phosphorizing

简明释义

英[ˈfɒsfəraɪzɪŋ]美[ˈfɑsfəraɪzɪŋ]

vt.加磷，与磷结合；使发出磷光（phosphorize 的现在分词）

英英释义

单词用法

同义词

反义词

例句

1.The present situation and future trend about degreasing, surface conditioning, phosphorizing, passivating in car pretreatment are outlined in this paper.

本文将就轿车预处理工艺中应用的脱脂、表调、磷化、钝化等材料的最新情况和未来发展趋势进行概述。

2.The present situation and future trend about degreasing, surface conditioning, phosphorizing, passivating in car pretreatment are outlined in this paper.

本文将就轿车预处理工艺中应用的脱脂、表调、磷化、钝化等材料的最新情况和未来发展趋势进行概述。

3.The process of phosphorizing the metal ensures better corrosion resistance.

对金属进行磷化处理可以确保更好的耐腐蚀性。

4.In electronics, phosphorizing is essential for improving the efficiency of certain components.

在电子产品中，磷化对提高某些组件的效率至关重要。

5.The factory specializes in phosphorizing steel to enhance its durability.

这家工厂专门对钢材进行磷化以增强其耐用性。

6.After phosphorizing, the surface of the material becomes more receptive to paint.

经过磷化处理后，材料表面对涂料的附着力增强。

7.They are phosphorizing the parts to prevent rust during storage.

他们正在对零件进行磷化以防止存储期间生锈。

作文

Phosphorizing is a process that involves the introduction of phosphorus into a material, typically metals or alloys, to enhance their properties. This technique is particularly important in the field of metallurgy and materials science. The process of phosphorizing (磷化) can significantly improve the hardness, wear resistance, and corrosion resistance of the treated materials. In many industrial applications, especially those involving high-stress environments, the benefits of phosphorizing (磷化) cannot be overstated. One of the most common applications of phosphorizing (磷化) is in the treatment of steel. When steel undergoes phosphorizing (磷化), it forms a layer of iron phosphate on its surface. This layer acts as a barrier against oxidation and other forms of corrosion, which can lead to significant degradation over time. Additionally, the phosphorizing (磷化) process can improve the steel's ability to withstand wear from friction, making it ideal for components in machinery that experience high levels of stress and movement. The phosphorizing (磷化) process can be carried out through various methods, including chemical and thermal treatments. Chemical phosphorizing (磷化) typically involves immersing the metal in a solution containing phosphoric acid, which allows phosphorus to diffuse into the surface of the material. On the other hand, thermal phosphorizing (磷化) involves heating the metal in a phosphorus-rich atmosphere, enabling the phosphorus to bond with the metal at elevated temperatures. Both methods have their advantages and are chosen based on the specific requirements of the application. In addition to improving mechanical properties, phosphorizing (磷化) also plays a role in enhancing the aesthetic qualities of metals. For instance, the process can produce a matte finish that is often desirable in consumer products. This is particularly relevant in the automotive and appliance industries, where the appearance of a product can significantly influence consumer choice. Therefore, the dual benefits of improved performance and enhanced appearance make phosphorizing (磷化) a valuable technique in modern manufacturing. Moreover, the environmental impact of phosphorizing (磷化) processes is becoming an increasingly important consideration. Traditional methods may involve the use of hazardous chemicals, leading to concerns about pollution and worker safety. Consequently, researchers are exploring more sustainable approaches to phosphorizing (磷化), such as using eco-friendly materials and processes that minimize harmful emissions. This shift not only helps protect the environment but also aligns with the growing trend towards sustainability in industry. In conclusion, phosphorizing (磷化) is a crucial process in materials science that enhances the properties of metals and alloys. Its applications range from improving durability and corrosion resistance to enhancing aesthetic qualities. As industries continue to evolve, the importance of phosphorizing (磷化) will likely grow, particularly as we seek more sustainable and efficient manufacturing practices. Understanding this process and its implications is essential for anyone involved in materials engineering, manufacturing, or related fields.