shunt wound dynamo

简明释义

并励发电机

英英释义

例句

1.The engineer explained that the performance of the shunt wound dynamo 并联绕组发电机 is stable under varying loads.

工程师解释说，shunt wound dynamo 并联绕组发电机 在不同负载下的性能是稳定的。

2.In our physics lab, we used a shunt wound dynamo 并联绕组发电机 to demonstrate the principles of electromagnetic induction.

在我们的物理实验室里，我们使用了一个 shunt wound dynamo 并联绕组发电机 来演示电磁感应的原理。

3.The shunt wound dynamo 并联绕组发电机 is commonly used in small-scale power generation applications.

shunt wound dynamo 并联绕组发电机 通常用于小规模发电应用中。

4.The design of the shunt wound dynamo 并联绕组发电机 allows for easy adjustment of the output voltage.

shunt wound dynamo 并联绕组发电机 的设计允许轻松调整输出电压。

5.When troubleshooting the circuit, we found that the shunt wound dynamo 并联绕组发电机 was not producing enough voltage.

在排查电路时，我们发现 shunt wound dynamo 并联绕组发电机 没有产生足够的电压。

作文

The concept of a shunt wound dynamo is an important topic in the field of electrical engineering. This type of dynamo is specifically designed to generate direct current (DC) electricity through electromagnetic induction. In essence, a shunt wound dynamo utilizes a shunt winding that is connected in parallel with the load, allowing it to maintain a relatively constant voltage output despite variations in the load. This characteristic makes it particularly useful in applications where stable voltage is crucial. To understand how a shunt wound dynamo operates, we first need to look at its components. The main parts include the rotor, stator, and the windings. The rotor is the rotating part of the dynamo, which is usually equipped with an armature winding. The stator, on the other hand, remains stationary and contains the field windings. The shunt wound dynamo has a unique configuration in which the field winding is connected in parallel with the armature winding, hence the term 'shunt.' One of the significant advantages of using a shunt wound dynamo is its ability to provide a stable output voltage. When the load increases, the current drawn from the dynamo also increases, which causes a drop in the field current due to the shunt connection. However, this drop is compensated by the increase in the speed of the rotor due to the mechanical energy input, which helps maintain the voltage level. This self-regulating feature is particularly beneficial in various industrial applications, such as in battery charging systems and for supplying power to small machines. Moreover, the shunt wound dynamo is known for its simplicity and ease of maintenance. Unlike other types of dynamos, such as series wound or compound wound dynamos, the shunt wound design minimizes the complexity involved in wiring and connections. This simplicity not only reduces the initial setup costs but also lowers the long-term maintenance requirements, making it a cost-effective choice for many users. In addition to its practical advantages, the shunt wound dynamo also serves as an excellent educational tool for those studying electrical engineering. Understanding its operation helps students grasp fundamental concepts of electromagnetism and circuit theory. By experimenting with a shunt wound dynamo, students can observe firsthand the principles of magnetic fields, induced currents, and the relationship between voltage and current. In conclusion, the shunt wound dynamo is a vital component in the world of electrical engineering. Its ability to generate stable DC voltage, combined with its straightforward design and low maintenance needs, makes it an ideal choice for various applications. As technology continues to advance, the principles behind the shunt wound dynamo will remain relevant, serving both practical purposes and educational insights into the fascinating field of electricity generation.

“分流绕组发电机”的概念在电气工程领域是一个重要的主题。这种类型的发电机专门设计用于通过电磁感应产生直流电（DC）电力。从本质上讲，“分流绕组发电机”利用与负载并联连接的分流绕组，使其能够在负载变化的情况下保持相对恒定的电压输出。这一特性使其在电压稳定至关重要的应用中尤为有用。要理解“分流绕组发电机”的工作原理，我们首先需要了解其组成部分。主要部件包括转子、定子和绕组。转子是发电机的旋转部分，通常配备有电枢绕组。定子则保持静止，包含励磁绕组。“分流绕组发电机”具有独特的配置，其中励磁绕组与电枢绕组并联连接，因此得名“分流”。使用“分流绕组发电机”的一个显著优势是它能够提供稳定的输出电压。当负载增加时，从发电机抽取的电流也会增加，这导致由于分流连接而引起的励磁电流下降。然而，由于机械能输入导致转子转速的提高，这一下降得到了补偿，从而帮助维持电压水平。这种自我调节特性在各种工业应用中尤其有益，例如在电池充电系统和为小型机器供电的场合。此外，“分流绕组发电机”以其简单性和易于维护而闻名。与其他类型的发电机（如串联绕组或复合绕组发电机）相比，分流绕组设计减少了接线和连接的复杂性。这种简单性不仅降低了初始安装成本，还降低了长期维护需求，使其成为许多用户的经济选择。除了实用优势外，“分流绕组发电机”也是学习电气工程的优秀教育工具。理解其操作帮助学生掌握电磁学和电路理论的基本概念。通过实验“分流绕组发电机”，学生可以亲身观察磁场、感应电流以及电压与电流之间关系的原理。总之，“分流绕组发电机”是电气工程领域的重要组成部分。它产生稳定直流电压的能力，加上简单的设计和低维护需求，使其成为各种应用的理想选择。随着技术的不断进步，“分流绕组发电机”背后的原理将继续保持相关性，为电力生成这一迷人领域提供实用目的和教育见解。