hydroforming

简明释义

英[ˈhaɪdrəʊˌfɔːmɪŋ]美[ˈhaɪdrəˌfɔrmɪŋ]

n. [油气]加氢重整

v. 液压成形（hydroform 的 ing 形式）

英英释义

单词用法

同义词

反义词

例句

1.Manufactured with seamless links for, at present there is usually used in hydroforming technology and hot forming two.

对于采用无缝管制造三通来讲，目前通常所采用的工艺有液压胀形和热压成形两种。

2.Manufacturing processes forming under combination of tensile and compressive conditions - Part 7: Hydroforming widening; Classification, subdivision, terms and definitions.

在拉伸和加压复合条件下复合成形的制造工艺。第7部分：液压成形加宽。分类、细类、术语和定义。

3.With superior control over forces and motions, Interlaken's Hydroforming Press provides a greater overall quality of formed parts.

随着对力和运动控制优势，因特拉肯的内高压成形媒体提供了更大的组成部分的整体素质。

4.By using non-linear finite element theory, a non-linear finite element model for hydroforming for rear axle housing is established.

利用非线性有限元理论方法，建立了后桥壳液压胀形有限元模型。

5.The hydroforming process is very repeatable.

内高压成形过程是很重复。

6.The support flanges are formed by pinching the blank during the hydroforming process to provide a double thickness flange.

在液压成形工艺期间，通过挤压坯料形成支撑凸缘，以提供双厚度凸缘。

7.The feasibility of hydroforming tri-branch tube is proved by FEM. The corresponding thickness and strain distribution of different axial feed velocity on the simulation is analyzed.

利用有限元法证实了内高压成形三通管的可行性，给出了不同轴向进给速度下零件的壁厚及应变分布，并就轴向进给速度对成形的影响进行了分析。

8.The double sides pressurized hydroforming process of metal sheet is numerically simulated by applying the commercial FEM software ANSYS/LS-DYNA.

应用商用有限元软件ANSYS/LS-DYNA，对板料的双向加压液压胀形过程进行了数值模拟。

9.The process of hydroforming 液压成型 allows for better material utilization, reducing waste during production.

hydroforming 液压成型过程允许更好的材料利用，减少生产过程中的浪费。

10.The automotive industry increasingly relies on hydroforming 液压成型 to create lightweight and strong components.

汽车行业越来越依赖于hydroforming 液压成型来制造轻便且坚固的部件。

11.Using hydroforming 液压成型, manufacturers can produce complex shapes that traditional methods cannot achieve.

通过使用hydroforming 液压成型，制造商可以生产传统方法无法实现的复杂形状。

12.Engineers are exploring new uses for hydroforming 液压成型 in the aerospace sector to improve part performance.

工程师们正在探索在航空航天领域中使用hydroforming 液压成型的新方法，以提高零件性能。

13.The flexibility of hydroforming 液压成型 makes it ideal for producing custom parts in small batches.

