Onshore vs offshore wind farms Installed capacity
wind in europe
onshore ~ 600 GW
offshore ~ 30 GW
Europe has 285 GW of wind power capacity in 2024, covering almost 20 % of EU energy demand
EU’s designated target is 425 GW
Grid connection of wind farms, Different topologies
Radial topologies
▪ #WT depends on rated cable current and rated WT power
▪ Most common, simple and cheap
▪ No redundancy within a string
Ring topologies
▪ Improved redundancy (two sides)
▪ Larger costs due to (a) additional or (b) oversized cables
Star topologies
▪ Reduce cable ratings required
▪ Very reliable, since independent connections
▪ Large costs and higher losse
Offshore Grid Connection: AC Transmission Limits
High voltage power cables
Capacitive behavior dominates
▪ The longer the cable, the higher the capacitance C = C’ ∙ l
AC vs. DC transmission
HVDC Converter Technologies
Voltage Source Converter (VSC)
Switch independent of phase angle
But: vulnerable to high (fault) currents
Variable current flow direction
Active and reactive power can be controlled independently
High Controllability: Allows grid forming control → Offshore AC grid voltage and frequency can be set via the MMC
reason for Modular Multilevel Converter (MMC) type for offshore wind
With this converter type, less AC-side filters are required, which saves spaces and money - especially offshore.
To operate the offshore AC network with wind turbines, a so-called grid forming capability of the HVDC converter is required. Only the chosen converter type can provide this capability.
tatements: fault ride through process of a wind turbine
The reason why wind turbines are required to ride through temporary grid faults is that a large-scale disconnection of WTs caused by a fault could endanger the AC system stability.
If the fault is not cleared within a couple of 100 ms, the WTs are allowed to disconnect from the grid and shut down.
Until the voltage has recovered, the power generated by the turbine is dissipated in breaking resistors (also called “choppers”) located within the DC bus of fully converter-coupled WTs
Wind turbine / rotors cannot be slowed down within a few ms
→ Power is generated during the AC-FRT period, but cannot be transmitted to the AC system since the voltage is (approx..) zero
▪ The energy is dissipated in breaking resistors (also called “choppers”) located at the DC bus of a converter coupled WT
▪ Note: More complex in case of DFIG setup!
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