safety against cracking

简明释义

抗裂安全性

英英释义

例句

1.For the new road surface, they incorporated a special coating for safety against cracking (防止裂纹的安全性) caused by heavy traffic.

对于新的路面，他们加入了一种特殊涂层，以确保因重型交通造成的safety against cracking (防止裂纹的安全性)。

2.This ceramic mug is designed with safety against cracking (防止裂纹的安全性) in mind, making it durable for daily use.

这款陶瓷杯的设计考虑到了safety against cracking (防止裂纹的安全性)，使其适合日常使用。

3.The construction company uses reinforced glass to provide safety against cracking (防止裂纹的安全性) in their buildings.

这家建筑公司使用加固玻璃以提供其建筑物的safety against cracking (防止裂纹的安全性)。

4.Engineers are testing materials for safety against cracking (防止裂纹的安全性) in extreme temperature conditions.

工程师们正在测试材料在极端温度条件下的safety against cracking (防止裂纹的安全性)。

5.The new design of the smartphone includes features that ensure safety against cracking (防止裂纹的安全性) during accidental drops.

这款智能手机的新设计包括确保在意外跌落时具有safety against cracking (防止裂纹的安全性)的功能。

作文

In the modern world, the integrity of materials and structures is of paramount importance. Engineers and architects face numerous challenges when designing buildings, bridges, and various infrastructures. One of the critical concerns in these designs is the potential for cracking, which can compromise the safety and longevity of the structures. To address this issue, the concept of safety against cracking (防止开裂的安全性) has become a focal point in material science and structural engineering. This essay will explore the significance of safety against cracking (防止开裂的安全性), the methods employed to ensure it, and its implications for construction practices.Cracking can occur due to various factors, including thermal expansion, shrinkage, excessive loading, or environmental influences. For instance, concrete, one of the most widely used construction materials, is particularly susceptible to cracking if not properly mixed or cured. Engineers must consider these factors during the design phase to minimize the risk of cracks developing over time. By ensuring safety against cracking (防止开裂的安全性), they can enhance the durability and stability of structures.One primary method to achieve safety against cracking (防止开裂的安全性) involves selecting appropriate materials. For example, high-performance concrete that incorporates additives can improve the material's resistance to cracking. Additionally, using reinforcement techniques, such as steel rebar or fiber reinforcement, can provide extra support and reduce stress concentrations that lead to cracking. These strategies not only help in preventing cracks but also contribute to the overall strength of the structure.Another important aspect of safety against cracking (防止开裂的安全性) is proper construction practices. This includes meticulous attention to detail during the mixing, pouring, and curing of concrete. For instance, ensuring that the concrete is adequately cured can significantly reduce the likelihood of shrinkage cracks. Moreover, implementing control joints in concrete slabs can help manage the natural expansion and contraction of the material, further enhancing safety against cracking (防止开裂的安全性).Furthermore, regular maintenance and inspection play a crucial role in ensuring safety against cracking (防止开裂的安全性) over a structure's lifespan. Identifying and addressing minor cracks early can prevent them from escalating into more significant issues that could jeopardize the safety of the building. Engineers often employ non-destructive testing methods to monitor the condition of structures and assess their integrity throughout their service life.In conclusion, the concept of safety against cracking (防止开裂的安全性) is essential in the field of engineering and construction. By understanding the causes of cracking and implementing effective measures to prevent it, engineers can ensure the longevity and safety of structures. The use of advanced materials, careful construction practices, and ongoing maintenance are all vital components in achieving this goal. As we continue to innovate and improve our construction techniques, the commitment to safety against cracking (防止开裂的安全性) will remain a cornerstone of sustainable and reliable infrastructure development.

在现代社会，材料和结构的完整性至关重要。工程师和建筑师在设计建筑、桥梁和各种基础设施时面临许多挑战。其中一个关键问题是开裂的潜在风险，这可能会危及结构的安全性和耐久性。为了应对这一问题，防止开裂的安全性的概念在材料科学和结构工程中成为了一个焦点。本文将探讨防止开裂的安全性的重要性、确保其的方法以及对建筑实践的影响。开裂可能由于多种因素引起，包括热膨胀、收缩、过度负荷或环境影响。例如，混凝土是最广泛使用的建筑材料之一，如果没有正确混合或养护，特别容易发生开裂。因此，工程师在设计阶段必须考虑这些因素，以尽量减少随着时间推移出现裂缝的风险。通过确保防止开裂的安全性，他们可以增强结构的耐久性和稳定性。实现防止开裂的安全性的一个主要方法是选择合适的材料。例如，掺有添加剂的高性能混凝土可以提高材料的抗裂能力。此外，使用钢筋或纤维增强等加固技术可以提供额外的支持，并减少导致开裂的应力集中。这些策略不仅有助于防止裂缝的产生，还能增强结构的整体强度。防止开裂的安全性的另一个重要方面是适当的施工实践。这包括在混合、浇筑和养护混凝土时对细节的严格关注。例如，确保混凝土得到充分养护，可以显著降低收缩裂缝的可能性。此外，在混凝土板中实施控制缝可以帮助管理材料的自然膨胀和收缩，进一步增强防止开裂的安全性。此外，定期维护和检查在确保结构的防止开裂的安全性方面发挥着至关重要的作用。早期识别并处理小裂缝可以防止它们升级为更严重的问题，从而危及建筑物的安全性。工程师通常采用非破坏性检测方法，以监测结构的状况并评估其在整个服务生命周期中的完整性。总之，防止开裂的安全性的概念在工程和建筑领域至关重要。通过了解开裂的原因并实施有效的预防措施，工程师可以确保结构的耐久性和安全性。使用先进的材料、仔细的施工实践和持续的维护都是实现这一目标的重要组成部分。随着我们不断创新和改进建筑技术，对防止开裂的安全性的承诺将始终是可持续和可靠基础设施发展的基石。