steady state voltage variiation

简明释义

静态电压变化

英英释义

例句

1.Engineers must account for steady state voltage variation 稳态电压变化 when designing electrical systems.

工程师在设计电气系统时必须考虑稳态电压变化 steady state voltage variation。

2.The engineer measured the steady state voltage variation 稳态电压变化 in the circuit to ensure its stability.

工程师测量了电路中的稳态电压变化 steady state voltage variation以确保其稳定性。

3.To minimize steady state voltage variation 稳态电压变化, the power supply was upgraded to a more stable model.

为了最小化稳态电压变化 steady state voltage variation，电源被升级为更稳定的型号。

4.The steady state voltage variation 稳态电压变化 in the transmission line was within acceptable limits.

传输线中的稳态电压变化 steady state voltage variation在可接受的范围内。

5.During the test, we observed significant steady state voltage variation 稳态电压变化 which could affect the performance of the device.

在测试过程中，我们观察到显著的稳态电压变化 steady state voltage variation，这可能会影响设备的性能。

作文

In electrical engineering, the concept of steady state voltage variation is crucial for understanding how electrical systems behave under stable conditions. This term refers to the changes in voltage levels that occur when a system reaches equilibrium after being subjected to external influences or disturbances. In simpler terms, it describes the fluctuations in voltage that can be observed when an electrical circuit has settled into a consistent operational state.To comprehend steady state voltage variation, one must first consider the nature of electrical circuits. When a circuit is powered on, various factors such as load changes, switching events, and environmental conditions can induce temporary voltage variations. However, once these factors stabilize, the circuit reaches a 'steady state' where the voltage levels become relatively constant. It is during this phase that engineers pay close attention to the steady state voltage variation to ensure that the system operates within acceptable limits.The importance of monitoring steady state voltage variation cannot be overstated. For instance, in power distribution systems, significant voltage variations can lead to equipment malfunction, reduced efficiency, and even damage to sensitive electronic devices. Therefore, engineers must design systems that can accommodate these variations while maintaining overall stability. This involves implementing various control strategies, such as voltage regulation techniques, to mitigate the impact of external disturbances.Moreover, understanding steady state voltage variation is essential for the integration of renewable energy sources into the grid. As more wind and solar power plants come online, they introduce new dynamics to the electrical system. These sources can cause voltage variations due to their intermittent nature, which must be managed effectively to maintain grid stability. Engineers employ advanced modeling and simulation tools to predict and analyze steady state voltage variation in these scenarios, ensuring that the grid can handle the influx of renewable energy without compromising reliability.In practical applications, measuring steady state voltage variation involves using specialized instruments such as oscilloscopes and multimeters. These devices allow engineers to capture voltage waveforms and analyze their behavior over time. By examining the data collected, engineers can identify patterns and make informed decisions about necessary adjustments to the system. This process is vital in industries ranging from manufacturing to telecommunications, where consistent voltage levels are critical for optimal performance.In conclusion, the concept of steady state voltage variation plays a significant role in the field of electrical engineering. It encompasses the voltage fluctuations observed in a circuit once it has stabilized after external influences. Understanding and managing these variations is essential for ensuring system reliability, particularly in the context of modern power systems that incorporate renewable energy sources. As technology continues to evolve, so too will the methods used to monitor and control steady state voltage variation, paving the way for more resilient and efficient electrical systems.

在电气工程中，稳态电压变化的概念对于理解电气系统在稳定条件下的行为至关重要。这个术语指的是在系统在受到外部影响或干扰后达到平衡时，电压水平发生的变化。简单来说，它描述了当电路稳定在一致的操作状态时，可以观察到的电压波动。要理解稳态电压变化，首先必须考虑电路的性质。当电路通电时，各种因素如负载变化、开关事件和环境条件会引起暂时的电压变化。然而，一旦这些因素稳定，电路就会达到“稳态”，在此状态下电压水平变得相对恒定。工程师在这一阶段特别关注稳态电压变化，以确保系统在可接受的范围内运行。监测稳态电压变化的重要性不容小觑。例如，在电力分配系统中，显著的电压变化可能导致设备故障、效率降低，甚至对敏感电子设备造成损害。因此，工程师必须设计能够适应这些变化的系统，同时保持整体稳定性。这涉及到实施各种控制策略，如电压调节技术，以减轻外部干扰的影响。此外，理解稳态电压变化对于将可再生能源源纳入电网也至关重要。随着越来越多的风能和太阳能发电厂上线，它们为电气系统引入了新的动态。这些能源由于其间歇性特性可能导致电压变化，必须有效管理，以维持电网的稳定性。工程师利用先进的建模和仿真工具来预测和分析这些场景中的稳态电压变化，确保电网能够处理可再生能源的涌入，而不影响可靠性。在实际应用中，测量稳态电压变化涉及使用专用仪器，如示波器和万用表。这些设备允许工程师捕获电压波形并分析其随时间的行为。通过检查收集的数据，工程师可以识别模式，并就系统所需的调整做出明智的决策。这个过程在从制造业到电信等行业中至关重要，因为一致的电压水平对最佳性能至关重要。总之，稳态电压变化的概念在电气工程领域发挥着重要作用。它涵盖了电路在外部影响后稳定下来时观察到的电压波动。理解和管理这些变化对于确保系统的可靠性至关重要，尤其是在现代电力系统中，这些系统整合了可再生能源。随着技术的不断发展，用于监测和控制稳态电压变化的方法也将不断演进，为更具弹性和高效的电气系统铺平道路。