Many thanks to Silverstream for the cooperation and professionality during ther Princess Regal project held on Palermo fincantieri Shipyard. Looking forward to continue the cooperation for other projects. RM Marine Team
Air Lubrication was tried on Atlantic Conveyor, prior to her loss in Falklands. In extensive tests, including Arran Measured Mile runs, no increase of speed or reduction of resistance could be detected. Maybe the only way the system could be effective is on a ship with large proportion of flat bottom area (which Atlantic Conveyor did not)
All systems draw power during operation from the vessels generators. Vessels power consumption at sea and in port is estimated during the design stage and then generators are installed to fulfil this power requirement with an additional standby one. Retrofitting systems like Scrubbers, BWTS and this one will draw additional power. That means increased fuel consumption and emissions. We are talking about fuel savings for the main engine. What about power consumed to run the additional systems ? That too will contribute to vessel emissions? Roughly how much power do these air lube systems draw for a 8500 TEU container vessel and a VLCC?
I would say it is safer to introduce air lubrication without drilling the hull with a lot of holes, so other methods are possible by welding bailers which will aerate the hull around the bulbous bows which is a closed compartment to the hull taking air from before the cutwater through a vertical pipe above the bulbous bow. . ru-vid.com/video/%D0%B2%D0%B8%D0%B4%D0%B5%D0%BE-yV_UPBWvlkI.html If the bulbous bow of a ship is designed with a flattish front to cause the water to turn fast on its way to the side of the bulbous bow, the inertia of the water will form an aeration ring about the bulbous bows and this aeration of the bows will cause air to run along the bottom and side of the hull lubricating it. This aeration ring about the bows is often seen when submarines are running on the surface. In fact, a surfaced submarine does leave a lot of bubbles around it ru-vid.com/video/%D0%B2%D0%B8%D0%B4%D0%B5%D0%BE-9lCY0qYgMqY.html ru-vid.com/video/%D0%B2%D0%B8%D0%B4%D0%B5%D0%BE-H5Iljls_hMs.html If the propellers are placed at the bows, cavitation bubbles will act as was tried in the US Navy high-speed Swath boat. See 2.28 ru-vid.com/video/%D0%B2%D0%B8%D0%B4%D0%B5%D0%BE-BlTibownuTQ.html My 13-foot wooden planing boat with a 7.5 Hp outboard motor used to make good use of the wind coming from ahead, and the boat felt lighter on the run but the drag on the above surface hull did counterbalance the effect of air lubrication on the hull's bottom.
The principal of pumping air under a hull has been around since John Thornycroft in 1877. Though this is using more modern technology than Thornycroft's clockwork powered bellows on a scale boat, we should tip our hats to his ingenuity.
This dates back to 1960-70's in racing boats so nothing new , also Deep heavy grit sanding allowed higher speed boats to hold the small bubbles thus reducing drag even more as more air next to hull, but then more ideas I have to make hull so slick and few they have not thought up yet LOL
I wonder if the US and Russian naval architects have considered this for their navy vessels. I guess that if they have, then it would be classified information. Sounds like a great way to get a bit of extra speed when necessary. Perhaps the Gerald R. Ford class aircraft carriers have this? If they don't, then why not?
@@MarkoDash If you are referring to noise being bad in regard to submarines being able to find a vessel, I think that the aircraft carriers make enough noise already to be easily found by submarines, so adding extra noise would probably not make any difference.
@@vladsnape6408 Not an expert here, but I suppose MarkoDash refers to aircraft carriers wanting to find the submarines, which they might not be able to do when they themselves create so much noise below the waterline.
