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MIT designs autonomous robot for oyster industry

Welfare Sustainability Technology & equipment +9 more

MIT students have collaborated with oyster farmers to create the “Oystamaran” – a robotic vehicle that can flip heavy, floating bags of oysters as they grow.

When Michelle Kornberg was about to graduate from the Massachusetts Institute of Technology (MIT), she wanted to use her knowledge of mechanical and ocean engineering to make the world a better place. Luckily, she found the perfect senior capstone class project: supporting sustainable seafood by helping aquaculture farmers grow oysters.

The Oystamaran combines the concept of a catamaran and a flipping mechanism between its two hulls

© MIT

“It’s our responsibility to use our skills and opportunities to work on problems that really matter,” says Kornberg, who now works for an aquaculture company called Innovasea. “Food sustainability is incredibly important from an environmental standpoint, of course, but it also matters on a social level.”

The project undertaken by Kornberg's capstone class came out of conversations between Michael Triantafyllou, who is MIT’s Henry L and Grace Doherty Professor in Ocean Science and Engineering and director of MIT Sea Grant, and Dan Ward. Ward, a seasoned oyster farmer and marine biologist, owns Ward Aquafarms on Cape Cod and has worked extensively to advance the aquaculture industry by seeking solutions to some of its biggest challenges.

Ward had explained that each of his thousands of floating mesh oyster bags need to be turned over about 11 times a year. The flipping allows algae, barnacles, and other “biofouling” organisms that grow on the part of the bag beneath the water’s surface to be exposed to air and light, so they can dry and chip off. If this task is not performed, water flow to the oysters, which is necessary for their growth, is blocked.

Oyster bags must be flipped multiple times during the production cycle

© Mook Farms, Maine

The bags are flipped by a farmworker in a kayak, and the task is monotonous, often performed in rough water and bad weather, and ergonomically injurious. Ward pays about $3,500 per year to have the bags turned over at each of his two farm sites — and struggles to find workers who want to do the job of flipping bags that can grow to a weight of 60 or 70 pounds just before the oysters are harvested.

Presented with this problem, the capstone class Kornberg was in brainstormed solutions. Most of the solutions, Kornberg says, involved an autonomous robot that would take over the bag-flipping. It was during that class that the original version of the “Oystamaran,” a catamaran with a flipping mechanism between its two hulls, was born.

“It was always ‘I already have this remotely operated vehicle; would it be useful to you as an oyster farmer if I strapped on some kind of sensor?’” Ward says. “They try to fit robotics into aquaculture without any industry collaboration, which leads to a robotic product that doesn’t solve any of the issues we experience out on the farm. Having the opportunity to work with MIT Sea Grant to really start from the ground up has been exciting. Their approach has been, ‘What’s the problem, and what’s the best way to solve the problem?’ We do have a real need for robotics in aquaculture, but you have to come at it from the customer-first, not the technology-first, perspective.”

Triantafyllou says that while the task the robot performs is similar to work done by robots in other industries, the “special difficulty” students faced while designing the Oystamaran was its work environment.

“You have a floating device, which must be self-propelled, and which must find these objects in an environment that is not neat,” Triantafyllou says. “It’s a combination of vision and navigation in an environment that changes, with currents, wind, and waves. Very quickly, it becomes a complicated task.”

Andrew Bennett, education administrator at MIT Sea Grant, co-taught that class, in which students designed an Oystamaran version 2.0, which was tested at Ward Aquafarms and managed to flip several rows of bags while being controlled remotely. Next steps will involve making the vessel more autonomous, so it can be launched, navigate autonomously to the oyster bags, flip them, and return to the launching point. A third capstone class related to the project will take place this spring.

Bennett says an ideal project outcome would be, “We have proven the concept, and now somebody in industry says, ‘You know, there’s money to be made in oysters. I think I’ll take over.’ And then we hand it off to them.”

Triantafyllou calls the Oystamaran “a first for the industry,” explaining that the project has demonstrated that robots can perform extremely useful tasks in the ocean, and will serve as a model for future innovations in aquaculture.

“Just by showing the way, this may be the first of a number of robots,” he says. “It will attract talent to ocean farming, which is a great challenge, and also a benefit for society to have a reliable means of producing food from the ocean.”

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