forged hardening
简明释义
锻造热处理
英英释义
Forged hardening refers to a process in metallurgy where metal is shaped through forging and subsequently treated to increase its hardness and strength. | 锻造硬化是指在冶金中,通过锻造将金属成型,然后经过处理以增加其硬度和强度的过程。 |
例句
1.The blacksmith demonstrated the process of forged hardening, which involves heating and then rapidly cooling the metal to enhance its strength.
铁匠展示了锻造硬化的过程,该过程包括加热然后快速冷却金属以增强其强度。
2.The knife maker explained how forged hardening improves the durability of the blade.
刀具制造商解释了锻造硬化如何提高刀片的耐用性。
3.Automotive parts are often subjected to forged hardening to enhance their performance and longevity.
汽车零部件常常经过锻造硬化以增强其性能和使用寿命。
4.The artist used forged hardening techniques to create a stunning sculpture from metal.
艺术家使用锻造硬化技术创造了一件惊艳的金属雕塑。
5.In aerospace engineering, components often undergo forged hardening to withstand extreme conditions during flight.
在航空航天工程中,部件通常会经历锻造硬化以承受飞行中的极端条件。
作文
The process of metalworking has evolved significantly over the centuries, with various techniques being developed to enhance the properties of metals. One such technique that stands out is forged hardening, which is a method used to improve the strength and durability of metal components. This process involves the application of heat and mechanical force to shape the metal, followed by rapid cooling to achieve desired hardness levels. Understanding forged hardening is essential for those involved in manufacturing and engineering, as it plays a crucial role in producing high-performance materials.When we talk about forged hardening (锻造硬化), we are referring to a combination of forging and hardening processes. Forging itself is a manufacturing process where metal is shaped by applying compressive forces, usually delivered through a hammer or a die. This process not only shapes the metal but also aligns its internal structure, enhancing its toughness and strength. However, the real magic happens when the forged metal undergoes hardening.Hardening is a heat treatment process that increases the hardness of a material. In the case of forged hardening (锻造硬化), the forged metal is heated to a specific temperature and then rapidly cooled, typically in water or oil. This sudden temperature change causes the microstructure of the metal to change, resulting in increased hardness. The combination of these two processes—forging and hardening—creates a material that is not only strong but also resistant to wear and deformation.The applications of forged hardening are vast and varied. It is commonly used in the automotive and aerospace industries, where components must withstand extreme stress and fatigue. For example, crankshafts and connecting rods in engines often undergo forged hardening to ensure they can handle the immense forces generated during operation. Similarly, aircraft components benefit from this process, as it ensures safety and reliability under high-stress conditions.Moreover, forged hardening (锻造硬化) is not limited to large-scale industrial applications. It is also prevalent in the production of tools and equipment, where durability is paramount. Cutting tools, such as drills and chisels, often undergo forged hardening to maintain their performance over time. The ability to create sharp, long-lasting edges is essential for efficiency in various trades, from construction to manufacturing.In conclusion, the significance of forged hardening (锻造硬化) in modern metallurgy cannot be overstated. It represents a fusion of ancient techniques and modern science, resulting in materials that meet the demanding needs of today's industries. As technology continues to advance, understanding processes like forged hardening will be vital for engineers and manufacturers aiming to innovate and improve the materials we rely on every day. By mastering this technique, we can ensure that the products we create are not only functional but also built to last, ultimately contributing to a more efficient and sustainable future.
金属加工的过程在几个世纪中发生了显著变化,开发了多种技术以增强金属的特性。其中一种突出的技术是锻造硬化,这是一种用于改善金属组件强度和耐用性的方法。该过程涉及热量和机械力的应用,以塑造金属,然后快速冷却以达到所需的硬度水平。理解锻造硬化对制造和工程领域的人士至关重要,因为它在生产高性能材料中起着关键作用。当我们谈论锻造硬化(锻造硬化)时,我们指的是锻造和硬化过程的结合。锻造本身是一种制造过程,通过施加压缩力来塑造金属,通常通过锤子或模具传递。这一过程不仅塑造了金属,还对其内部结构进行了排列,从而增强了其韧性和强度。然而,真正的魔力发生在锻造金属经过硬化之后。硬化是一种热处理过程,可以提高材料的硬度。在锻造硬化(锻造硬化)的情况下,锻造金属被加热到特定温度,然后迅速冷却,通常是在水或油中。这种突然的温度变化导致金属的微观结构发生变化,从而增加了硬度。这两种过程的结合——锻造和硬化——创造出一种不仅强大且耐磨变形的材料。锻造硬化的应用广泛而多样。它通常用于汽车和航空航天工业,在这些行业中,组件必须承受极大的压力和疲劳。例如,发动机中的曲轴和连杆通常经过锻造硬化以确保它们能够承受操作过程中产生的巨大力量。同样,飞机部件也从这一过程中受益,因为它确保在高压力条件下的安全性和可靠性。此外,锻造硬化(锻造硬化)并不仅限于大规模工业应用。它在工具和设备的生产中也很普遍,其中耐用性至关重要。切削工具,如钻头和凿子,通常经过锻造硬化以保持其长期性能。能够制造出锋利、持久的边缘对于各个行业的效率至关重要,从建筑到制造。总之,锻造硬化(锻造硬化)在现代冶金学中的重要性不容小觑。它代表了古老技术与现代科学的融合,创造出满足当今工业需求的材料。随着技术的不断进步,理解像锻造硬化这样的过程将对旨在创新和提高我们日常依赖材料的工程师和制造商至关重要。通过掌握这一技术,我们可以确保所创造的产品不仅功能齐全,而且经久耐用,最终有助于更高效和可持续的未来。
相关单词
