delay angle

简明释义

滞后角

英英释义

例句

1.The pilot was trained to calculate the delay angle during navigation.

飞行员接受过在导航过程中计算延迟角的培训。

2.In telecommunications, understanding the delay angle can help improve network performance.

在电信领域，理解延迟角可以帮助提高网络性能。

3.Adjusting the delay angle can significantly reduce interference in audio systems.

调整延迟角可以显著减少音频系统中的干扰。

4.The technician measured the delay angle to ensure proper alignment of the satellite dish.

技术员测量了延迟角以确保卫星天线的正确对准。

5.The engineer adjusted the delay angle to optimize the signal transmission.

工程师调整了延迟角以优化信号传输。

作文

In the realm of physics and engineering, the term delay angle refers to a specific phase difference that occurs in alternating current (AC) circuits. More specifically, it describes the angle by which the current waveform lags behind the voltage waveform. This concept is crucial for understanding how electrical systems operate, particularly in the context of inductive loads such as motors and transformers. When we analyze the behavior of these devices, it becomes evident that the delay angle plays a significant role in determining their efficiency and performance.To elaborate further, the delay angle is often measured in degrees and is a critical factor in power factor calculations. The power factor is a measure of how effectively electrical power is being converted into useful work output. A lower power factor indicates that a larger portion of the electrical energy is wasted, primarily due to the effects of the delay angle. Therefore, engineers strive to minimize this angle in order to optimize the performance of electrical systems.The implications of the delay angle extend beyond just technical specifications; they also have real-world applications. For instance, in industrial settings, machines that operate with a high delay angle may experience overheating or reduced lifespan due to inefficient energy usage. Consequently, understanding and managing the delay angle can lead to significant cost savings and improved reliability in machinery.Moreover, the delay angle is not merely an abstract concept confined to textbooks; it is a tangible factor that engineers must consider during the design and implementation of electrical systems. By incorporating strategies to reduce the delay angle, such as using capacitors to counteract inductive effects, engineers can enhance the overall efficiency of the system. This proactive approach not only benefits the equipment but also contributes to a more sustainable energy landscape by reducing waste.In addition to its importance in engineering, the delay angle also has implications in the field of renewable energy. As the world shifts towards more sustainable energy sources, understanding the dynamics of AC circuits becomes increasingly relevant. For example, in wind and solar energy systems, the delay angle can affect how energy is fed into the grid, impacting the overall stability and reliability of the energy supply. Thus, addressing the delay angle is essential for integrating renewable energy technologies into existing power systems.In conclusion, the term delay angle encapsulates a fundamental aspect of electrical engineering that influences both the performance of devices and the efficiency of energy consumption. Its significance cannot be overstated, as it directly affects the functionality and sustainability of electrical systems. By gaining a deeper understanding of the delay angle and its implications, engineers and technicians can make informed decisions that lead to improved performance and reduced energy waste. Ultimately, the study of the delay angle is not just a theoretical exercise; it is a vital component of modern engineering practices that shapes the future of energy consumption and efficiency.

在物理和工程领域，术语延迟角指的是交变电流（AC）电路中发生的特定相位差。更具体地说，它描述了电流波形滞后于电压波形的角度。这个概念对于理解电气系统的运作至关重要，特别是在电感负载如电动机和变压器的背景下。当我们分析这些设备的行为时，很明显延迟角在决定它们的效率和性能方面发挥着重要作用。进一步阐述，延迟角通常以度数来测量，是功率因数计算中的关键因素。功率因数是衡量电能如何有效转化为有用工作输出的指标。较低的功率因数表明，电能的较大部分被浪费，主要是由于延迟角的影响。因此，工程师努力减少这个角度，以优化电气系统的性能。延迟角的影响不仅限于技术规格；它们也具有现实世界的应用。例如，在工业环境中，具有高延迟角的机器可能由于能量使用效率低下而经历过热或缩短寿命。因此，理解和管理延迟角可以带来显著的成本节约和设备可靠性的提高。此外，延迟角并不仅仅是一个局限于教科书的抽象概念；它是工程师在设计和实施电气系统时必须考虑的一个切实因素。通过采用减少延迟角的策略，例如使用电容器来抵消电感效应，工程师可以增强系统的整体效率。这种主动的方法不仅有利于设备，也通过减少浪费，有助于更可持续的能源格局。除了在工程中的重要性之外，延迟角在可再生能源领域也具有重要意义。随着世界向更可持续的能源来源转变，理解交流电路的动态变得越来越相关。例如，在风能和太阳能系统中，延迟角可能影响能量如何输入电网，从而影响整体的稳定性和可靠性。因此，解决延迟角的问题对于将可再生能源技术整合到现有电力系统中至关重要。总之，术语延迟角概括了电气工程中的一个基本方面，影响着设备的性能和能量消耗的效率。它的重要性不容小觑，因为它直接影响着电气系统的功能和可持续性。通过深入了解延迟角及其影响，工程师和技术人员可以做出明智的决策，从而提高性能和减少能量浪费。最终，研究延迟角不仅仅是一个理论练习；它是现代工程实践的一个重要组成部分，塑造着未来的能源消费和效率。