VR tool from the subsea sector finds new home in the aqua industry

A digital platform inspired by virtual reality (VR) that got its start in the subsea energy and oil and gas industry is being retooled for aquaculture and will help safeguard divers on fish farms.

The Fish Site
by The Fish Site
29 September 2022, at 12:00pm
underwater model
VR underwater model

The system uses underwater 3D scanning with images captured by (ROVs) to create a virtual replica of a seafood farm

Led by researchers at the National Manufacturing Institute Scotland (NMIS), operated by the University of Strathclyde, the project was recently awarded funding of around £50,000 from the UK Seafood Innovation Fund (SIF) with additional support from the Sustainable Aquaculture Innovation Centre (SAIC).

Designed to replace existing paper-based dive planning, the system will use underwater 3D scanning with images captured by remotely operated vehicles (ROVs) to create a virtual replica of a seafood farm, supporting divers to plan activities ahead of entering the water.

Divers will be able to use a mobile, tablet or even a VR headset to gain a better understanding of the fish farm environment through a digital model that can help them to assess the difficulty of the dive, what actions are required in terms of maintenance and cleaning and whether any additional equipment is needed underwater.

person wearing a VR headset
Testing the virtual reality device

In the future, the system could have the potential to become part of a full digital twin

NMIS is working with Ocean Kinetics – a provider of diving services to a range of sectors including aquaculture, energy and renewables – and Viewport 3, specialists in subsea 3D scanning, to create a test platform based on a Scottish Sea Farms site in Shetland.

Awais Munawar, visualisation theme lead – digital factory at NMIS, said,"3D scanning and VR technology is already used in many industries such as aerospace and energy, and there could be a significant opportunity for aquaculture to follow. Of course, there are also challenges to overcome, which is the purpose of this feasibility study. For instance, fish farms are not fixed structures in the way that many oil platforms are, and the environment can be quite different depending on the location and depth of the water.

“We are also looking to test a small 5G network to improve communications as part of diving activity in remote locations. This could be used to update the information captured by the remotely operated vehicles in real-time, as well as being used to alert any nearby vessels to the fact that divers are in the water. In the future, the system could have the potential to become part of a full digital twin, with additional data and images already captured by sites integrated into the platform to give a full picture of the situation under the water.”

Diving is considered one of the most complex and dangerous roles in aquaculture still undertaken manually, but the new digital planning tool could boost health and safety in a range of ways. With better access to information ahead of a dive, it could reduce the time needed in the water, support a better understanding of new or unfamiliar sites, and identify additional training or support needs.

For seafood producers, it could also enhance the efficiency of maintenance programmes, with the images captured by ROVs identifying issues such as the presence of marine growth ahead of divers going underwater. More streamlined dive schedules could also reduce interaction with fish.

Sarah Riddle, director of innovation and engagement at SAIC, said, “this is a great example of how the aquaculture sector can work together with experts in subsea technology, manufacturing and other industries to learn from best practice and accelerate digital transformation. Designed specifically for seafood producers, the new tool could support training, maintenance, inspections and even environmental monitoring, helping to future proof the sector as it continues to grow.”