ausforming

简明释义

英[ˈɔsˌfɔrmɪŋ]美[ˈɔsˌfɔrmɪŋ]

n. [机] 形变热处理；沃斯成型钢；[机] 奥氏体形变

英英释义

单词用法

同义词

反义词

例句

1.The ausforming process can be joined in the CSP production line. Thus the product scope of CSP could be widened.

CSP生产流程中尚可汇集形变热处理工艺，因此CSP工艺技术将拓展出更广阔的产品范围。

2.The ausforming process can be joined in the CSP production line. Thus the product scope of CSP could be widened.

CSP生产流程中尚可汇集形变热处理工艺，因此CSP工艺技术将拓展出更广阔的产品范围。

3.The artist is currently ausforming her ideas into a beautiful sculpture.

这位艺术家正在将她的想法塑造成一座美丽的雕塑。

4.During the workshop, participants learned the technique of ausforming clay into intricate designs.

在工作坊中，参与者学习了将粘土塑造成复杂设计的技巧。

5.The engineer is ausforming the metal to create a more efficient component.

工程师正在塑造金属，以创造更高效的组件。

6.In the fashion industry, designers are ausforming fabric to create unique garments.

在时尚行业，设计师正在塑造面料，以创造独特的服装。

7.The chef is ausforming ingredients to create a stunning presentation of the dish.

厨师正在塑造食材，以创造菜肴的惊艳呈现。

作文

In the realm of manufacturing and design, the term ausforming refers to a specific process that involves the transformation of materials through controlled deformation. This technique is particularly significant in the production of high-strength components that require precise specifications. The process of ausforming allows engineers to manipulate the microstructure of metals, enhancing their mechanical properties while maintaining their ductility. This makes ausforming an essential method in industries such as aerospace, automotive, and construction, where material integrity is paramount. To understand ausforming better, it is crucial to explore its underlying mechanisms. The process usually begins with heating the metal to a temperature where it becomes malleable. Once at this optimal temperature, the material is subjected to a series of deformations—these can include rolling, forging, or pressing. The key aspect of ausforming is that it occurs within a specific temperature range, typically just below the material's recrystallization temperature. This careful control ensures that the grain structure of the metal is refined, leading to improved strength and toughness. One of the most notable advantages of ausforming is its ability to produce materials that possess superior mechanical properties compared to those achieved through conventional forming methods. For instance, components produced through ausforming often exhibit increased yield strength and fatigue resistance. This is particularly beneficial in applications where durability and reliability are critical, such as in aircraft components that must withstand extreme conditions. Moreover, ausforming contributes to sustainability in manufacturing. By optimizing the material properties, manufacturers can reduce the amount of material needed for a given application. This not only lowers production costs but also minimizes waste, aligning with modern goals of reducing environmental impact. As industries continue to seek more sustainable practices, the relevance of ausforming is expected to grow. In conclusion, ausforming is a vital process in modern manufacturing that enhances the performance characteristics of materials through controlled deformation. Its ability to improve mechanical properties while promoting sustainability makes it an invaluable technique across various industries. Understanding ausforming is essential for anyone involved in material science or engineering, as it represents a key innovation in the quest for stronger, lighter, and more durable materials. As we move forward, the continued exploration and application of ausforming will undoubtedly lead to advancements that drive the industry towards greater efficiency and effectiveness.

在制造和设计领域中，术语ausforming指的是一种通过控制变形来转化材料的特定过程。这项技术在生产高强度组件时尤为重要，这些组件需要精确的规格。ausforming过程使工程师能够操控金属的微观结构，增强其机械性能，同时保持其延展性。这使得ausforming成为航空航天、汽车和建筑等行业中一种必不可少的方法，在这些行业中，材料的完整性至关重要。 要更好地理解ausforming，必须探讨其基本机制。该过程通常始于将金属加热到可塑性温度。一旦达到此最佳温度，材料就会经历一系列变形——这些可以包括轧制、锻造或压制。ausforming的关键在于它发生在特定的温度范围内，通常低于材料的再结晶温度。这种精确控制确保了金属的晶粒结构得到细化，从而提高了强度和韧性。 ausforming最显著的优势之一是其能够生产出相比于传统成形方法具有优越机械性能的材料。例如，通过ausforming生产的组件通常表现出更高的屈服强度和疲劳抗力。这在飞机组件等关键应用中尤其有益，因为这些组件必须承受极端条件。 此外，ausforming还促进了制造业的可持续发展。通过优化材料性能，制造商可以减少给定应用所需的材料数量。这不仅降低了生产成本，还最小化了浪费，与现代减少环境影响的目标相一致。随着各行业继续寻求更可持续的做法，ausforming的重要性预计将不断增长。 总之，ausforming是现代制造中一种重要的过程，通过控制变形来增强材料的性能特征。其在改善机械性能的同时促进可持续性，使其成为各行业中一种无价的技术。理解ausforming对任何涉及材料科学或工程的人来说都是至关重要的，因为它代表了在追求更强、更轻和更耐用材料方面的关键创新。随着我们向前发展，ausforming的持续探索和应用无疑将推动行业向更高的效率和效果迈进。