articulated mechanism

简明释义

铰接机构

英英释义

例句

1.Engineers studied the articulated mechanism to improve the performance of robotic arms in manufacturing.

工程师们研究了关节机制以提高制造业中机器人手臂的性能。

2.The robot's arm was designed with an articulated mechanism to allow for greater flexibility in movement.

机器人的手臂采用了关节机制设计，以允许更大的运动灵活性。

3.In the new vehicle, the articulated mechanism helps to navigate tight corners smoothly.

在新车中，关节机制有助于平稳地转弯。

4.The articulated mechanism of the folding chair allows it to be compactly stored when not in use.

折叠椅的关节机制使其在不使用时可以紧凑存储。

5.The articulated mechanism in this model allows for a wide range of motion, making it ideal for animation.

该模型中的关节机制允许广泛的运动范围，使其非常适合动画制作。

作文

In the realm of engineering and robotics, the concept of an articulated mechanism is fundamental to understanding how complex movements can be achieved through simple components. An articulated mechanism refers to a system of interconnected parts that can move relative to one another, often allowing for a wide range of motion and flexibility. This type of mechanism is commonly found in robotic arms, where each joint can articulate independently to reach various positions and perform tasks with precision.The design of an articulated mechanism typically involves multiple links and joints, which can be rotational or translational. Each joint acts as a pivot point, enabling the links to rotate around it, thereby creating movement. For instance, in a robotic arm, the shoulder joint allows the arm to move up and down, while the elbow joint permits bending and extending. The combination of these movements allows the robotic arm to mimic the dexterity of a human hand.One of the key advantages of using an articulated mechanism is its ability to navigate complex environments. In manufacturing, robots equipped with articulated mechanisms can reach into tight spaces, assemble intricate parts, and perform tasks that would be difficult or impossible for human workers. This capability not only enhances productivity but also improves safety by reducing the risk of injury in hazardous work conditions.Moreover, the versatility of articulated mechanisms extends beyond industrial applications. In the field of animation and character design, artists utilize articulated mechanisms to create lifelike movements in their creations. By rigging characters with a series of joints and controls, animators can achieve fluid motion that adds realism to animated films and video games. This technique allows for greater creative expression, as characters can perform a variety of actions ranging from subtle gestures to dynamic movements.The study of articulated mechanisms also intersects with the field of biomechanics. Researchers analyze the natural movements of living organisms to inspire the design of more efficient and effective robotic systems. By understanding how animals use their joints and limbs to navigate their environments, engineers can develop articulated mechanisms that replicate these biological movements, leading to advancements in robotics and prosthetics.As technology continues to evolve, the importance of articulated mechanisms cannot be overstated. From autonomous vehicles that rely on sophisticated jointed systems to navigate roads, to advanced surgical robots that perform delicate procedures with precision, articulated mechanisms are at the forefront of innovation. The future of engineering and robotics will undoubtedly see further exploration and refinement of these mechanisms, paving the way for new applications and improved designs.In conclusion, the concept of an articulated mechanism is integral to various fields, including robotics, animation, and biomechanics. Its ability to facilitate complex movements through simple connections highlights the ingenuity of engineering design. As we continue to push the boundaries of technology, understanding and mastering the principles behind articulated mechanisms will be essential for future advancements. Whether in the manufacturing industry or in creative arts, the impact of articulated mechanisms will surely shape the way we interact with machines and the world around us.

在工程和机器人领域，关节机制的概念对于理解如何通过简单的组件实现复杂运动至关重要。关节机制是指一组相互连接的部件，可以相对移动，通常允许广泛的运动范围和灵活性。这种类型的机制通常出现在机器人手臂中，每个关节可以独立活动，以达到各种位置并精确执行任务。关节机制的设计通常涉及多个链接和关节，这些关节可以是旋转的或平移的。每个关节作为一个支点，使得链接围绕它旋转，从而产生运动。例如，在一个机器人手臂中，肩关节允许手臂上下移动，而肘关节则允许弯曲和伸展。这些运动的组合使得机器人手臂能够模仿人类手的灵活性。使用关节机制的一个主要优点是其能够在复杂环境中导航。在制造业中，配备关节机制的机器人可以进入狭小空间，组装复杂部件，并执行人类工人难以完成的任务。这种能力不仅提高了生产力，还通过减少在危险工作条件下受伤的风险来改善安全性。此外，关节机制的多功能性超越了工业应用。在动画和角色设计领域，艺术家利用关节机制为他们的创作创造栩栩如生的运动。通过为角色装配一系列关节和控制器，动画师可以实现流畅的运动，为动画电影和视频游戏增添现实感。这种技术允许更大的创意表达，因为角色可以执行从细微手势到动态动作的各种行为。对关节机制的研究还与生物力学领域交叉。研究人员分析生物体的自然运动，以激发更高效和有效的机器人系统的设计。通过理解动物如何使用其关节和肢体来导航其环境，工程师可以开发出复制这些生物运动的关节机制，从而推动机器人技术和假肢的发展。随着技术的不断发展，关节机制的重要性不容小觑。从依赖复杂关节系统在道路上导航的自动驾驶汽车，到能够以精确度执行精细程序的先进外科机器人，关节机制处于创新的前沿。未来的工程和机器人技术无疑将进一步探索和完善这些机制，为新的应用和改进的设计铺平道路。总之，关节机制的概念是多个领域的核心，包括机器人技术、动画和生物力学。它通过简单的连接促进复杂运动的能力突显了工程设计的巧妙。随着我们继续推动技术的边界，理解和掌握关节机制背后的原理将对未来的进步至关重要。无论是在制造业还是在创意艺术中，关节机制的影响无疑将塑造我们与机器及周围世界的互动方式。