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This analysis gives insight what optimal capacity (kWh) a electrical storage system could have for a household/building with PV and a certain consumption pattern. Goal is to reach as much autoconsumption as possible with a system with an optimal cost (because a very big battery will of course reach the best autoconsumption but is financially bullshit)
Input:
Timeseries Import from Grid, Export from Grid, PV production
Typical pricing / kWh for storage systems
Process:
Simulation of different systems with different cost/capacities/max charge-discharge power
Output:
% autoconsumption to reach with the optimal system (price/performance)
Graphs in Demo: linegraph of simulation of charge/discharge power of battery and linegraphs of inputs (also power) changed with simulated storage interaction
The text was updated successfully, but these errors were encountered:
This is one for the longer term :-)
This analysis gives insight what optimal capacity (kWh) a electrical storage system could have for a household/building with PV and a certain consumption pattern. Goal is to reach as much autoconsumption as possible with a system with an optimal cost (because a very big battery will of course reach the best autoconsumption but is financially bullshit)
Input:
Timeseries Import from Grid, Export from Grid, PV production
Typical pricing / kWh for storage systems
Process:
Simulation of different systems with different cost/capacities/max charge-discharge power
Output:
% autoconsumption to reach with the optimal system (price/performance)
Graphs in Demo: linegraph of simulation of charge/discharge power of battery and linegraphs of inputs (also power) changed with simulated storage interaction
The text was updated successfully, but these errors were encountered: