ferrography

简明释义

英[ˌfɛrəˈɡræfi]美[ˌfɛroʊˈɡræfi]

n. [冶] 铁粉记录术

英英释义

单词用法

同义词

反义词

例句

1.The recognition of the wear particle is the most important for realizing the automatic ferrography analysis.

磨损磨粒的模式识别方法是实现铁谱分析数字化和智能化的最为重要的内容。

2.It is pointed out that, moreover, combined with the other techniques of oil analysis, OLF 1 on line ferrography can monitor and diagnose gear wear condition more accurately.

本文同时指出，OLF -1在线铁谱与其它油液分析技术相结合，可以更准确地进行齿轮磨损状态的监测和诊断。

3.Therefore, using for real time and continuous monitoring of gear wear condition, OLF 1 on line ferrography is of good properties.

因而，OLF -1在线铁谱仪用于齿轮磨损状态的实时和连续监测具有良好的性能。

4.This paper Outlines the application of ferrography in the test of a diesel engine.

本文概述铁谱技术应用于柴油机试验的情况。

5.An optimization method for magnetic field of on-line Ferrography was presented firstly.

提出了一种适用于在线铁谱仪磁场的优化设计方法。

6.The ferrography is a fault diagnosis method based on the analysis of wear debris.

铁谱技术是以磨损磨粒分析为基础的故障诊断方法。

7.The ferrography is a fault diagnosis method based on the analysis of wear particle.

铁谱技术是以磨损磨粒分析为基础的故障诊断方法。

8.The image processing technology and pattern recognition theory were used to design ferrography image recognition system of 12150 engines.

本文将计算机图像处理技术和模式识别理论结合起来进行了12150发动机铁谱图像识别系统的设计。

9.On the basis of the practice, the distinguishing features and the correlation of ferrography and spectrography in the condition monitoring are also discussed.

并结合监测实际，对铁谱光谱的特性和对应关系进行了讨论。

10.The engineer used ferrography to analyze the wear particles in the lubricant.

工程师使用铁谱分析来分析润滑剂中的磨损颗粒。

11.By applying ferrography, we can identify the source of contamination in machinery.

通过应用铁谱分析，我们可以确定机器中污染的来源。

12.The results from ferrography helped us improve our maintenance schedule.

来自铁谱分析的结果帮助我们改善了维护计划。

13.Using ferrography, the technician discovered abnormal wear patterns in the gearbox.

技术人员使用铁谱分析发现了变速箱中的异常磨损模式。

14.The study of ferrography is crucial for extending the life of industrial equipment.

研究铁谱分析对延长工业设备的使用寿命至关重要。

作文

Ferrography is a specialized diagnostic technique used primarily in the field of tribology, which is the study of friction, wear, and lubrication. This method allows engineers and researchers to analyze the wear particles generated during the operation of machinery and mechanical systems. By examining these particles, one can gain valuable insights into the condition of the equipment and predict potential failures before they occur. The term ferrography (铁谱学) comes from the Greek word 'ferro,' meaning iron, and 'graphy,' meaning to write or describe. Essentially, it involves the 'writing' or recording of information about ferrous particles in lubricants and oils. The process of ferrography (铁谱学) typically involves collecting samples of lubricating oil from machinery. These samples are then passed through a ferrograph, an instrument designed to filter out wear particles based on their size and magnetic properties. The resulting data provides a detailed analysis of the types and quantities of particles present, which can indicate the health of the machinery. For instance, a high concentration of metal particles may suggest excessive wear, while the presence of specific types of materials can point to particular issues within the system. One of the significant advantages of ferrography (铁谱学) is its ability to detect problems early. Many mechanical failures do not occur suddenly; instead, they develop over time as wear and tear accumulate. By routinely analyzing lubricant samples, maintenance teams can identify trends and make informed decisions regarding maintenance schedules, part replacements, and overall equipment management. This proactive approach can significantly reduce downtime and repair costs, ultimately leading to increased productivity and efficiency in industrial operations. In addition to its applications in predictive maintenance, ferrography (铁谱学) also plays a crucial role in research and development. Engineers use this technique to study new materials and lubricants, assessing their performance under various conditions. By understanding how different substances interact and degrade over time, researchers can develop better products that enhance machine longevity and performance. Moreover, ferrography (铁谱学) is not limited to heavy machinery; it is also applicable in the automotive industry, aerospace engineering, and even in everyday devices like computers and household appliances. Any system that relies on lubrication can benefit from the insights provided by ferrography (铁谱学). As technology continues to advance, the techniques and tools used in ferrography (铁谱学) are also evolving, incorporating digital imaging and machine learning to enhance data analysis and interpretation. In conclusion, ferrography (铁谱学) is an invaluable tool in the realm of mechanical engineering and maintenance. It not only aids in the early detection of potential failures but also contributes to the ongoing improvement of machinery and lubrication technologies. As industries strive for greater efficiency and reliability, the importance of ferrography (铁谱学) will undoubtedly continue to grow, making it a key area of study for engineers and researchers alike.