Carbon capture and storage (CCS) will be a key technology if the world is to meet the goals of the Paris and Glasgow agreements. Although the technologies and the industry are very much still emerging, a possible challenge is connecting capture sources to facilities for use or storage sites, especially where pipelines are not an option.
As a result, CO2 transport ship technology will be needed if large quantities are to be safely transported at costs that are commercially viable. Most transport of CO2 via ship takes place at small scale and at medium pressure (15 bar at -28ºC), limiting the possibilities of scaling up to meet future growth in CCS.
Reduced transportation costs
The JIP looks to build experience in low pressure transport and fill a vital knowledge gap
To transport CO2 safely and efficiently at industrial scale by ship, low pressure transport systems (approx. 7 bar at -49ºC) are a potential solution, as this enables much larger tank volumes, cargo capacities and therefore reduced transportation costs. However, the industry currently has little practical experience with the transport of liquid CO2 (LCO2) under these conditions.
The JIP looks to build experience in low pressure transport and fill a vital knowledge gap, by examining the fundamentals of a low-pressure CO2 transport chain, including:
- A LCO2 ship design, with low pressure tank and cargo handling system.
- Material choice and testing.
- Medium scale testing and simulation of cargo handling.
- Conditioning and liquefaction.
- Testing LCO2 behaviour at low pressure.
Safe and economical operations
As an important part of tackling the climate crisis, reducing costs across the whole CCS value chain is essential"
“As an important part of tackling the climate crisis, reducing costs across the whole CCS value chain is essential,” said Johan Petter Tutturen, VP, Special Projects – Gas at DNV.
“Low pressure CO2 ship designs are a potentially important piece of the chain, but they need to be reliable and meet accepted safety standards. That is why we are very pleased to be working together with this strong consortium of CCS stakeholders to identify the technical risks and challenges to enable safe and economical operations going forward.”
Low pressure ship transport
“As we build a wider global CCUS (carbon capture, utilisation and storage) network that connects CO2 emitters with sinks, it is critical that we are able to ship CO2 safely, economically and at scale,” said Syrie Crouch, VP Carbon Capture Utilisation and Storage at Shell. “Ensuring these CO2 transport vessels and their associated loading/unloading facilities are standardised to enable interconnectivity between capture and storage facilities will be key to success. Shell looks forward to working with the JIP on the next generation of CO2 ships to deliver this vision.”
Equinor believes that low pressure ship transport is an interesting way to scale up CO2 transport solutions"
“Equinor believes that low pressure ship transport is an interesting way to scale up CO2 transport solutions, but we need to make sure the technical risks are reduced to an acceptable level. That is why this project is important,” Elisabeth Birkeland, VP for Carbon capture and storage solutions in Equinor, says.
Net-zero emissions
“We are very pleased to be part of this initiative, alongside our partners, to develop low pressure CO2 ship carriers,” said Bruno Pahlawan, VP R&D Line Sustainability, TotalEnergies. “This future technology will open the door to the large-scale transport of CO2, which is an essential element for the upscaling of the CCS industry. It is fully in line with TotalEnergies’ ambition to get to net-zero emissions by 2050 together with society, for its global business across its production and energy products used by its customers.”
The CETO JIP is named after Ceto, who is a primordial sea goddess in Greek mythology, and builds on an earlier project carried out by the partners that investigated the technology gaps and identified qualification activities to demonstrate that the technologies offer the required levels of operational safety and reliability.