mechanical arrangement

简明释义

机械装置

英英释义

例句

1.The architect incorporated a unique mechanical arrangement in the building's design to enhance ventilation.

建筑师在建筑设计中融入了独特的机械布置以增强通风。

2.The mechanical arrangement in the clock allows for precise timekeeping.

时钟中的机械布置使得时间保持精确。

3.The engineer designed a new mechanical arrangement to improve the efficiency of the assembly line.

工程师设计了一种新的机械布置以提高装配线的效率。

4.In robotics, the mechanical arrangement of the joints determines the range of motion.

在机器人技术中，关节的机械布置决定了运动范围。

5.We need to analyze the mechanical arrangement of this device to identify any potential failures.

我们需要分析该设备的机械布置以识别任何潜在故障。

作文

In the realm of engineering and design, the term mechanical arrangement refers to the systematic organization of components within a mechanical system. This concept is crucial for ensuring that all parts work together efficiently and effectively. A well-thought-out mechanical arrangement can significantly enhance the performance of a machine, reduce wear and tear, and ultimately extend its lifespan.For instance, consider the design of an automobile engine. The mechanical arrangement of various components such as pistons, crankshafts, and camshafts must be meticulously planned to ensure optimal performance. If these parts are not aligned correctly or if they interfere with one another, the engine may suffer from decreased efficiency or even catastrophic failure. Engineers spend countless hours analyzing and testing different configurations to find the best possible mechanical arrangement that balances power output, fuel efficiency, and durability.Moreover, the importance of mechanical arrangement extends beyond just traditional machinery. In the field of robotics, for example, the arrangement of sensors, motors, and control systems is critical for achieving desired movements and functions. A robot designed for assembly tasks in a factory setting must have a precise mechanical arrangement to navigate its environment and manipulate objects effectively. Any misalignment or poor arrangement could lead to operational errors, which might compromise the entire production line.In addition to practical applications, the concept of mechanical arrangement also plays a significant role in education. Engineering students learn about the principles of mechanics and dynamics, which include understanding how different arrangements of mechanical components can influence the behavior of systems. Through hands-on projects and simulations, students can experiment with various mechanical arrangements, gaining valuable insights into the complexities of designing efficient systems.Furthermore, advancements in technology have introduced new materials and manufacturing techniques that allow for more innovative mechanical arrangements. For example, 3D printing has revolutionized the way components are designed and assembled. Engineers can now create complex geometries that were previously impossible to manufacture, leading to more compact and efficient mechanical arrangements. This innovation not only saves space but also reduces the weight of machines, contributing to better energy efficiency.In conclusion, the concept of mechanical arrangement is fundamental to the fields of engineering, robotics, and education. It encompasses the strategic organization of components to ensure that systems operate smoothly and efficiently. As technology continues to evolve, so too will the possibilities for creating sophisticated mechanical arrangements that push the boundaries of what is achievable in mechanical design. Understanding and mastering this concept will remain essential for future engineers and designers as they strive to innovate and improve the machines that shape our world.

在工程和设计领域，术语机械排列指的是机械系统中组件的系统组织。这个概念对于确保所有部件高效而有效地协同工作至关重要。一个经过深思熟虑的机械排列可以显著提高机器的性能，减少磨损，并最终延长其使用寿命。例如，考虑汽车发动机的设计。各种组件如活塞、曲轴和凸轮轴的机械排列必须经过精心规划，以确保最佳性能。如果这些部件没有正确对齐或相互干扰，发动机可能会遭受效率降低甚至灾难性故障。工程师们花费无数小时分析和测试不同的配置，以找到最佳的机械排列，以平衡功率输出、燃油效率和耐用性。此外，机械排列的重要性不仅限于传统机械。在机器人技术领域，例如，传感器、电机和控制系统的排列对于实现所需的运动和功能至关重要。为工厂组装任务设计的机器人必须具有精确的机械排列，以有效地导航其环境并操作物体。任何不对齐或不良的排列都可能导致操作错误，从而可能危及整个生产线。除了实际应用，机械排列的概念在教育中也发挥着重要作用。工程学生学习力学和动力学的原理，包括理解不同机械组件的排列如何影响系统的行为。通过动手项目和模拟，学生可以实验各种机械排列，获得有关设计高效系统复杂性的宝贵见解。此外，技术的进步引入了新的材料和制造技术，使得更具创新性的机械排列成为可能。例如，3D打印彻底改变了组件的设计和组装方式。工程师现在可以创造出以前无法制造的复杂几何形状，从而导致更紧凑和高效的机械排列。这一创新不仅节省了空间，还减少了机器的重量，有助于更好的能源效率。总之，机械排列的概念是工程、机器人和教育领域的基础。它涵盖了组件的战略组织，以确保系统平稳高效地运行。随着技术的不断发展，创造复杂的机械排列的可能性也将不断增加，推动机械设计的边界。理解和掌握这一概念将对未来的工程师和设计师至关重要，因为他们努力创新和改进塑造我们世界的机器。