作文

In the world of engineering and robotics, the term handling radius is crucial for understanding the capabilities of a robotic arm or any automated system designed to manipulate objects. The handling radius refers to the maximum distance from a fixed point that a robot can effectively reach to pick up, move, or place an item. This concept is not only applicable in robotics but also extends to various fields such as logistics, manufacturing, and even everyday tasks involving tools and machinery.To illustrate the importance of the handling radius, consider a warehouse that employs robotic systems to manage inventory. Each robot has a designated handling radius that determines how far it can extend its arm to retrieve products from shelves. If the handling radius is too limited, the robot may not be able to access all necessary items efficiently, leading to delays in operations. Conversely, if the handling radius is too extensive, it may require more complex programming and energy consumption, making the system less efficient overall.Moreover, the design of the robotic arm itself greatly influences the handling radius. Engineers must carefully calculate the dimensions and joint configurations to optimize the reach while maintaining stability and precision. For instance, a robotic arm with multiple joints can achieve a greater handling radius than a simple linear actuator because it can maneuver around obstacles and reach into tight spaces.In addition to physical limitations, the handling radius also encompasses the operational limits imposed by the environment. For example, a robot operating in a cluttered space may need to adjust its handling radius dynamically to avoid collisions and ensure safe operation. This adaptability is vital for modern robotic systems, which are increasingly being integrated into environments that are unpredictable and filled with variables.Furthermore, understanding the handling radius is essential for workflow optimization. In manufacturing settings, knowing the handling radius allows managers to arrange workstations and equipment strategically. By placing tools and materials within the handling radius of a robot, companies can minimize the time spent on movements and maximize productivity. This careful planning can lead to significant cost savings and improved efficiency.In conclusion, the concept of handling radius plays a pivotal role in the effectiveness of robotic systems and automation. It influences design choices, operational strategies, and overall efficiency in various industries. As technology continues to advance, understanding and optimizing the handling radius will remain a key area of focus for engineers and developers alike. By doing so, we can harness the full potential of robotics and automation, paving the way for smarter and more efficient systems that enhance our daily lives and business practices.

在工程和机器人领域，术语处理半径对于理解机器人臂或任何设计用于操纵物体的自动化系统的能力至关重要。处理半径是指从固定点到机器人能够有效地伸展以拾取、移动或放置物品的最大距离。这个概念不仅适用于机器人，还扩展到物流、制造甚至日常涉及工具和机械的任务等多个领域。为了说明处理半径的重要性，考虑一个使用机器人系统来管理库存的仓库。每个机器人都有一个指定的处理半径，决定它可以多远地伸展其手臂以从货架上取回产品。如果处理半径过于有限，机器人可能无法高效地访问所有必要的物品，从而导致操作延迟。相反，如果处理半径过于广泛，则可能需要更复杂的编程和能量消耗，使系统整体效率降低。此外，机器人臂本身的设计在很大程度上影响处理半径。工程师必须仔细计算尺寸和关节配置，以优化伸展，同时保持稳定性和精确性。例如，具有多个关节的机器人臂可以达到比简单线性执行器更大的处理半径，因为它可以绕过障碍物并进入狭小空间。除了物理限制外，处理半径还包括环境施加的操作限制。例如，在拥挤的空间中工作的机器人可能需要动态调整其处理半径以避免碰撞并确保安全操作。这种适应能力对于现代机器人系统至关重要，这些系统正越来越多地被集成到不可预测且充满变量的环境中。此外，理解处理半径对于工作流程优化至关重要。在制造环境中，了解处理半径使管理者能够战略性地安排工作站和设备。通过将工具和材料放置在机器人的处理半径内，公司可以最小化移动所花费的时间，并最大化生产力。这种精心规划可以带来显著的成本节省和效率提高。总之，处理半径的概念在机器人系统和自动化的有效性中发挥着关键作用。它影响设计选择、操作策略以及各行业的整体效率。随着技术的不断进步，理解和优化处理半径将始终是工程师和开发人员关注的重点领域。通过这样做，我们可以充分利用机器人技术和自动化，为更智能、更高效的系统铺平道路，从而改善我们的日常生活和商业实践。