breaking test

简明释义

破断试验

英英释义

例句

1.The engineers conducted a breaking test to determine the maximum load the bridge could withstand.

工程师进行了破坏性测试以确定桥梁能承受的最大负荷。

2.During the quality assurance phase, the team performed a breaking test on the new smartphone model.

在质量保证阶段，团队对新款智能手机进行了破坏性测试。

3.The materials were subjected to a breaking test to assess their durability under extreme conditions.

这些材料经过了破坏性测试以评估它们在极端条件下的耐用性。

4.A breaking test is essential for ensuring product safety before market release.

在市场发布之前，进行破坏性测试对确保产品安全至关重要。

5.The fabric was tested using a breaking test to evaluate its strength and resistance to tearing.

该面料通过破坏性测试来评估其强度和抗撕裂能力。

作文

In the world of engineering and material science, the term breaking test refers to a critical evaluation method used to determine the strength and durability of materials. This process involves applying force to a material until it fails, thereby providing essential data on its breaking point and overall structural integrity. Understanding the concept of the breaking test is crucial for engineers and designers who seek to ensure that the materials they use can withstand the stresses they will encounter in real-world applications.The importance of conducting a breaking test cannot be overstated. For example, in the construction industry, the safety of buildings and bridges relies heavily on the strength of the materials used. If a material fails under stress, it could lead to catastrophic failures, resulting in injuries or even fatalities. Therefore, engineers must perform breaking tests on concrete, steel, and other materials to verify their load-bearing capacity.Moreover, the breaking test is not limited to just construction materials. It is also widely used in the manufacturing of consumer products, such as electronics and automotive components. For instance, when developing a new smartphone, manufacturers will conduct breaking tests on various parts, including the screen, casing, and internal components, to ensure that they can withstand drops, pressure, and other potential hazards. This testing phase is vital for product reliability and customer satisfaction.The methodology behind a breaking test typically involves standardized procedures to ensure accuracy and consistency. Engineers will often use specialized equipment to apply controlled forces to a sample material. The results are then recorded and analyzed to determine the maximum load the material can handle before failure occurs. This data is invaluable for making informed decisions about material selection and design specifications.In addition to practical applications, the breaking test also has implications in research and development. Scientists may explore new materials with unique properties, and breaking tests allow them to assess whether these materials can be viable alternatives to traditional options. As industries evolve and seek more sustainable solutions, understanding the performance characteristics of new materials through breaking tests becomes increasingly important.Furthermore, the results of breaking tests contribute to the development of safety standards and regulations. Organizations such as ASTM International and ISO set guidelines for how these tests should be performed and what criteria must be met. Compliance with these standards ensures that products are safe for consumers and that manufacturers are held accountable for their materials' performance.In conclusion, the breaking test is a fundamental aspect of material science and engineering that plays a vital role in ensuring safety and reliability across various industries. From construction to consumer goods, understanding the outcomes of breaking tests helps engineers make informed decisions, leading to better designs and safer products. As technology advances and new materials are developed, the significance of breaking tests will continue to grow, highlighting the need for rigorous testing protocols in our ever-evolving world.

在工程和材料科学的世界中，术语破坏试验指的是一种关键的评估方法，用于确定材料的强度和耐久性。这个过程涉及对材料施加力，直到其失效，从而提供有关其断裂点和整体结构完整性的基本数据。理解破坏试验的概念对于寻求确保所用材料能够承受实际应用中遇到的压力的工程师和设计师至关重要。进行破坏试验的重要性不容小觑。例如，在建筑行业，建筑物和桥梁的安全在很大程度上依赖于所用材料的强度。如果材料在压力下失效，可能导致灾难性的故障，造成伤害甚至死亡。因此，工程师必须对混凝土、钢材和其他材料进行破坏试验，以验证其承载能力。此外，破坏试验不仅限于建筑材料。它还广泛应用于消费产品的制造，如电子产品和汽车零部件。例如，在开发一款新智能手机时，制造商会对各种部件进行破坏试验，包括屏幕、外壳和内部组件，以确保它们能够承受跌落、压力和其他潜在危险。这一测试阶段对于产品的可靠性和客户满意度至关重要。破坏试验背后的方法通常涉及标准化程序，以确保准确性和一致性。工程师通常会使用专门的设备对样本材料施加控制力。然后记录和分析结果，以确定材料在失效前能够承受的最大负荷。这些数据对于做出明智的材料选择和设计规范至关重要。除了实际应用之外，破坏试验在研究与开发中也具有重要意义。科学家可能会探索具有独特属性的新材料，而破坏试验使他们能够评估这些材料是否可以作为传统选项的可行替代品。随着行业的发展，寻求更可持续的解决方案，通过破坏试验了解新材料的性能特征变得越来越重要。此外，破坏试验的结果有助于制定安全标准和法规。诸如ASTM国际和ISO等组织为这些测试应如何进行以及必须满足哪些标准设定了指导方针。遵守这些标准确保了产品对消费者的安全，并使制造商对其材料的性能负责。总之，破坏试验是材料科学和工程的基本方面，在确保各行业安全和可靠性方面发挥着至关重要的作用。从建筑到消费品，理解破坏试验的结果帮助工程师做出明智的决策，从而导致更好的设计和更安全的产品。随着技术的发展和新材料的开发，破坏试验的重要性将继续增长，突显出在我们不断发展的世界中严格测试协议的必要性。