ver the past eight years, the Michigan team has investigated a variety of techniques to cut friction drag. First it looked at injecting slippery polymers into the water at the boundary layer. "Near the injector, drag was reduced by 70 percent, but the polymer degrades in the turbulence and just diffuses away," Ceccio says, "which means it needs constant replenishment, so we turned elsewhere." The researchers next shot bubbles-a millimeter or less in diameter-into the boundary layer. They got an 80 percent drag decrease for six feet (two meters) or so, but again, no satisfaction; the bubbles refused to cling to the hull surface long enough to have a significant effect on overall efficiency. If one injects enough gas, however, the bubbles eventually coalesce into a buoyant film that can sit (at least for awhile) between the horizontal hull and the water, which is what Ceccio's team is working on now-air layer drag reduction. In this concept, the bubbles typically would leak sternward and out from under the hull. New air would be injected forward to constantly refill the lubricating air pocket. Scientists speculate that more effective drag-lowering systems using smaller "microbubbles" might be possible if someone could come up with a low-cost way to make the sub-millimeter bubbles. Winkler says that his company is working on a "super-microbubble generator" that would enable existing ship hull designs to be retrofitted with such technology. These systems would also require the installation of surface cavities in the hulls. The big issue then becomes maintaining stable coverage of nearly the entire hull surface so that rough seas do not simply wash away the bubbles. Continuous, maximal coverage is the key to success; every millisecond that a section of hull contacts water directly contributes to drag. This means ships might have to be equipped with radar and laser sensors that detect oncoming waves, which could permit constant adjustment of air flow in time to compensate for rough seas. Although the costs of this air-carpet technology have not been fully worked out, Winkler says that adding relatively simple air cavity systems into new ship construction would add 2 to 3 percent to building costs.ggggAir lubrication: Only big bubbles do the trick Date: September 2, 2016 Source: University of Twente Summary: Blowing bubbles underneath a ship’s hull, causes them to be pushed against the surface. In the surface layer between the ship and water, these air bubbles cause less friction: it’s also known as air lubrication. In practice, friction can be reduced 20 percent, with a huge impact on fuel consumption and carbon dioxide emission. The precise mechanism is still unknown, as the local water flow is complex and turbulent. As scientists demonstrate, the size of the bubbles make a big difference: tiny bubble don’t have a net effect at all. This may seem counterintuitive, but large bubbles that can be deformed easily, give the strongest effect. Share: FULL STORY Blowing bubbles underneath a ship's hull, causes them to be pushed against the surface. In the surface layer between the ship and water, these air bubbles cause less friction: it's also known as air lubrication. In practice, friction can be reduced 20 percent, with a huge impact on fuel consumption and CO2 emission. The precise mechanism is still unknown, as the local water flow is complex and turbulent. As UT scientists now demonstrate, the size of the bubbles make a big difference: tiny bubble don't have a net effect at all. This may seem counterintuitive, but large bubbles that can be deformed easily, give the strongest effect. For investigating the effects, the University of Twente has a unique 'Taylor Couette' setup, capable of generating fully developed turbulent flow. This machine consist of two large cylinders with fluid in between. When the inner cylinder is turning fast, injected bubbles will be pressed against the surface, just like they do at the ship's hull. At the surface of the cylinder, they start influencing drag. This setup enables the scientists to search for the relevant parameters in efficient air lubrication. With four percent of air in the water, a reduction of 40 percent is feasible in the experimental setup, using large, millimeter size bubbles. By adding a tiny amount of 'surfactant', the scientists were able to vary the surface tension between bubbles and water, and they could vary bubble dimensions. The other properties, like flow speed and density, were kept the same. What was the result? On average, the bubbles get much smaller, because the surfactant prevents bubbles getting together, coalescing, forming larger bubbles. Within the turbulent flow, the bubble have a uniform distribution and moreover, they will not be pushed against the surface. With, again, four percent of air that is in microbubbles now, there is four percent reduction: there is no net air lubrication at the ship's hull. Ruben Verschoof: "From previous experiments, we knew that deformable bubbles work well, but in no way we expected a dramatic difference like this. By doing the experiments in real life turbulent flows, and not in the simplified situation of slow and laminary flow, the outcome of this research is directly applicable in the naval sector. For reducing drag in pipelines, the experiments also provide valuable new insight. The research has been done in the Physics of Fluids group of Professor Detlef Lohse. This group is part of UT's MESA+ Institute for Nanotechnology. Research is funded by Dutch Technology Foundation STW and Dutch Foundation for Fundament Research on Matter (FOM).
where air compressors take suction from? does savings in fuel greater than the power needed to produce the air boundary layer? how are the microbubbles kept in the boundary layer?
