ferritic

简明释义

英[feˈrɪtɪk]美[fəˈrɪtɪk]

adj. 铁素体的，铁氧体的

英英释义

单词用法

同义词

反义词

例句

1.Therefore, in thin section castings, for eliminating eutectic carbides and obtaining ferritic matrix, melts treated by re need high carbon content and hypereutectic composition.

在薄壁铸件中获得无游离渗碳体和铁素体基体的稀土球铁的关键是高碳过共晶原铁水。

2.For ferritic chromium steel, its thickness of layer is greater than that of austenite chromium steel.

铁素体型钢的渗层厚度明显大于奥氏体型钢。

3.Recently , Many studies have been focused an ferritic rolling technology because it can reduce production cost and improve productivity of ULC steels substantially .

铁素体区轧制技术，因为在节能、降耗、提高产品性能和提高生产效率等方面具有巨大优越性而引起普遍重视。

4.With austenitic welding material, solid wire, flux-cored wire and electrode, welded joint mechanical property of TCS ferritic stainless steel all can meet usability.

T CS铁素体不锈钢采用奥氏体型焊材，实芯焊丝、药芯焊丝和电焊条方法，焊接接头力学性能可以满足使用要求。

5.In this article, the technology and the conditions of producing as-cast ferritic nodular cast iron are introduced.

本文介绍了生产铸态铁素体球铁的条件及其工艺措施。

6.The antibacterial properties and relevant mechanism of copper-containing ferritic and austenitic antibacterial stainless steels have been studied.

研究了铁素体和奥氏体含铜抗菌不锈钢的抗菌特性及相关机制。

7.In this paper the range of manganese and sulphur constituents of ferritic malleable cast iron and the correlation between them are studied.

本文研究了铁素体可锻铸铁的锰硫量范围及其相互关系。

8.The rare earth element was added into low - chromium ferritic stainless steel in order to improve the mechanical properties.

本研究尝试在低铬铁素体不锈钢中加入稀土，以改善合金的力学性能。

9.The steel used in this construction is primarily ferritic (铁素体的), which gives it excellent ductility.

这项工程中使用的钢材主要是ferritic（铁素体的），这使其具有优良的延展性。

10.In the production of automotive parts, ferritic (铁素体的) stainless steels are often preferred for their corrosion resistance.

在汽车零部件的生产中，通常更喜欢使用ferritic（铁素体的）不锈钢，因为它们具有耐腐蚀性。

11.The ferritic (铁素体的) microstructure contributes to the material's overall strength and toughness.

这种ferritic（铁素体的）微观结构有助于材料的整体强度和韧性。

12.Researchers are studying ferritic (铁素体的) alloys to improve the performance of nuclear reactors.

研究人员正在研究ferritic（铁素体的）合金，以提高核反应堆的性能。

13.The ferritic (铁素体的) phase in the alloy enhances its magnetic properties, making it suitable for electrical applications.

合金中的ferritic（铁素体的）相增强了其磁性，使其适用于电气应用。

作文

The term ferritic refers to a specific type of microstructure found in iron and its alloys. This structure is characterized by the presence of a body-centered cubic (BCC) lattice, which is one of the two primary crystalline structures of iron, the other being face-centered cubic (FCC). Understanding the properties of ferritic materials is essential for various applications in engineering and manufacturing. For instance, ferritic stainless steels are known for their excellent corrosion resistance and good mechanical properties, making them suitable for environments where oxidation is a concern. In the context of metallurgy, the ferritic phase is typically stable at lower temperatures and can be influenced by the alloying elements present in the steel. For example, chromium is often added to enhance the corrosion resistance of ferritic stainless steels, while nickel is generally associated with austenitic steels. The balance between these elements determines the final properties of the material, such as strength, ductility, and toughness. Moreover, the ferritic phase plays a crucial role in the overall performance of steel products. In construction, automotive, and aerospace industries, the choice of ferritic steel can significantly impact the durability and safety of structures and vehicles. Engineers and material scientists must carefully consider the microstructure when designing components that will withstand harsh conditions. One of the advantages of ferritic steels is their ability to be welded without the risk of cracking, which is a common issue with some types of stainless steel. This property makes ferritic steels an attractive option for applications requiring strong weld joints. However, it is essential to note that ferritic steels may not perform as well under high-temperature conditions compared to their austenitic counterparts, which can lead to reduced toughness. In recent years, research has focused on enhancing the properties of ferritic materials through various processing techniques. Innovations such as thermomechanical processing and advanced heat treatments have been developed to optimize the microstructure of ferritic steels. These advancements aim to improve characteristics like strength and ductility while maintaining the desirable corrosion resistance. In conclusion, the study of ferritic materials is vital for developing high-performance alloys that meet the demands of modern engineering applications. With ongoing research and technological advancements, the future of ferritic steels looks promising, providing solutions for a wide range of industrial challenges. Understanding the unique properties and behaviors of ferritic phases will continue to be an essential aspect of material science and engineering, ensuring that we can create safer, more efficient, and sustainable products for the future.

术语ferritic指的是铁及其合金中发现的一种特定微观结构。这种结构的特征是存在体心立方（BCC）晶格，这是铁的两种主要晶体结构之一，另一种是面心立方（FCC）。理解ferritic材料的特性对于工程和制造中的各种应用至关重要。例如，ferritic不锈钢因其优良的耐腐蚀性和良好的机械性能而闻名，适合用于氧化问题的环境。 在冶金学的背景下，ferritic相通常在较低温度下稳定，并且会受到钢中合金元素的影响。例如，通常添加铬以增强ferritic不锈钢的耐腐蚀性，而镍通常与奥氏体钢相关联。这些元素之间的平衡决定了材料的最终性质，如强度、延展性和韧性。 此外，ferritic相在钢产品的整体性能中起着至关重要的作用。在建筑、汽车和航空航天工业中，ferritic钢的选择可以显著影响结构和车辆的耐用性和安全性。工程师和材料科学家必须在设计能够承受恶劣条件的组件时仔细考虑微观结构。 ferritic钢的一大优势是它们能够焊接而不会出现开裂的风险，这是某些类型的不锈钢常见的问题。这一特性使得ferritic钢成为要求强焊接接头的应用的一个有吸引力的选择。然而，需要注意的是，与其奥氏体对应物相比，ferritic钢在高温条件下的表现可能不如后者，这可能导致韧性降低。 近年来，研究集中在通过各种加工技术增强ferritic材料的特性。诸如热机械加工和先进热处理等创新已被开发出来，以优化ferritic钢的微观结构。这些进展旨在提高强度和延展性，同时保持所需的耐腐蚀性。 总之，研究ferritic材料对开发满足现代工程应用需求的高性能合金至关重要。随着持续的研究和技术进步，ferritic钢的未来看起来充满希望，为解决广泛的工业挑战提供了解决方案。理解ferritic相的独特性质和行为将继续成为材料科学和工程的一个重要方面，确保我们能够为未来创造更安全、更高效和可持续的产品。