vitrified bond

简明释义

陶瓷粘结剂

英英释义

例句

1.The vitrified bond used in this application provides excellent thermal stability for high-temperature processes.

该应用中使用的玻璃化结合为高温过程提供了优异的热稳定性。

2.Engineers prefer tools with a vitrified bond for their ability to withstand heavy cutting loads.

工程师更喜欢使用玻璃化结合的工具，因为它们能够承受重切削负荷。

3.In the manufacturing of grinding wheels, the vitrified bond plays a crucial role in maintaining the wheel's shape during use.

在磨轮的制造过程中，玻璃化结合在使用过程中保持磨轮形状方面起着至关重要的作用。

4.The vitrified bond in these abrasives allows for faster cutting speeds without overheating.

这些磨料中的玻璃化结合允许更快的切割速度而不会过热。

5.The ceramic tiles were secured with a strong vitrified bond, ensuring durability and resistance to moisture.

这些陶瓷瓷砖通过强大的玻璃化结合固定，确保了耐用性和抗潮湿性。

作文

In the world of materials science, the term vitrified bond refers to a type of bonding process that occurs when certain materials are heated to a high temperature and then cooled rapidly. This process creates a glass-like structure that enhances the properties of the material. The vitrified bond is particularly significant in the production of ceramics and abrasives, where durability and strength are essential. Understanding this concept is crucial for anyone involved in manufacturing or engineering, as it directly impacts the performance and longevity of products. The formation of a vitrified bond involves the melting of specific components within a mixture. When these components are heated, they reach a point where they become fluid and can flow together. As the temperature rises, various chemical reactions occur, leading to the formation of a glassy phase. Upon cooling, this glassy phase solidifies, creating a robust bond between the particles in the material. This transformation is what gives the vitrified bond its unique characteristics. One of the primary advantages of materials with a vitrified bond is their resistance to wear and tear. For example, in the case of grinding wheels, the vitrified bond ensures that the abrasive particles remain firmly anchored, allowing for efficient cutting and grinding. This is particularly important in industrial applications where precision and efficiency are paramount. The longevity of tools and equipment can be significantly improved through the use of vitrified bonds, reducing the need for frequent replacements and thus lowering operational costs. Moreover, the vitrified bond also contributes to the thermal stability of materials. In high-temperature applications, materials with this type of bond can maintain their integrity without deforming or losing their structural properties. This makes them ideal for use in environments where heat resistance is critical, such as in kilns or furnaces. In addition to their mechanical and thermal properties, vitrified bonds also play a role in the aesthetic qualities of materials. For instance, many pottery and tile products utilize vitrified bonds to achieve a smooth and glossy finish. This not only enhances the visual appeal but also adds to the material's impermeability, making it easier to clean and maintain. Despite the many benefits, the creation of a vitrified bond requires precise control over the manufacturing process. Factors such as temperature, time, and the composition of materials must be carefully monitored to ensure optimal bonding. Any deviation can lead to defects, compromising the overall quality of the product. Therefore, understanding the intricacies of vitrified bonds is essential for engineers and manufacturers alike. In conclusion, the concept of vitrified bond is fundamental in the field of materials science, especially for those working with ceramics and abrasives. Its ability to enhance durability, thermal stability, and aesthetic qualities makes it a valuable process in various industries. By grasping the principles behind vitrified bonds, professionals can better design and produce materials that meet the demanding requirements of modern applications.

在材料科学的世界中，术语vitrified bond指的是一种在某些材料被加热到高温后迅速冷却时发生的结合过程。这个过程创造了一种玻璃状的结构，从而增强了材料的性能。vitrified bond在陶瓷和磨料的生产中尤为重要，因为耐用性和强度是必不可少的。理解这一概念对于任何参与制造或工程的人来说都是至关重要的，因为它直接影响到产品的性能和使用寿命。vitrified bond的形成涉及到混合物中某些成分的熔化。当这些成分被加热时，它们会达到一个流动的点，可以相互融合。随着温度的升高，各种化学反应发生，导致玻璃相的形成。在冷却过程中，这个玻璃相固化，创造出材料颗粒之间的坚固结合。这种转变就是赋予vitrified bond独特特性的原因。具有vitrified bond的材料的主要优点之一是它们的耐磨损性。例如，在磨削轮的情况下，vitrified bond确保磨料颗粒牢牢固定，从而实现高效的切割和磨削。这在工业应用中尤为重要，因为精确性和效率至关重要。通过使用vitrified bonds，工具和设备的使用寿命可以显著提高，从而减少频繁更换的需要，降低运营成本。此外，vitrified bond还提高了材料的热稳定性。在高温应用中，具有这种类型结合的材料可以保持其完整性，而不会变形或失去结构特性。这使得它们非常适合用于热阻力至关重要的环境，如窑炉或熔炉。除了机械和热性能，vitrified bonds还对材料的美学质量起着作用。例如，许多陶器和瓷砖产品利用vitrified bonds来实现光滑和光泽的表面。这不仅增强了视觉吸引力，还增加了材料的防水性，使清洁和维护更加容易。尽管有许多好处，创建vitrified bond需要对制造过程进行精确控制。温度、时间和材料成分等因素必须仔细监控，以确保最佳结合。任何偏差都可能导致缺陷，妨碍产品的整体质量。因此，理解vitrified bonds的复杂性对于工程师和制造商来说都是至关重要的。总之，vitrified bond的概念在材料科学领域是基础性的，尤其是对于那些从事陶瓷和磨料工作的人。它增强耐用性、热稳定性和美学质量的能力使其成为各个行业中一种有价值的工艺。通过掌握vitrified bonds背后的原理，专业人士可以更好地设计和生产满足现代应用要求的材料。