A buoyancy engine is a device that alters the

buoyancy Buoyancy (), or upthrust, is an upward force exerted by a fluid that opposes the weight of a partially or fully immersed object. In a column of fluid, pressure increases with depth as a result of the weight of the overlying fluid. Thus the ...

of a vehicle or object in order to either move it vertically, as in the case of underwater profiling floats and stealth buoys, or provide forward motion (therefore providing variable-buoyancy propulsion) such as with

underwater glider An underwater glider is a type of autonomous underwater vehicle (AUV) that employs variable-buoyancy propulsion instead of traditional propellers or thrusters. It employs variable buoyancy in a similar way to a profiling float, but unlike a flo ...

s and some

autonomous aircraft An autonomous aircraft is an aircraft which flies under the control of automatic systems and needs no intervention from a human pilot. Most autonomous aircraft are unmanned aerial vehicle or drones. However, autonomous control systems are reachi ...

. For underwater applications, buoyancy engines typically involve a hydraulic pump that either inflates and deflates an external bladder filled with hydraulic fluid, or extends and retracts a rigid plunger. The change in the vehicle's total volume alters its buoyancy, making it float upwards or sink as required. Alternative systems employing gas obtained from

water electrolysis Electrolysis of water, also known as electrochemical water splitting, is the process of using electricity to decompose water into oxygen and hydrogen gas by electrolysis. Hydrogen gas released in this way can be used as hydrogen fuel, or remi ...

, rather than hydraulic fluid, have also been proposed. as have systems which pump ambient water into and out of a pressure vessel

Operation

The

engine is a fairly new piece of technology currently in research by many institutions and organizations that utilize underwater surveillance and mapping technologies. A

engine works by inflating and deflating an oil bladder. In doing so, this changes the density of the craft the engine is installed on. As a result, an

autonomous underwater vehicle An autonomous underwater vehicle (AUV) is a robot that travels underwater without requiring input from an operator. AUVs constitute part of a larger group of undersea systems known as unmanned underwater vehicles, a classification that includ ...

such as an

can adjust its buoyancy without external input. This allows the glider to remain in operation, untethered to a surface vessel, for a longer duration of time. This increases efficiency and makes the underwater glider a more viable tool for mapping the ocean floor. An underwater glider works similarly to how a normal

glider Glider may refer to: Aircraft and transport Aircraft * Glider (aircraft), heavier-than-air aircraft primarily intended for unpowered flight ** Glider (sailplane), a rigid-winged glider aircraft with an undercarriage, used in the sport of glidin ...

works. It utilizes the flow of water over a set of wings to generate lift. The shape of the wings are a specially designed shape called an airfoil. Underwater gliders use this same principle and design to glide underwater. The way weight is distributed within the underwater glider helps with this by putting the center of gravity at or just in front of the leading edge of the wings. This promotes an efficient and smooth glide slope. The buoyancy engine allows an underwater glider to continue this gliding process for extended periods of time. Without a buoyancy engine, an underwater glider would either have to be towed by a surface vessel or only be used once and deploy a package that would float to the surface where it can be retrieved. However, if it is towed by a surface vessel, then it is no longer classified as a glider. With the addition of a buoyancy engine, the underwater glider becomes a viable tool as it can stay in operation longer and can be reused. An underwater glider, like an aircraft glider, loses altitude as it moves forward. In the case of an underwater glider, its depth increases. Eventually, any glider will touch the ground. With a gliding aircraft, this is not much of an issue since they are expected to land and are reusable when they do so. This is not true for an underwater glider. If an underwater glider were to land on the ocean floor, it is essentially lost. Since a buoyancy engine allows a glider to change its density, the glider can glide in two directions. It can glide down like an aircraft, or it can glide up if it makes itself less dense than the water around it. In this way, as long as the buoyancy engine remains active, an underwater glider can continue to operate. The actual operation of a buoyancy engine occurs through a complex system of tubing, valves, and sensors. When a glider equipped with a buoyancy engine is deployed, the glider will increase its density to sink to an appropriate depth at which to start its mission. Once at that depth, the glider will begin the mission and the buoyancy engine will adjust the density to a value that is efficient for gliding. When a predetermined depth has been reached, the buoyancy engine will decrease

density Density (volumetric mass density or specific mass) is the substance's mass per unit of volume. The symbol most often used for density is ''ρ'' (the lower case Greek letter rho), although the Latin letter ''D'' can also be used. Mathematical ...

and this will cause the glider to glide back towards the surface. In this way, the underwater glider remains in operation between two preset depths. The mechanism used to modify buoyancy for this purpose is often a

variable buoyancy pressure vessel A variable buoyancy pressure vessel system is a type of rigid buoyancy control device for diving systems that retains a constant volume and varies its density by changing the weight (mass) of the contents, either by moving the ambient fluid into a ...

Application

The buoyancy engine, when combined with the

, gives scientists and other individuals or organizations access to hardware to survey the ocean depths. For instance, the buoyancy engine, since it is used on underwater gliders and extends the capabilities of such craft, would be able to more effectively map the ocean floor. The use of the buoyancy engine has other effects as well. It could be used to improve the detection of underwater stores of

oil An oil is any nonpolar chemical substance that is composed primarily of hydrocarbons and is hydrophobic (does not mix with water) & lipophilic (mixes with other oils). Oils are usually flammable and surface active. Most oils are unsaturated ...

. In addition, since the operational range of underwater gliders is increased through the use of buoyancy engines, ocean floors can be mapped in larger sections which is more efficient than pre-existing technologies. Also, buoyancy engines do not give off environmentally harmful substances making them an environmentally safe technology. Other applications that extend from this include investigating disasters that happen at sea. Due to the increased mapping capabilities provided by the buoyancy engine, searching for the wreckage of an airliner or passenger ship can be conducted more economically by a larger number of units, so the wreckage may be found sooner and evidence can be collected more efficiently. Ocean mapping and underwater surveillance are important as they can reveal resources that would not be available otherwise.

References

{{Reflist Buoyancy Fluid mechanics