cavitation noise

简明释义

空泡噪声

英英释义

例句

1.The cavitation noise 气蚀噪声 can often be heard in high-speed pumps.

在高速泵中，气蚀噪声 气蚀噪声 通常是可以听到的。

2.The engineer noted that the cavitation noise 气蚀噪声 from the pump indicated a potential issue with the system.

工程师注意到泵产生的气蚀噪声 气蚀噪声 表明系统可能存在问题。

3.To reduce cavitation noise 气蚀噪声, modifications were made to the impeller design.

为了减少气蚀噪声 气蚀噪声，对叶轮设计进行了修改。

4.Operators were trained to identify cavitation noise 气蚀噪声 as a sign of equipment malfunction.

操作员接受了培训，以识别气蚀噪声 气蚀噪声 作为设备故障的迹象。

5.During testing, excessive cavitation noise 气蚀噪声 was detected, prompting further investigation.

在测试过程中，检测到过量的气蚀噪声 气蚀噪声，这促使了进一步的调查。

作文

Cavitation is a phenomenon that occurs in fluids when there is a rapid change in pressure. This can lead to the formation of small vapor-filled cavities or bubbles within the liquid. When these bubbles collapse or implode, they generate a significant amount of energy and produce a sound known as cavitation noise">气蚀噪声. Understanding cavitation noise">气蚀噪声 is crucial in various engineering applications, particularly in fluid dynamics and mechanical systems. In many industrial settings, cavitation noise">气蚀噪声 can be detrimental. For instance, in pumps and propellers, cavitation can lead to a reduction in efficiency and even damage to the machinery. The noise generated during cavitation is often a warning sign that the system is operating under conditions that could lead to failure. Engineers must therefore monitor cavitation noise">气蚀噪声 levels to ensure the longevity and reliability of their equipment.The characteristics of cavitation noise">气蚀噪声 can vary depending on several factors, including the type of fluid, the temperature, and the pressure conditions. In general, the sound produced by cavitation is described as a loud, rumbling noise that can be easily recognized. This noise can also be measured using specialized equipment, allowing engineers to analyze the severity of cavitation in a given system.Research into cavitation noise">气蚀噪声 has led to the development of various strategies to mitigate its effects. For example, altering the design of pumps and propellers can help minimize the occurrence of cavitation. Additionally, maintaining optimal operating conditions, such as ensuring that the fluid flow remains steady and within specified limits, can reduce the likelihood of cavitation and the accompanying noise.Moreover, understanding cavitation noise">气蚀噪声 is not only important for avoiding damage but also for improving performance. By controlling cavitation, engineers can enhance the efficiency of fluid systems, leading to better energy use and lower operational costs. This is particularly relevant in industries where fluid movement is critical, such as in aerospace and marine applications.In conclusion, cavitation noise">气蚀噪声 is a significant concern in fluid dynamics that warrants attention from engineers and researchers alike. Its implications extend beyond mere noise; it serves as an indicator of potential problems within fluid systems. By studying and addressing cavitation noise">气蚀噪声, we can improve the reliability and efficiency of various technologies that rely on fluid movement. As our understanding of this phenomenon grows, so too does our ability to design systems that operate smoothly and quietly, ultimately benefiting both industry and the environment.

气蚀是一种流体现象，当压力迅速变化时，会导致液体中形成小的充满蒸汽的空腔或气泡。当这些气泡崩溃或爆炸时，会产生大量能量并发出一种被称为cavitation noise">气蚀噪声的声音。理解cavitation noise">气蚀噪声在各种工程应用中至关重要，特别是在流体动力学和机械系统中。在许多工业环境中，cavitation noise">气蚀噪声可能是有害的。例如，在泵和螺旋桨中，气蚀会导致效率下降，甚至对机械造成损坏。气蚀过程中产生的噪声通常是一个警告信号，表明系统在可能导致故障的条件下运行。因此，工程师必须监测cavitation noise">气蚀噪声水平，以确保设备的耐用性和可靠性。cavitation noise">气蚀噪声的特征可能因多种因素而异，包括流体类型、温度和压力条件。通常，气蚀产生的声音被描述为一种响亮、隆隆的噪声，容易被识别。这种噪声也可以使用专业设备进行测量，使工程师能够分析给定系统中气蚀的严重程度。对cavitation noise">气蚀噪声的研究促成了各种减轻其影响的策略的发展。例如，改变泵和螺旋桨的设计可以帮助最小化气蚀的发生。此外，保持最佳操作条件，例如确保流体流动保持稳定并在规定范围内，可以减少气蚀及其伴随噪声的可能性。此外，理解cavitation noise">气蚀噪声不仅对于避免损坏至关重要，而且对于提高性能也同样重要。通过控制气蚀，工程师可以提高流体系统的效率，从而实现更好的能源利用和降低运营成本。这在流体运动至关重要的行业中尤为相关，例如航空航天和海洋应用。总之，cavitation noise">气蚀噪声是流体动力学中的一个重要问题，值得工程师和研究人员的关注。它的影响超出了单纯的噪音；它作为流体系统潜在问题的指示器。通过研究和解决cavitation noise">气蚀噪声，我们可以改善各种依赖流体运动的技术的可靠性和效率。随着我们对这一现象理解的加深，我们的设计能力也将不断提升，使系统运行更加顺畅和安静，最终使工业和环境受益。