rebound deflection

简明释义

回弹弯沉

英英释义

例句

1.In sports science, rebound deflection is crucial for understanding how balls behave after hitting a surface.

在运动科学中，回弹偏移对于理解球体撞击表面后的行为至关重要。

2.The engineer measured the rebound deflection to assess the material's elasticity.

工程师测量了回弹偏移以评估材料的弹性。

3.The rebound deflection of the basketball can affect shooting accuracy.

篮球的回弹偏移会影响投篮的准确性。

4.During the testing phase, the rebound deflection was recorded for various materials.

在测试阶段，各种材料的回弹偏移被记录下来。

5.The architect considered the rebound deflection when designing the roof structure.

建筑师在设计屋顶结构时考虑了回弹偏移。

作文

Understanding the concept of rebound deflection is crucial in various fields, including engineering, sports science, and material science. The term refers to the amount of deformation or displacement that occurs when a material or object is subjected to an impact and then returns to its original shape. This phenomenon can be observed in everyday life, such as when a basketball bounces off the floor or when a car hits a speed bump. In these scenarios, the rebound deflection plays a significant role in determining how well the object performs under stress and how quickly it can return to its initial state.In engineering, understanding rebound deflection is particularly important for designing structures and materials that can withstand dynamic loads. For instance, when engineers design bridges or buildings, they must consider how the materials will behave under sudden forces, such as earthquakes or strong winds. A material with a high rebound deflection may absorb more energy from the impact, allowing it to return to its original shape without permanent damage. Conversely, materials with low rebound deflection might suffer from cracks or fractures after experiencing similar forces, leading to structural failures.In sports science, the concept of rebound deflection is vital for optimizing athletic performance. For example, the design of sports equipment, such as tennis rackets or running shoes, often incorporates materials that exhibit specific rebound characteristics. A tennis racket with a higher rebound deflection can provide players with better power and control when hitting the ball, while running shoes designed with optimal rebound deflection can enhance a runner's efficiency and reduce the risk of injury by absorbing shock during each stride.Moreover, rebound deflection also has implications in the field of material science, where researchers study how different materials respond to impacts. By analyzing the rebound deflection of various substances, scientists can develop new materials that are more resilient and better suited for specific applications. For instance, materials used in protective gear, such as helmets or padding, are often tested for their rebound deflection properties to ensure they can effectively absorb and dissipate energy from impacts, thereby protecting the wearer.In conclusion, the concept of rebound deflection is multifaceted and applies to numerous disciplines. Whether in engineering, sports science, or material science, understanding how materials and objects behave under stress is essential for innovation and safety. As we continue to explore and refine our knowledge of rebound deflection, we can improve the design and functionality of products that enhance our daily lives and safeguard us against potential dangers. Thus, grasping the intricacies of rebound deflection not only furthers academic pursuits but also contributes to practical advancements in technology and human well-being.

理解反弹偏移的概念在工程、运动科学和材料科学等多个领域至关重要。该术语指的是当材料或物体受到冲击并返回原始形状时发生的变形或位移量。这种现象可以在日常生活中观察到，例如，当篮球从地板上反弹时，或者当汽车撞击减速带时。在这些情况下，反弹偏移在决定物体在应力下的表现以及它多快能够恢复到初始状态方面发挥着重要作用。在工程学中，理解反弹偏移对于设计能够承受动态载荷的结构和材料尤为重要。例如，当工程师设计桥梁或建筑物时，他们必须考虑材料在突然力量下的表现，例如地震或强风。具有高反弹偏移的材料可能会吸收更多的冲击能量，从而使其能够恢复到原始形状而不受永久性损坏。相反，具有低反弹偏移的材料在经历类似力量后可能会出现裂缝或断裂，从而导致结构失效。在运动科学中，反弹偏移的概念对优化运动表现至关重要。例如，运动设备的设计，如网球拍或跑鞋，通常采用具有特定反弹特性的材料。具有较高反弹偏移的网球拍可以为球员在击球时提供更好的力量和控制，而设计得当的跑鞋则可以通过吸收每一步的冲击，提高跑者的效率并降低受伤风险。此外，反弹偏移在材料科学领域也有重要意义，研究人员研究不同材料如何应对冲击。通过分析各种物质的反弹偏移，科学家们可以开发出更具韧性的新材料，更适合特定应用。例如，用于保护装备（如头盔或护垫）的材料通常会测试其反弹偏移特性，以确保它们能够有效吸收和消散冲击能量，从而保护佩戴者。总之，反弹偏移的概念是多方面的，适用于许多学科。无论是在工程、运动科学还是材料科学中，理解材料和物体在应力下的行为对于创新和安全至关重要。随着我们继续探索和完善对反弹偏移的理解，我们可以改善产品的设计和功能，增强我们的日常生活并保护我们免受潜在危险。因此，掌握反弹偏移的复杂性不仅促进了学术追求，还为技术和人类福祉的实际进步作出了贡献。