diametral vibration

简明释义

径向振动

英英释义

例句

1.Regular maintenance checks can help identify diametral vibration issues before they escalate.

定期的维护检查可以帮助在问题升级之前识别出直径振动的问题。

2.Excessive diametral vibration can lead to premature wear and tear on equipment.

过度的直径振动可能导致设备的过早磨损。

3.The technician adjusted the alignment to reduce diametral vibration in the rotating shaft.

技术员调整了对准，以减少旋转轴的直径振动。

4.The engineers monitored the machine for signs of diametral vibration to ensure it was operating smoothly.

工程师监测机器的直径振动以确保其平稳运行。

5.The team used sensors to detect diametral vibration in the turbine during operation.

团队在涡轮机运行期间使用传感器检测直径振动。

作文

In the realm of engineering and physics, understanding various types of vibrations is crucial for the design and maintenance of mechanical systems. One such concept that often arises in discussions of mechanical dynamics is diametral vibration. This term refers to the oscillation or vibration that occurs along the diameter of a circular object or system, which can significantly impact its performance and longevity. 直径振动是指沿着圆形物体或系统的直径发生的振荡或振动，这可能会显著影响其性能和寿命。To delve deeper into the implications of diametral vibration, we must first understand the basic principles of vibration in mechanical systems. Vibrations are typically caused by an imbalance in mass, external forces, or internal structural defects. In rotating machinery, for instance, if the mass is not evenly distributed, it can lead to vibrations that manifest as diametral vibration. These vibrations can result in excessive wear and tear on components, ultimately leading to failures if not properly addressed.The significance of addressing diametral vibration becomes apparent when we consider its effects on machinery. For example, in turbines and generators, any form of vibration can lead to misalignment, increased friction, and even catastrophic failure. Engineers often utilize vibration analysis techniques to monitor and mitigate diametral vibration. By using sensors and diagnostic tools, they can identify the frequency and amplitude of vibrations, allowing them to make necessary adjustments to the system.Moreover, the study of diametral vibration extends beyond just mechanical systems; it also plays a role in civil engineering, particularly in the design of structures that must withstand dynamic loads, such as bridges and buildings. Understanding how diametral vibration affects structural integrity can help engineers design safer and more resilient structures. For instance, during an earthquake, buildings experience various types of vibrations, including diametral vibration, and knowing how to manage these forces is essential for preventing structural failure.In conclusion, diametral vibration is a critical concept in both mechanical and civil engineering fields. Its implications stretch across various applications, from improving the reliability of machinery to ensuring the safety of structures. As technology advances, the methods for analyzing and mitigating diametral vibration will continue to evolve, providing engineers with better tools to enhance performance and durability in their designs. Therefore, comprehending this phenomenon is not only beneficial but necessary for anyone involved in engineering disciplines. As we move forward in our technological pursuits, a keen awareness of diametral vibration will undoubtedly contribute to more efficient and sustainable engineering practices. Thus, fostering a deeper understanding of this concept is essential for future innovations in the field.

在工程和物理学领域，理解各种类型的振动对于机械系统的设计和维护至关重要。一个常常出现在机械动态讨论中的概念是直径振动。这个术语指的是沿着圆形物体或系统的直径发生的振荡或振动，这可能会显著影响其性能和寿命。为了深入了解直径振动的影响，我们首先必须理解机械系统中振动的基本原理。振动通常是由质量不平衡、外部力量或内部结构缺陷引起的。例如，在旋转机械中，如果质量分布不均，就会导致以直径振动的形式出现的振动。这些振动可能导致组件的过度磨损，如果不加以处理，最终可能导致故障。解决直径振动问题的重要性在我们考虑其对机械的影响时变得显而易见。例如，在涡轮机和发电机中，任何形式的振动都可能导致失调、摩擦增加甚至灾难性故障。工程师们经常利用振动分析技术来监测和减轻直径振动。通过使用传感器和诊断工具，他们可以识别振动的频率和幅度，从而允许他们对系统进行必要的调整。此外，直径振动的研究不仅仅局限于机械系统；它在土木工程中也发挥着作用，特别是在设计必须承受动态荷载的结构（如桥梁和建筑物）时。理解直径振动如何影响结构完整性可以帮助工程师设计更安全、更坚固的结构。例如，在地震期间，建筑物会经历各种类型的振动，包括直径振动，了解如何管理这些力量对于防止结构失效至关重要。总之，直径振动是机械和土木工程领域中的一个关键概念。它的影响跨越了各种应用，从提高机械的可靠性到确保结构的安全。随着技术的进步，分析和减轻直径振动的方法将继续发展，为工程师提供更好的工具，以增强其设计的性能和耐用性。因此，理解这一现象对于任何参与工程学科的人来说不仅是有益的，而且是必要的。随着我们在技术追求中的不断前进，对直径振动的敏锐意识无疑将有助于更高效和可持续的工程实践。因此，培养对这一概念的更深刻理解对于未来在该领域的创新至关重要。