rheostatic

简明释义

英[ˌriːəʊˈstætɪk]美[ˌriːoʊˈstætɪk]

adj. 变阻器的；电阻的

英英释义

单词用法

同义词

反义词

例句

1.The circuitous philosophy and the application range of rheostatic current control are also introduced.

还介绍了变阻抗电流控制的电路原理和应用范围。

2.The circuitous philosophy and the application range of rheostatic current control are also introduced.

还介绍了变阻抗电流控制的电路原理和应用范围。

3.In the laboratory, we used a rheostatic 电阻调节的 device to manage the current flow in our experiments.

在实验室中，我们使用了一个电阻调节的设备来管理实验中的电流流动。

4.By employing a rheostatic 电阻调节的 circuit, we minimized power loss in the system.

通过使用电阻调节的电路，我们最小化了系统中的功率损失。

5.The rheostatic 电阻调节的 control allowed the technician to precisely calibrate the equipment.

技术人员能够通过电阻调节的控制精确校准设备。

6.The rheostatic 电阻调节的 feature of the light dimmer allows for smooth adjustments in brightness.

灯光调光器的电阻调节的功能允许平滑调整亮度。

7.The engineer adjusted the rheostatic 电阻调节的 controls to fine-tune the motor speed.

工程师调整了电阻调节的控制器，以微调电机速度。

作文

In the world of electrical engineering, the term rheostatic refers to the use of a rheostat, which is a variable resistor that allows for the adjustment of current flow in a circuit. Understanding the rheostatic principles is essential for anyone involved in designing or working with electrical systems, as it plays a crucial role in controlling voltage and current levels. A rheostat can be used in various applications, from simple dimmer switches in lighting systems to more complex systems in industrial machinery. For instance, when a rheostat is introduced into a circuit, it provides a way to change the resistance without altering the entire circuit's configuration. This ability to adjust resistance makes it a valuable component for managing energy consumption and optimizing performance. The rheostatic properties allow engineers to fine-tune devices to meet specific operational requirements, which is particularly important in fields such as robotics and automation. Moreover, the concept of rheostatic control extends beyond just electrical circuits. In many modern applications, including renewable energy systems, the ability to regulate power flow is vital. For example, in solar power systems, a rheostatic approach can help manage the energy produced by the solar panels, ensuring that the energy is used efficiently and effectively. This is especially important in off-grid systems where energy storage and management are critical for maintaining a reliable power supply.The use of rheostatic devices also plays a significant role in educational settings. Students studying physics and engineering often engage with rheostats in laboratory experiments to gain hands-on experience with electrical concepts. By manipulating the resistance in a circuit, they can observe firsthand how current and voltage interact, reinforcing theoretical knowledge with practical application. This experiential learning is invaluable in developing a deeper understanding of electrical principles.Furthermore, as technology advances, the traditional rheostatic methods are being integrated with digital controls and smart systems. This evolution allows for more precise control over electrical parameters and enhances the efficiency of systems. Engineers are now able to design smart rheostats that can automatically adjust based on real-time data, making them more responsive to changing conditions. This innovation represents a significant leap forward in the field of electrical engineering, merging the old with the new to create more efficient and effective solutions.In conclusion, the term rheostatic encompasses a fundamental concept in electrical engineering that has far-reaching implications across various industries. From its role in basic electrical circuits to its applications in advanced technologies, understanding rheostatic principles is essential for anyone looking to excel in this field. As we continue to innovate and develop new technologies, the importance of rheostatic devices will only grow, making it a key area of study and application for future engineers and technologists.

在电气工程的世界中，术语rheostatic指的是使用电位器，这是一种可变电阻器，允许在电路中调节电流流动。理解rheostatic原理对于任何参与设计或与电气系统工作的人来说都是必不可少的，因为它在控制电压和电流水平方面发挥着关键作用。电位器可以用于各种应用，从照明系统中的简单调光开关到工业机械中的更复杂系统。例如，当电位器被引入电路时，它提供了一种改变电阻的方法，而不改变整个电路的配置。这种调整电阻的能力使其成为管理能量消耗和优化性能的宝贵组件。rheostatic特性使工程师能够精细调整设备以满足特定的操作要求，这在机器人技术和自动化等领域尤为重要。此外，rheostatic控制的概念超越了简单的电路。在许多现代应用中，包括可再生能源系统，调节电力流动的能力至关重要。例如，在太阳能发电系统中，rheostatic方法可以帮助管理太阳能电池板产生的能量，确保能量的高效和有效使用。这在离网系统中尤其重要，因为能量存储和管理对于维持可靠的电源至关重要。rheostatic设备的使用在教育环境中也发挥着重要作用。学习物理和工程的学生通常会在实验室实验中接触电位器，以获得电气概念的实践经验。通过操纵电路中的电阻，他们可以亲身观察电流和电压如何相互作用，从而巩固理论知识与实践应用之间的联系。这种体验式学习对于深入理解电气原理是无价的。此外，随着技术的发展，传统的rheostatic方法正在与数字控制和智能系统相结合。这种演变使得对电气参数的控制更加精确，提高了系统的效率。工程师们现在能够设计出能够根据实时数据自动调整的智能电位器，使其对变化的条件更加敏感。这一创新代表了电气工程领域的一次重大飞跃，将旧技术与新技术结合起来，创造出更高效、更有效的解决方案。总之，术语rheostatic涵盖了电气工程中的一个基本概念，在各个行业中具有深远的影响。从它在基本电路中的作用到在先进技术中的应用，理解rheostatic原理对于任何希望在这一领域取得成功的人来说都是必不可少的。随着我们不断创新和开发新技术，rheostatic设备的重要性只会增加，使其成为未来工程师和技术人员研究和应用的关键领域。