retardation of solar on side real time

简明释义

恒星时换算平时的减量

英英释义

例句

1.The research focused on the retardation of solar on side real time and its impact on energy efficiency.

这项研究集中在太阳能实时侧延迟及其对能效的影响。

2.Engineers implemented a new algorithm to calculate the retardation of solar on side real time more accurately.

工程师们实施了一种新算法，以更准确地计算太阳能实时侧延迟。

3.The software was updated to monitor the retardation of solar on side real time for better predictive analytics.

软件已更新，以监控太阳能实时侧延迟，以便进行更好的预测分析。

4.Understanding the retardation of solar on side real time is crucial for optimizing the performance of solar panels.

理解太阳能实时侧延迟对于优化太阳能电池板的性能至关重要。

5.The engineers discussed the retardation of solar on side real time during the project meeting to ensure efficient energy management.

工程师们在项目会议上讨论了太阳能实时侧延迟，以确保能量管理的有效性。

作文

In recent years, the concept of solar energy has gained significant attention due to its potential to provide a sustainable and renewable source of power. However, one of the challenges faced in harnessing solar energy effectively is the retardation of solar on side real time, which refers to the delays or lags in the collection and utilization of solar energy in real-time applications. Understanding this phenomenon is crucial for optimizing solar energy systems and improving their efficiency.Solar panels are designed to convert sunlight into electricity, but various factors can affect their performance. The retardation of solar on side real time can occur due to several reasons, including environmental conditions, technological limitations, and the inherent nature of solar energy generation. For instance, clouds, dust, and shading can significantly reduce the amount of sunlight that reaches solar panels, leading to a delay in energy production. Moreover, the efficiency of solar panels can vary depending on their orientation, angle, and the time of day, which complicates the real-time assessment of solar energy availability.To mitigate the effects of the retardation of solar on side real time, researchers and engineers are continually exploring innovative solutions. One approach is the development of smart solar tracking systems that adjust the position of solar panels throughout the day to maximize exposure to sunlight. These systems can significantly reduce the lag in energy production by ensuring that panels are always optimally oriented towards the sun.Additionally, advancements in energy storage technologies, such as batteries, play a vital role in addressing the challenges posed by the retardation of solar on side real time. By storing excess energy generated during peak sunlight hours, these systems can provide a steady supply of electricity even when solar generation is interrupted due to clouds or nighttime. This capability enhances the reliability of solar energy as a power source and helps to balance supply and demand in real-time.Furthermore, integrating artificial intelligence (AI) and machine learning algorithms into solar energy systems can improve the prediction and management of energy production. By analyzing historical weather data and real-time conditions, AI can help forecast solar energy availability, thereby reducing the impact of the retardation of solar on side real time. Such predictive analytics enable better planning and optimization of energy usage, ensuring that solar power is utilized efficiently.In conclusion, the retardation of solar on side real time presents a significant challenge in the field of solar energy. However, through innovative technologies, strategic planning, and real-time monitoring, it is possible to minimize these delays and enhance the overall efficiency of solar energy systems. As we continue to strive for a more sustainable future, understanding and addressing the implications of this phenomenon will be essential in maximizing the potential of solar energy as a reliable power source. By doing so, we can pave the way for a cleaner, greener world powered by renewable energy.

近年来，太阳能的概念因其提供可持续和可再生能源的潜力而受到广泛关注。然而，在有效利用太阳能的过程中，面临的一个挑战是实时侧面太阳能的滞后，即在实时应用中收集和利用太阳能的延迟或滞后。理解这一现象对于优化太阳能系统和提高其效率至关重要。太阳能电池板旨在将阳光转化为电能，但多种因素会影响其性能。实时侧面太阳能的滞后可能由于多种原因而发生，包括环境条件、技术限制以及太阳能发电的固有特性。例如，云层、灰尘和阴影会显著减少到达太阳能电池板的阳光量，导致能量生产的延迟。此外，太阳能电池板的效率可能会根据其朝向、角度和一天中的时间而有所不同，这使得实时评估太阳能可用性变得复杂。为了减轻实时侧面太阳能的滞后的影响，研究人员和工程师们不断探索创新解决方案。一种方法是开发智能太阳能跟踪系统，这些系统在一天中调整太阳能电池板的位置，以最大限度地增加阳光照射。这些系统可以通过确保电池板始终朝向太阳的最佳方向，显著减少能量生产的滞后。此外，能源存储技术的进步，如电池，对于应对实时侧面太阳能的滞后所带来的挑战至关重要。通过储存在峰值阳光时段产生的多余能量，这些系统可以在太阳能发电因云层或夜晚中断时提供稳定的电力供应。这种能力增强了太阳能作为电源的可靠性，并有助于实时平衡供需。此外，将人工智能（AI）和机器学习算法集成到太阳能系统中，可以改善能源生产的预测和管理。通过分析历史天气数据和实时条件，人工智能可以帮助预测太阳能的可用性，从而减少实时侧面太阳能的滞后的影响。这种预测分析能够更好地规划和优化能源使用，确保太阳能得到高效利用。总之，实时侧面太阳能的滞后在太阳能领域提出了重大挑战。然而，通过创新技术、战略规划和实时监测，可以最小化这些延迟，提高太阳能系统的整体效率。随着我们继续追求更可持续的未来，理解和解决这一现象的影响对于最大化太阳能作为可靠电源的潜力至关重要。通过这样做，我们可以为一个由可再生能源驱动的更清洁、更绿色的世界铺平道路。