deflection winding

简明释义

致偏线圈

英英释义

例句

1.During the testing phase, the deflection winding 偏转绕组 showed significant improvement in thermal stability.

在测试阶段，偏转绕组 deflection winding 显示出显著的热稳定性改善。

2.In the design of transformers, the deflection winding 偏转绕组 helps to reduce noise and improve efficiency.

在变压器的设计中，偏转绕组 deflection winding 有助于减少噪音并提高效率。

3.The technician adjusted the deflection winding 偏转绕组 to optimize the performance of the induction heater.

技术员调整了偏转绕组 deflection winding 以优化感应加热器的性能。

4.The engineer explained that the deflection winding 偏转绕组 is crucial for controlling the magnetic field in the motor.

工程师解释说，偏转绕组 deflection winding 对于控制电机中的磁场至关重要。

5.The deflection winding 偏转绕组 configuration was altered to achieve better voltage regulation in the circuit.

为了在电路中实现更好的电压调节，偏转绕组 deflection winding 的配置被改变。

作文

In the field of electrical engineering, various components and techniques are utilized to enhance the performance and efficiency of electrical devices. One such component is the deflection winding, which plays a crucial role in the functioning of certain types of instruments, particularly in cathode ray tubes (CRTs) and oscilloscopes. Understanding the concept and application of deflection winding is essential for anyone involved in the design or maintenance of these electronic devices.The primary purpose of deflection winding is to control the movement of an electron beam within a CRT. This is achieved by generating magnetic fields that influence the path of the electrons as they travel from the cathode to the phosphorescent screen. By manipulating the deflection winding, engineers can direct the electron beam to specific locations on the screen, allowing for the display of images and waveforms.There are two main types of deflection winding: vertical and horizontal. The vertical deflection winding is responsible for moving the electron beam up and down, while the horizontal deflection winding controls the side-to-side movement. Together, these two windings enable precise control over the positioning of the electron beam, which is vital for accurate representation of data.The operation of deflection winding is based on the principles of electromagnetism. When an electric current passes through the winding, it generates a magnetic field. The strength and direction of this field can be altered by changing the current flowing through the winding. This allows for dynamic control of the electron beam’s trajectory, enabling the display of complex signals and images.In addition to its use in CRTs, deflection winding also finds applications in other areas, such as in certain types of sensors and actuators. For instance, in some electromagnetic devices, deflection winding is used to create motion or to measure displacement. This versatility makes it a valuable component in various engineering applications.Moreover, advancements in technology have led to the development of more sophisticated deflection winding systems. Modern oscilloscopes, for example, utilize digital signal processing to enhance the accuracy and speed of the deflection process. These innovations have significantly improved the performance of electronic devices, making them more efficient and reliable.Understanding the intricacies of deflection winding is not only important for engineers but also for technicians and hobbyists who work with electronic equipment. A solid grasp of how deflection winding operates can aid in troubleshooting issues and optimizing device performance. Additionally, as technology continues to evolve, staying informed about developments related to deflection winding will be beneficial for anyone in the field of electronics.In conclusion, the deflection winding is a fundamental component in the realm of electrical engineering, particularly in devices that require precise control of electron beams. Its ability to manipulate the trajectory of electrons has made it indispensable in the design of CRTs and oscilloscopes. As technology progresses, the significance of deflection winding will likely continue to grow, underscoring the need for ongoing education and understanding of this essential concept in electrical engineering.

在电气工程领域，各种组件和技术被用来提高电气设备的性能和效率。其中一个重要的组件是偏转绕组，它在某些类型仪器的功能中发挥着关键作用，特别是在阴极射线管（CRT）和示波器中。理解偏转绕组的概念和应用对于任何参与这些电子设备设计或维护的人来说都是至关重要的。偏转绕组的主要目的是控制阴极射线管内电子束的运动。这是通过生成磁场来实现的，这些磁场影响电子在从阴极到荧光屏的旅行路径。通过操控偏转绕组，工程师可以将电子束引导到屏幕上的特定位置，从而允许图像和波形的显示。偏转绕组主要分为两种类型：垂直和水平。垂直偏转绕组负责使电子束上下移动，而水平偏转绕组则控制左右运动。通过这两种绕组的配合，可以精确控制电子束的位置，这对于数据的准确表示至关重要。偏转绕组的操作基于电磁学原理。当电流通过绕组时，它会生成一个磁场。通过改变流经绕组的电流，可以改变这个磁场的强度和方向。这使得对电子束轨迹的动态控制成为可能，从而能够显示复杂的信号和图像。除了在CRT中的应用外，偏转绕组还在其他领域中找到了应用，例如在某些类型的传感器和执行器中。例如，在某些电磁设备中，偏转绕组用于产生运动或测量位移。这种多功能性使其在各种工程应用中成为一种有价值的组件。此外，技术的进步促使了更复杂的偏转绕组系统的发展。现代示波器利用数字信号处理来增强偏转过程的准确性和速度。这些创新显著提高了电子设备的性能，使其更加高效和可靠。理解偏转绕组的复杂性不仅对工程师重要，对与电子设备打交道的技术人员和爱好者也同样重要。深入了解偏转绕组的工作原理可以帮助排除故障并优化设备性能。此外，随着技术的不断发展，保持对与偏转绕组相关的进展的了解将对任何从事电子领域的人都有益。总之，偏转绕组是电气工程领域的基本组件，特别是在需要精确控制电子束的设备中。它操纵电子轨迹的能力使其在CRT和示波器的设计中不可或缺。随着技术的进步，偏转绕组的重要性可能会继续增长，这凸显了在电气工程中持续教育和理解这一基本概念的必要性。