The Serpent remotely operated vehicle (ROV) from Seaview Systems is designed for exploring very small-diameter pipelines. It can investigate conduits as small as 9 inches (23 cm) in diameter, and fit around bends with a radius as narrow as 27 inches (68.5 cm). Measuring 9 inch x 9 inch x 57 inch (23 cm x 23 cm x 145 cm) and weighing 70 lb (32 kg), the Serpent runs on two 300W brushless DC motors that give it a total forward thrust of 18 lb (8 kg). With a 0.5 inch (1.3 cm) diameter fiber-optic tether, it can explore as far as 6,000 ft (1,830 m) down a pipe or tunnel. A 360-degree pan/orbit/zoom color camera and two color cameras are included, along with two 70W high-intensity LEDs. The robot also has heading, pitch and roll, and depth sensors, as well as sonar. A fiber-optic telemetry system provides up to three video channels, four RS232 channels, and two RS485 channels. (Source: Seaview Systems)
I think you're right, Rob. The two things I noticed that came up again and again in underwater robot design were, of course, seals and water-tight protection of electronics etc., but also movement through water and how differently it must be engineered than movement through air. That said, most of these robots' purpose is neither speed nor maneuverability but to carry out certain research or military functions, usually some kind of surveillance or data gathering. Speed and maneuverability are generally secondary or even tertiary goals, with one or two exceptions, for instance, the robots that have to squeeze into tight spaces, such as this robotic tuna: http://www.designnews.com/author.asp?section_id=1386&doc_id=251209
Ann, if shape matters underwater, I would imagine we'll see more and more robots that take a lead from nature. How that will play out will probably depend on the purpose of the robot -- whether it's intended for speed or maneuverability.
Of course it could be t6hat the material is just descriped as "styrofoam" even though it is one of those inorganic silicon based materials, or even a whote ceramic foam. And possibly purchasing substituted something"just as good".
Thanks, William, glad you enjoyed the slideshow. I had the same reaction to the Styrofoam material on hydrocarbon lakes on Titan's moon. But this *IS* a prototype, and that material will no doubt be changed out along the way, after some of the basic ME design is under control.
Images 1 through 12 each have a link as well. I'm suggesting having that link point to the next page. Now, on the page with image 10 on it for example, the image has a link to the current page with image 10 on it and "next" has a link to the next page with image 11 on it. Can't the image point to the next page also?
According to a study by the National Institute of Standards and Technology, one of the factors in the collapse of the original World Trade Center towers on Sept. 11, 2001, was the reduction in the yield strength of the steel reinforcement as a result of the high temperatures of the fire and the loss of thermal insulation.
Robots are getting more agile and automation systems are becoming more complex. Yet the most impressive development in robotics and automation is increased intelligence. Machines in automation are increasingly able to analyze huge amounts of data. They are often able to see, speak, even imitate patterns of human thinking. Researchers at European Automation
call this deep learning.
The promise of the Internet of Things (IoT) is that devices, gadgets, and appliances we use every day will be able to communicate with one another. This potential is not limited to household items or smartphones, but also things we find in our yard and garden, as evidenced by a recent challenge from the element14 design community.
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