forming without stock removal

简明释义

非切削成形

英英释义

例句

1.In metalworking, forming without stock removal can lead to stronger and more durable parts.

在金属加工中，无切削成形可以导致更强大和更耐用的零件。

2.Using forming without stock removal techniques, the company was able to create complex shapes directly from raw materials.

通过使用无切削成形技术，公司能够直接从原材料中创造复杂的形状。

3.The new manufacturing process focuses on forming without stock removal, which increases efficiency and reduces waste.

新的制造工艺专注于无切削成形，这提高了效率并减少了废料。

4.One advantage of forming without stock removal is that it minimizes the need for secondary operations.

使用无切削成形的一个优点是它最小化了对二次操作的需求。

5.The automotive industry is increasingly adopting forming without stock removal methods to produce lighter components.

汽车工业越来越多地采用无切削成形方法来生产更轻的部件。

作文

In the world of manufacturing, various techniques are employed to create products that meet specific requirements. One such technique is known as forming without stock removal, which refers to the process of shaping materials without cutting away any excess material. This method is particularly significant in industries where material conservation and precision are paramount. By utilizing forming without stock removal, manufacturers can reduce waste and enhance the structural integrity of their products. The concept of forming without stock removal can be applied to several processes, including forging, extrusion, and molding. Each of these methods allows for the manipulation of materials into desired shapes while retaining the original mass. For instance, in forging, a metal piece is heated and then shaped using compressive forces, which alters its form without removing any material. Similarly, extrusion involves forcing material through a die to create long shapes, such as pipes or sheets, again without cutting away any part of the original material.One of the primary advantages of forming without stock removal is the efficiency it offers in terms of resource utilization. Traditional machining methods often involve cutting away large amounts of material, leading to significant waste. In contrast, forming without stock removal minimizes this waste by preserving the majority of the raw material. This not only saves costs but also aligns with sustainable manufacturing practices, which aim to reduce environmental impact.Moreover, forming without stock removal can lead to enhanced mechanical properties in the final product. Since the material undergoes deformation rather than removal, the grain structure can be manipulated to improve strength and durability. This is especially important in industries such as aerospace and automotive, where component reliability is critical. By choosing forming without stock removal, manufacturers can produce parts that withstand higher stress and perform better over time.Another significant aspect of forming without stock removal is its ability to produce complex shapes that may be difficult or impossible to achieve through traditional machining. Techniques like injection molding allow for the creation of intricate designs with high precision. This capability opens up new possibilities for product innovation, enabling designers to think outside the box and create components that enhance functionality and aesthetics.However, it is essential to note that forming without stock removal also presents certain challenges. The initial setup for processes like forging or extrusion can be more costly and time-consuming compared to traditional machining. Additionally, the need for specialized equipment and skilled labor can pose barriers to entry for some manufacturers. Despite these challenges, the benefits of forming without stock removal often outweigh the drawbacks, making it an attractive option for many production scenarios.In conclusion, forming without stock removal represents a vital approach in modern manufacturing that emphasizes efficiency, sustainability, and innovation. By shaping materials without the need to remove stock, manufacturers can conserve resources, improve product performance, and create complex designs. As industries continue to evolve, the adoption of forming without stock removal techniques will likely play a crucial role in shaping the future of production, driving advancements that benefit both businesses and the environment.

在制造业中，各种技术被用来创建符合特定要求的产品。其中一种技术被称为无切削成形，它指的是在不切除任何多余材料的情况下对材料进行成型的过程。这种方法在材料保护和精度至关重要的行业中尤为重要。通过利用无切削成形，制造商可以减少浪费，并增强其产品的结构完整性。无切削成形的概念可以应用于几种工艺，包括锻造、挤压和模具成型。这些方法都允许在保留原始质量的同时对材料进行操作。例如，在锻造过程中，一块金属件被加热，然后使用压缩力塑形，这样就改变了其形状而没有去除任何材料。类似地，挤压涉及将材料强行通过模具以创建长形状，如管道或板材，同样没有切割掉原材料的任何部分。无切削成形的主要优点之一是它在资源利用方面提供的效率。传统的机械加工方法通常涉及切除大量材料，从而导致显著的浪费。相比之下，无切削成形通过保留大部分原材料来最小化这种浪费。这不仅节省了成本，还符合可持续制造实践，旨在减少环境影响。此外，无切削成形可以提高最终产品的机械性能。由于材料经历的是变形而不是去除，因此可以操控晶粒结构以提高强度和耐用性。这在航空航天和汽车等行业尤其重要，因为组件的可靠性至关重要。通过选择无切削成形，制造商可以生产出能够承受更高应力并在时间上表现更好的零件。无切削成形的另一个重要方面是它能够生产复杂的形状，而这些形状可能通过传统机械加工难以或不可能实现。诸如注塑成型等技术允许以高精度创建复杂设计。这种能力为产品创新开辟了新可能，使设计师能够跳出框架，创造出增强功能和美学的组件。然而，需要注意的是，无切削成形也存在某些挑战。锻造或挤压等工艺的初始设置可能比传统机械加工更昂贵且耗时。此外，对专业设备和熟练劳动力的需求可能对一些制造商构成进入障碍。尽管存在这些挑战，无切削成形的好处通常超过缺点，使其成为许多生产场景中具有吸引力的选择。总之，无切削成形代表了一种现代制造中至关重要的方法，强调效率、可持续性和创新。通过在不需要去除材料的情况下对材料进行成型，制造商可以节约资源、提高产品性能并创建复杂设计。随着各行业的不断发展，采用无切削成形技术可能在塑造未来生产中发挥关键作用，推动有利于企业和环境的进步。