restraint of displacement

简明释义

位移抑制

英英释义

例句

1.Proper restraint of displacement can enhance the durability of bridges, especially in areas prone to heavy traffic.

适当的位移约束可以增强桥梁的耐久性，特别是在交通繁忙的地区。

2.The engineer emphasized the importance of restraint of displacement in the structural design to prevent excessive movement during an earthquake.

工程师强调了在结构设计中，位移约束的重要性，以防止在地震期间过度移动。

3.During the experiment, the scientists noted that the restraint of displacement affected the results significantly.

在实验过程中，科学家们注意到位移约束显著影响了结果。

4.The construction team implemented restraint of displacement techniques to ensure that the building would withstand high winds.

施工团队实施了位移约束技术，以确保建筑物能够承受强风。

5.In robotics, the restraint of displacement is crucial for maintaining the precision of robotic arms during operation.

在机器人技术中，位移约束对于保持机器人臂在操作过程中的精确性至关重要。

作文

In the field of physics and engineering, the term restraint of displacement refers to the limitation or control of the movement of an object within a specific boundary. This concept is crucial in various applications, such as structural engineering, mechanical systems, and even robotics. Understanding the restraint of displacement is essential for ensuring the stability and functionality of structures and machines. One of the most common examples of restraint of displacement can be found in buildings. Engineers often design structures with specific restraints to prevent excessive movement during events like earthquakes or strong winds. These restraints may include braces, shear walls, or base isolators that allow the building to absorb and dissipate energy without collapsing. The restraint of displacement in this context ensures that the building remains within safe limits and protects the occupants inside.Another area where restraint of displacement plays a significant role is in mechanical systems. For instance, consider a bridge. The components of the bridge must be designed to withstand forces while allowing for some movement due to temperature changes or load variations. The restraint of displacement here helps maintain the integrity of the bridge while accommodating these changes. Engineers use various materials and designs to create effective restraints that ensure the safety and longevity of the structure.Robotics also heavily relies on the concept of restraint of displacement. In robotic arms, precise control over movement is critical for performing tasks accurately. The joints of a robotic arm are designed with specific constraints to limit their range of motion. This restraint of displacement allows the robot to perform delicate operations, such as surgery or assembly, with high precision. Without these restraints, the robot could easily lose control and fail to execute its tasks effectively.Furthermore, the restraint of displacement is not limited to physical structures but can also be applied to abstract concepts in mathematics and computer science. In optimization problems, for example, constraints are placed on variables to achieve desired outcomes. These constraints act as a form of restraint of displacement, guiding the solution process towards feasible and optimal results.In conclusion, the concept of restraint of displacement is fundamental across various disciplines, including engineering, robotics, and mathematics. It serves as a guiding principle that ensures stability, safety, and efficiency in systems ranging from buildings to machines. As we continue to innovate and develop new technologies, a deeper understanding of the restraint of displacement will be crucial in creating designs that are not only functional but also resilient to the challenges they face in the real world.

在物理和工程领域，术语位移约束指的是限制或控制物体在特定边界内移动的能力。这个概念在结构工程、机械系统甚至机器人等各种应用中至关重要。理解位移约束对于确保结构和机器的稳定性和功能性至关重要。位移约束的一个常见例子可以在建筑中找到。工程师通常设计具有特定约束的结构，以防止在地震或强风等事件期间发生过度移动。这些约束可能包括支撑、剪力墙或基础隔离器，这些结构允许建筑吸收和消散能量而不倒塌。在这种情况下，位移约束确保建筑保持在安全范围内，并保护内部的居住者。位移约束在机械系统中也发挥着重要作用。例如，考虑一座桥梁。桥梁的各个组成部分必须设计成能够承受力量，同时允许因温度变化或负载变化而产生的一定运动。此处的位移约束有助于维持桥梁的完整性，同时适应这些变化。工程师使用各种材料和设计来创建有效的约束，以确保结构的安全性和耐久性。机器人技术也严重依赖于位移约束的概念。在机器人手臂中，对运动的精确控制对于准确执行任务至关重要。机器手臂的关节设计有特定的约束，以限制它们的运动范围。这种位移约束使机器人能够高精度地执行精细操作，例如外科手术或装配。如果没有这些约束，机器人可能会失去控制，无法有效地完成任务。此外，位移约束不仅限于物理结构，还可以应用于数学和计算机科学中的抽象概念。例如，在优化问题中，会对变量施加约束以实现期望的结果。这些约束作为一种形式的位移约束，引导解决过程朝着可行和最优的结果前进。总之，位移约束的概念在工程、机器人和数学等多个学科中都是基础性的。它作为一个指导原则，确保了从建筑到机器的系统的稳定性、安全性和效率。随着我们不断创新和开发新技术，对位移约束的更深入理解将对创造不仅功能性而且能够抵御现实世界挑战的设计至关重要。