safety against rupture

简明释义

抗破坏安全性

英英释义

例句

1.Using high-quality materials contributes significantly to safety against rupture in industrial applications.

使用高质量材料对工业应用中的防止破裂的安全性有显著贡献。

2.The construction of the dam included features that provided safety against rupture during heavy rainfall.

大坝的建设包括在大雨期间提供防止破裂的安全性的功能。

3.The safety guidelines emphasize the importance of safety against rupture in chemical storage tanks.

安全指南强调在化学储存罐中防止破裂的安全性的重要性。

4.The engineers designed the pipeline with safety against rupture in mind to prevent any hazardous leaks.

工程师在设计管道时考虑了防止破裂的安全性，以防止任何危险泄漏。

5.Regular maintenance checks are crucial for ensuring safety against rupture in high-pressure vessels.

定期维护检查对于确保高压容器的防止破裂的安全性至关重要。

作文

In modern engineering and construction, ensuring the structural integrity of buildings and infrastructure is paramount. One of the key concepts that professionals must consider is safety against rupture (防止破裂的安全性). This term refers to the measures taken to prevent catastrophic failures in materials or structures that can lead to significant damage or loss of life. Understanding this concept is crucial for engineers, architects, and safety inspectors alike.When designing a structure, engineers must select materials that can withstand various forces, such as tension, compression, and shear. For instance, steel and reinforced concrete are commonly used due to their high tensile strength and durability. However, even the strongest materials can fail if subjected to extreme conditions or poor design practices. Therefore, implementing safety against rupture (防止破裂的安全性) involves not only choosing the right materials but also ensuring that they are used correctly in the construction process.One of the primary factors in achieving safety against rupture (防止破裂的安全性) is understanding the load-bearing capacity of materials. Engineers conduct extensive testing to determine how much weight a material can support before it begins to deform or break. This information is critical when calculating the overall stability of a structure. Additionally, factors such as temperature fluctuations, environmental conditions, and potential wear and tear over time must be considered.Another essential aspect of safety against rupture (防止破裂的安全性) is regular maintenance and inspection. Even well-designed structures can develop weaknesses over time due to exposure to the elements or other external factors. Routine inspections help identify potential issues before they escalate into serious problems. For example, cracks in concrete or rust on steel beams can indicate that a structure is at risk of failure. By addressing these issues promptly, engineers can enhance the safety against rupture (防止破裂的安全性) of the structure.Moreover, advancements in technology have significantly improved our ability to ensure safety against rupture (防止破裂的安全性). Innovative materials, such as fiber-reinforced polymers and smart materials, offer enhanced performance characteristics that can help prevent failures. Additionally, computer modeling and simulation tools allow engineers to predict how structures will behave under various conditions, enabling them to make informed decisions during the design phase.In conclusion, safety against rupture (防止破裂的安全性) is a fundamental principle in engineering and construction. It encompasses the careful selection of materials, rigorous testing, ongoing maintenance, and the use of advanced technologies. By prioritizing this concept, professionals can create safe and resilient structures that protect lives and property. As we continue to innovate and push the boundaries of engineering, maintaining a focus on safety against rupture (防止破裂的安全性) will remain essential in safeguarding our built environment.

在现代工程和建筑中，确保建筑物和基础设施的结构完整性至关重要。专业人员必须考虑的关键概念之一是防止破裂的安全性（safety against rupture）。这个术语指的是为了防止材料或结构发生灾难性故障而采取的措施，这些故障可能导致重大损害或生命损失。理解这一概念对工程师、建筑师和安全检查员来说都是至关重要的。在设计结构时，工程师必须选择能够承受各种力的材料，例如拉力、压力和剪切力。例如，钢材和钢筋混凝土因其高抗拉强度和耐久性而被广泛使用。然而，即使是最坚固的材料，在极端条件或不良设计实践下也可能会失效。因此，实现防止破裂的安全性（safety against rupture）不仅涉及选择合适的材料，还涉及确保在施工过程中正确使用这些材料。实现防止破裂的安全性（safety against rupture）的一个主要因素是了解材料的承载能力。工程师进行广泛的测试，以确定材料在开始变形或破裂之前能够支持多少重量。这些信息在计算结构的整体稳定性时至关重要。此外，温度波动、环境条件和随时间推移可能出现的磨损等因素也必须考虑在内。防止破裂的安全性（safety against rupture）的另一个重要方面是定期维护和检查。即使是设计良好的结构，也可能由于暴露在恶劣环境中或其他外部因素而随着时间的发展而产生弱点。例行检查有助于在问题升级为严重问题之前识别潜在问题。例如，混凝土中的裂缝或钢梁上的锈蚀可能表明结构面临失效风险。通过及时解决这些问题，工程师可以增强结构的防止破裂的安全性（safety against rupture）。此外，技术的进步显著提高了我们确保防止破裂的安全性（safety against rupture）的能力。创新材料，如纤维增强聚合物和智能材料，提供了增强的性能特征，可以帮助防止失效。此外，计算机建模和仿真工具使工程师能够预测结构在各种条件下的表现，从而使他们在设计阶段做出明智的决策。总之，防止破裂的安全性（safety against rupture）是工程和建筑中的基本原则。它包括材料的精心选择、严格的测试、持续的维护以及先进技术的使用。通过优先考虑这一概念，专业人士可以创建安全和韧性的结构，以保护生命和财产。随着我们不断创新并推动工程的边界，关注防止破裂的安全性（safety against rupture）将始终是保护我们建成环境的关键。