deflection speed

简明释义

偏转速率

英英释义

例句

1.The deflection speed 偏转速度 of the beam was measured to determine its structural integrity.

测量梁的偏转速度 deflection speed以确定其结构完整性。

2.The research focused on how the deflection speed 偏转速度 affects the overall dynamics of the system.

研究集中在偏转速度 deflection speed如何影响系统的整体动态。

3.Monitoring the deflection speed 偏转速度 of the aircraft wing during flight tests is crucial for performance analysis.

在飞行测试中监测飞机机翼的偏转速度 deflection speed对性能分析至关重要。

4.In robotics, controlling the deflection speed 偏转速度 of the robotic arm is essential for precision tasks.

在机器人技术中，控制机器人手臂的偏转速度 deflection speed对于精确任务至关重要。

5.The engineer calculated the deflection speed 偏转速度 of the bridge under heavy traffic conditions to ensure safety.

工程师计算了桥梁在重型交通条件下的偏转速度 deflection speed以确保安全。

作文

In the field of engineering and physics, understanding various concepts is essential for designing effective systems and structures. One such concept is deflection speed, which plays a critical role in analyzing how materials respond to forces. The term deflection speed refers to the rate at which a structure or material deforms under load. This deformation can be temporary or permanent, depending on the material properties and the magnitude of the applied force. Engineers must consider deflection speed when designing bridges, buildings, and other structures to ensure safety and functionality.When a load is applied to a beam or a similar structure, it experiences bending, leading to deflection. The deflection speed indicates how quickly this bending occurs over time. A higher deflection speed may suggest that the material is less rigid or more susceptible to rapid changes in shape. Conversely, a lower deflection speed indicates that the material can withstand loads without significant deformation.To illustrate the importance of deflection speed, consider the design of a suspension bridge. Engineers must carefully calculate the expected loads from vehicles, wind, and other environmental factors. If the deflection speed of the bridge is too high, it could lead to excessive swaying or even structural failure. Therefore, understanding how different materials behave under stress is crucial for ensuring the bridge's longevity and safety.Moreover, deflection speed is not only relevant in large-scale constructions but also in everyday items. For example, think about the springs in a mattress. When someone lies down, the spring compresses, and the deflection speed determines how quickly the spring returns to its original shape. A mattress with a suitable deflection speed provides comfort while supporting the body effectively.In addition to practical applications, the concept of deflection speed is also significant in research and development. Scientists and engineers often conduct experiments to measure the deflection speed of various materials, helping them to innovate and improve product designs. By understanding how materials react under different conditions, they can create safer and more efficient products.Furthermore, advancements in technology have allowed researchers to develop new materials with tailored deflection speeds. For instance, in aerospace engineering, lightweight materials with specific deflection speeds are essential for optimizing performance while maintaining structural integrity. This balance is crucial for the safety of aircraft and spacecraft, where every component must withstand extreme conditions.In conclusion, the concept of deflection speed is vital across multiple fields, from construction to product design and research. Recognizing its significance helps engineers and scientists create safer, more efficient structures and materials. As technology continues to advance, the ability to manipulate and understand deflection speed will remain an essential skill for professionals in various industries. By mastering this concept, we can ensure that our built environment is both functional and safe for future generations.

在工程和物理学领域，理解各种概念对于设计有效的系统和结构至关重要。其中一个概念是挠度速度，它在分析材料如何响应力方面发挥着关键作用。术语挠度速度指的是结构或材料在负载下变形的速率。这种变形可以是暂时的，也可以是永久的，具体取决于材料的性质和施加力的大小。工程师在设计桥梁、建筑物和其他结构时，必须考虑挠度速度以确保安全性和功能性。当负载施加到梁或类似结构上时，它会经历弯曲，导致挠度。挠度速度表示这种弯曲随时间发生的快慢。较高的挠度速度可能表明材料的刚度较低，或更容易快速改变形状。相反，较低的挠度速度表明材料能够承受负载而不会显著变形。为了说明挠度速度的重要性，考虑一下悬索桥的设计。工程师必须仔细计算来自车辆、风和其他环境因素的预期负载。如果桥梁的挠度速度过高，可能会导致过度摇摆甚至结构失效。因此，了解不同材料在应力下的行为对于确保桥梁的耐久性和安全性至关重要。此外，挠度速度不仅与大型建筑相关，还与日常物品相关。例如，想想床垫中的弹簧。当有人躺下时，弹簧被压缩，而挠度速度决定了弹簧恢复到原始形状的速度。具有合适挠度速度的床垫能够有效地支持身体，同时提供舒适感。除了实际应用外，挠度速度的概念在研发中也非常重要。科学家和工程师通常进行实验以测量各种材料的挠度速度，帮助他们创新和改进产品设计。通过了解材料在不同条件下的反应，他们可以创造出更安全、更高效的产品。此外，技术的进步使研究人员能够开发具有特定挠度速度的新材料。例如，在航空航天工程中，轻质材料与特定的挠度速度对优化性能同时保持结构完整性至关重要。这种平衡对于飞机和航天器的安全至关重要，其中每个组件都必须承受极端条件。总之，挠度速度的概念在多个领域至关重要，从建筑到产品设计和研究。认识到其重要性可以帮助工程师和科学家创造出更安全、更高效的结构和材料。随着技术的不断进步，操控和理解挠度速度的能力将继续成为各行业专业人士的重要技能。通过掌握这一概念，我们可以确保我们的建筑环境在未来几代人中既功能齐全又安全。