There is a growing need for inexpensive robots that detect important sub-surface ocean data (e.g., temperature, salinity, currents) in the upper ocean. However, the current ocean profilers are expensive and use proprietary software, making them difficult for users to customize to serve their individual applications. As a result, there is a need for an upper ocean profiling robot that increases accessibility to global marine data acquisition through reduced device costs and decreased training requirements.
In the prior art, there are programs, such as the Global Drifter Program and the Air-Sea Interaction Regional Initiative, each of which aims to deliver oceanic data at high enough resolution to satisfy the models to improve weather predictability and ocean health monitoring. In addition to remote sensing devices (e.g. satellites or shore-based systems), large arrays of in-situ technologies are deployed to take direct measurements of atmospheric, ocean surface and subsurface data. Each of these prior art technologies has its own benefits, costs and limitations, but the capital needed to deploy and maintain these technologies directly limits the spatial and temporal resolutions of these observations made throughout the ocean, in turn, limiting the accuracy of predictions, especially over longer time periods.
A variety of these prior art technologies have been employed that have supplied and had data sets accepted to the World Ocean Database. Ocean Station Data (OSD) comes from oceanographic research cruises and are often referred to as “bottle data” since the method to collect data often uses bottles, buckets, or net tows, which function by collecting discrete water samples that are later analyzed. This method dates to 1772. Since the gathered data can be later tested in a lab, a high percentage of these casts are further analyzed giving the ability to study multiple variables per cast, without having to equip the bottles themselves with arrays of expensive sensors.
Mechanical Bathythermograph (MBT) Data is collected by a tube that is dropped into the ocean to produce a temperature profile by recording temperature data versus depth using a 17 m long coiled Bourdon tube with a mechanical stylus that moves in one direction due to the Bourdon tube pressure and the other due to a temperature sensor. As it descends the stylus scratches the relation into a glass plate.
The Expendable Bathythermograph (XBT) is a three-part system with an expendable probe that sends temperature data over a copper wire to a launcher device which is operated from a ship, aircraft or submarine. The XBT has a maximum depth recording of just over 1800 m but the most popular versions focus on the upper 500 m of the ocean. The depth of the temperature readings is estimated using a depth-time equation with an accuracy of ±2% or 5 m whichever is largest.
Conductivity-Temperature-Depth (CTD) measures multiple ocean variables, with the default device typically including temperature, salinity and pressure. The vertical resolution of this device is high.
Moored Buoy (MRB) are surface floating devices which are anchored to the ocean floor. They collect both atmospheric and subsurface data which includes surface wind, rain rates, sea surface temperature, and humidity as well as subsurface temperature, current and salinity. The subsurface data is typically low vertical resolution.
Drifting Buoy (DRB) is a drifting buoy attached to ice drifts and has a subsurface profiling device tethered which measures ocean variables at a preprogrammed range of depths. A second style freely drifts in the ocean with a chain of subsurface sensors placed at discrete locations and a ballast at the end of the chain for stability.
Profiling Float (PFL) drift autonomously at a user defined depth and rise to the ocean surface to collect and transmit data via satellite. The original idea was developed by Swallow in 1955, which used a float that was neutrally buoyant at a pre-calibrated depth and was tracked by a ship to approximate ocean currents. This idea was improved through use of sonar in the 1960s with SOFAR which allowed for longer range tracking of the device. The latest profilers are based on a version of this device called the ALACE float which used a variable buoyancy device to ascend the water column after drifting and ARGOs satellite networks to communicate its locational data.
Autonomous Pinniped (APB) Data is gathered using recording devices attached to marine animals. Newer versions of this device are equipped with satellite communication which transmits data when the animal surfaces and are used to fill data gaps in harsh environments or remote areas of interest.
Glider (GLD) Data are autonomous vehicles, similar to profilers, which vary their buoyancy to descend into the ocean. The gliders have fins that allow them to descend at an angle in the ocean to traverse both vertical and horizontal distances. The Seaglider has a CTD and a fluorometer with optical/backscatter sensors, but the technology can be used to gather data from a wide range of ocean variables similar to profilers.
The present disclosure generally relates to a programmable, autonomous, sub-surface water data profiler. More specifically, the present disclosure provides a lightweight, efficient, autonomous water profiler that can be easily programmed and deployed to collect sample data at a variety of water depths.
The present disclosure features a unique, simple-to-use programmable, autonomous, sub-surface water data profiler. The device has a low-cost design with a low-cost depth control system that allows several dive/surface trips, an Android graphical interface for Bluetooth programming and a deployable antenna for retrieval after completing its mission. The data is collected using an open-source, user-friendly Android interface, and other ease-of-use implementations such as Bluetooth programming using Android and longer-range radio communications with a deployable antenna. The present design provides a product with a wider market appeal which is usable by anyone with a deep pond, lake, ocean or even a pool that they would like to monitor.
