The technology is a design for a flexible and scalable vehicle for use in underwater operations
About
Background: This technology was developed to provide an efficient vehicle for extended underwater exploration. Most vehicles designed for this purpose are based on rigid-hull submarines. Their effectiveness is limited by the need to incorporate long tethered cables to a mother ship, propellers that become entangled in sea grass or debris, and rigid hulls that prevent maneuvering in close proximity to fragile ocean features. Furthermore, these vehicles require fuel for propulsion and cannot carry all that they would need for an extended deployment. Torpedo-shaped vehicles use buoyancy and gravity for efficient descend-ascend propulsion; however, these vehicles cannot readily maintain a constant depth and have limited maneuvering capabilities. More recently, researchers have explored the use of vehicles based on biomimicry of batoids—such as rays or skates—that employ mechanically actuated components for propulsion and maneuvering. However, these designs are complex and require considerable power—making them impractical for extended exploration. This Georgia Tech innovation offers an improved batoid-based design. Technology: Ari Glezer, Mark G. Allen, and Lora Weiss from the Schools of Mechanical Engineering and Electrical and Computer Engineering at Georgia Tech have developed an efficient submersible vehicle design suitable for extended underwater missions. The vehicle uses buoyancy to effectively control descent and ascent. By mimicking the movement of batoids, it has superior hydrodynamic characteristics. The vehicle has a system of bladders that are inflated or deflated selectively to control propulsion, roll, and pitch. The bladders are also used to control fins that can flap, oscillate, or undulate to further control movement of the vehicle—built on the morphology and control surface architecture of batoids. Potential Commercial Applications: The technology is a design for a flexible and scalable vehicle for use in underwater operations. It has primary applications for oceanographic exploration and military applications. The technology may also have applications for unmanned vehicles, aircraft, or surface marine vehicles. Benefits/Advantages: Extended range: This vehicle’s propulsion system does not require refueling, allowing for long range deployments. Nearly silent: Its limited use of mechanical components reduces the acoustic signature. Highly maneuverable: Scalable system provides three-dimensional maneuvering capabilities.