thyratron

简明释义

英[ˈθaɪrəˌtrɒn]美[ˈθaɪrəˌtrɑːn]

n. [电子] 闸流管

英英释义

单词用法

同义词

反义词

例句

1.This power supply can reduce the impenetrate probability of thyratron, at the same time it can ensure the high steadiness of the charge for the laser.

该电源在有效降低闸流管连通概率的同时保证了激光器充电的高稳定性。

2.The on-off character of the thyratron is advantageous to the arc-starting and arc-stabling of the welder.

晶闸管的通断特性，有利于焊机起弧、稳弧。

3.The switch rate of thyratron is related to the triggering signal. The fast thyristor is usually used in the trigger circuit, but the triggering signal is not ideal.

氢闸流管的导通速度与触发信号有关，常用触发电路中使用快速晶闸管，触发信号并不是很理想。

4.It was shown that appropriate selection of sharpening capacitor and circuit inductance would decrease the current-pulse length without any harm to the thyratron.

适当选择锐化电容和回路电感量，可以使放电电流脉冲变窄而又不加重闸流管的负担。

5.The trigger is used for generating excitation pulse for the thyratron to ignite.

触发器用来产生激励脉冲，供闸流管点火。

6.Using a double-grid hydrogen thyratron, a fast pulse generator with four outputs, high-voltage, low jitter, was made to use at special occasion.

采用双栅极氢闸流管作为主开关，研制成功一种四路输出高压低晃动快脉冲源应用于某种特殊场合。

7.Magnetic pulse compressor (MPC) with thyratron as discharge switch used in ti: Sapphire laser was put forward for the first time.

首次提出了将磁脉冲压缩开关应用于钛宝石激光器中，由磁脉冲压缩开关和闸流管组合作为放电开关。

8.The term "thyristor" came from its gas tube equivalent, thyratron.

晶闸管一词源于其气体管等价物——闸流管。

9.The high-voltage thyratron 氮气阀 is essential for the operation of particle accelerators.

高压thyratron 氮气阀对粒子加速器的运行至关重要。

10.The engineer explained how the thyratron 氮气阀 is used in high-power pulse applications.

工程师解释了如何在高功率脉冲应用中使用thyratron 氮气阀。

11.In radar systems, a thyratron 氮气阀 can switch on and off rapidly to generate pulses.

在雷达系统中，thyratron 氮气阀可以快速开关以产生脉冲。

12.We replaced the faulty thyratron 氮气阀 in the laser system to improve performance.

我们更换了激光系统中故障的thyratron 氮气阀以提高性能。

13.The thyratron 氮气阀 plays a crucial role in controlling the timing of electrical circuits.

thyratron 氮气阀在控制电路的时序中起着至关重要的作用。

作文

The world of electronics is filled with various components that play crucial roles in the functioning of devices we use every day. One such component, though not as commonly known as transistors or diodes, is the thyratron. A thyratron is a type of gas-filled tube that acts as a switch or amplifier for electrical signals. It was first developed in the early 20th century and has since found applications in various fields, including radar technology, lighting, and high-frequency switching. Understanding how a thyratron works can provide insights into its significance in modern technology.A thyratron operates on the principle of gas ionization. When a small voltage is applied to the control electrode, it causes the gas inside the tube to ionize, allowing a larger current to flow between the anode and cathode. This ability to control large currents with a small input makes the thyratron particularly useful in applications where rapid switching is essential. For instance, in radar systems, thyratrons are used to generate high-voltage pulses necessary for transmitting signals.One of the key advantages of using a thyratron is its ability to handle high voltages and currents, which is often required in industrial applications. They can switch on and off very quickly, making them ideal for controlling motors and other heavy machinery. Additionally, the thyratron can be found in some types of light dimmers and flash photography equipment, showcasing its versatility beyond just high-power applications.However, despite their advantages, thyratrons have some limitations. They can only operate in specific conditions, such as certain gas pressures and temperatures. Moreover, the rise of solid-state devices, like transistors, has led to a decline in the use of thyratrons in many applications. Solid-state devices offer greater reliability, smaller size, and lower power consumption, making them more appealing for modern electronic designs.Despite these challenges, thyratrons still hold a niche in certain applications. Researchers continue to explore new materials and designs to enhance the performance of thyratrons and expand their range of applications. For example, advancements in gas mixtures and electrode designs have shown promise in improving the efficiency and lifespan of these devices.In conclusion, the thyratron is a fascinating component that has played a significant role in the development of electronic technology. Its unique properties allow it to control high-voltage and high-current applications effectively. While it may not be as prevalent as it once was due to the rise of solid-state technologies, the thyratron remains an important part of the history of electronics and continues to be relevant in specific fields. Understanding the workings and applications of the thyratron not only highlights the evolution of electronic components but also emphasizes the importance of innovation in technology.

电子世界充满了各种组件，这些组件在我们每天使用的设备的功能中发挥着至关重要的作用。一个这样的组件，尽管不如晶体管或二极管那样广为人知，但却是thyratron。Thyratron是一种气体填充管，充当电信号的开关或放大器。它是在20世纪初首次开发的，随后在雷达技术、照明和高频开关等多个领域找到了应用。理解thyratron的工作原理可以提供对其在现代技术中重要性的洞察。Thyratron基于气体电离的原理工作。当施加小电压到控制电极时，会导致管内的气体电离，从而允许较大的电流在阳极和阴极之间流动。这种用小输入控制大电流的能力使得thyratron在需要快速开关的应用中尤为有用。例如，在雷达系统中，thyratron用于生成传输信号所需的高电压脉冲。使用thyratron的一个主要优点是它能够处理高电压和电流，这在工业应用中通常是必需的。它们可以非常快速地开关，使其非常适合控制电动机和其他重型机械。此外，thyratron还可以在某些类型的灯光调光器和闪光摄影设备中找到，展示了其超越高功率应用的多功能性。然而，尽管有其优点，thyratron也存在一些局限性。它们只能在特定条件下工作，例如某些气体压力和温度。此外，固态设备（如晶体管）的崛起导致了thyratron在许多应用中的使用下降。固态设备提供更高的可靠性、更小的体积和更低的功耗，使其在现代电子设计中更具吸引力。尽管面临这些挑战，thyratron在某些应用中仍然占有一席之地。研究人员继续探索新材料和设计，以提高thyratron的性能并扩展其应用范围。例如，气体混合物和电极设计的进步显示出改善这些设备的效率和寿命的前景。总之，thyratron是一个迷人的组件，在电子技术的发展中发挥了重要作用。它独特的特性使其能够有效地控制高电压和高电流应用。尽管由于固态技术的崛起，它可能不再像以前那样普遍，但thyratron仍然是电子历史的重要组成部分，并在特定领域继续相关。理解thyratron的工作原理和应用不仅突显了电子组件的演变，还强调了技术创新的重要性。