How the German Electricity Market Works, Its Challenges, and the Essential Role of Batteries
How the German Electricity Market Works, Its Challenges, and the Essential Role of Batteries
Mayur Andulkar
8 min read
Understanding the Basics of the Electricity Market
Electricity is a unique commodity: unlike most other goods, it cannot be easily stored in large quantities. This means that supply and demand must be perfectly balanced to ensure a stable grid. In Germany, this task falls to four major Transmission System Operators (TSOs) and over 800 distribution grid operators who work together to keep the grid frequency at a stable 50 hertz, critical for machines and devices to function correctly.
Grid operators are constantly on alert, ready to act if the grid frequency shifts. When there's too much energy and frequency rises, they may cut back on the feed-in by switching off certain generators. If the frequency drops, indicating a shortfall, they activate reserves to bring it back up. However, the rise of renewable energy sources, like wind and solar, brings a new challenge: these sources cannot be controlled as flexibly as traditional fossil fuel plants, making grid balancing even more complex.
The Structure of the Electricity Market
The electricity market is divided into several sub-markets, each with its specific timeframes and purposes:
Long-Term Market (Forwards/Futures): In this market, contracts are signed to purchase electricity months or even years in advance. This enables energy providers to hedge against price changes.
Short-Term Market (Day-Ahead and Intraday Markets): Energy is bought closer to the time of use, either a day ahead or within hours on the same day. On the day-ahead market, energy is traded 24 hours in advance, allowing for relatively accurate predictions based on weather forecasts and demand. The intraday market operates in shorter windows, providing flexibility to address unexpected fluctuations.
Balancing Energy Market: This market is crucial for stabilizing the grid during sudden disruptions. It consists of three levels:
Primary Control Power: Reacts on a second-by-second basis, typically using power plants with built-in buffer capacity.
Secondary Control Power and Minute Reserves: These reserves respond within minutes to balance the grid in cases of sudden demand or supply changes. Industrial sites can even disconnect temporarily, freeing up power for other areas in exchange for compensation.
The costs associated with balancing the grid are significant and ultimately impact the electricity prices consumers pay.
The Influence of Renewable Energy and Geographic Imbalance
As Germany increases its share of renewable energy, managing supply and demand becomes more complex. Renewable sources, like solar and wind, depend on weather conditions, while fossil fuel plants can be adjusted as needed. Even with highly accurate forecasting, demand and generation do not always match perfectly. Germany’s consumption pattern includes typical daily peaks around midday and early evening, with the lowest demand occurring overnight.
A further complication comes from the geographic distribution of generation and consumption. Northern Germany produces an abundance of wind energy, but most of the demand lies in the industrial hubs of the south. Moving energy from north to south strains the grid, sometimes requiring energy to be rerouted through neighboring countries or “redispatched” at a high cost, which reached €1.9 billion in Germany in 2022.
Electricity Pricing and the Merit Order Principle
In Germany, electricity prices follow a “merit order” principle, where power sources are used in ascending order of their cost. Renewable energy sources like wind and solar are typically the cheapest and are prioritized. If renewables aren’t enough to meet demand, more expensive sources, such as coal and gas plants, are added until supply meets demand. All suppliers receive the price of the most expensive source needed to fulfill demand at a given time.
The growing share of renewables has increased price volatility. For instance, when solar production peaks at midday, prices sometimes drop to negative, meaning producers pay consumers to use the surplus energy. This highlights the need for more flexible solutions to align renewable production with consumption.
Optimizing the Electricity Market
Several strategies can help address these market challenges:
Path 1: Flexible Consumption
Shifting electricity use to times of high renewable production could greatly improve market efficiency. Flexible tariffs and smart meters, which allow consumers to monitor and adjust their usage, are essential for this strategy. While many European countries like France and Italy have smart meter adoption rates above 90%, Germany lags behind, particularly for small businesses and private consumers. With more smart meters, consumers could better match their electricity use with renewable energy production, reducing grid strain.
Path 2: Price Zones
Creating regional price zones within Germany could also help balance the market. For example, the price might be lower in the north, where there’s ample wind power, and higher in the south, where demand is greater. This could encourage industries to locate production near renewable energy sources or incentivize further renewable investment in the south.
Path 3: Large-Scale Energy Storage with Batteries
Large-scale battery storage is an increasingly viable solution for integrating renewables. Batteries can store excess energy when renewable production is high and release it when demand spikes, as is the case in California. There, investments in solar and battery storage have reduced the need for fossil fuel plants during peak hours. This approach reduces prices by stabilizing supply without requiring new regulations, as batteries offer lower marginal costs and follow market demand automatically.
The Role of Batteries in the Future Electricity Market
Batteries are particularly valuable in the balancing energy market, where they help smooth fluctuations from renewable sources, reducing the need for expensive redispatching. By storing excess energy, batteries can reduce costs and help maintain grid stability. As battery costs decrease, they become more economically viable for grid operators, developers, and private companies alike.
Re-Twin Energy supports the full lifecycle of battery energy storage systems, from initial investment analysis to electricity trading. Our goal is to ensure a stable supply of renewable power while maximizing returns for battery owners. With well-integrated storage solutions, grid operators can better match renewable energy generation with demand patterns, moving the electricity market toward a more sustainable, balanced future.
Conclusion
Batteries play a vital role in the evolving electricity market. By providing storage capacity for renewable energy, they enable a more flexible, resilient, and cost-effective grid. With advances in technology and supportive policies, batteries could be the key to achieving a cleaner and more sustainable energy system for the future.
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