Like a game Snake come to life, a new robot being developed at Stanford grows like a vine and has the ability to weave through tight spaces to provide applications from disaster relief to simplifying construction projects.
The main idea behind the robot is uncomplicated; the “snake” is a tube of soft thin plastic that is folded inside itself. As the material is forced out, either pneumatically or hydraulically, the robot grows longer. According to Stanford, the robot’s design is so useful because the tip moves and results in growth while the body remains stationary, making it incredibly difficult for the robot to become stuck.
“The body can be stuck to the environment or jammed between rocks, but that doesn’t stop the robot because the tip can continue to progress as new material is added to the end,” says Elliot Hawkes, a visiting Assistant Professor from the University of California, Santa Barbara in a Stanford article on the robot.
As the robot grows, it can pull cables along, which means it could be used in the construction industry to help wire new and renovated buildings by traveling in the walls, floors, or ceilings. The robot can make turns via a control system that differentially inflates the body and a software system bases direction decisions on images received from a camera at the tip, so pipes or other obstacles already located in the wall, ceiling, or floor space become non-issues.
Other applications include scaling the robot up for search and rescue operations, growing vertically to act as an antenna, or being used to deliver materials, such as water, to hard to reach places.
The robot is detailed in a Science Robotics paper published on June 19.
Related Stories
| Mar 12, 2014
14 new ideas for doors and door hardware
From a high-tech classroom lockdown system to an impact-resistant wide-stile door line, BD+C editors present a collection of door and door hardware innovations.
| Mar 10, 2014
Meet Tally – the Revit app that calculates the environmental impact of building materials
Tally provides AEC professionals with insight into how materials-related decisions made during design influence a building’s overall ecological footprint.
| Mar 7, 2014
Thom Mayne's high-tech Emerson College LA campus opens in Hollywood [slideshow]
The $85 million, 10-story vertical campus takes the shape of a massive, shimmering aircraft hangar, housing a sculptural, glass-and-aluminum base building.
| Mar 4, 2014
How EIFS came to America
Design experts from Hoffmann Architects offer a brief history of exterior insulation and finish systems in the U.S.
| Feb 20, 2014
5 myths about cross laminated timber
A CLT expert clears up several common misconceptions and myths surrounding the use of wood as a building material.
| Feb 19, 2014
Harvard's 'termite robots' can build any thing, any way [video]
The robots build by observing thier environment and then obeying a set of traffic rules programmed by researchers.
| Feb 14, 2014
Scrap tires used to boost masonry blocks at Missouri University of S&T
Research could lead to blocks that use waste material and have seismic and insulating benefits.
| Feb 14, 2014
The Technology Report 2014: Top tech tools and trends for AEC professionals
In this special five-part report, Building Design+Construction explores how Building Teams throughout the world are utilizing advanced robotics, 3D printers, drones, data-driven design, and breakthroughs in building information modeling to gain efficiencies and create better buildings.
| Feb 14, 2014
Crowdsourced Placemaking: How people will help shape architecture
The rise of mobile devices and social media, coupled with the use of advanced survey tools and interactive mapping apps, has created a powerful conduit through which Building Teams can capture real-time data on the public. For the first time, the masses can have a real say in how the built environment around them is formed—that is, if Building Teams are willing to listen.
| Feb 13, 2014
University officials sound off on net zero energy buildings
As part of its ongoing ZNE buildings research project, Sasaki Associates, in collaboration with Buro Happold, surveyed some 500 campus designers and representatives on the top challenges and opportunities for achieving net-zero energy performance on university and college campuses.
