flexural bond

简明释义

弯曲粘结力

英英释义

例句

1.The research focused on improving the flexural bond between steel and concrete in composite structures.

研究集中在改善复合结构中钢材与混凝土之间的弯曲粘结。

2.Testing the flexural bond is essential for evaluating the performance of new construction materials.

测试弯曲粘结对于评估新建筑材料的性能至关重要。

3.A weak flexural bond can lead to cracking and failure in structural components.

弱的弯曲粘结可能导致结构组件的开裂和失效。

4.The engineer calculated the strength of the flexural bond to ensure the bridge could withstand heavy loads.

工程师计算了弯曲粘结的强度，以确保桥梁能够承受重载。

5.In concrete structures, the flexural bond plays a crucial role in maintaining integrity under stress.

在混凝土结构中，弯曲粘结在承受压力时保持结构完整性方面起着至关重要的作用。

作文

The concept of flexural bond is crucial in the field of materials science, particularly when discussing the strength and durability of composite materials. A flexural bond refers to the adhesive or mechanical connection between two materials that allows them to withstand bending forces without failing. This property is especially important in applications such as construction, where beams and other structural elements must endure various loads over time.To better understand flexural bond, it is essential to consider how materials behave under stress. When a load is applied to a beam, it experiences tension on one side and compression on the other. The flexural bond between the materials must be strong enough to resist these opposing forces. If the bond is weak, the materials may separate or crack, leading to structural failure.In engineering, the strength of a flexural bond can be tested through various methods, including bending tests and shear tests. These tests help determine the maximum load that a material can handle before the bond fails. Understanding the properties of flexural bond is vital for engineers as they design structures that are both safe and efficient.Moreover, different materials exhibit varying levels of flexural bond strength. For instance, epoxy resins are often used in composite materials due to their excellent bonding capabilities. When combined with fibers such as carbon or glass, the resulting composite exhibits superior strength and flexibility. This is why many modern engineering applications utilize composites that rely on strong flexural bonds to achieve desired performance characteristics.In addition to traditional construction materials, the concept of flexural bond is also relevant in the development of new technologies. For example, in the aerospace industry, lightweight materials with strong flexural bonds are essential for creating aircraft that can withstand the stresses of flight while minimizing weight.Furthermore, understanding flexural bond is not limited to engineering and construction. It also has implications in everyday life. For example, when you sit on a chair, the flexural bond between the seat and its legs must be strong enough to support your weight. If the bond fails, the chair collapses, demonstrating the importance of this concept in practical applications.In conclusion, the term flexural bond encompasses a fundamental aspect of material science and engineering. It represents the strength and resilience of connections between materials when subjected to bending forces. As technology advances and new materials are developed, the understanding of flexural bond will continue to play a critical role in ensuring the safety and effectiveness of various structures and products. Whether in construction, aerospace, or everyday items, the significance of flexural bond cannot be overstated. By continuing to study and improve flexural bond properties, we can enhance the performance and longevity of materials used in many applications.

“flexural bond”这一概念在材料科学领域至关重要，特别是在讨论复合材料的强度和耐用性时。“flexural bond”指的是两种材料之间的粘合或机械连接，使其能够承受弯曲力而不发生失效。这一特性在建筑等应用中尤为重要，因为梁和其他结构元素必须经受各种负荷。要更好地理解“flexural bond”，必须考虑材料在应力下的行为。当负荷施加到梁上时，它一侧会经历拉伸，而另一侧则会受到压缩。两种材料之间的“flexural bond”必须足够强，以抵抗这些相对的力量。如果粘结弱，材料可能会分离或开裂，导致结构失效。在工程学中，可以通过各种方法测试“flexural bond”的强度，包括弯曲试验和剪切试验。这些测试帮助确定材料在粘结失效之前能够承受的最大负荷。理解“flexural bond”的性质对工程师设计既安全又高效的结构至关重要。此外，不同材料表现出不同程度的“flexural bond”强度。例如，环氧树脂常用于复合材料中，因为它们具有优良的粘合能力。当与碳纤维或玻璃纤维结合时，所产生的复合材料表现出卓越的强度和柔韧性。这就是为什么许多现代工程应用利用依赖强“flexural bond”的复合材料以实现所需的性能特征。除了传统建筑材料外，“flexural bond”的概念在新技术的发展中也相关。例如，在航空航天工业中，具有强“flexural bond”的轻质材料对于制造能够承受飞行压力而又能减轻重量的飞机至关重要。此外，了解“flexural bond”不仅限于工程和建筑。它在日常生活中也有影响。例如，当你坐在椅子上时，座位与椅腿之间的“flexural bond”必须足够强，以支撑你的体重。如果粘结失效，椅子就会倒塌，这表明这一概念在实际应用中的重要性。总之，“flexural bond”这一术语涵盖了材料科学和工程的基本方面。它代表了在弯曲力作用下材料之间连接的强度和韧性。随着技术的进步和新材料的发展，对“flexural bond”的理解将继续在确保各种结构和产品的安全性和有效性方面发挥关键作用。无论是在建筑、航空航天还是日常物品中，“flexural bond”的重要性都不容小觑。通过不断研究和改善“flexural bond”特性，我们可以增强许多应用中使用的材料的性能和耐用性。