grid conductance

简明释义

栅极电导

英英释义

例句

1.The increase in grid conductance has led to more efficient energy distribution.

增加的电网导电性使得能源分配更加高效。

2.A higher grid conductance can reduce transmission losses significantly.

更高的电网导电性可以显著减少传输损耗。

3.The new materials used in the grid have improved grid conductance.

在电网中使用的新材料改善了电网导电性。

4.Engineers are focused on optimizing grid conductance for renewable energy sources.

工程师们专注于优化可再生能源的电网导电性。

5.Researchers are studying how grid conductance affects the stability of the electrical network.

研究人员正在研究电网导电性如何影响电力网络的稳定性。

作文

Understanding the concept of grid conductance is crucial in the field of electrical engineering and renewable energy. The term refers to the measure of how easily electric current can flow through a grid system, which is essential for ensuring efficient energy distribution and consumption. In today's world, where the demand for electricity is ever-increasing, optimizing grid conductance can lead to significant improvements in energy efficiency and sustainability.To grasp the importance of grid conductance, one must first understand its role within the electrical grid. The electrical grid is a complex network that connects power plants to consumers, allowing electricity to be transmitted over long distances. The ability of this grid to conduct electricity efficiently is influenced by various factors, including the materials used in the transmission lines, the design of the grid, and the overall load placed on it.When we talk about grid conductance, we are essentially discussing the characteristics of these transmission lines and how well they can carry electrical current. High conductance means that less energy is lost as heat during transmission, which is a common issue in electrical systems. This loss occurs due to the resistance present in the conductors, which converts some of the electrical energy into thermal energy. Therefore, improving grid conductance can directly impact the efficiency of energy delivery.Moreover, with the integration of renewable energy sources such as solar and wind, understanding grid conductance becomes even more critical. Renewable energy sources often produce electricity in a decentralized manner, meaning that energy generation can occur at various locations rather than in a centralized power plant. This shift requires an adaptable grid that can handle varying loads and sources of energy. By enhancing grid conductance, the grid can better accommodate these fluctuations and ensure a stable supply of electricity.In addition to improving energy efficiency, increasing grid conductance can also contribute to reducing greenhouse gas emissions. When energy is lost during transmission, additional power plants may need to be brought online to meet demand, often resulting in increased fossil fuel consumption. By optimizing grid conductance, we can minimize these losses and reduce our reliance on carbon-intensive energy sources.Furthermore, advancements in technology are paving the way for smarter grids that can monitor and manage grid conductance in real-time. Smart grid technologies utilize sensors and data analytics to optimize energy flow and detect issues before they become significant problems. This proactive approach allows for better maintenance and management of the grid, leading to improved reliability and efficiency.In conclusion, the significance of grid conductance cannot be overstated. As the world moves towards a more sustainable energy future, understanding and improving the conductance of electrical grids will play a vital role in achieving energy efficiency, integrating renewable resources, and reducing environmental impacts. Engineers and policymakers must prioritize research and development in this area to create a resilient and efficient energy infrastructure that meets the needs of society while protecting our planet.

理解电网导电性的概念在电气工程和可再生能源领域至关重要。这个术语指的是电流在电网系统中流动的容易程度，这对于确保有效的能源分配和消费是必不可少的。在当今世界，电力需求不断增加，优化电网导电性可以显著提高能源效率和可持续性。要理解电网导电性的重要性，首先必须了解其在电网中的作用。电网是一个复杂的网络，将发电厂与消费者连接起来，允许电力在长距离内传输。这个电网导电电力的能力受到多种因素的影响，包括传输线使用的材料、网格的设计以及施加在其上的整体负载。当我们谈论电网导电性时，我们实际上是在讨论这些传输线的特性以及它们承载电流的能力。高导电性意味着在传输过程中损失的能量更少，这在电气系统中是一个常见问题。这种损失是由于导体中存在的电阻造成的，电阻将一些电能转换为热能。因此，改善电网导电性可以直接影响能源交付的效率。此外，随着可再生能源如太阳能和风能的整合，理解电网导电性变得更加关键。可再生能源通常以分散的方式产生电力，这意味着能源生成可以发生在不同的位置，而不是集中在一个发电厂。这一转变要求一个能够处理变化负载和能源来源的适应性电网。通过增强电网导电性，电网可以更好地适应这些波动，并确保电力供应的稳定性。除了提高能源效率外，增加电网导电性还可以有助于减少温室气体排放。当在传输过程中损失能量时，可能需要额外的发电厂上线以满足需求，这往往会导致化石燃料消费的增加。通过优化电网导电性，我们可以最小化这些损失并减少对碳密集型能源来源的依赖。此外，技术的进步为智能电网的出现铺平了道路，这些电网可以实时监测和管理电网导电性。智能电网技术利用传感器和数据分析来优化能源流动，并在问题变得重大之前检测到它们。这种主动的方法允许更好的维护和管理电网，从而提高可靠性和效率。总之，电网导电性的重要性不容小觑。随着世界朝着更可持续的能源未来迈进，理解和改善电网的导电性将在实现能源效率、整合可再生资源和减少环境影响方面发挥至关重要的作用。工程师和政策制定者必须优先考虑这一领域的研究和开发，以创建一个能够满足社会需求，同时保护我们星球的韧性和高效的能源基础设施。