Az éghajlati viszonyok hatása a napenergia-elemek tárolórendszereire

The impact of climate conditions on the performance of solar battery storage systems is significant and can be illustrated in several key areas:

Effects of Sunshine Hours

• The electricity generation capacity of solar panels is closely related to sunshine hours. The longer the sunshine hours, the more light the solar panels receive, leading to higher electricity output. For example, Xinhua County averages over 190 hours of sunshine each year, with periods from March to June having sunshine hours exceeding 200 hours, peaking at 264.1 hours in May. This prolonged sunshine is conducive to the efficient operation of solar battery storage systems.
• Increased sunshine hours directly improve the system’s daily utilization hours, which shows a significant positive correlation. As sunshine hours increase, the system can charge for a longer duration, thus enhancing the overall efficiency of the storage system.

Effects of Solar Radiation Intensity

• Solar radiation intensity is a key factor affecting solar panel electricity generation. The stronger the radiation, the higher the output power of the solar panels. For instance, the total annual radiation in the Dunhuang region is 6882 MJ/m², with a daily average of 18.86 MJ/m², making it one of the richest areas in solar resources in China.
• Variations in solar radiation intensity under different weather conditions can lead to fluctuations in system performance. On sunny days, solar radiation intensity is at its peak, with the system’s thermal collection efficiency and energy conversion efficiency reaching up to 53.0% and 50.7%, respectively.

Effects of Temperature

• Temperature significantly affects the electrical performance of solar panels. Generally, as temperature increases, the open circuit voltage of solar panels decreases, while the short circuit current may slightly increase, but the maximum power significantly decreases. For instance, when the temperature of crystalline silicon solar cells exceeds 25°C, every 1°C rise results in about a 1% loss in power.
• High temperatures can lead to increased surface temperature of photovoltaic panels, further affecting their efficiency. For example, in the Dunhuang region, daytime temperatures can exceed 25°C from April to October, reaching above 30°C between May and September.

Effects of Relative Humidity

• Lower relative humidity enhances photovoltaic power. Studies indicate that every 1% reduction in relative humidity increases photovoltaic power by 27.35 kW, meaning that solar battery storage systems perform better in drier climates.
• High relative humidity can reduce the output power of photovoltaic systems because the moisture in high-humidity environments absorbs part of the solar radiation, reducing illumination on the solar panels.

Effects of Wind Speed

• Wind speed significantly affects the cooling of solar panels. Appropriate wind speeds can remove heat from the panel’s surface, lowering temperatures and thereby improving electricity generation efficiency. However, excessively high wind speeds may cause mechanical damage or other problems, which need to be considered in system design.
• Changes in wind speed also influence dust accumulation on photovoltaic systems. Higher wind speeds can reduce dust accumulation, improving the cleanliness of solar panels and consequently enhancing energy generation efficiency.

Effects of Dust Accumulation

• Dust accumulation is a significant factor impacting the energy efficiency of photovoltaic systems. Dust can block solar panels and reduce illumination, leading to lower output power. Research shows that dust affects photovoltaic efficiency through shading and optical loss effects.
• Air pollution, precipitation, and wind all impact dust generation and distribution. High air pollution leads to more dust; precipitation can wash off dust; meanwhile, lower dust deposition occurs with high wind speeds.

Comprehensive Impact

• The combined effects of climate conditions need to be considered in the design and operation of solar energy systems. Mathematical models and simulation analysis can help to better understand performance variations under different climate conditions.
• Meteorological forecasting technologies can predict weather changes in advance, optimizing charging and discharging strategies for systems.

Recommendation for Automated Cleaning Machines

To ensure optimal performance of solar energy systems, it is highly recommended to use automated cleaning machines. These machines can efficiently keep solar panels clean from dust, dirt, and debris, which is crucial for maintaining high energy efficiency and production. Regular maintenance through automation not only reduces manual labor but also ensures that the panels receive maximum sunlight exposure.

In conclusion, climate conditions have a wide-ranging and complex impact on the performance of solar energy battery storage systems, necessitating a comprehensive consideration of these factors in system design and operation to ensure efficient, reliable, and economical performance.