intermittent current

简明释义

断续电流

英英释义

例句

1.We need to install a stabilizer to handle the intermittent current (间歇性电流) in the electrical system.

我们需要安装一个稳压器来处理电气系统中的间歇性电流（间歇性电流）。

2.The technician explained that the intermittent current (间歇性电流) could affect the performance of the machinery.

技术人员解释说，间歇性电流（间歇性电流）可能会影响机器的性能。

3.During the storm, we experienced intermittent current (间歇性电流) which caused fluctuations in our power supply.

在暴风雨期间，我们经历了间歇性电流（间歇性电流），这导致我们的电力供应波动。

4.The solar panel system can manage intermittent current (间歇性电流) from varying sunlight conditions.

太阳能电池板系统可以管理来自不同阳光条件的间歇性电流（间歇性电流）。

5.The device was designed to operate under conditions of intermittent current (间歇性电流) to ensure energy efficiency.

该设备设计用于在间歇性电流（间歇性电流）的条件下工作，以确保能效。

作文

The concept of intermittent current refers to a type of electrical current that is not constant but rather fluctuates or varies over time. This phenomenon can be observed in various applications, particularly in renewable energy systems like solar panels and wind turbines. In these systems, the generation of electricity is often dependent on environmental conditions, leading to an intermittent current that can pose challenges for energy storage and distribution. Understanding how to manage and utilize this type of current is essential for maximizing the efficiency and reliability of renewable energy sources.In solar energy systems, for instance, the output of electricity is heavily influenced by sunlight availability. During sunny days, the solar panels generate a significant amount of electricity, while on cloudy days or at night, the output drops dramatically. This creates an intermittent current that requires careful planning and infrastructure to ensure a continuous power supply. Energy storage solutions, such as batteries, play a critical role in mitigating the effects of this variability by storing excess energy generated during peak sunlight hours for use during periods of low generation.Similarly, wind energy generation is also subject to intermittent current. Wind speeds can fluctuate significantly, leading to varying levels of electricity production. In regions where wind energy is a primary source of power, grid operators must account for these fluctuations to maintain a stable energy supply. This often involves integrating multiple energy sources and employing advanced forecasting techniques to predict when and how much energy will be generated.The challenge of managing intermittent current extends beyond just renewable energy. It also affects traditional power generation methods. For example, during peak demand periods, utilities may rely on quick-start generators that can ramp up production rapidly. However, if these generators are not properly synchronized with the main grid, it can lead to instability and outages. Therefore, understanding the nature of intermittent current is crucial for all forms of electricity generation.Furthermore, the rise of smart grid technology offers promising solutions to address the challenges posed by intermittent current. Smart grids utilize advanced communication and automation technologies to enhance the efficiency and reliability of electricity distribution. By incorporating real-time data and analytics, utilities can better predict energy demand and supply, allowing them to respond more effectively to fluctuations in intermittent current. This not only improves the stability of the grid but also enhances the integration of renewable energy sources.In conclusion, the term intermittent current encapsulates a significant aspect of modern energy systems, particularly in the context of renewable energy. As we continue to transition towards cleaner energy sources, understanding and managing intermittent current will be vital for ensuring a reliable and sustainable energy future. By investing in energy storage, smart grid technologies, and diversified energy portfolios, we can harness the full potential of renewable energy while mitigating the challenges associated with its inherent variability.

“间歇电流”这一概念指的是一种电流，其性质不是恒定的，而是随着时间的推移而波动或变化。这种现象可以在各种应用中观察到，尤其是在可再生能源系统中，如太阳能电池板和风力涡轮机。在这些系统中，电力的生成往往取决于环境条件，导致出现“间歇电流”，这对能源储存和分配构成了挑战。理解如何管理和利用这种类型的电流对于最大化可再生能源的效率和可靠性至关重要。例如，在太阳能系统中，电力的输出受到阳光可用性的严重影响。在阳光明媚的日子里，太阳能电池板产生大量电力，而在多云的日子或夜间，输出则急剧下降。这就产生了“间歇电流”，需要仔细规划和基础设施，以确保持续的电力供应。能源储存解决方案，如电池，在缓解这种可变性方面发挥着关键作用，可以在高峰阳光时段储存多余的电力，以便在低发电期间使用。同样，风能发电也会受到“间歇电流”的影响。风速可能会显著波动，导致电力生产水平不同。在以风能为主要电源的地区，电网运营商必须考虑这些波动，以保持稳定的能源供应。这通常涉及整合多个能源来源，并采用先进的预测技术，以预测何时以及产生多少能量。管理“间歇电流”的挑战不仅限于可再生能源。它还影响传统的发电方式。例如，在需求高峰期，公用事业公司可能依赖快速启动的发电机，这些发电机能够迅速增加产量。然而，如果这些发电机没有与主电网正确同步，就可能导致不稳定和停电。因此，理解“间歇电流”的性质对于所有形式的电力生成至关重要。此外，智能电网技术的兴起为应对“间歇电流”所带来的挑战提供了有希望的解决方案。智能电网利用先进的通信和自动化技术来提高电力分配的效率和可靠性。通过整合实时数据和分析，公用事业公司可以更好地预测能源需求和供应，使他们能够更有效地应对“间歇电流”的波动。这不仅改善了电网的稳定性，还增强了可再生能源的整合。总之，“间歇电流”这一术语概括了现代能源系统中的一个重要方面，特别是在可再生能源的背景下。随着我们继续向清洁能源转型，理解和管理“间歇电流”将对确保可靠和可持续的能源未来至关重要。通过投资能源储存、智能电网技术和多元化的能源组合，我们可以充分利用可再生能源的潜力，同时减轻其固有可变性所带来的挑战。