Robert Kohrs scite author profile

The German Federal Government wants to establish Germany as a leading market for electric mobility. Potential environmental benefits and changes in the economic framework conditions of the energy sector are described in this paper. In order to quantify the electricity split which is actually used for charging electric vehicles, two economic models for the energy sector, a model for the market penetration of electric vehicles, a vehicle model and an LCA model are brought together. Based on an assumed dynamic increase of electric vehicles to 12 million in 2030, an additional electricity demand of about 18 TWh is calculated. If the vehicles are charged directly after their last daily trip, the peak load increases by 12% despite the small increase in electricity demand. First model calculations for the development of the European power generation system show that the direct impact on the construction of new power plants remains low even until 2030. An impact of electric mobility on CO2 certificate prices can only be seen from 2025 onwards and is limited to an increase in certificate prices by a maximum of 8 % in 2030. An optimisation is possible with intelligent charging strategies: The peak load without demand side management can be reduced by 5 GW and about 600 GWh of additional wind energy can used which would otherwise have been throttled due to feed-in management—about 3.5 % of the total electricity demand of electric vehicles. On the other hand, demand side management leads to more coal power plants instead of gas power plants being used to meet the additional electricity demand. If additional renewable sources are installed along with demand side management, the electricity for electric vehicles is almost carbon free. This is also reflected in the life cycle balance of electric vehicles which also includes vehicle and battery production: With today’s average electricity split in Germany, the greenhouse gas emissions of electric vehicles are about comparable to vehicles with conventional combustion engines. However, the electricity split in 2030 or the use of additional renewable energy sources lead to a significant advantage in the greenhouse gas balance

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Progress towards a large area, thin DEPFET detector module

Fischer

Andricek²,

Herrmann³

et al. 2007

Nuclear Instruments and Methods in Physics Research Section A:

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DEPFET, a monolithic active pixel sensor for the ILC

Velthuis

Kohrs

Mathes

et al. 2007

Nuclear Instruments and Methods in Physics Research Section A:

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Clear-performance of linear DEPFET devices

Sandow

Andricek

Fischer³

et al. 2006

Nuclear Instruments and Methods in Physics Research Section A:

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Robert Kohrs

A DEPFET Based Beam Telescope With Submicron Precision Capability

Elektroautos in einer von erneuerbaren Energien geprägten Energiewirtschaft

Progress towards a large area, thin DEPFET detector module

DEPFET, a monolithic active pixel sensor for the ILC

Clear-performance of linear DEPFET devices

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