The FINANCIAL -- The Norwegian Minister of Petroleum and Energy, Kjell-Børge Freiberg, officially opened the power-from-shore solution which will provide the Johan Sverdrup field in the North Sea with electricity for more than 50 years. Power from shore makes Johan Sverdrup one of the most carbon-efficient fields worldwide.
The giant development in the North Sea has been through the busiest installation campaign ever for a field in the North Sea. Today Johan Sverdrup reached another milestone, when power from shore was officially switched on about a year before production start-up. With electric power supplied from shore Johan Sverdrup operations can be run without the use of fossil fuels, which makes it one of the most carbon-efficient fields worldwide, according to Equinor.
The Minister of Petroleum and Energy, Kjell-Børge Freiberg, had the honours of switching off the temporary generators which had supplied the field with electricity during the first months of the installation campaign offshore. And after the four generators had quietened down, the milestone was celebrated in the traditional offshore style with coffee and cake.
Johan Sverdrup full-field production is estimated to reach 660,000 barrels of oil per day at plateau, with a break-even of less than 20 dollars per barrel, and with CO2 emissions of only 0.67 kg per barrel. Power from shore to Johan Sverdrup will help reduce emissions by an estimated 460,000 tonnes of CO2 per year, equivalent to the emissions of 230,000 private cars each year.
Power from shore about a year before production start-up
Working closely with partners and suppliers, Equinor has taken initiatives to enable the supply of power from shore already in the commissioning phase offshore. With several energy intensive operations planned prior to production start-up – including the tieback of the eight predrilled production wells – the early supply of electricity from shore helps further reduce the carbon footprint of the project.
The Johan Sverdrup partnership has also, in collaboration with the supplier Master Marine, taken steps to ensure that the temporary accommodation rig Haven – where most of the offshore workers currently live – is also supplied with power from shore during the remainder of the project finalization stage.
Seamless collaboration between onshore and offshore
In phase 1 of the Johan Sverdrup development the power-from-shore solution has a capacity of 100 MW, based on a production capacity of up to 440,000 barrels per day.
Several suppliers across several countries, both onshore and offshore, have been involved in developing and delivering the chosen solution for power from shore to Johan Sverdrup phase 1.
ABB delivered the HVDC equipment for the two converter stations, onshore at Haugsneset close to Kårstø and offshore at the Johan Sverdrup field centre. First, at Haugsneset, the electric current is converted from alternating current (AC) to direct current (DC), enabling the transmission of electricity for 200 km offshore, while minimizing loss. Then, offshore, the electric current is converted back to the alternating current needed to run the field centre equipment.
Aibel was responsible for all construction related to the onshore converter station at Haugsneset. Aker Solutions was responsible for the engineering and Samsung Heavy Industries built the riser platform including the converter module where the HVDC equipment is placed offshore. And NKT was responsible for fabrication and installation of the 200 km power cables from Haugsneset out to the Johan Sverdrup field centre offshore.
In Johan Sverdrup phase 2, with start-up expected in Q4 2022, the power from shore capacity will be expanded with 200 MW, giving a total capacity of 300 MW. This enables Johan Sverdrup to facilitate access to power from shore to the other fields at Utsira High – Edvard Grieg, Gina Krog og Ivar Aasen. The expanded power capacity will also be needed for the added Johan Sverdrup production capacity of 220,000 barrels per day, and the total full field production capacity of 660,000 barrels daily.