Hi Sanzhar. The compressors pump air down into the air release units at very low pressure, around 1 atmosphere, meaning the power needed to generate the air bubble carpet is extremely low. In terms of keeping the microbubbles in the boundary layer, they form a rigid carpet and each bubble is approximately 1mm in diameter. This means they do not try to merge and therefore escape the boundary layer. Finally, we have proven fuel savings of 5-10% in our installations to date. These results have been independently verified by a variety of bodies including HSVA and Lloyd's Register.
Newer hull coatings that move on from sacrificial anodes and biocidal coated steel to durable PTFE low fouling release energy coatings will not be affected. It would be interesting to have a study on the bubbles' ability to reduce or improve the fouling resistance of teflon and silicone coatings, though. The bubbles may slightly increase cavitation if they are allowed to travel into the clean water stream that the impellers or propellers pull in, however, they may also reduce the skin drag of the propeller significantly, while the overall thrust of the propeller may remain high. You would have to do a simulation.
Air & Water check valves. Pipe should be enough of a pneumatic buffer for the head pressure. I'm not affiliated, nor an engineer. Just spend too much time on RU-vid. The 'algorithm' may start to take my job soon if they figure out how to train it for STEM topics suggestions... its getting there.
Thank you for your comment. The air release units on the vessel's flat bottom are part of the hull construction. Our system therefore has no effect on the seaworthiness of the vessel.
I was just kidding, but its plausible that the ship could loose some buoyancy ;) ru-vid.com/video/%D0%B2%D0%B8%D0%B4%D0%B5%D0%BE-MSmAXp_BHcQ.html ru-vid.com/video/%D0%B2%D0%B8%D0%B4%D0%B5%D0%BE-nAmlvYJnURs.html If the air isn't constrained at the bottom (like air cavity systems) what stops it from going on the sides of the ship (path of least resistance)?
@@My-Opinion-Doesnt-Matter It should be considered constrained under the hull if they are not allowed to leave the bottom surface. When the ship is turning and the bubbles are allowed to 'flow up' the sides, given enough quantity, it might have a slight but negligible impact on buoyancy. Would need to be dynamically simulated. Not hard if you know the multiphysics software. There are some free ones out there if you want to get back to me about the results (open source).
@@My-Opinion-Doesnt-Matter cold have an edge protruding down at sides and a bit higher flat bottom between them to hold bupples in place but willl the edge do something bad
@@My-Opinion-Doesnt-Matter lose * not loose. And no it increases buoyancy as shown in the video or else the fuel usage would go up. The bubbles in your videos are not comparable.
this is impossible because it destroys the air lifting force, which means that the ship will be more fuel-consuming and more fuel-consuming (I hope I have written it in an agreeable manner)
Thank you for your comment. Our system utilises compressors which force air through cavities or Air Release Units (ARUs) installed along the flat bottom of the vessel. The air-water interaction (i.e. difference in speed/density of air and water) results in the formation of microbubbles in the water scientifically known as the Kelvin-Helmholtz instability. Due to the size and buoyancy, the microbubbles remain in the boundary layer and flow downstream along the flat bottom of the vessel. This reduces the turbulence intensity in the boundary layer between the vessel’s hull and water thereby reducing the frictional resistance of the vessel as it moves through the water. Frictional resistance accounts for one of the major resistance components of a vessel and as such this translates to a reduction of total resistance reducing the power required for a given speed as Effective Power (PE) = Total Resistance (RT) x Vessel Speed (VS). In this way, the fuel consumed reduces as a lower power is required for a certain speed. Also, for a constant power, a speed increase can be seen. There is no effect on any 'air lifting force' and vessels do not become more fuel consuming which has been tested after installing our system on three full-scale ships over the past 4 years. Our sea trials and ongoing in-service analysis on vessels installed with our system have also proven savings in fuel and reduction of GHG emissions of 5-10%, depending on particular vessel characteristics.
@@silverstreamtechnologies3936 thx for the answer, but how about cavitation along the hull over the months/year? How much can this system affected that?
