forgeability

简明释义

英[/ˈfɔrdʒəˌbɪlɪti/]美[/ˈfɔrdʒəˌbɪlɪti/]

n. [材] 可锻性

英英释义

单词用法

同义词

反义词

例句

1.The effects of semicontinuous casting process with different technological parameters on the ingot microstructure and forgeability of B30 alloy were studied.

研究了不同工艺参数的半连续铸造工艺对铸锭组织及可锻性的影响，并将常用于改善铸钢组织性能的电渣重熔工艺引入B30铜合金铸造。

2.The effects of semicontinuous casting process with different technological parameters on the ingot microstructure and forgeability of B30 alloy were studied.

研究了不同工艺参数的半连续铸造工艺对铸锭组织及可锻性的影响，并将常用于改善铸钢组织性能的电渣重熔工艺引入B30铜合金铸造。

3.Wrought alloys possess good forgeability, it gives way to pressure.

锻造合金具有良好的可锻性，在压力下会变形。

4.The forgeability of dispersion strengthened copper was studied.

对弥散强化铜的锻造性进行了研究。

5.The new metal alloy has improved forgeability, allowing it to be shaped easily without cracking.

这种新型金属合金具有更好的可锻性，可以在不破裂的情况下轻松成型。

6.Engineers are testing the forgeability of different materials to find the best option for manufacturing.

工程师正在测试不同材料的可锻性，以找到制造的最佳选择。

7.High forgeability is essential for producing complex shapes in automotive parts.

高可锻性对于生产复杂形状的汽车零件至关重要。

8.The research focused on enhancing the forgeability of titanium for aerospace applications.

研究集中在提高钛在航空航天应用中的可锻性。

9.A material's forgeability can significantly affect the production cost and efficiency.

材料的可锻性会显著影响生产成本和效率。

作文

In the realm of manufacturing and material sciences, one term that often arises is forgeability. This concept refers to the ability of a material to be shaped or deformed under compressive stress without cracking or breaking. It is a critical property that influences how metals and alloys can be processed into various forms and components. Understanding forgeability is essential for engineers and manufacturers as it directly impacts production efficiency, material selection, and the overall quality of the final product. The process of forging involves applying pressure to metal to shape it into desired forms. This can be done through various methods, including hot forging, cold forging, and warm forging. Each of these techniques has its own advantages and limitations, which are heavily influenced by the forgeability of the material being used. For instance, materials with high forgeability can be easily manipulated at lower temperatures, reducing energy costs and improving production speed. Materials such as aluminum and certain alloys are known for their excellent forgeability, making them popular choices in industries ranging from automotive to aerospace. In contrast, materials with low forgeability may require higher temperatures or more complex processes to achieve the desired shapes, which can lead to increased production times and costs. Moreover, the forgeability of a material can be affected by various factors, including its chemical composition, microstructure, and the presence of impurities. For example, adding specific alloying elements can enhance the forgeability of steel, allowing it to be forged into intricate shapes without failure. Therefore, understanding the underlying principles of forgeability is crucial for material scientists and engineers when developing new alloys or optimizing existing ones. In addition to its technical implications, forgeability also has economic significance. Industries that rely on forging processes must consider the forgeability of materials to minimize waste and maximize productivity. A material that is difficult to forge may result in higher scrap rates and increased labor costs, ultimately affecting the bottom line of a manufacturing operation. Furthermore, the concept of forgeability extends beyond just the physical properties of materials; it also encompasses the design and engineering aspects of the forging process. Engineers must take into account the forgeability of materials when designing parts to ensure that they can be efficiently produced. This includes considerations such as the geometry of the part, the type of forging method to be used, and the expected mechanical properties of the finished component. In conclusion, forgeability is a vital property that plays a significant role in the manufacturing and engineering industries. Its implications reach far beyond the mere ability to shape materials; it affects production efficiency, cost-effectiveness, and the overall quality of products. As industries continue to evolve and innovate, a deeper understanding of forgeability will remain essential for engineers and manufacturers alike. By focusing on this critical aspect of material science, we can enhance our capabilities in producing high-quality components that meet the demands of modern technology and industry.

在制造和材料科学领域，一个经常出现的术语是forgeability。这个概念指的是材料在不破裂或断裂的情况下，能够在压缩应力下被塑形或变形的能力。这是一个关键特性，影响着金属和合金如何被加工成各种形式和组件。理解forgeability对于工程师和制造商至关重要，因为它直接影响生产效率、材料选择以及最终产品的整体质量。 锻造过程涉及对金属施加压力，以将其塑造成所需的形状。这可以通过各种方法完成，包括热锻、冷锻和温锻。每种技术都有其自身的优缺点，而这些都受到所使用材料的forgeability的重大影响。例如，具有高forgeability的材料可以在较低的温度下轻松操作，从而降低能源成本并提高生产速度。 铝和某些合金等材料以其优良的forgeability而闻名，使其在从汽车到航空航天等行业中成为热门选择。相比之下，具有低forgeability的材料可能需要更高的温度或更复杂的工艺才能达到所需的形状，这可能导致生产时间和成本的增加。 此外，材料的forgeability可能会受到多种因素的影响，包括其化学成分、微观结构和杂质的存在。例如，添加特定的合金元素可以增强钢的forgeability，使其能够在不失败的情况下被锻造成复杂的形状。因此，理解forgeability的基本原理对于材料科学家和工程师在开发新合金或优化现有合金时至关重要。 除了其技术意义外，forgeability还具有经济意义。依赖锻造过程的行业必须考虑材料的forgeability，以最小化浪费并最大化生产率。难以锻造的材料可能导致更高的废料率和更高的劳动成本，最终影响制造操作的底线。 此外，forgeability的概念不仅仅局限于材料的物理特性；它还涵盖了锻造过程的设计和工程方面。工程师在设计零件时必须考虑材料的forgeability，以确保它们能够高效地生产。这包括零件的几何形状、所用锻造方法的类型以及成品组件的预期机械性能等考虑。 总之，forgeability是一种重要的属性，在制造和工程行业中发挥着重要作用。它的影响远远超出了单纯塑形材料的能力；它影响着生产效率、成本效益和产品的整体质量。随着行业的不断发展和创新，对forgeability的更深入理解将继续对工程师和制造商至关重要。通过关注这一材料科学的重要方面，我们可以增强在生产满足现代技术和行业需求的高质量组件方面的能力。