Faster ships could be on the horizon after scientists develop a slippery surface inspired by fish and seaweed to reduce the hull’s drag through the water
- Artificial mucus could help tiny cavities on ship hulls reduce water resistance
- Long-distance cargo ships lose a huge amounts of energy due to fluid friction
- Korean physicists have monitored open areas of these lubricant-filled cavities
Slippery coatings inspired by the mucus produced by fish and seaweed can reduce water resistance on ships, scientists say.
Korean researchers have designed a lubricant-infused surface, intended to cover a ship’s hull, which is covered with tiny cavities.
As the cavities are continuously filled with the lubricant, a layer is formed over the surface that helps slip easily though the water.
Computer simulations showed the coating can cut ‘fluid friction’ by nearly a fifth, the experts say.
Slippery coatings will mean ships will require less power when travelling long distances, which will mean less fuel burnt.
An X-ray image of a loach’s mucus storage system, and a schematic diagram demonstrating how lubricant is secreted in the authors’ setup
‘Our investigation of the hydrodynamics of a lubricant layer with a slippery surface in a basic configuration has provided significant insight into the benefits of a lubricant-infused surface,’ say the researchers in their paper.
‘Further research into mucus layers is expected to stimulate improvements in the energy-saving technology.’
Long-distance cargo ships lose propulsive power due to fluid friction, which is caused by the exposure of their large hull surfaces to seawater.
However, the hydrodynamics of lubricant-infused surfaces is ‘not yet fully understood’, the team say.
The group looked at the average speed of a cargo ship with realistic material properties and simulated how it behaves under various lubrication setups
The experts, from Korea Advanced Institute of Science and Technology and Pohang University of Science and Technology, looked at the average speed of a cargo ship with realistic material properties, such as the density and surface tension.
They then investigated how the size of the cavities in the material and the thickness of their ‘lids’ affected the amount of drag on the vessel.
They found that for larger open areas, the lubricant spread more than it does with smaller open areas, leading to a more slippery surface.
On the other hand, the lid thickness was not found to have much of an effect on resistance, though a thicker lid created a thicker lubricant build-up layer.
Researchers believe a breakdown of the physics of different types of cavity will help implementation in real-life marine vehicles.
‘If the present design parameters are adopted, the drag reduction rate will increase significantly,’ said study author Hyung Jin Sung.
Because drag increases with speed, the faster the ship moves, the more fuel it requires to counteract the resulting resistance.
The physics behind the technique will therefore help save the planet by affecting how much fuel a ship needs.
It could help slash emissions of potentially harmful sulphur compounds and CO2 produced by exhausts that power propellers.
The study has been published in Physics of Fluids.