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Mai 12, 2025

DC/AC-Verhältnis erklärt: Was es bedeutet und der beste Bereich für Solarsysteme

3 min read

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What is DC/AC Ratio?

The DC/AC ratio, also known as the DC to AC ratio, refers to the ratio between the direct current (DC) rated power of a photovoltaic (PV) array and the alternating current (AC) rated output of an inverter.

Formula:

DC/AC Ratio= PV Array’s DC Power (kW) / Inverter’s AC Power (kW)

DC/AC Ratio Formula
DC/AC Ratio Formula

Example:

If a PV array has a rated DC capacity of 12kW and the inverter has an AC rated output of 10kW, the DC/AC ratio would be 1.2.

What Is the Ideal DC/AC Ratio?

In most cases, the ideal DC/AC ratio typically ranges between 1.2 and 1.4. However, the optimal value can vary based on local climate conditions, equipment costs, and specific project goals.

Application ScenarioRecommended DC/AC Ratio
Standard Residential or Commercial Solar Projects1.1 ~ 1.3
Cloudy Regions or Low Light Areas1.3 ~ 1.5
High-Sunlight RegionsAround 1.1 or slightly lower
Expensive Inverters and Cheap Panels (Economic Optimization)1.3 ~ 1.5
Cases Where Inverter Overloading Must Be Minimized1.1 or lower

Risks of a High DC/AC Ratio (>1.5)

Common Issues:

  • Clipping Loss: When sunlight is abundant, the inverter becomes overloaded and cannot convert all available DC power into AC, resulting in energy loss.
  • Equipment Stress: Prolonged high-load operation can shorten inverter lifespan.
  • Reduced ROI: Excess solar panel capacity is underutilized, lowering overall system returns.

Example:

If a system has a DC/AC ratio of 1.8 (18kW DC to 10kW AC inverter), during peak sunlight hours, the inverter can only output 10kW, and the extra 8kW is “clipped.”

Risks of a Low DC/AC Ratio (<1.0)

Common Issues:

  • Inverter Underutilization: AC capacity is not fully used, leading to investment waste.
  • Reduced Energy Yield: During peak sunlight, the system output is limited.
  • Higher System Costs: Oversized inverters result in higher initial investment and installation costs.

Example:

If a system has a DC/AC ratio of 0.8 (8kW DC to 10kW AC inverter), the inverter would often operate below its full capacity, leaving 2kW unused.

DC-Strom
DC-Strom

Key Factors to Balance When Designing DC/AC Ratio

  • 1. Clipping Tolerance: A small amount of clipping (e.g., less than 5% of annual hours) is often acceptable to achieve higher overall energy production.
  • 2. Temperature Impact: In high-temperature regions, PV module efficiency decreases, thus a higher DC/AC ratio can help compensate for losses.
  • 3. Inverter Technology: Some inverters allow short-term overloading (e.g., up to 110% rated output), offering more flexible system designs.

Real-World Optimization Case

In California, where solar irradiance is strong and temperatures are moderate, a solar plant was designed with a DC/AC ratio of 1.3. This setup achieved a 12% increase in annual energy production, with only 2% clipping losses, delivering the best overall economic return.

Conclusion

Designing the right DC/AC ratio is crucial for maximizing the efficiency, lifespan, and profitability of a solar PV system. By carefully balancing local conditions, equipment characteristics, and project goals, solar developers can significantly improve the overall performance and financial returns of their solar installations.

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