number of repeated impact to breaking

简明释义

导致破断重复冲击次数

英英释义

例句

1.In the lab, we tested the number of repeated impact to breaking for various metals to find the strongest one.

在实验室，我们测试了各种金属的破坏前的重复冲击次数以找到最强的金属。

2.Understanding the number of repeated impact to breaking helps in selecting the right materials for construction.

理解破坏前的重复冲击次数有助于选择合适的建筑材料。

3.The engineer calculated the number of repeated impact to breaking in order to determine the material's durability.

工程师计算了破坏前的重复冲击次数以确定材料的耐用性。

4.We recorded the number of repeated impact to breaking during the stress tests on the new prototype.

在新原型的压力测试中，我们记录了破坏前的重复冲击次数。

5.The product design must consider the number of repeated impact to breaking to ensure safety.

产品设计必须考虑到破坏前的重复冲击次数以确保安全性。

作文

In the realm of materials science and engineering, understanding the durability and resilience of various substances is crucial. One of the key concepts that often arises in this field is the number of repeated impact to breaking, which refers to the total count of impacts a material can endure before it ultimately fails or breaks. This concept is essential for engineers and designers who aim to create products that can withstand everyday wear and tear, as well as extreme conditions.To illustrate the importance of the number of repeated impact to breaking, consider the example of sports equipment, such as a tennis racket. The materials used in the construction of the racket must be able to handle not only the force of the ball upon impact but also the cumulative effects of repeated use over time. If the racket cannot withstand the number of repeated impact to breaking, it will eventually crack or break, rendering it unusable and potentially leading to injury for the player.Moreover, in industries such as automotive and aerospace, the number of repeated impact to breaking becomes even more critical. Components like car frames or airplane wings are subjected to numerous stresses and impacts throughout their operational life. Engineers conduct rigorous testing to determine how many impacts these components can absorb before they fail. This information is vital for ensuring the safety and reliability of vehicles and aircraft.The methodology to assess the number of repeated impact to breaking typically involves standardized tests, where samples of materials are subjected to controlled impacts at specific intervals. By measuring the energy absorbed by the material and observing its structural integrity after each impact, researchers can accurately determine its breaking point. This data is then used to inform design decisions, ensuring that products meet safety standards and perform reliably under expected conditions.In addition to its applications in engineering, the concept of the number of repeated impact to breaking can also be observed in everyday life. For instance, when we consider the durability of our smartphones, we often think about how many times the device can drop without shattering the screen. Manufacturers conduct extensive testing to estimate the number of repeated impact to breaking for various components, allowing consumers to make informed choices about the devices they purchase.Ultimately, the number of repeated impact to breaking serves as a fundamental metric in evaluating the longevity and performance of materials across various applications. Understanding this concept allows engineers to innovate and improve product designs, ensuring that they can withstand the rigors of their intended use. As technology advances and new materials are developed, the significance of the number of repeated impact to breaking will continue to play a vital role in shaping the future of engineering and manufacturing.In conclusion, whether in high-stakes industries or everyday consumer products, the number of repeated impact to breaking is an essential factor that influences design, safety, and performance. By prioritizing this aspect, engineers can create more durable and reliable products that enhance user experience and promote safety in various environments.

在材料科学和工程领域，理解各种物质的耐久性和韧性至关重要。一个常常出现的关键概念是破坏前重复冲击次数，它指的是材料在最终失败或破裂之前能够承受的总冲击次数。这个概念对于旨在创造能够承受日常磨损及极端条件的产品的工程师和设计师来说是必不可少的。为了说明破坏前重复冲击次数的重要性，可以考虑运动器材的例子，比如网球拍。网球拍的构造材料必须能够处理不仅是球碰撞时的力量，还要能够承受随时间推移的重复使用的累积影响。如果网球拍无法承受破坏前重复冲击次数，最终会出现裂纹或折断，使其无法使用，并可能导致运动员受伤。此外，在汽车和航空等行业，破坏前重复冲击次数变得更加关键。汽车框架或飞机机翼等部件在其操作生命周期中会受到无数的压力和冲击。工程师们进行严格的测试，以确定这些部件在失败之前可以吸收多少次冲击。这些信息对于确保车辆和飞机的安全性和可靠性至关重要。评估破坏前重复冲击次数的方法通常涉及标准化测试，其中材料样本在特定间隔下受到控制的冲击。通过测量材料吸收的能量并观察每次冲击后的结构完整性，研究人员可以准确确定其破坏点。然后，这些数据用于指导设计决策，确保产品符合安全标准并在预期条件下可靠运行。除了在工程中的应用，破坏前重复冲击次数的概念也可以在日常生活中观察到。例如，当我们考虑智能手机的耐用性时，我们经常会想到设备掉落多少次而不碎屏。制造商进行广泛的测试，以估计各种组件的破坏前重复冲击次数，使消费者能够做出明智的购买选择。最终，破坏前重复冲击次数作为评估材料在各种应用中耐用性和性能的基本指标。理解这一概念使工程师能够创新和改进产品设计，确保它们能够承受预期使用的严酷环境。随着技术的进步和新材料的开发，破坏前重复冲击次数的重要性将在塑造工程和制造的未来中继续发挥关键作用。总之，无论是在高风险行业还是日常消费产品中，破坏前重复冲击次数都是影响设计、安全和性能的一个重要因素。通过优先考虑这一方面，工程师可以创造出更耐用和可靠的产品，从而增强用户体验并促进各种环境中的安全。