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    3D Printer solves engineering challenges onboard USS Somerset

    USS Somerset Sailor cuts 3D printed component

    Photo By Petty Officer 2nd Class Evan Diaz | Hull Technician 3rd Class Mario EnriquezSanchez, a Denver native, cuts the baseplate...... read more read more

    PACIFIC OCEAN

    07.19.2024

    Story by Lt. Zachary Anderson 

    Commander, U.S. 3rd Fleet           

    When the team of engineers from the Consortium for Advanced Manufacturing Research and Education (CAMRE) loaded their 3D hybrid-metal printer onboard Somerset as part of the experimentation sector of Exercise Rim of the Pacific 2024, they had no idea that they would soon be asked to solve a real-world engineering casualty.

    Hours after being loaded on board, a critical component of the reverse osmosis pump, which generates clean water for the crew – an absolute necessity for ships spending long periods at sea – shattered.

    “What we didn’t expect was that we would have the opportunity to directly help ship readiness so soon,” said Lt. Charles Wallace, a mechanical engineer from the Naval Postgraduate School, and one of the team members onboard. “Especially for something as mission-essential as a reverse osmosis pump, where if you run out of water you’re going to be coming home pretty quick.”

    3D printing, or additive manufacturing (AM), has been a major area of interest for Department of Defense in recent years. In January 2021, the DoD published its first-ever Additive Manufacturing Strategy to “provide a shared set of guiding principles and a framework for AM technology development and transition to support modernization and warfighter readiness,” across the military.

    “For Trident Warrior, CAMRE organized the largest distributed advanced manufacturing demonstration the Department of Defense has ever conducted to date,” explains Lt. Col. Michael Radigan with the Marine Innovation Unit, and government lead on the CAMRE team. “This was accomplished by linking advanced manufacturing equipment, joint subject matter experts, and commercial partners to tackle real-life readiness solutions.”

    The benefits of successfully implementing additive manufacturing on ships include saving time, money, space, and increasing overall warfighting readiness by allowing for repair and replacement of equipment in a contested environment. In the case of Somerset, had the reverse osmosis pump failed during their 6-month deployment, it would have reduced their ability to produce drinking water for the Sailors and Marines.

    “If the crew had to rely on a replacement part without using additive manufacturing, it would have taken weeks or months,” said Staff Sgt. Jordan Blake, a member of the Marine Innovation Unit, and tasked with technical oversight of the project aboard ship. “With this technology, we’ll have the new component printed and ready for installation before the order for a replacement would be completed.”

    While 3D printing on Navy ships is still in its infancy, Somerset is not the first ship to utilize AM. In April, 2024, the amphibious transport dock USS San Diego (LPD 22) piloted a liquid metal jetting additive manufacturing process fielded by the CAMRE team, operationally showcasing this novel technology’s capabilities at sea.

    What makes the Somerset demonstration unique, is that the machine is a metal hybrid design, combining subtractive and additive manufacturing in one machine. Subtractive manufacturing is an umbrella term for the process by which solid blocks of material are shaped into the desired object via cutting, boring, drilling, and grinding. This is in contrast to additive manufacturing, which builds something by adding material one layer at a time – hence additive.
    Oftentimes, constructing a replacement part involves both additive and subtractive manufacturing. Before they tested the model on Somerset, this meant alternating between different machines, however by combining the two processes it effectively streamlines the overall workflow.

    “The benefit of a system like this is that you’re able to computerize [a component], send the code, then once you’ve printed something, it becomes replicable,” said Wallace when asked how the hybrid machine represents a step forward for the military.

    Not only is 3D printing faster and safer than traditional machinery repair, but the replacement parts are often stronger as well. The weld is nearly as strong, or stronger, than the parent metal. AM is essentially building through welding, which means the replacement pump will potentially surpass the strength of the previous version.

    The project builds upon a unique cross-sectional effort from the DoD and industry partners to provide hands-on experience for military students. The printer test itself falls under the umbrella of CAMRE, which funded the project and sent four NPS students to study advanced manufacturing capabilities in an operational scenario. Two soldiers on the team operate the printer and three Marines operate the polymer printers which help augment the capabilities of the metal printer.

    A project engineer and representative for the industrial printer’s parent company, is also on hand to teach the Somerset crew to operate the printer independently. This includes a combined effort with ship's company machinery repairmen, providing feedback and guidance to correctly build and fit the new component.

    The intent of Trident Warrior and, more broadly, Fleet experimentation is to allow the Navy and its partners to incorporate real-world warfighter feedback early in the acquisition process by exposing the Fleet to emerging capabilities. Repairing the reverse osmosis pump on Somerset in an operational scenario demonstrates why operationalizing 3D printing capabilities remains a focus for many leaders in DoD.

    3D printing will directly contribute to Somerset accomplishing something previously impossible – the creation, repair, and replacement of vital equipment at sea. While the Department of Defense may face various material readiness issues to come, there is no doubt that advanced manufacturing will be a part of future solutions. 3D printing opens new avenues to ensure the U.S. Navy can provide continuous security and stability from any place, at any time.

    Twenty-nine nations, 40 surface ships, three submarines, 14 national land forces, more than 150 aircraft, and 25,000 personnel are participating in RIMPAC in and around the Hawaiian Islands, June 27 to Aug. 1. The world’s largest international maritime exercise, RIMPAC provides a unique training opportunity while fostering and sustaining cooperative relationships among participants critical to ensuring the safety of sea lanes and security on the world’s oceans. RIMPAC 2024 is the 29th exercise in the series that began in 1971.

    NEWS INFO

    Date Taken: 07.19.2024
    Date Posted: 07.19.2024 17:30
    Story ID: 476635
    Location: PACIFIC OCEAN

    Web Views: 1,164
    Downloads: 4

    PUBLIC DOMAIN