ceramic coated particle

简明释义

敷有陶瓷粒子

英英释义

例句

1.The addition of ceramic coated particle to paints can enhance their resistance to wear and tear.

在涂料中添加陶瓷涂层颗粒可以增强其耐磨性。

2.The aerospace industry is increasingly adopting ceramic coated particle for thermal barrier coatings.

航空航天行业越来越多地采用陶瓷涂层颗粒作为热障涂层。

3.The use of ceramic coated particle in automotive applications enhances the durability of engine components.

在汽车应用中使用陶瓷涂层颗粒可以提高发动机部件的耐用性。

4.Research shows that ceramic coated particle can significantly reduce friction in machinery.

研究表明，陶瓷涂层颗粒可以显著减少机械中的摩擦。

5.In the field of electronics, ceramic coated particle helps improve the thermal conductivity of components.

在电子领域，陶瓷涂层颗粒有助于提高组件的热导率。

作文

The advancement of materials science has led to the development of various innovative materials that enhance the performance of products across multiple industries. One such remarkable innovation is the use of ceramic coated particles, which have gained significant attention in recent years for their unique properties and applications. 陶瓷涂层颗粒 refers to small particles that are coated with a layer of ceramic material, providing enhanced durability, thermal resistance, and chemical stability. The process of creating ceramic coated particles involves several steps, including the selection of suitable base particles, the application of a ceramic coating, and the curing process to ensure proper adhesion. The choice of base particles can vary, ranging from metals to polymers, depending on the intended application. The ceramic coating typically consists of materials such as alumina, zirconia, or silica, which are known for their hardness and resistance to wear and corrosion. One of the most significant advantages of using ceramic coated particles is their ability to withstand extreme temperatures. In industries such as aerospace and automotive, components are often exposed to high heat and abrasive environments. By incorporating ceramic coated particles into these components, manufacturers can significantly extend their lifespan and improve performance. For instance, turbine blades in jet engines can benefit from the thermal barrier properties of these particles, reducing the risk of failure due to overheating. Moreover, the use of ceramic coated particles can enhance the surface properties of materials. When applied to tools and machinery, these particles can provide a hard, smooth surface that reduces friction and wear. This not only improves the efficiency of the equipment but also decreases maintenance costs. In the field of electronics, ceramic coated particles are used to create insulative coatings that protect sensitive components from environmental factors such as moisture and dust. In addition to their mechanical and thermal benefits, ceramic coated particles also offer excellent chemical resistance. This property is particularly important in industries such as chemical processing and pharmaceuticals, where equipment is often exposed to harsh chemicals. By utilizing ceramic coated particles, manufacturers can ensure that their products remain functional and safe over time, even in challenging conditions. Furthermore, the versatility of ceramic coated particles allows them to be tailored for specific applications. Researchers are continually exploring new formulations and methods to enhance the performance of these particles, leading to exciting developments in the field. For example, the incorporation of nanoparticles into the ceramic coating can further improve its properties, resulting in even greater durability and resistance. In conclusion, the innovation of ceramic coated particles represents a significant advancement in materials science, offering numerous benefits across various industries. Their ability to enhance thermal resistance, improve surface properties, and provide chemical stability makes them an invaluable asset in modern manufacturing. As research continues to evolve, we can expect to see even more applications and improvements in the use of ceramic coated particles, paving the way for more efficient and durable products in the future. Overall, understanding the significance of ceramic coated particles is crucial for professionals in engineering and technology fields, as they play a vital role in the development of next-generation materials.

材料科学的进步导致了各种创新材料的发展，这些材料提高了多个行业产品的性能。其中一个显著的创新就是使用陶瓷涂层颗粒，近年来因其独特的特性和应用而受到广泛关注。陶瓷涂层颗粒指的是被一层陶瓷材料涂层的小颗粒，提供了增强的耐用性、热阻和化学稳定性。制造陶瓷涂层颗粒的过程包括几个步骤，包括选择合适的基体颗粒、施加陶瓷涂层，以及固化过程以确保良好的附着力。基体颗粒的选择可以有所不同，从金属到聚合物，具体取决于预期的应用。陶瓷涂层通常由铝土矿、锆石或二氧化硅等材料组成，这些材料以其硬度和耐磨损、耐腐蚀性而闻名。使用陶瓷涂层颗粒的一个重要优势是它们能够承受极端温度。在航空航天和汽车等行业，组件经常暴露在高温和磨损环境中。通过将陶瓷涂层颗粒融入这些组件，制造商可以显著延长其使用寿命并提高性能。例如，喷气发动机中的涡轮叶片可以受益于这些颗粒的热障碍特性，从而降低因过热而导致的故障风险。此外，使用陶瓷涂层颗粒还可以改善材料的表面特性。当应用于工具和机械时，这些颗粒可以提供一个坚硬、光滑的表面，减少摩擦和磨损。这不仅提高了设备的效率，还降低了维护成本。在电子领域，陶瓷涂层颗粒用于创建绝缘涂层，以保护敏感组件免受湿气和灰尘等环境因素的影响。除了机械和热性能外，陶瓷涂层颗粒还具有出色的化学抗性。这一特性在化学加工和制药等行业尤为重要，因为设备经常暴露在苛刻的化学品中。通过利用陶瓷涂层颗粒，制造商可以确保他们的产品在挑战性条件下仍然保持功能和安全。此外，陶瓷涂层颗粒的多功能性使其能够针对特定应用进行定制。研究人员不断探索新的配方和方法，以增强这些颗粒的性能，导致该领域激动人心的发展。例如，将纳米颗粒纳入陶瓷涂层可以进一步改善其性能，从而获得更大的耐用性和抗性。总之，陶瓷涂层颗粒的创新代表了材料科学的重要进步，为各个行业提供了众多好处。它们增强热阻、改善表面特性和提供化学稳定性的能力使它们成为现代制造中不可或缺的资产。随着研究的持续发展，我们可以期待看到更多的应用和对陶瓷涂层颗粒的改进，为未来更高效、更耐用的产品铺平道路。总体而言，理解陶瓷涂层颗粒的重要性对于工程和技术领域的专业人士至关重要，因为它们在下一代材料的发展中发挥着关键作用。