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1.: Power Grid with Different Voltage Levels (created by Philipp Danner / CC BY SA 4.0)

1.: Power Grid with Different Voltage Levels (created by Philipp Danner / CC BY SA 4.0)

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Figure 1.1.: Prediction of PV Adoption in Germany until 2025; Agents...
Figure 1.3.: Chapter Structure and Dependencies
Figure 2.1.: Power Grid with Different Voltage Levels (created by...
Figure 2.2 illustrates the main concepts of voltage in terms of PQ as...
+22 Figure 2.2.: Illustration of Voltage Dip and a short supply...
E-Mobility Management: Towards a Grid-friendly Smart Charging Solution
Thesis
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  • Jul 2021
Replacing fossil-fueled vehicles with Electric Vehicles (EVs) poses new challenges for power distribution networks. Specifically speaking, the electrification of the mobility sector relies on the ability to process and analyze information on when, where, for how long, or how fast charging processes will take place. Nevertheless, such kind of inform...
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Context 1
... is transported via a network of ultra-high and high voltages to be distributed to individual grid areas and consumers through distribution networks. However, there are four different voltage levels according to IEC 60038 [28], as depicted in Figure 2.1: ultra-high voltage, high voltage, medium voltage, and low voltage. ...
Context 2
... that end, any vehicle using electrical energy partially or entirely for moving is called Electric Drive Vehicle (EDV). As depicted in Figure 2.3, they can be distinguished in supply line bound vehicles like trains, or trams, and gridindependent vehicles. ...
Context 3
... different actors (Stakeholders) do exist in the EV ecosystem as depicted in Figure 2.4, directly and indirectly increasing the complexity of such a system. ...
Context 4
... addition to this relatively big number of different stakeholders in this immature market, a variety of different technical integration and standards is observed as outlined in Figure 2.5. Smart charging is now adding another layer complexity to a highly complex ecosystem. ...
Context 5
... different kinds of smart charging approaches (including a and b) enable EVs to provide flexibility to the power grid as depicted in Figure 2.6 ...
Context 6
... it is crucial to distinguish among the different design factors through developing new intelligent charging strategies. In the following section, the main design factors depicted in Figure 2.7 are highlighted. ...
Context 7
... is transported via a network of ultra-high and high voltages to be distributed to individual grid areas and consumers through distribution networks. However, there are four different voltage levels according to IEC 60038 [28], as depicted in Figure 2.1: ultra-high voltage, high voltage, medium voltage, and low voltage. ...
Context 8
... that end, any vehicle using electrical energy partially or entirely for moving is called Electric Drive Vehicle (EDV). As depicted in Figure 2.3, they can be distinguished in supply line bound vehicles like trains, or trams, and gridindependent vehicles. ...
Context 9
... different actors (Stakeholders) do exist in the EV ecosystem as depicted in Figure 2.4, directly and indirectly increasing the complexity of such a system. ...
Context 10
... addition to this relatively big number of different stakeholders in this immature market, a variety of different technical integration and standards is observed as outlined in Figure 2.5. Smart charging is now adding another layer complexity to a highly complex ecosystem. ...
Context 11
... different kinds of smart charging approaches (including a and b) enable EVs to provide flexibility to the power grid as depicted in Figure 2.6 ...
Context 12
... it is crucial to distinguish among the different design factors through developing new intelligent charging strategies. In the following section, the main design factors depicted in Figure 2.7 are highlighted. ...