Issued on: January 21, 2003
Experimental Fiber Optic Cables To Warn of Potential Pipeline Damage
First Field Test of High-Tech Method for Improving Safety of the Nation's Gas Delivery System
Des Plaines, IL - Every year natural gas pipelines are damaged by construction activities even though warning signs often mark utility right-of-ways. Now, a new fiber optic cable system being tested in a joint U.S. Department of Energy/Gas Technology Institute (Des Plaines, IL) project could give gas pipeline companies a remote method for detecting encroaching construction activity and help prevent potentially harmful accidents.
||A technician deploys the underground fiber optic "early warning system."
This month, in the first field test of the system, crews from ANR Pipeline Company, a subsidiary of El Paso Corp. of Houston, TX, buried fiber optic cables over one mile of active pipeline in northwest Indiana.
During the next several months, construction equipment will create vibrations in the ground, causing compressions in the soil surrounding the pipeline. If the vibrations and soil compressions are sufficiently close to the pipeline, the fiber optic cable will bend ever so slightly. Even a minute deformation in the cable will change its light transmission and reflection properties and send an early warning of a potentially hazardous encroachment.
"Third-party damage" is the major cause of damage to natural gas transmission pipelines. As urban areas expand and the demand for natural gas increases, buildings are being constructed increasingly closer to pipelines. More construction near pipelines increases the probability and consequence of damage.
Several approaches have been suggested or are being studied for detecting potentially harmful impacts on the hundreds of thousands of miles of underground gas pipelines that crisscross the United States. Satellite, ground-based visual, and global positioning system monitoring systems are among the new technologies being studied to help protect the integrity of the nation's pipeline system. Fiber optic technology, however, is projected to be one of the least costly options. Moreover, it can help prevent pipeline damage, not simply detect it after it happens.
GTI will test four different fiber optic cables. Three multi-mode fibers (Hergalite®, Corning® 62.5/125 and Corning® 50/125) and one single-mode fiber (Fibercore Limited's SM600), were buried above the pipeline approximately 15-50 centimeters below the surface of the ground.
Construction equipment does not have to break the fiber to be detected. When intrusion is detected, an alarm sounds, alerting the pipeline company of equipment encroaching on its pipe. This would enable pipeline companies in the future to take immediate action to stop unauthorized excavation and prevent potential damage to the pipeline.
The system not only can warn of approaching construction activity, it can also help operators pinpoint where along the pipeline the potential hazard is developing. Stresses in the fiber optic cable will cause some of the light to be reflected back to its source. Because the velocity of light in the fiber will be known, the location of the encroaching equipment can be determined by measuring the time for the reflected light pulse to return.
The largest technical barrier to perfecting fiber optic cable technology for pipelines is in developing methods to distinguish between potentially hazardous and benign intrusions into the right-of-way. Compared to benign activities and noises, such as pedestrian traffic and thunder, construction equipment will be large and have characteristic signals. One goal of the project is to minimize or eliminate false readings from the cables through all seasons and soil conditions.
The research project is funded through the DOE Office of Fossil Energy's Natural Gas Delivery Reliability Program, which is managed by the National Energy Technology Laboratory. Results of the project are expected in the fall of 2003.
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For more information, contact:
David Anna, DOE National Energy Technology Laboratory, 412/386-4646, e-mail: firstname.lastname@example.org
Rodney J. Anderson, DOE National Energy Technology Laboratory, 304/285-4709, e-mail: email@example.com
Daniel J. Driscoll, DOE National Energy Technology Laboratory, 304/285-4717, e-mail: firstname.lastname@example.org