sialon
简明释义
n. [高分子] 硅铝氧氮聚合材料
英英释义
单词用法
同义词
反义词
| 金属 | Metals are often used in construction due to their strength. | 金属因其强度常用于建筑。 | |
| 陶瓷 | Ceramics are known for their heat resistance and aesthetic qualities. | 陶瓷以其耐热性和美观特性而闻名。 |
例句
1.Sialon bonded silicon carbide bricks, characterized by good resistance to oxidation and alkali corrosion, are mainly used on the underside, belly and bosh of blast furnace.
赛隆结合碳化硅砖具有优质的抗氧化和抗碱侵蚀性,主要用于炼铁高炉的路身下部、炉腰和炉腹等部位。
2.Sialon bonded silicon carbide bricks, characterized by good resistance to oxidation and alkali corrosion, are mainly used on the underside, belly and bosh of blast furnace.
赛隆结合碳化硅砖具有优质的抗氧化和抗碱侵蚀性,主要用于炼铁高炉的路身下部、炉腰和炉腹等部位。
3.The results show that after being corroded, the structure of TiN/O′-Sialon material is composed of slag zone, penetrated zone and unchanged zone.
结果表明:材料被侵蚀后结构发生变化, 可大致分为渣带、渗透带和未变带;
4.The hardness of sialon makes it an ideal material for wear-resistant coatings.
氮化硅铝的硬度使其成为耐磨涂层的理想材料。
5.Researchers are exploring the properties of sialon for use in high-temperature applications.
研究人员正在探索氮化硅铝的特性,以用于高温应用。
6.The thermal stability of sialon allows it to perform well in extreme environments.
氮化硅铝的热稳定性使其在极端环境下表现良好。
7.The new cutting tool made from sialon has significantly improved our machining efficiency.
由氮化硅铝制成的新切割工具显著提高了我们的加工效率。
8.We decided to replace traditional ceramics with sialon in our latest product line.
我们决定在最新产品系列中用氮化硅铝替代传统陶瓷。
作文
In the world of materials science, one of the most fascinating compounds is sialon. This material, which is a silicon nitride-based ceramic, has gained significant attention for its unique properties and potential applications. Sialon is a composite that combines silicon, aluminum, and oxygen with nitrogen, resulting in a material that exhibits exceptional strength, thermal stability, and resistance to wear and corrosion. These properties make sialon an ideal candidate for various industrial applications, including cutting tools, automotive components, and even aerospace parts.The development of sialon can be traced back to the need for advanced materials that could withstand extreme conditions. Traditional ceramics often fail under high temperatures or mechanical stress, but sialon offers a solution to these challenges. Its ability to maintain structural integrity at elevated temperatures makes it particularly useful in environments where conventional materials would degrade. For instance, in the manufacturing of cutting tools, sialon can enhance performance and longevity, leading to more efficient production processes.Moreover, sialon is not just limited to high-temperature applications. Its excellent chemical resistance also makes it suitable for use in harsh chemical environments. Industries such as petrochemicals and pharmaceuticals can benefit from sialon components that resist corrosion and wear, thus reducing maintenance costs and downtime.Another remarkable feature of sialon is its lightweight nature compared to metals and other ceramics. This characteristic is particularly advantageous in the aerospace sector, where reducing weight is critical for improving fuel efficiency and overall performance. Engineers are increasingly looking towards sialon for parts that require both strength and low weight, allowing for innovative designs that were previously unattainable.In addition to its physical properties, the versatility of sialon in terms of processing techniques is noteworthy. It can be manufactured using various methods, including sintering and hot pressing, which allows for tailored properties depending on the intended application. This adaptability further solidifies sialon's position as a material of choice in modern engineering.Despite its many advantages, the production of sialon does come with challenges. The synthesis process can be complex and requires precise control over the composition and processing conditions to achieve the desired properties. Researchers continue to explore new methods to optimize the production of sialon, aiming to reduce costs and increase scalability for commercial use.In conclusion, sialon represents a significant advancement in the field of materials science. Its unique combination of properties makes it a valuable asset across various industries, from manufacturing to aerospace. As research continues to unlock its full potential, we can expect to see sialon playing an increasingly important role in the development of next-generation materials. Understanding sialon and its applications not only broadens our knowledge of materials but also paves the way for innovations that can drive technological progress in numerous fields.
在材料科学的世界中,最引人入胜的化合物之一就是sialon。这种基于氮化硅的陶瓷材料因其独特的性质和潜在应用而受到广泛关注。sialon是一种复合材料,它将硅、铝、氧与氮结合在一起,形成一种具有卓越强度、热稳定性以及耐磨损和耐腐蚀性的材料。这些特性使得sialon成为各种工业应用的理想候选者,包括切削工具、汽车部件甚至航空航天零件。sialon的发展可以追溯到对能够承受极端条件的先进材料的需求。传统陶瓷在高温或机械应力下常常失效,但sialon提供了应对这些挑战的解决方案。它在高温下保持结构完整性的能力使其在传统材料会降解的环境中特别有用。例如,在切削工具的制造中,sialon可以提升性能和使用寿命,从而导致更高效的生产过程。此外,sialon不仅限于高温应用。它出色的化学抗性也使其适合在恶劣的化学环境中使用。石油化工和制药等行业可以从耐腐蚀和耐磨损的sialon组件中受益,从而降低维护成本和停机时间。sialon的另一个显著特点是其相较于金属和其他陶瓷的轻量特性。这一特性在航空航天领域尤为重要,因为减轻重量对于提高燃油效率和整体性能至关重要。工程师们越来越多地关注sialon,用于需要强度和低重量的部件,从而实现以前无法达到的创新设计。除了其物理特性外,sialon在加工技术上的多样性也值得注意。它可以采用多种方法进行制造,包括烧结和热压,这使得根据预期应用定制特性成为可能。这种适应性进一步巩固了sialon作为现代工程中首选材料的地位。尽管有许多优点,sialon的生产确实面临挑战。合成过程可能复杂,需要精确控制成分和加工条件,以实现所需的特性。研究人员继续探索新方法,以优化sialon的生产,旨在降低成本并提高商业使用的可扩展性。总之,sialon代表了材料科学领域的重要进展。其独特的特性组合使其在多个行业中成为宝贵资产,从制造业到航空航天。随着研究继续揭示其全部潜力,我们可以期待看到sialon在下一代材料开发中发挥越来越重要的作用。理解sialon及其应用不仅拓宽了我们对材料的知识,也为推动多个领域的技术进步铺平了道路。
