crack resistance

简明释义

抗裂度

英英释义

例句

1.Engineers are testing the crack resistance 抗裂性 of different materials for the bridge construction.

工程师正在测试不同材料的抗裂性，抗裂性以用于桥梁建设。

2.This polymer coating enhances the crack resistance 抗裂性 of the underlying surface against environmental stress.

这种聚合物涂层增强了底层表面对环境压力的抗裂性，抗裂性。

3.The new concrete mix has improved crack resistance 抗裂性, making it ideal for high-stress environments.

这种新混凝土配方具有更好的抗裂性，抗裂性，使其非常适合高应力环境。

4.In cold climates, materials with high crack resistance 抗裂性 are essential to prevent damage from freeze-thaw cycles.

在寒冷气候中，具有高抗裂性的材料对于防止因冻融循环造成的损害至关重要。

5.The manufacturer claims their tiles have superior crack resistance 抗裂性 compared to traditional ceramics.

制造商声称他们的瓷砖相比传统陶瓷具有更优越的抗裂性，抗裂性。

作文

In the modern world, the construction industry has made significant advancements in technology and materials. One of the most important qualities that engineers and architects look for in building materials is their crack resistance. This term refers to the ability of a material to withstand cracking under stress, which is crucial for ensuring the longevity and safety of structures. For instance, concrete is widely used in construction due to its strength, but without proper additives and techniques, it can be prone to cracking. Therefore, enhancing the crack resistance of concrete has become a focal point in research and development.The importance of crack resistance cannot be overstated. Cracks in buildings can lead to structural failures, water infiltration, and even safety hazards. When a building suffers from cracks, it not only compromises the integrity of the structure but also incurs significant repair costs. This is why many construction companies are investing in materials that offer superior crack resistance. By using advanced polymers or fiber reinforcement, they can improve the durability of concrete and other materials, thus extending the lifespan of buildings.Moreover, the concept of crack resistance extends beyond just construction materials. It is also relevant in the manufacturing of products such as tiles, glass, and even electronics. For example, ceramic tiles that are designed with high crack resistance are preferred for flooring in high-traffic areas because they can endure heavy loads without breaking. Similarly, in the electronics industry, devices that have better crack resistance are more reliable and have a longer shelf life, which is a significant selling point for consumers.In addition to improving material properties, understanding the factors that contribute to crack resistance is essential. Factors such as temperature fluctuations, humidity levels, and the load-bearing capacity of materials play a significant role in how well a material can resist cracking. Engineers must consider these variables when designing structures to ensure they can withstand environmental stresses over time.Furthermore, testing for crack resistance is a critical part of the quality assurance process in construction. Various methods, such as flexural tests and tensile tests, are employed to evaluate how materials respond to stress. These tests provide valuable data that help engineers select the right materials for specific applications, ensuring that buildings are safe and durable.In conclusion, crack resistance is a vital attribute in both construction and manufacturing. As technology continues to evolve, the development of materials with enhanced crack resistance will play a crucial role in creating safer, more sustainable structures. By prioritizing crack resistance, the construction industry can reduce maintenance costs, improve safety, and ultimately provide better living and working environments for everyone. The future of construction depends on our ability to innovate and adapt, making crack resistance an essential focus for engineers and architects alike.

在现代世界中，建筑行业在技术和材料方面取得了显著进展。工程师和建筑师在建筑材料中寻找的最重要的品质之一就是它们的抗裂性。这个术语指的是材料在压力下抵御开裂的能力，这对于确保结构的耐久性和安全性至关重要。例如，混凝土因其强度而被广泛用于建筑，但如果没有适当的添加剂和技术，它可能会容易开裂。因此，提高混凝土的抗裂性已成为研究和开发的重点。抗裂性的重要性不容小觑。建筑物中的裂缝可能导致结构失效、水渗透，甚至安全隐患。当一座建筑物出现裂缝时，不仅会损害结构的完整性，还会产生巨大的修复成本。这就是为什么许多建筑公司正在投资于具有优越抗裂性的材料。通过使用先进的聚合物或纤维增强材料，他们可以改善混凝土和其他材料的耐用性，从而延长建筑物的使用寿命。此外，抗裂性的概念不仅限于建筑材料。它在瓷砖、玻璃甚至电子产品的制造中也很相关。例如，设计具有高抗裂性的陶瓷瓷砖更受欢迎，因为它们可以承受重负荷而不易破裂，适合用于高流量区域的地板。同样，在电子行业中，具有更好抗裂性的设备更可靠，使用寿命更长，这对消费者来说是一个重要的卖点。除了改善材料特性外，理解影响抗裂性的因素也至关重要。温度波动、湿度水平和材料的承载能力等因素在材料抵抗开裂的能力上起着重要作用。工程师在设计结构时必须考虑这些变量，以确保它们能够经受住时间的环境压力。此外，测试抗裂性是建筑质量保证过程中的关键部分。各种方法，如弯曲测试和拉伸测试，被用于评估材料对压力的响应。这些测试提供了有价值的数据，帮助工程师为特定应用选择合适的材料，确保建筑物的安全和耐用。总之，抗裂性是建筑和制造中至关重要的属性。随着技术的不断发展，具有增强抗裂性的材料的发展将在创建更安全、更可持续的结构中发挥关键作用。通过优先考虑抗裂性，建筑行业可以减少维护成本，提高安全性，并最终为每个人提供更好的生活和工作环境。建筑的未来取决于我们创新和适应的能力，使得抗裂性成为工程师和建筑师的必然关注焦点。