hydroforming 液压成型的灵活性使其非常适合小批量定制零件的生产。

作文

Hydroforming is a manufacturing process that uses high-pressure fluid to shape malleable materials, typically metals. This innovative technique has gained popularity in various industries, including automotive, aerospace, and consumer goods, due to its ability to create complex shapes with minimal waste. The process involves placing a metal sheet or tube into a mold and then applying hydraulic pressure to form the material into the desired shape. One of the significant advantages of hydroforming (水压成形) is that it allows for the production of lightweight yet strong components, which is essential in modern engineering, where efficiency and performance are paramount.The history of hydroforming (水压成形) dates back to the early 20th century, but it has evolved significantly over the years. Initially used for creating simple shapes, advancements in technology have enabled manufacturers to produce intricate designs that were previously impossible with traditional methods. For instance, in the automotive industry, hydroforming (水压成形) is often employed to create parts such as chassis components and exhaust systems. These parts benefit from the strength and reduced weight that hydroforming (水压成形) provides, leading to improved fuel efficiency and performance.Another key advantage of hydroforming (水压成形) is its ability to reduce material waste. Traditional metal forming processes often involve cutting and machining, which can generate significant scrap material. In contrast, hydroforming (水压成形) utilizes the entire sheet or tube, minimizing waste and making it a more environmentally friendly option. This aligns with the growing trend towards sustainable manufacturing practices, where companies are increasingly focused on reducing their environmental impact.Moreover, hydroforming (水压成形) allows for greater design flexibility. Engineers can create complex and lightweight structures that would be difficult or impossible to achieve using conventional methods. This capability is particularly valuable in industries where design innovation is critical, such as aerospace, where every gram of weight saved can translate into significant fuel savings over time.Despite its many advantages, hydroforming (水压成形) does have some limitations. For instance, the initial setup costs can be high, as specialized equipment and molds are required. Additionally, not all materials are suitable for hydroforming (水压成形), as the process works best with ductile metals that can withstand the high pressures involved. However, ongoing research and development are continually expanding the range of materials that can be used, making hydroforming (水压成形) an increasingly versatile option for manufacturers.In conclusion, hydroforming (水压成形) represents a significant advancement in manufacturing technology, offering numerous benefits such as reduced waste, enhanced design flexibility, and improved material properties. As industries continue to seek innovative solutions to meet the demands of modern engineering, hydroforming (水压成形) is likely to play an increasingly important role in shaping the future of manufacturing. Its ability to produce lightweight, strong components will be crucial as we move towards more efficient and sustainable designs in various applications. Therefore, understanding and mastering the principles of hydroforming (水压成形) can provide valuable insights into the future of manufacturing and engineering.

水压成形是一种制造工艺，利用高压液体来塑造可塑性材料，通常是金属。这种创新技术在汽车、航空航天和消费品等多个行业中越来越受欢迎，因为它能够以最小的浪费创造复杂的形状。该过程涉及将金属板或管放入模具中，然后施加液压压力以将材料形成所需形状。水压成形的一个显著优势是，它允许生产轻量且坚固的部件，这在现代工程中至关重要，因为效率和性能是重中之重。水压成形的历史可以追溯到20世纪初，但随着时间的推移，它已经发生了显著变化。最初用于创建简单的形状，技术的进步使制造商能够生产以前用传统方法无法实现的复杂设计。例如，在汽车工业中，水压成形通常用于制造底盘部件和排气系统等部件。这些部件受益于水压成形提供的强度和减轻重量，从而提高了燃油效率和性能。另一个关键优势是水压成形能够减少材料浪费。传统的金属成形工艺通常涉及切割和机械加工，这可能会产生大量废料。相比之下，水压成形利用整个板材或管材，最小化了废料，使其成为更环保的选择。这与日益关注减少环境影响的可持续制造实践的趋势相一致。此外，水压成形还允许更大的设计灵活性。工程师可以创建复杂且轻量的结构，这在传统方法中是困难或不可能实现的。这一能力在设计创新至关重要的行业中尤为重要，例如航空航天，在那里每节省一克重量都可以转化为长期显著的燃油节省。尽管有许多优点，水压成形也有一些局限性。例如，初始设置成本可能很高，因为需要专门的设备和模具。此外，并非所有材料都适合水压成形，因为该过程最佳适用于能够承受高压的延展性金属。然而，持续的研究和开发不断扩大可使用的材料范围，使得水压成形成为制造商越来越多样化的选择。总之，水压成形代表了制造技术的重大进步，提供了许多好处，如减少浪费、增强设计灵活性和改善材料性能。随着各行业继续寻求创新解决方案以满足现代工程的需求，水压成形在塑造制造未来方面可能会发挥越来越重要的作用。其生产轻量、坚固部件的能力对于我们朝着更高效和可持续的设计迈进是至关重要的。因此，理解和掌握水压成形的原理可以为我们提供有关制造和工程未来的宝贵见解。