ball milling

简明释义

球磨研磨

英英释义

例句

1.By adjusting the speed of ball milling 球磨, we can control the particle size distribution.

通过调整球磨的速度，我们可以控制颗粒大小分布。

2.The process of ball milling 球磨 is essential in the production of fine powders.

在细粉生产中，球磨过程是必不可少的。

3.The ball milling 球磨 technique is widely used in the mineral processing industry.

球磨技术在矿物加工行业被广泛应用。

4.Researchers are exploring the effects of ball milling 球磨 on the reactivity of certain materials.

研究人员正在探索球磨对某些材料反应性的影响。

5.In ceramics, ball milling 球磨 helps to achieve a uniform particle size.

球磨有助于陶瓷材料获得均匀的颗粒尺寸。

作文

Ball milling is a widely used technique in materials science and engineering, particularly in the field of powder metallurgy. The process involves the grinding of materials into a fine powder using a rotating cylindrical vessel, known as a ball mill. In this vessel, balls made of hard materials such as steel or ceramic are added to the mixture. As the ball mill rotates, the balls collide with the material, causing it to break down into smaller particles. This process is not only effective for size reduction but also plays a crucial role in mixing different components uniformly. ball milling (球磨) can be applied to various materials, including metals, ceramics, and even some organic compounds.The advantages of ball milling (球磨) are numerous. Firstly, it allows for the production of very fine powders, which can be essential for applications such as creating high-performance materials or improving the properties of existing ones. Secondly, the process can be conducted under controlled atmospheres, which minimizes contamination and oxidation of sensitive materials. Furthermore, ball milling (球磨) can be scaled up easily for industrial applications, making it a versatile choice for manufacturers.However, there are also challenges associated with ball milling (球磨). One of the main issues is the potential for overheating, which can lead to changes in the material properties or even combustion in some cases. Additionally, the energy consumption of the process can be significant, especially when processing large quantities of material. To mitigate these issues, researchers are constantly looking for ways to optimize the ball milling (球磨) parameters, such as the speed of rotation, the size of the balls, and the duration of milling.In recent years, advancements in technology have further enhanced the capabilities of ball milling (球磨). For instance, the introduction of high-energy ball mills has allowed for more efficient milling processes, resulting in finer powders in shorter time frames. Moreover, the integration of real-time monitoring systems enables operators to adjust parameters on-the-fly, ensuring optimal performance and product quality.Furthermore, ball milling (球磨) has found applications beyond traditional materials processing. In the field of nanotechnology, it is used to create nanoparticles with specific properties for use in electronics, medicine, and environmental applications. For example, researchers have successfully utilized ball milling (球磨) to produce nanoparticles that exhibit enhanced catalytic activity, which can lead to more efficient chemical reactions.In conclusion, ball milling (球磨) is an essential process in the field of materials science, offering a range of benefits from size reduction to improved material properties. While there are challenges to overcome, ongoing research and technological advancements continue to push the boundaries of what can be achieved with this technique. As industries evolve and demand for advanced materials grows, the importance of ball milling (球磨) will undoubtedly increase, solidifying its role as a cornerstone in the development of innovative materials.

球磨是材料科学和工程中广泛使用的一种技术，特别是在粉末冶金领域。该过程涉及使用一个称为球磨机的旋转圆柱形容器将材料研磨成细粉。在这个容器中，加入由钢或陶瓷等坚硬材料制成的球。当球磨机旋转时，球与材料碰撞，使其分解成更小的颗粒。这个过程不仅有效降低了颗粒的尺寸，还在均匀混合不同成分方面发挥了重要作用。ball milling（球磨）可以应用于各种材料，包括金属、陶瓷，甚至一些有机化合物。ball milling（球磨）的优点是显而易见的。首先，它允许生产非常细的粉末，这对于创建高性能材料或改善现有材料的性能至关重要。其次，该过程可以在受控气氛下进行，从而最小化对敏感材料的污染和氧化。此外，ball milling（球磨）可以轻松扩展到工业应用，使其成为制造商的多功能选择。然而，ball milling（球磨）也面临一些挑战。其中一个主要问题是过热的潜在风险，这可能导致材料性质的变化，甚至在某些情况下会引起燃烧。此外，处理大量材料时，过程的能耗可能相当可观。为了减轻这些问题，研究人员不断寻找优化ball milling（球磨）参数的方法，例如转速、球的大小和研磨时间。近年来，技术的进步进一步增强了ball milling（球磨）的能力。例如，高能球磨机的引入使得更高效的研磨过程成为可能，从而在更短的时间内获得更细的粉末。此外，实时监测系统的集成使操作员能够动态调整参数，确保最佳性能和产品质量。此外，ball milling（球磨）在传统材料处理之外找到了应用。在纳米技术领域，它用于创造具有特定性能的纳米颗粒，用于电子、医学和环境应用。例如，研究人员成功利用ball milling（球磨）生产出显示出增强催化活性的纳米颗粒，这可以导致更高效的化学反应。总之，ball milling（球磨）是材料科学领域的重要过程，提供了从尺寸减少到改善材料性能的一系列好处。尽管面临挑战，但持续的研究和技术进步继续推动这一技术的边界。随着行业的发展和对先进材料需求的增长，ball milling（球磨）的重要性无疑会增加，巩固其作为创新材料开发基石的角色。