bending resistance

简明释义

抗弯强度

英英释义

例句

1.The research focused on improving the bending resistance 抗弯强度 of composite materials used in automotive parts.

研究集中在提高用于汽车零件的复合材料的bending resistance 抗弯强度。

2.The new alloy was tested for its bending resistance 抗弯强度 before being used in aerospace applications.

在航空航天应用中使用之前，新合金经过了bending resistance 抗弯强度的测试。

3.In furniture design, the bending resistance 抗弯强度 of materials affects durability and stability.

在家具设计中，材料的bending resistance 抗弯强度影响耐用性和稳定性。

4.Materials with high bending resistance 抗弯强度 are essential for constructing bridges.

具有高bending resistance 抗弯强度的材料对于建造桥梁至关重要。

5.The structural engineer calculated the bending resistance 抗弯强度 of the beam to ensure it could support the weight of the building.

结构工程师计算了梁的bending resistance 抗弯强度，以确保其能够支撑建筑的重量。

作文

Bending resistance is a crucial property of materials that determines their ability to withstand bending forces without deforming or breaking. This characteristic is particularly important in engineering and construction, where the integrity of structures relies heavily on the materials used. For instance, when designing a bridge, engineers must consider the bending resistance of the materials to ensure that they can support the weight of vehicles and withstand environmental stresses such as wind and earthquakes. If the materials chosen have low bending resistance, the bridge could suffer from structural failure, leading to catastrophic consequences.In everyday life, we encounter various objects that demonstrate bending resistance. Take, for example, a simple pencil. The wooden body of the pencil has a certain level of bending resistance that allows it to be held and used for writing without breaking easily. However, if too much force is applied, the pencil will snap, indicating its limits in terms of bending resistance. This principle applies to many materials, including metals, plastics, and composites, each of which has different levels of bending resistance based on their composition and structure.Understanding bending resistance is not only vital for engineers but also for architects and designers. When creating buildings, they must select materials that will not only support loads but also resist bending under various conditions. For example, steel beams are often used in construction due to their high bending resistance, allowing for large open spaces without the need for excessive support columns. This not only enhances the aesthetic appeal of a building but also maximizes usable space.Moreover, advancements in material science have led to the development of new materials with enhanced bending resistance. Innovations such as carbon fiber and advanced composites are becoming increasingly popular in industries ranging from aerospace to automotive. These materials offer superior bending resistance while being lightweight, which is essential for improving fuel efficiency and performance in vehicles and aircraft.In conclusion, bending resistance is an essential factor in the selection and application of materials across various fields. Its significance extends from everyday objects to complex engineering projects, impacting safety, functionality, and design. As we continue to innovate and develop new materials, understanding the principles of bending resistance will remain critical in ensuring the reliability and durability of the products we create and use every day.

弯曲抗力是材料的一个关键特性，决定了它们在不变形或破裂的情况下抵抗弯曲力的能力。这个特性在工程和建筑中尤为重要，因为结构的完整性在很大程度上依赖于所使用的材料。例如，在设计一座桥时，工程师必须考虑材料的弯曲抗力，以确保它们能够承受车辆的重量，并抵御风和地震等环境压力。如果所选材料的弯曲抗力较低，桥梁可能会遭受结构失效，导致灾难性后果。在日常生活中，我们会遇到各种展示弯曲抗力的物体。比如，一个简单的铅笔。铅笔的木制外壳具有一定的弯曲抗力，使其可以被握住并用于书写而不易折断。然而，如果施加过多的力量，铅笔将会折断，这表明其在弯曲抗力方面的极限。这一原则适用于许多材料，包括金属、塑料和复合材料，每种材料的弯曲抗力基于其成分和结构而有所不同。理解弯曲抗力不仅对工程师至关重要，对建筑师和设计师也是如此。在创建建筑时，他们必须选择不仅能支撑负载，还能在各种条件下抵抗弯曲的材料。例如，钢梁常用于建筑中，因为它们具有高弯曲抗力，允许在不需要过多支撑柱的情况下形成大开间。这不仅增强了建筑的美观，还最大化了可用空间。此外，材料科学的进步导致了新材料的开发，这些材料具有增强的弯曲抗力。碳纤维和先进复合材料等创新在航空航天和汽车等行业中越来越受欢迎。这些材料提供优越的弯曲抗力，同时又轻便，这对于提高车辆和飞机的燃油效率和性能至关重要。总之，弯曲抗力是选择和应用各种领域材料的一个基本因素。它的重要性从日常物品延伸到复杂的工程项目，影响着安全性、功能性和设计。随着我们不断创新和开发新材料，理解弯曲抗力的原理仍将是确保我们创造和使用的产品的可靠性和耐用性的关键。