destruction test

简明释义

破坏性试验

英英释义

例句

1.The results of the destruction test showed that the device could withstand high temperatures.

该破坏性测试的结果显示设备能够承受高温。

2.The engineers conducted a destruction test to evaluate the durability of the new material.

工程师们进行了破坏性测试以评估新材料的耐用性。

3.During the destruction test, the product was subjected to extreme conditions to ensure safety standards.

在破坏性测试中，产品在极端条件下进行，以确保安全标准。

4.A destruction test is often required before a product can be approved for market release.

在产品可以批准上市之前，通常需要进行破坏性测试。

5.The destruction test revealed weaknesses in the design that needed to be addressed.

该破坏性测试揭示了设计中的弱点，需要加以解决。

作文

In the world of engineering and product design, ensuring safety and reliability is of utmost importance. One of the critical methods used to evaluate the performance and durability of materials and products is known as the destruction test. This testing procedure involves subjecting a material or product to extreme conditions until it fails, thereby providing valuable data on its limits and capabilities. The destruction test (破坏测试) serves multiple purposes in various industries, including automotive, aerospace, and construction.Firstly, the destruction test helps engineers understand how much stress a material can withstand before it breaks. For instance, in the automotive industry, safety is paramount. Engineers perform destruction tests on components like seat belts, airbags, and chassis parts to ensure they will perform adequately during a crash. By applying forces that exceed normal usage scenarios, they can identify potential failure points and improve the design before mass production.Moreover, the destruction test is crucial for compliance with industry standards and regulations. Many products must meet specific safety criteria before they can be sold to consumers. Conducting destruction tests allows manufacturers to demonstrate that their products adhere to these standards. For example, building materials like concrete and steel are routinely subjected to destruction tests to ensure they can support the loads they will encounter in real-world applications.Another significant aspect of the destruction test is its role in research and development. When developing new materials or innovative designs, engineers often need to push the boundaries of what is possible. The destruction test provides insights into the behavior of new materials under extreme conditions, helping researchers refine their approaches and develop safer, more efficient products. For instance, when creating lightweight composites for aircraft, engineers may conduct destruction tests to assess how these materials behave under high stress and temperature variations.Additionally, the destruction test can help identify manufacturing defects or inconsistencies in materials. By testing samples from different production batches, engineers can determine whether a batch meets quality standards. If a destruction test reveals unexpected failures, it may indicate a problem in the manufacturing process that needs to be addressed. This proactive approach can save companies from costly recalls and enhance overall product reliability.However, it is essential to conduct destruction tests responsibly. While they provide valuable information, they also involve destroying materials or products, which can be costly and wasteful. Therefore, engineers often use simulation techniques to predict failure modes before conducting physical tests. Advanced software can model how a product will respond under various conditions, allowing for more targeted and efficient testing.In conclusion, the destruction test (破坏测试) is a vital tool in engineering, providing crucial insights into material performance, safety, and reliability. By understanding how products fail, engineers can create safer and more effective designs. As industries continue to advance, the importance of such tests will only grow, ensuring that the products we rely on every day are built to withstand the challenges they face.

在工程和产品设计领域，确保安全性和可靠性至关重要。评估材料和产品性能及耐用性的关键方法之一被称为破坏测试。该测试程序涉及将材料或产品置于极端条件下，直到其失效，从而提供有关其极限和能力的宝贵数据。破坏测试（destruction test）在汽车、航空航天和建筑等多个行业中发挥着多重作用。首先，破坏测试帮助工程师了解材料在断裂前可以承受多少应力。例如，在汽车行业，安全至关重要。工程师对座椅安全带、安全气囊和底盘部件等组件进行破坏测试，以确保它们在碰撞时能够充分发挥作用。通过施加超出正常使用场景的力量，他们可以识别潜在的故障点，并在大规模生产之前改进设计。此外，破坏测试对遵守行业标准和法规至关重要。许多产品必须满足特定的安全标准才能销售给消费者。进行破坏测试使制造商能够证明其产品符合这些标准。例如，混凝土和钢材等建筑材料通常会接受破坏测试，以确保它们能够支持在实际应用中遇到的负载。破坏测试的另一个重要方面是它在研发中的作用。在开发新材料或创新设计时，工程师通常需要突破可能的界限。破坏测试提供了关于新材料在极端条件下行为的见解，帮助研究人员完善他们的方法，开发出更安全、更高效的产品。例如，在为飞机创建轻质复合材料时，工程师可能会进行破坏测试，以评估这些材料在高应力和温度变化下的表现。此外，破坏测试还可以帮助识别制造缺陷或材料不一致性。通过测试来自不同生产批次的样品，工程师可以确定某一批次是否符合质量标准。如果破坏测试显示出意外的故障，这可能表明制造过程存在问题，需要解决。这种主动的方法可以为公司节省昂贵的召回费用，并提高整体产品的可靠性。然而，进行破坏测试时必须负责任地进行。虽然它们提供了有价值的信息，但它们也涉及到摧毁材料或产品，这可能是昂贵和浪费的。因此，工程师通常使用仿真技术来预测故障模式，然后再进行物理测试。先进的软件可以模拟产品在各种条件下的反应，从而允许更有针对性和高效的测试。总之，破坏测试（destruction test）是工程中一项重要工具，为材料性能、安全性和可靠性提供了至关重要的见解。通过了解产品的失效方式，工程师可以创造出更安全、更有效的设计。随着各行业的不断发展，这类测试的重要性只会增加，确保我们每天依赖的产品能够经受住所面临的挑战。