impact bending strength

简明释义

冲挥曲强度

英英释义

例句

1.High impact bending strength 抗冲击弯曲强度 is crucial for materials used in construction to withstand severe weather conditions.

高impact bending strength 抗冲击弯曲强度 对于用于建筑的材料至关重要，以承受恶劣天气条件。

2.The laboratory results indicated that the impact bending strength 抗冲击弯曲强度 of the alloy exceeded industry standards.

实验室结果表明，该合金的impact bending strength 抗冲击弯曲强度 超过了行业标准。

3.During the product development phase, we focused on enhancing the impact bending strength 抗冲击弯曲强度 of the plastic components.

在产品开发阶段，我们专注于提高塑料组件的impact bending strength 抗冲击弯曲强度。

4.The engineer conducted tests to measure the impact bending strength 抗冲击弯曲强度 of the new composite material.

工程师进行了测试，以测量新复合材料的impact bending strength 抗冲击弯曲强度。

5.Manufacturers often test the impact bending strength 抗冲击弯曲强度 of materials before they are approved for use in safety equipment.

制造商通常在安全设备使用前测试材料的impact bending strength 抗冲击弯曲强度。

作文

The term impact bending strength refers to the ability of a material to withstand sudden forces or shocks while being bent. This property is crucial in various engineering and manufacturing applications, where materials are subjected to dynamic loads. Understanding impact bending strength is essential for designers and engineers, as it helps them select appropriate materials for specific uses. For example, in the construction of buildings and bridges, materials must endure not only static loads but also dynamic forces such as wind, earthquakes, and impacts from vehicles. Materials with high impact bending strength can absorb energy without fracturing, making them ideal for structural components. Steel, for instance, is known for its excellent impact bending strength, which is why it is widely used in the construction industry. On the other hand, brittle materials like glass or certain ceramics may fail under similar conditions due to their low impact bending strength. This highlights the importance of selecting materials based on their mechanical properties, including impact bending strength. In addition to construction, impact bending strength is also critical in the automotive and aerospace industries. Vehicles and aircraft are often exposed to various impact forces during operation. Components such as bumpers, wings, and fuselage must possess sufficient impact bending strength to ensure safety and performance. Engineers conduct tests to measure the impact bending strength of materials, allowing them to predict how these materials will behave in real-world scenarios. Moreover, the impact bending strength of a material can be influenced by several factors, including temperature, strain rate, and the presence of defects. For instance, materials may exhibit different impact bending strength at low temperatures compared to room temperature. This variability necessitates thorough testing and analysis to ensure that materials will perform reliably under expected conditions. In conclusion, understanding impact bending strength is vital across various fields of engineering and manufacturing. It informs material selection and design processes, ensuring that structures and components can withstand unforeseen impacts and stresses. As technology advances, the methods for measuring and improving impact bending strength continue to evolve, leading to safer and more efficient designs. Therefore, a comprehensive grasp of this concept is fundamental for anyone involved in material science or structural engineering.

术语impact bending strength指的是材料在弯曲时抵御突发力量或冲击的能力。这一特性在各种工程和制造应用中至关重要，因为材料会承受动态负载。理解impact bending strength对设计师和工程师来说非常重要，因为这帮助他们为特定用途选择合适的材料。例如，在建筑物和桥梁的建设中，材料不仅必须承受静态负载，还必须承受动态力量，如风、地震和车辆撞击。具有高impact bending strength的材料能够在不破裂的情况下吸收能量，使其成为结构组件的理想选择。例如，钢材因其出色的impact bending strength而被广泛用于建筑行业。另一方面，像玻璃或某些陶瓷这样的脆性材料在相似条件下可能会破裂，原因是它们的impact bending strength较低。这凸显了根据机械特性（包括impact bending strength）选择材料的重要性。除了建筑外，impact bending strength在汽车和航空航天工业中也至关重要。车辆和飞机在操作过程中经常会受到各种冲击力的影响。保险杠、机翼和机身等组件必须具备足够的impact bending strength以确保安全和性能。工程师进行测试以测量材料的impact bending strength，使他们能够预测这些材料在实际情境中的表现。此外，材料的impact bending strength可能受到多种因素的影响，包括温度、应变速率和缺陷的存在。例如，材料在低温下的impact bending strength可能与室温下不同。这种变异性需要彻底测试和分析，以确保材料在预期条件下能够可靠地发挥作用。总之，了解impact bending strength在各个工程和制造领域至关重要。它为材料选择和设计过程提供了信息，确保结构和组件能够承受意外的冲击和压力。随着技术的进步，测量和改善impact bending strength的方法不断演变，从而导致更安全和更有效的设计。因此，全面掌握这一概念对于任何涉及材料科学或结构工程的人来说都是基础。