This application relates generally to underwater vehicles which may include unmanned underwater vehicles (UUV), also known as autonomous underwater vehicles (AUV), as well as manned underwater vehicles. The disclosure has specific application to vehicles referred to as blended wing gliders, but may also have application to designs that are not considered as blended wing.
Underwater gliders have the ability to travel through water to significant depths. The gliders are relatively quiet and can travel long distances on minimal fuel. These benefits allow gliders to be used for a range of purposes, including oceanographic science activities, military and defense applications, etc.
An underwater glider typically includes a fuselage or body that supports wings or hydrofoils either side of the fuselage. The fuselage and/or wings may house a drive system, typically a variable buoyancy engine. The variable buoyancy engine changes the overall buoyancy of the vehicle causing the vehicle to dive or surface accordingly. The angle of attack of the hydrofoil causes the vehicle to glide forwards as it moves up and down through the water, allowing the vehicle to attain velocities appropriate to its purpose. Once a suitable velocity is obtained a steady forward motion at a steady depth can be achieved by adjusting the trim of the vehicle.
To achieve prolonged autonomous operation of the vehicle, balance of the vehicle is essential. However, the hydrodynamic balance requirements of existing underwater gliders can often be at odds with the other functional requirements of the vehicle. Therefore, what is required is an improved underwater glider design.
In an underwater glider, stability and versatility can be enhanced by the use of a high wing design. In a high wing design, a centerline of the wings extending from the sides of the body of the glider are located above a relative centerline of the body of the glider. The relative centerline of the wings may rise continuously from a region where the wings attach to the body to respective ends of the wings. In particular for a blended wing glider, a top surface of the glider is level in a line extending between ends of each wing.
In one aspect of the disclosure, there is provided an underwater glider including a body and first and second wings extending from respective first and second sides of the body. A relative centerline of the first and second wings at any point along the first and second wings is disposed above a relative centerline of the body.
In one embodiment, a relative centerline of the wing rises continuously from the body toward a tip of the respective wing.
In one embodiment, each wing is substantially symmetrical about the relative centerline along the length of the respective wing.
In one embodiment, a top surface of the glider is level in a line extending between ends of each wing.
In one aspect of the disclosure, there is provided an underwater glider including a body and first and second wings that extend from the body. For each of the first and second wings, a relative centerline of the respective wing rises continuously from the body toward a tip of the respective wing.
Reference will now be made, by way of example only, to specific embodiments and to the accompanying drawings in which:
As stated above, balance of a glider is essential for long, stable operation. Unlike air gliders which, being heavier than are only required to glide downwards after being towed into the air, underwater gliders are near neutral density to their environment so they can ascend or descend by making changes to buoyancy. The change is generally very small when compared to the total displacement of the vehicle. This makes the vehicle very susceptible to instability if the center of mass is incorrect or inadequate with respect to vehicle center of displacement. For optimal balance, current underwater gliders are believed to require the wings or hydrofoils to be centered on a horizontal plane through a horizontal center of the body or fuselage. However, the present inventors have found that particular advantages may be achieved with a high wing design as will be herein described.
When a glider is not in the water, the glider tilts and rests on an undersurface of the wing and body. Equipment such as sensors for ocean surveys, cameras, etc. may be located on the undersurface of the wing and can be damaged while the glider is in transit. Launch and recovery of the glider can also be problematic. Such disadvantages may also be reduced with the high wing design to be described herein.
The glider 100 includes a body 110. The body 110 is generally a wing profile having a front or nose 112 and tail 114. Extending from the sides of the body 110 are left and right wings or hydrofoils 120, 130. Each wing extends from the body 110 to a respective wing tip 122, 132. The glider 100 is a blended wing design. The term blended wing refers to there being no clear dividing line between the wings and the body of the glider. The fuselage itself forms part of the hydrodynamic surface. That is, the wing and body structure are smoothly blended together. This is shown in
The body 110 and wings 120, 130 of an underwater glider may be made of a syntactic foam which has the properties of low density, low compressibility and high strength, making it suitable for deep sea usage. Syntactic foams are known in the art and no further description of such materials is considered necessary for the present disclosure.
The present disclosure is concerned primarily with the outer hydrodynamics and configuration of the vehicle. The internal configuration of the body, location of the variable buoyancy engine and control electronics etc. are not considered pertinent to the present disclosure. The person skilled in the art will readily understand that variations to the internal layout and design of the glider will be dependent on a range of factors including mass placement (as it changes center of mass), size, purpose, extraneous equipment requirements, range, etc. Thus, the section views of
The present applicants and inventors refer to the configuration of the glider depicted herein as a high-wing design. That is, rather than the wing being centered on the body, as is the case for conventional underwater glider design, particularly blended wing gliders, the relative centerline of the wing at any point is disposed above the centerplane of the body.
An alternative manner for considering the wing profile depicted is that a relative centerline of the wing rises continuously from the region where the wing extends from the body toward a tip of the respective wing. This may be an appropriate consideration particularly for non-blended wing glider designs.
In one embodiment, the wing profile is substantially symmetrical along its length. That is, for any section, the wing profile is mirrored above and below the relative centerline. This allows wing lift at various angles of attack in both ascent and descent to be equally effective. In an alternative embodiment, the wing may have a non-symmetrical design. For example, the wing may have a flexible profile, where the profile is distorted one way in ascent and the other way in descent. Non-symmetry may also be intentional to achieve greater efficiency in ascent or descent as required.
In one embodiment, the relative centerline rises continuously from its lowest at the longitudinal axis of the body (
Returning again to
In
The high wing design as described herein can provide enhanced stability benefits over conventional underwater gliders. In particular, the high-wing design described herein enables a greater righting moment to be achieved to improve stability.
An advantage of the high wing design of the presently described embodiments includes that the design allows safer and greater flexibility to add side-scan or bottom profiling transducers/instruments to a blended wing glider designed underwater vehicle.
Higher wings will be further from the ship deck during launch and recovery, providing protection to the wings and any sensor or purpose-specific equipment mounted thereto. A further advantage during launch is that a greater vehicle mass will enter the water first, allowing the vehicle to become more stable before more vulnerable extremities enter the water. The opposite in recovery is also an advantage.
In one embodiment, solar panels may be added to the upper side of the wings. Solar panels may be used as emergency power, for example, for recovery beacon operation.
A glider as herein described may be equipped and configured for a range of purposes.
It will be understood by the person skilled in the art that terms of orientation such as top, bottom, front, back, left, right, inner, outer, horizontal, vertical etc. are used herein with reference to the drawings in order to provide a clear and concise description. Such terms indicate examples of the relative relationship of components to each other, rather than specific orientations of those components in space. These terms are not intended to limit the examples and embodiments in any manner and the scope of the disclosure as defined herein will encompass other possible orientations of the components as will be perceived by the person skilled in the art.
Although embodiments of the present invention have been illustrated in the accompanied drawings and described in the foregoing description, it will be understood that the invention is not limited to the embodiments disclosed, but is capable of numerous rearrangements, modifications, and substitutions without departing from the spirit of the invention as set forth and defined by any claims that follow.
Number | Date | Country | Kind |
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2019902248 | Jun 2019 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2020/050670 | 6/26/2020 | WO |