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Download Network connection issues for offshore wind farms in UK waters
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Transcript
Some electrical connection design issues for offshore wind farms Paul Gardner, Helen Snodin, & Nigel Scott Garrad Hassan and Partners [email protected] Presentation Rationale Most UK projects quite advanced Grid connections and costs known Issues of design choices Unknowns ? Electrical Design Can be split into 3 key areas: Offshore array Transmission to shore Grid connection will concentrate on the latter two. Some Electrical Design Issues Subsea vs land cable 33kV vs 132kV transmission to shore Export security Parallel 132/33kV transformers Teed vs looped vs busbar connections Grid Code changes Electrical Design Diagram Onshore Offshore Existing 132kV grid line Wind turbine Wind turbine transformer Other wind turbines 132/33kV transformer 132kV switch circuit breaker 33kV cable onshore 33kV cable to shore 33kV submarine cable within array 132kV cable Tee or loop connection ? Single or double transformer arrangement ? Continue with submarine cable onshore ? Offshore transformation to 132kV or continue at 33kV ? Arrangement of offshore array ? Subsea vs Land Cables Offshore 33kV - use either EPR submarine cables or XLPE cable with additional waterproofing 132kV - use XLPE cables Better electrical insulator Sealed in watertight lead sheath - not land cable ! Onshore Subsea cables can be used but only worth considering for short and simple routes. Key issues are costs and practicability 33kV vs 132kV Transmission to Shore Item Cable Cable installation Power losses Substation Power factor correction O&M Other costs / risks Highest Cost 132kV 33kV £ £ £ £ £ £ £ Export Security Teed vs Loop vs Busbar connections Capital cost vs improved export security against grid faults, operations and maintenance outages E.g. 100MW at £0.035/kWh and 35% load factor Cost of Lost Production £1.2k £29k £206k £412k Time 1 hour 1 day 1 week 2 weeks Export Security - Tee & Loop Existing grid line Circuit breaker/switch Wind farm Tee connection Loop connection arrangement arrangement Export Security Single or double 132/33kV transformers One transformer = all eggs in one basket Two transformers Extra capital cost Improved security against transformer failure new transformer or repairs could take months failure rates are low reduced export depending on transformer rating Higher O&M costs Grid Code Changes Compliance in full or in part mandatory New Grid Code due in 2002 Possible requirements Control of real and reactive power Frequency response Voltage regulation Stability Implications - more cost ? Summary Impossible to cover all the issues, design choices and best practices Hopefully raised awareness of one or two issues The answers are often project specific
