grid coupling

简明释义

栅极耦合

英英释义

例句

1.By optimizing grid coupling 电网耦合, we can reduce energy losses during distribution.

通过优化电网耦合，我们可以减少分配过程中的能源损失。

2.In renewable energy projects, grid coupling 电网耦合 allows for better integration of solar and wind power into the existing grid.

在可再生能源项目中，电网耦合使太阳能和风能更好地融入现有电网。

3.Engineers designed a new model that enhances grid coupling 电网耦合 between different energy sources.

工程师设计了一种新模型，增强了不同能源之间的电网耦合。

4.The research focused on the effects of grid coupling 电网耦合 on stability during peak load times.

研究集中在高峰负载期间电网耦合对稳定性的影响。

5.The efficiency of the power transmission system was significantly improved by implementing grid coupling 电网耦合 technologies.

通过实施电网耦合技术，电力传输系统的效率显著提高。

作文

In the realm of engineering and physics, the term grid coupling refers to the method of connecting different systems or components through a common grid structure. This concept is particularly significant in fields such as renewable energy, telecommunications, and electrical engineering. The importance of grid coupling lies in its ability to facilitate efficient energy transfer and data communication between various entities, ensuring that they can work together seamlessly.To better understand grid coupling, let us consider its application in renewable energy systems. For instance, in a solar power plant, multiple solar panels are connected to a grid that distributes the generated electricity. Here, grid coupling is crucial because it allows the energy produced by individual panels to be aggregated and fed into the main power grid. This not only maximizes the efficiency of energy production but also enhances the reliability of power supply to consumers.Moreover, grid coupling plays a vital role in the integration of various energy sources. In modern smart grids, different forms of energy generation, such as wind, solar, and hydroelectric power, are interconnected through a unified grid. This interconnection enables the optimization of energy distribution based on real-time demand and supply conditions. By employing advanced technologies like smart meters and sensors, grid coupling ensures that energy flows smoothly from one source to another, reducing waste and improving overall system performance.In telecommunications, grid coupling is equally important. It involves the integration of various communication networks, allowing them to share resources and information effectively. For example, when a mobile network operator collaborates with an internet service provider, grid coupling enables seamless connectivity for users. This collaboration ensures that data can be transmitted efficiently across different platforms, enhancing user experience and service reliability.The significance of grid coupling extends beyond technical aspects; it also has economic implications. By optimizing energy distribution and communication networks, grid coupling can lead to cost savings for both providers and consumers. For energy companies, a well-coupled grid means less energy loss during transmission, which translates to lower operational costs. Similarly, in telecommunications, effective grid coupling can reduce infrastructure expenses and improve service delivery, ultimately benefiting end-users.However, implementing grid coupling is not without challenges. One major hurdle is the need for standardization across different technologies and systems. Without a common framework, integrating disparate components can lead to inefficiencies and increased costs. Additionally, as systems become more interconnected, the complexity of managing these connections grows, necessitating advanced management tools and strategies.In conclusion, grid coupling serves as a fundamental principle in various fields, enabling efficient energy transfer and communication. Its applications in renewable energy and telecommunications highlight its importance in modern society. As we continue to advance technologically, the need for effective grid coupling will only increase, making it essential for engineers and scientists to develop innovative solutions that address the challenges associated with it. Ultimately, mastering the concept of grid coupling will pave the way for a more interconnected and efficient future, benefiting both industries and consumers alike.

在工程和物理学领域，术语grid coupling指的是通过共同的网格结构连接不同系统或组件的方法。这个概念在可再生能源、电信和电气工程等领域尤为重要。grid coupling的重要性在于它能够促进不同实体之间高效的能量传输和数据通信，确保它们能够无缝协作。为了更好地理解grid coupling，让我们考虑它在可再生能源系统中的应用。例如，在一个太阳能发电厂中，多个太阳能电池板连接到一个分配生成电力的电网。在这里，grid coupling至关重要，因为它允许各个电池板产生的能量被汇总并送入主电网。这不仅最大化了能源生产的效率，还增强了对消费者的电力供应的可靠性。此外，grid coupling在各种能源源的整合中也发挥着至关重要的作用。在现代智能电网中，不同形式的能源生成，如风能、太阳能和水电，通过统一的电网互联。这种互联使得根据实时需求和供应条件优化能源分配成为可能。通过采用先进的技术，如智能表和传感器，grid coupling确保能量从一个来源流向另一个来源，减少浪费，提高整体系统性能。在电信领域，grid coupling同样重要。它涉及到各种通信网络的整合，使它们能够有效地共享资源和信息。例如，当一家移动网络运营商与互联网服务提供商合作时，grid coupling使用户能够实现无缝连接。这种合作确保数据能够在不同平台间高效传输，提高用户体验和服务可靠性。grid coupling的重要性不仅体现在技术方面，还具有经济意义。通过优化能源分配和通信网络，grid coupling可以为提供者和消费者带来成本节约。对于能源公司来说，一个良好耦合的电网意味着在传输过程中能量损失较少，从而降低运营成本。同样，在电信行业，有效的grid coupling可以减少基础设施费用，提高服务质量，最终惠及终端用户。然而，实施grid coupling并非没有挑战。一个主要障碍是需要在不同技术和系统之间进行标准化。如果没有共同的框架，整合不同的组件可能导致效率低下和成本增加。此外，随着系统的互联程度加深，管理这些连接的复杂性也在增加，这需要先进的管理工具和策略。总之，grid coupling作为一个基本原则，在各个领域中发挥着作用，使得高效的能量传输和通信成为可能。它在可再生能源和电信中的应用突显了它在现代社会中的重要性。随着我们技术的不断进步，对有效的grid coupling的需求只会增加，这使得工程师和科学家们必须开发创新的解决方案，以应对与之相关的挑战。最终，掌握grid coupling的概念将为一个更加互联和高效的未来铺平道路，惠及各个行业和消费者。