Abstract
Model-based scenario analyses of future energy systems often come to deviating results and conclusions when different models are used. This may be caused by heterogeneous input data and by inherent differences in model formulations. The representation of technologies for the conversion, storage, use, and transport of energy is usually stylized in comprehensive system models in order to limit the size of the mathematical problem, and may substantially differ between models. This paper presents a systematic comparison of nine power sector models with sector coupling. We analyze the impact of differences in the representation of technologies, optimization approaches, and further model features on model outcomes. The comparison uses fully harmonized input data and highly simplified system configurations to isolate and quantify model-specific effects. We identify structural differences in terms of the optimization approach between the models. Furthermore, we find substantial differences in technology modeling primarily for battery electric vehicles, reservoir hydro power, power transmission, and demand response. These depend largely on the specific focus of the models. In model analyses where these technologies are a relevant factor, it is therefore important to be aware of potential effects of the chosen modeling approach. For the detailed analysis of the effect of individual differences in technology modeling and model features, the chosen approach of highly simplified test cases is suitable, as it allows to isolate the effects of model-specific differences on results. However, it strongly limits the model’s degrees of freedom, which reduces its suitability for the evaluation of fundamentally different modeling approaches.
Highlights
To quantify the understanding of the effect of fundamental and smallscale modeling decisions on the results of temporally and spatially resolved power system models, our work was dedicated to the detailed analysis of nine models and their application in full harmonized but highly stylized test cases
The aggregated approach is sufficient for an approximate assessment of the role of hydro power in integrated future energy systems
Because it considers the interaction of power flow across all lines connected to a node, the direct current (DC) load flow approach is more suited when the focus is on analyzing the use of existing grid connections, especially in the evaluation of critical supply situations
Summary
The transformation of the energy system towards green technologies has to be accelerated. This requires a switch primarily to variable renewable energy (VRE) technologies such as wind and solar photovoltaics (PV), whose output strongly depends on regional and local weather conditions [2]. The need for system flexibility increases since power supply and demand have to be balanced in real-time to ensure the security of supply. This flexibility can be provided by different technologies, including controllable power plants, energy storage, transmission grids, or demand-side management [3]
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