While the specification concludes with claims particularly pointing out and distinctly claiming embodiments of the instant invention, various embodiments of the invention can be more readily understood and appreciated from the following descriptions of various embodiments of the invention when read in conjunction with the accompanying drawings in which:
Certain exemplary embodiments will now be described to provide an overall understanding of the principles of the structure, function, manufacture, and use of the device and methods disclosed herein. One or more examples of these embodiments are illustrated in the accompanying drawings. Those skilled in the art will understand that the devices and methods specifically described herein and illustrated in the accompanying drawings are non-limiting exemplary embodiments and that the scope of the present invention is defined solely by the claims. The features illustrated or described in connection with one exemplary embodiment may be combined with the features of other embodiments. Such modifications and variations are intended to be included within the scope of the present disclosure. Further, in the present disclosure, like-numbered components of the embodiments generally have similar features, and thus within a particular embodiment each feature of each like-numbered component is not necessarily fully elaborated upon.
Additionally, to the extent that linear or circular dimensions are used in the description of the disclosed systems, devices, and methods, such dimensions are not intended to limit the types of shapes that can be used in conjunction with such systems, devices, and methods. A person skilled in the art will recognize that an equivalent to such linear and circular dimensions can easily be determined for any geometric shape. Further, to the extent that directional terms like top, bottom, up, or down are used, they are not intended to limit the systems, devices, and methods disclosed herein. A person skilled in the art will recognize that these terms are merely relative to the system and device being discussed and are not universal.
Parts and components are labeled throughout the drawing figures for clarity. Referring now to
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The buoyancy engine 16 is an assembly that is contained within the housing 12 and includes a piston 30 that extends into the dive control tube 22. An O-ring 29 or other suitable gasket is installed in a groove 31 about the piston to form a watertight seal between the piston 30 and the dive control tube 22 as the piston is displaced therein as will be discussed below. As can best be seen in
A stepper motor 32 is provided to operate the buoyancy engine 16. The stepper motor 32 is preferably capable of 112 oz in of torque which limits the operational depth of the water data profiler 10 device to the upper 100 m due to the water pressure exerted on the piston 30 beyond that depth. While the current configuration's capabilities may exclude it from some deep-water applications, the device is capable of being easily scaled by increasing the hull dimensions, adding a more powerful motor, increasing the dive control tube 22 length or diameter, and adding higher capacity batteries.
As already stated, the dive control system 16 includes piston 30 and dive control tube 22 wherein the dive control tube 22 has a cylinder configuration where the cylinder has a greater length than its width/diameter, allowing a predetermined amount of displacement of either air or water by moving the piston 30 within the dive control tube 22. The length to width/diameter ratio may in some embodiments be between 1:1 to as much as 20:1. The dive control tube 22 has an opening to the exterior water environment to draw water in or expel water out to change buoyancy of the device.
A stepper motor 32 is coupled to the top end of a guide rail system 34 contained within a watertight housing structure. The guide rail system 34 provides lightweight torsional stability as a guide to move the piston 30 up and down based on rotation of the stepper motor 32. A threaded rod 36, positioned within the guide rail 34 is driven in a rotational manner by the stepper motor 32, which in turn engages with a setscrew end stop trigger 38 or collar 40. As the threaded rod 36 rotates, it engages with threads in the end stop trigger 38 or collar 40 causing the end stop trigger 38 or collar 40 to advance or retract along the guide rail 34. In turn, the end stop trigger 38 or collar 40 is engaged with a piston rod 42 that engages the piston 30 positioned within the dive control tube 22 that is internal to the housing and having an end open to the exterior water environment. As the piston rod 42 drives the piston 30 down, water is discharged and the air compression within the water data profiler 10 is reduced causing a greater volume of displacement, which as a result, causes the water data profiler 10 to rise. By retracting the piston 30, water is drawn into the end of the dive control tube 22 and the air within the water data profiler 10 is compressed which reduces the volume of displacement and causes the water data profiler 10 to sink. By controlling the stepper motor 32 via control electronics 44 that contain a preprogrammed dive profile the device can autonomously execute changes in depth to follow the desired sampling pattern. There are two limit switches mounted at the upper and lower extents of the guide rail 34 that are triggered by the setscrew stop trigger to prevent over travel of the piston 30.
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One major application for the device of the present disclosure is the study of the ocean mixed layer, which plays a large roll in systems of energy transfer and biological productivity. The mixed layer is typically tens of meters deep and is a locally uniform region of the ocean which is mixed mostly by wind shear and convective motion from heat loss or gain from the diurnal cycle. Knowing the physical characteristics of the fluid in and just below the mixed layer, such as the depth and strength of the temperature and salinity stratification, gives valuable insight into the ocean's energy budget and potential for upwelling which introduces nutrient rich waters from below into the photic zone allowing for production of phytoplankton.
While there is shown and described herein certain specific structures embodying various embodiments of the invention, it will be manifest to those skilled in the art that various modifications and rearrangements of the parts may be made without departing from the spirit and scope of the underlying inventive concept and that the same is not limited to the particular forms herein shown and described except insofar as indicated by the scope of the appended claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2022/026781 | 4/28/2022 | WO |
Number | Date | Country | |
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63182267 | Apr 2021 | US |