Daniel Scharrer, M. Sc.
Starting 2010, Daniel Scharrer studied Energy Engineering at the FAU Erlangen-Nuremberg and successfully completed his studies in 2016. During his studies, he worked in the Department for Surface Technology of the Schaeffler GmbH in Herzogenaurach and for the Chair of Energy Process Engineering in Nuremberg. After a long stay abroad, he has been working as a research assistant at the Chair of Computer Science 7 for Computer Networks and Communication Systems since 2017. With the focus on Energy Process Engineering during his master’s degree, he is now working on the implementation of thermal components in the i7-AnyEnergy simulation model.
Life Cycle Assessment of a Reversible Heat Pump –
Organic Rankine Cycle – Heat Storage System with
Geothermal Heat Supply
In: Energies 13 (2020), p. 3253
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Simulation of Part Load Behaviour of Pumped Thermal Energy Storages with Real Load Profile
IRES 2019 (Düsseldorf, 2019-03-12 - 2019-03-14)
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Properties of Reversible Heat Pump ORC Energy Storage Systems for Base Load Generation
IRES 2018 - 12th International Renewable Energy Storage Conference (Düsseldorf, 2018-03-13 - 2018-03-15)
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Reversible heat pump-organic rankine cycle systems for the storage of renewable electricity
In: Energies 11 (2018), Article No.: en11061352
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Dynamic Simulation of Energy Flows and Storage of Waste Heat from Data Centers and of the Integration of Large Storage Systems in Local Heating Networks
(Third Party Funds Group – Sub project)Overall project: Energie Campus Nürnberg 2
Term: 2017-01-01 - 2019-12-31
Funding source: Bayerische StaatsministerienThe share of electricity from photovoltaics in the electricity mix in Germany has been greatly expanded in recent years. In the near future, electricity generation from renewable energies and thus also solar generated electricity will continue to increase. At high solar radiation, this already leads to a local oversupply in the power grid, while the photovoltaic at night naturally can not contribute to the power supply. Ensuring the nightly base load at night is therefore largely ensured by fossil production from coal and lignite with corresponding CO2 emissions.
By using base load storage systems with low-temperature storage, the use of polluting thermal power plants should be reduced. During the day, heat from geothermal energy or industrial processes is upgraded with excess electricity from photovoltaics using heat pumps (HP) and stored in a low-temperature storage system. To generate nocturnal base load power, this heat energy is then removed from the storage via an Organic Rankine Cycle (ORC) process.
The aim of the project is the dynamic simulation of energy flows in HP-ORC heat storages that are integrated into the energy system and use excess heat and power. With the simulation models, the dimensioning and suitable operating modes for the economic operation of low-temperature storage systems should be investigated.