galvanometric

简明释义

英[ˌɡælvənəʊˈmetrɪk]美[ˌɡælvənoʊˈmetrɪk]

adj. 检流计的

英英释义

单词用法

同义词

反义词

例句

1.Instruments requiring the testing of Resolvers, Synchros, Galvanometric Movements and Lighting Circuits can be fully tested for operational performance in the Airborne Electrical Environment.

它对于需要做旋变，自整角，检流计的运动和照明电路测试的仪器，能够在航空电力环境里进行全面的使用特性测试。

2.Instruments requiring the testing of Resolvers, Synchros, Galvanometric Movements and Lighting Circuits can be fully tested for operational performance in the Airborne Electrical Environment.

它对于需要做旋变，自整角，检流计的运动和照明电路测试的仪器，能够在航空电力环境里进行全面的使用特性测试。

3.At present, three kinds of seismographs are used at Chinese seismic stations. They are the direct-coupled seismometer, the galvanometric seismograph, and the electronic seismograph.

目前，我国基准地震台上使用三种类型地震仪：直接耦合地震仪、电流计记录地震仪和电子放大地震仪。

4.The theoretical problems of the position feedback galvanometric recording system are systematically considered in this paper.

本文系统分析了位置反馈检流计式笔描记录系统。

5.The scientist used a galvanometric 电流计 to measure the current flowing through the circuit.

科学家使用了一个galvanometric 电流计来测量电路中的电流。

6.In the laboratory, the galvanometric 电流计 provided accurate readings of electrical resistance.

在实验室中，galvanometric 电流计提供了电阻的准确读数。

7.The galvanometric 电流计 is essential for experiments involving electromagnetism.

在涉及电磁学的实验中，galvanometric 电流计是必不可少的。

8.Using a galvanometric 电流计, we can detect very small changes in electric current.

使用galvanometric 电流计，我们可以检测到电流的微小变化。

9.The galvanometric 电流计 was calibrated to ensure precise measurements.

为了确保精确测量，galvanometric 电流计经过了校准。

作文

In the realm of physics and engineering, the term galvanometric refers to a method or device that measures electric current through the use of a galvanometer. A galvanometer is an instrument that detects and measures small amounts of electric current by utilizing the magnetic field generated by the current flow. The significance of galvanometric measurements cannot be overstated, as they play a crucial role in various applications, including electrical engineering, physics research, and even medical diagnostics. One of the most common uses of galvanometric devices is in laboratories where precise measurements of current are required. For instance, in experiments involving electrochemistry, researchers often rely on galvanometric techniques to measure the current flowing through an electrolytic cell. This data is vital for understanding the reaction kinetics and optimizing the conditions for maximum efficiency. Moreover, galvanometric methods are also utilized in industrial applications. For example, in the manufacturing sector, monitoring electric currents can help ensure that machinery operates within safe limits. Any fluctuations in current can indicate potential malfunctions or inefficiencies, allowing engineers to address issues before they escalate into costly downtime. In addition to its practical applications, the concept of galvanometric measurement is foundational in teaching electrical principles. Students studying physics and engineering often conduct experiments involving galvanometers to visualize the relationship between current and magnetic fields. Such hands-on experiences enhance their understanding of electromagnetic theory and its real-world implications. The galvanometric approach also extends into the realm of medical technology. Devices like electrocardiograms (EKGs) utilize galvanometric principles to measure the electrical activity of the heart. By analyzing the current generated by heartbeats, healthcare professionals can diagnose various cardiac conditions, making this technology essential for patient care. Furthermore, advancements in technology have led to the development of digital galvanometric devices that offer enhanced precision and ease of use. These modern instruments often come equipped with software that allows for real-time data analysis and visualization, making them invaluable tools in both research and industrial settings. In conclusion, the term galvanometric encapsulates a vital area of study within the fields of physics and engineering. Its applications range from laboratory research to industrial monitoring and medical diagnostics. Understanding galvanometric principles not only aids in technical proficiency but also fosters innovation in various scientific and engineering disciplines. As technology continues to evolve, the importance of galvanometric measurements will undoubtedly grow, paving the way for new discoveries and advancements across multiple fields.

在物理和工程领域，术语galvanometric指的是通过使用电流计来测量电流的方法或设备。电流计是一种通过利用电流流动产生的磁场来检测和测量微小电流的仪器。galvanometric测量的重要性不容小觑，因为它们在电气工程、物理研究甚至医学诊断等各种应用中发挥着关键作用。 galvanometric设备最常见的用途之一是在需要精确电流测量的实验室中。例如，在涉及电化学的实验中，研究人员通常依赖galvanometric技术来测量电解池中的电流。这些数据对于理解反应动力学和优化最大效率的条件至关重要。 此外，galvanometric方法也被广泛应用于工业领域。例如，在制造行业中，监测电流可以帮助确保机器在安全范围内运行。任何电流波动都可能表明潜在的故障或低效，使工程师能够在问题升级为昂贵的停机之前解决问题。 除了实际应用外，galvanometric测量的概念在教授电气原理时也是基础。学习物理和工程的学生通常会进行涉及电流计的实验，以可视化电流与磁场之间的关系。这种动手体验增强了他们对电磁理论及其现实世界影响的理解。 galvanometric方法还延伸到医学技术领域。心电图（EKG）等设备利用galvanometric原理来测量心脏的电活动。通过分析心跳所产生的电流，医疗专业人员可以诊断各种心脏病，使这项技术对患者护理至关重要。 此外，技术的进步导致了数字galvanometric设备的发展，这些设备提供了更高的精度和易用性。这些现代仪器通常配备有软件，可以实时进行数据分析和可视化，成为研究和工业环境中不可或缺的工具。 总之，术语galvanometric概括了物理和工程领域内一个重要的研究领域。它的应用范围从实验室研究到工业监测和医学诊断。理解galvanometric原理不仅有助于技术熟练度的提高，还促进了各个科学和工程学科的创新。随着技术的不断发展，galvanometric测量的重要性无疑会增长，为多个领域的新发现和进步铺平道路。