interrupted hardening

简明释义

分级硬化

英英释义

例句

1.Engineers must consider interrupted hardening when designing components that will undergo thermal treatments.

工程师在设计将经历热处理的组件时，必须考虑到中断硬化。

2.To achieve the desired finish, we need to control interrupted hardening during the cooling phase.

为了达到所需的表面处理，我们需要在冷却阶段控制中断硬化。

3.The study showed that interrupted hardening affects the tensile strength of the material.

研究表明，中断硬化会影响材料的抗拉强度。

4.The process of interrupted hardening can lead to unexpected material properties.

过程中的中断硬化可能导致意想不到的材料特性。

5.In metalworking, interrupted hardening can occur if cooling is not uniform.

在金属加工中，如果冷却不均匀，可能会发生中断硬化。

作文

The process of material strengthening is crucial in various fields, especially in engineering and manufacturing. One of the key methods used to enhance the durability and strength of materials is through hardening. However, there are instances where this process can be disrupted, leading to what is known as interrupted hardening. This term refers to a situation where the hardening process is stopped prematurely or altered due to various factors, such as temperature fluctuations or time constraints. Understanding interrupted hardening is essential for engineers and manufacturers, as it can significantly affect the mechanical properties of the final product.When metals undergo hardening, they typically experience a series of controlled heating and cooling cycles. These cycles allow the material to reach a desired hardness level, improving its resistance to wear and deformation. However, if the hardening process is interrupted, the material may not achieve the intended hardness. For instance, if a metal is heated to a specific temperature but is then cooled too quickly or inconsistently, it may result in a less uniform microstructure, which can compromise its overall strength and performance.In practical applications, interrupted hardening can occur during various stages of production. For example, in the heat treatment of steel, if the quenching process is not executed correctly, it can lead to uneven cooling rates. This unevenness can cause internal stresses within the material, leading to potential failures in the end product. Moreover, in some cases, manufacturers may intentionally choose to implement interrupted hardening to achieve specific characteristics in a material. By controlling the interruption of the hardening process, they can tailor the material's properties to meet particular requirements.The implications of interrupted hardening extend beyond just mechanical properties; they also influence the material's performance in real-world applications. For instance, components subjected to high stress or extreme conditions may fail prematurely if their hardening processes were not properly managed. This is particularly critical in industries such as aerospace, automotive, and construction, where safety and reliability are paramount.To mitigate the risks associated with interrupted hardening, engineers must pay close attention to the parameters involved in the hardening process. This includes monitoring temperature, time, and cooling rates to ensure that they remain within specified limits. Additionally, advanced techniques, such as computer simulations and real-time monitoring, can help predict the outcomes of hardening processes and identify potential issues before they arise.In conclusion, understanding interrupted hardening is vital for anyone involved in material science and engineering. It highlights the importance of precision in manufacturing processes and the need for thorough testing and quality control. By recognizing the factors that can lead to interruptions in hardening, professionals can better design materials that meet the demands of their applications, ensuring safety and performance across various industries.

材料强化过程在各个领域都是至关重要的，尤其是在工程和制造业中。增强材料耐久性和强度的关键方法之一是通过硬化。然而，有时这个过程会被中断，导致所谓的interrupted hardening。这个术语指的是由于温度波动或时间限制等各种因素，硬化过程被提前停止或改变的情况。理解interrupted hardening对于工程师和制造商来说至关重要，因为它会显著影响最终产品的机械性能。当金属经历硬化时，它们通常会经历一系列受控的加热和冷却周期。这些周期使材料达到所需的硬度水平，提高其耐磨性和变形抵抗力。然而，如果硬化过程被中断，材料可能无法达到预期的硬度。例如，如果金属被加热到特定温度，但随后冷却过快或不一致，可能会导致微观结构不均匀，从而影响其整体强度和性能。在实际应用中，interrupted hardening可能在生产的各个阶段发生。例如，在钢的热处理过程中，如果淬火过程未正确执行，可能导致不均匀的冷却速率。这种不均匀性可能在材料内部造成应力，从而导致最终产品的潜在故障。此外，在某些情况下，制造商可能故意选择实施interrupted hardening以获得材料的特定特性。通过控制硬化过程的中断，他们可以根据特定要求调整材料的属性。interrupted hardening的影响不仅限于机械性能；它们还影响材料在实际应用中的表现。例如，遭受高应力或极端条件的组件，如果其硬化过程未得到适当管理，可能会过早失效。这在航空航天、汽车和建筑等行业尤为关键，这些行业对安全和可靠性要求极高。为了降低与interrupted hardening相关的风险，工程师必须密切关注硬化过程中的参数。这包括监测温度、时间和冷却速率，以确保它们保持在规定的范围内。此外，先进技术，如计算机模拟和实时监测，可以帮助预测硬化过程的结果，并在问题出现之前识别潜在问题。总之，理解interrupted hardening对于任何参与材料科学和工程的人来说都是至关重要的。它突显了制造过程精确性的必要性，以及彻底测试和质量控制的需求。通过认识到可能导致硬化中断的因素，专业人员可以更好地设计满足应用需求的材料，确保各个行业的安全性和性能。