formability

简明释义

英[fɔrˈmæbɪlɪti]美[fɔrˈmæbɪlɪti]

n. 成形性，成型性能；[材] 可成形性

英英释义

单词用法

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反义词

例句

1.Some simulated formability related to essential formability strongly, and the coefficient of total correlation reached more than 0.95.

有的模拟成形性能指标甚至与基本性能之间存在着较强的相关性。全相关性系数达0 . 95以上。

2.The formability of galvannealed steel plate depends on both the character of the substrate and the nature of the coating.

合金化热镀锌钢板的成形性既取决于基体钢板的特性，也决定于镀层本身的成分和结构。

3.In this paper, the formability of cold rolled steels after laser welding were analyzed.

在本研究中，对汽车用冷轧钢板在激光焊接后成形性能进行了细致的分析。

4.Formability of magnesium alloy (AZ31B) sheets can be investigated by thermal deep drawing experiments.

镁合金(AZ31B)板材的成形性能可以通过热拉深试验来进行观察评估。

5.This paper combines the technology of semisolid forming and micro-forming to discuss the micro-formability of semisolid alloy.

结合半固态成形技术与微成形技术，探讨半固态金属的微成形性能。

6.The numerical simulation result indicates that the variable blank-holder force can improve the formability of box deep drawing.

模拟结果表明，变压边力控制技术可以显著地改善矩形件的成形性能，增加矩形件的拉深极限。

7.Yoshida Buckling test (YBT) which has been developed by Japanese famous scholar Yoshida is a notable test for appraising the sheet stamping formability.

方板对角拉伸试验即y BT模型是日本冲压行业著名学者吉田清太提出的评价板材冲压成形性能的著名试验。

8.The squeezed-casting formability of AZ91D magnesium alloy in semi-solid state was studied.

研究了AZ91D镁合金在不同半固态温度下的挤压铸造。

9.The new alloy has improved formability that allows for more intricate designs.

这种新合金具有更好的成形性，可以实现更复杂的设计。

10.Engineers must consider the formability of materials when designing components.

工程师在设计组件时必须考虑材料的成形性。

11.High formability is essential for producing thin-walled structures.

高成形性对于生产薄壁结构至关重要。

12.The formability of this plastic makes it suitable for various packaging applications.

这种塑料的成形性使其适用于各种包装应用。

13.Researchers are studying the formability of metals at different temperatures.

研究人员正在研究不同温度下金属的成形性。

作文

The concept of formability is crucial in various fields, especially in manufacturing and material science. It refers to the ability of a material to be shaped or formed into desired geometries without losing its integrity or mechanical properties. Understanding formability allows engineers and designers to select appropriate materials for specific applications, ensuring that the final products meet performance standards and aesthetic requirements. For instance, metals like aluminum and steel exhibit excellent formability, making them popular choices in the automotive and aerospace industries. In the context of metalworking, formability is often assessed through various tests that measure how well a material can undergo processes such as bending, stretching, and drawing. These tests help determine the limits of a material's formability, which is essential for avoiding defects during production. A material with high formability can be manipulated into complex shapes without cracking or breaking, which is vital for creating intricate designs. Moreover, the formability of a material can be influenced by several factors, including temperature, strain rate, and the presence of impurities. For example, heating a metal can increase its formability by allowing it to deform more easily under stress. This principle is widely applied in processes like hot forging and rolling, where materials are shaped at elevated temperatures to improve their formability. In addition to metals, polymers also exhibit formability characteristics, although the mechanisms may differ. Thermoplastics, for instance, can be heated and molded into various shapes, demonstrating significant formability at elevated temperatures. This property makes them ideal for applications in packaging, automotive components, and consumer goods. Understanding the formability of polymers is essential for engineers who design products that require specific shapes and functions. The importance of formability extends beyond manufacturing; it plays a critical role in sustainability as well. By selecting materials with optimal formability, manufacturers can reduce waste during production processes. Efficient use of materials not only lowers costs but also minimizes environmental impact, aligning with modern practices aimed at sustainability. In conclusion, formability is a fundamental property that influences material selection and processing techniques across various industries. Its significance cannot be overstated, as it directly affects product quality, manufacturing efficiency, and environmental sustainability. As technology continues to advance, ongoing research into improving the formability of materials will undoubtedly lead to innovations that enhance our ability to create complex and efficient designs. Engineers and designers must remain aware of the formability of the materials they work with to ensure that they can achieve their goals while maintaining the integrity and functionality of their products.

‘成形性’这一概念在多个领域中至关重要，尤其是在制造和材料科学中。它指的是材料在不失去其完整性或机械性能的情况下，被塑造成所需几何形状的能力。理解‘成形性’使工程师和设计师能够选择适合特定应用的材料，确保最终产品符合性能标准和美学要求。例如，铝和钢等金属表现出优良的‘成形性’，使它们成为汽车和航空航天工业中的热门选择。 在金属加工的背景下，‘成形性’通常通过各种测试来评估，这些测试测量材料在弯曲、拉伸和拉深等过程中表现出的能力。这些测试帮助确定材料的‘成形性’极限，这对于避免生产过程中的缺陷至关重要。具有高‘成形性’的材料可以在不出现裂纹或断裂的情况下被加工成复杂形状，这对于创建复杂设计至关重要。 此外，材料的‘成形性’可能受到多种因素的影响，包括温度、应变速率和杂质的存在。例如，加热金属可以通过允许其在应力下更容易地变形来提高其‘成形性’。这一原理广泛应用于热锻和轧制等工艺中，在这些工艺中，材料在高温下被塑造成形，以改善其‘成形性’。 除了金属，聚合物也表现出‘成形性’特征，尽管机制可能有所不同。例如，热塑性塑料可以被加热并模塑成各种形状，在高温下表现出显著的‘成形性’。这一特性使它们在包装、汽车组件和消费品等应用中理想。理解聚合物的‘成形性’对设计需要特定形状和功能的产品的工程师至关重要。 ‘成形性’的重要性不仅限于制造，它在可持续性方面也发挥着关键作用。通过选择具有最佳‘成形性’的材料，制造商可以减少生产过程中的浪费。有效利用材料不仅降低了成本，还最小化了环境影响，与现代旨在可持续性的实践相一致。 总之，‘成形性’是影响各行业材料选择和加工技术的基本属性。其重要性无法夸大，因为它直接影响产品质量、制造效率和环境可持续性。随着技术的不断进步，对改善材料‘成形性’的持续研究无疑将带来创新，增强我们创造复杂和高效设计的能力。工程师和设计师必须始终关注他们所使用材料的‘成形性’，以确保他们能够在保持产品完整性和功能的同时实现目标。