destruction test

简明释义

破坏性试验

英英释义

例句

1.The engineers conducted a destruction test to evaluate the material's durability under extreme conditions.

工程师进行了破坏性测试以评估材料在极端条件下的耐用性。

2.Before releasing the product, the team performed a series of destruction tests to ensure safety standards were met.

在发布产品之前，团队进行了一系列破坏性测试以确保安全标准得到满足。

3.Our laboratory specializes in destruction tests for various construction materials.

我们的实验室专门进行各种建筑材料的破坏性测试。

4.The destruction test revealed that the structure could withstand a significant amount of pressure.

这项破坏性测试显示该结构能够承受相当大的压力。

5.During the destruction test, the team was able to identify critical failure points in the design.

在破坏性测试中，团队能够识别出设计中的关键故障点。

作文

In the field of engineering and material science, the term destruction test refers to a method used to evaluate the strength and durability of materials by subjecting them to extreme conditions until they fail. This testing approach is crucial for ensuring that materials can withstand the forces and stresses they will encounter in real-world applications. For instance, when designing a bridge, engineers must ensure that the materials used can handle not only the weight of the structure itself but also the dynamic loads from vehicles and environmental factors such as wind and earthquakes. To achieve this, a destruction test is performed on samples of the materials to determine their breaking point and overall structural integrity.The destruction test process typically involves applying increasing amounts of stress to a specimen until it reaches its failure point. By analyzing the data collected during this test, engineers can gain insights into how the material behaves under pressure and identify any potential weaknesses. This information is invaluable, as it helps in making informed decisions about material selection and design practices.Moreover, the results from a destruction test are often used to develop safety standards and regulations. For example, in the aerospace industry, where the stakes are incredibly high, materials must undergo rigorous testing to ensure they can endure the harsh conditions of flight. A failure in this context could lead to catastrophic consequences, making the destruction test an essential part of the development process.In addition to its applications in engineering, the concept of a destruction test can also be found in other fields, such as electronics and consumer goods. For example, manufacturers of smartphones often conduct destruction tests to assess the durability of their devices. These tests may involve dropping the phone from various heights or exposing it to extreme temperatures to see how it holds up. The goal is to ensure that the product can withstand everyday use and potential accidents.Furthermore, the findings from destruction tests can lead to innovations in material science. As researchers analyze the failure points of different materials, they can develop new composites or alloys that offer superior performance. This continuous cycle of testing, analysis, and improvement drives advancements in technology and enhances the safety and reliability of products across various industries.In conclusion, the destruction test is a vital procedure in engineering and manufacturing that helps ensure the safety and efficacy of materials used in various applications. By understanding the limits of materials through these tests, engineers and researchers can create safer, more reliable structures and products. The implications of destruction tests extend far beyond the laboratory, influencing everything from infrastructure development to consumer electronics. As technology continues to evolve, the importance of these tests will only grow, underscoring the need for rigorous evaluation of materials in our ever-changing world.

在工程和材料科学领域，术语破坏测试指的是一种评估材料强度和耐久性的方法，通过将其置于极端条件下直到它们失效。这种测试方法对于确保材料能够承受在实际应用中遇到的力量和压力至关重要。例如，在设计桥梁时，工程师必须确保所用材料不仅能承受结构自身的重量，还能承受来自车辆和环境因素（如风和地震）的动态负载。为了实现这一点，通常会对材料样本进行破坏测试，以确定其断裂点和整体结构完整性。破坏测试过程通常涉及对样品施加逐渐增加的压力，直到达到其失效点。通过分析在此测试期间收集的数据，工程师可以深入了解材料在压力下的表现，并识别任何潜在的弱点。这些信息非常宝贵，因为它有助于做出关于材料选择和设计实践的明智决策。此外，破坏测试的结果通常用于制定安全标准和法规。例如，在航空航天工业中，风险极高，材料必须经过严格测试，以确保它们能够承受飞行的恶劣条件。在这种情况下的失败可能导致灾难性的后果，这使得破坏测试成为开发过程中的重要部分。除了在工程中的应用外，破坏测试的概念也可以在其他领域找到，例如电子产品和消费品。例如，智能手机制造商经常进行破坏测试以评估其设备的耐用性。这些测试可能涉及将手机从不同高度掉落或暴露于极端温度，以查看其如何保持性能。目标是确保产品能够承受日常使用和潜在事故。此外，破坏测试的发现可以推动材料科学的创新。当研究人员分析不同材料的失效点时，他们可以开发出性能更优越的新复合材料或合金。这一持续的测试、分析和改进循环推动了技术的进步，并提高了各行业产品的安全性和可靠性。总之，破坏测试是工程和制造中一个至关重要的程序，帮助确保在各种应用中使用的材料的安全性和有效性。通过了解这些测试揭示的材料极限，工程师和研究人员可以创造出更安全、更可靠的结构和产品。破坏测试的影响远远超出了实验室，影响着从基础设施开发到消费电子的方方面面。随着技术的不断发展，这些测试的重要性只会增加，凸显了在我们不断变化的世界中对材料进行严格评估的必要性。