Explosions caused by leaking gas pipes under city streets have frequently made headlines in recent years, including one that leveled an apartment building in New York this spring. But while the problem of old and failing pipes has garnered much attention, methods for addressing such failing infrastructure have lagged far behind. Typically, leaks are found using aboveground acoustic sensors, which listen for faint sounds and vibrations caused by leakage, or in-pipe detectors, which sometimes use video cameras to look for signs of pipe breaks. But all such systems are very slow, and can miss small leaks altogether. Now researchers at Massachusetts Institute of Technology (MIT) and King Fahd University of Petroleum and Minerals (KFUPM) in Saudi Arabia have devised a robotic system that can detect leaks at a rapid pace and with high accuracy by sensing a large pressure change at leak locations. The concept was presented at two recent international conferences, and has been described in several recent papers. This new system “can detect leaks of just 1mm to 2mm, and at relatively low pressure”, according to Dimitrios Chatzigeorgiou, a PhD student in mechanical engineering at MIT and lead author of the research papers. “We’ve proved that the concept works.” The researchers have begun discussions with gas companies and water companies — the system can also detect leaks in water pipes, or in petroleum pipelines — about setting up field tests under real-world conditions. Chatzigeorgiou presented the concept this month at the International Conference on Robotics and Automation in Hong Kong, and at the American Control Conference in Portland, Oregon. CURRENT ACOUSTIC TESTS  [caption id="attachment_15085" align="alignright" width="639"] Rendering of robotic device (Image: Christine Daniloff/MIT)[/caption] Current acoustic tests are only effective for detecting sound and vibration in metal pipes, Chatzigeorgiou said – plastic pipes tend to dissipate the sounds too quickly. Such systems are also time-consuming and require expert operators, he explained, whereas the small robotic device that he and his collaborators have developed can move as fast as three miles per hour through pipes, and are almost entirely automated. Ultimately, according to Chatzigeorgiou, such devices could be put into a system of pipes and left in place indefinitely, conducting automatic, nonstop monitoring of the system. In addition to their potential for dangerous explosions, leaking gas pipes can be a significant contributor to global warming. Methane, the primary constituent of natural gas, is a greenhouse gas that is 25 times more potent than carbon dioxide. Leaks in water pipes can waste up to half the water in a system; oil-pipeline leaks can lead to toxic spills and prolonged, expensive cleanup operations. All of these systems could benefit significantly from improved leak-detection methods, according to the engineers. While existing detection systems work under certain conditions, there is not yet an approach that can efficiently detect leaks in any of these pipe systems. “We believe this can solve the general problem,” Chatzigeorgiou said. The new device could be produced in various sizes to fit different kinds of pipes and should be effective in gas, water and oil pipes. MIT mechanical engineering professor Kamal Youcef-Toumi, a co-author of the research papers, added: “This technology allows for an unambiguous and reliable sensing of very small leaks that often go undetected for long periods of time.” The current device consists of two parts: a small robot, with wheels to propel it through pipes (or, in some cases, to simply be swept along by flowing liquid) and a drum-like membrane that forms a seal across the width of the pipe. When a leak is encountered, liquid flowing toward it distorts the membrane, pulling it slightly toward the leak site. That distortion can be detected by force-resistive sensors via a carefully designed mechanical system (similar to the sensors used in computer trackpads), and the information sent back via wireless communications. Detecting leaks by sensing a pressure gradient close to leak openings is a novel idea and Chatzigeorgiou said it was key to the effectiveness of this method: this approach can sense a rapid change in pressure close to the leak itself, providing pinpoint accuracy in locating leaks. It also allows for relatively rapid monitoring of large systems: At present, the three-miles-per-hour top speed of the device is imposed by the propulsion motors and not the detector itself, so faster surveying is possible. DETECTING MORE SMALLER LEAKS Because of the sensitivity of the membrane, Chatzigeorgiou and his colleagues believe that the system can detect leaks one-tenth to one-twentieth the size of those that can be detected by most of the existing methods. At present, the system requires a fairly uniform pipe diameter, but the researchers are working on a version that will have more flexibility to deal with variations caused by damage, obstacles or scale buildup inside pipes. Co-author Rached Ben-Mansour, a professor of mechanical engineering at KFUPM, said that current leak-detection systems were quite expensive, typically costing $250,000 (€312,000) annually to monitor 100 kilometers of pipe. “We’re hoping this system will be much more affordable,” he said, as well as faster and more sensitive. The research was supported by KFUPM through the Center for Clean Water and Energy at MIT.