This guest blog post is part of a series written by Edward J. Farmer, PE, author of the new ISA book Detecting Leaks in Pipelines. To read all the posts in this series, scroll to the bottom of this post for the link archive.
Assessing process conditions, such as whether a pipeline is leaking, begins with some core strategy, such as the law of conservation of mass. Whatever it is, the chosen strategy enables identification and definition of the process parameters that must be observed to reliably assess it. Each of these parameters must be accounted for, either by assumption or from measurements. Measurements must be sufficiently accurate and often to provide observability of the process including transient events of interest, such as a leak developing. These parameters are usually affected by local conditions at the leak site, other conditions in the pipeline, the location of the leak, and, of course, its size.
Generally, the size of the leak affects the relevant parameters and the observed changes in them help with determining of the state of the pipeline. The precision of those measurements (their accuracy) must be adequate to disclose information relevant to the requirements of the monitoring methodology applied. Timing matters – a reading taken yesterday, or this morning, or an hour ago does not help with assessing an event that comes and goes over a period of a few minutes at the most. The set of parameter measurements must be related in time (coherent) to the degree they can reliably be assessed as resulting from the same initial cause. The inherent timing and accuracy of the observations must not be degraded by transmission, collection, storage, and data management.
Assuming all those conditions are met, the observations can be submitted to an inference engine, e.g. for analysis, resulting in an assessment of the condition of the process:
Some response plans benefit from an assessment of the leak’s location. The inference engine can estimate the location of the leak. Location speed and accuracy depend on observability. Almost any desired location accuracy is achievable, but the economic value of enhanced precision is determined from the direct benefit the investment required to achieve it provides. Some situations also benefit from an estimate of the size of a detected leak. Categorizing into assessments like “tiny” or “huge” can usually be accomplished with training in data interpretation or immediate human inspection. When warranted, the inference engine can be set up to calculate the leakage rate as data from the pipeline accumulates and measurements stabilize in the “leaking” condition. It’s worth remembering that observability of leak-related parameters involves a frequency of measurement that supports seeing the changes that come and go as the event proceeds and stabilizes.This can be as simple as a daily mass balance (a common goal in the 1960s) or it can involve detection in a fraction of a minute with location determination within a few meters. The equipment to meet these disparate goals is very different in design and cost – most of it didn’t even exist in the 1960s. In the 1980s I had a four-inch pipeline running down my longest office hallway with three plugged holes in it. An in-line centrifugal fan produced air flow. A potential user was asked to walk down the hallway and pull out one of the plugs, and then I would immediately yell the number of the hole he’d opened. This was impressive and confidence-building but implementation benefit (as assessed from measurement and communication cost) often got in the way. So, the performance characteristics of interest are:
Testing – applicable and relevant testing – is crucial to assessing performance. It must be relevant, pertinent, and repeatable. It’s a great subject for a future post.
How to Optimize Pipeline Leak Detection: Focus on Design, Equipment and Insightful Operating Practices
What You Can Learn About Pipeline Leaks From Government Statistics
Is Theft the New Frontier for Process Control Equipment?
What Is the Impact of Theft, Accidents, and Natural Losses From Pipelines?
Can Risk Analysis Really Be Reduced to a Simple Procedure?
Do Government Pipeline Regulations Improve Safety?
What Are the Performance Measures for Pipeline Leak Detection?
What Observations Improve Specificity in Pipeline Leak Detection?
Three Decades of Life with Pipeline Leak Detection
How to Test and Validate a Pipeline Leak Detection System
About the Author
Edward Farmer has more than 40 years of experience in the “high tech” part of the oil industry. He originally graduated with a bachelor of science degree in electrical engineering from California State University, Chico, where he also completed the master’s program in physical science. Over the years, Edward has designed SCADA hardware and software, practiced and written extensively about process control technology, and has worked extensively in pipeline leak detection. He is the inventor of the Pressure Point Analysis® leak detection system as well as the Locator® high-accuracy, low-bandwidth leak location system. He is a Registered Professional Engineer in five states and has worked on a broad scope of projects worldwide. His work has produced three books, numerous articles, and four patents. Edward has also worked extensively in military communications where he has authored many papers for military publications and participated in the development and evaluation of two radio antennas currently in U.S. inventory. He is a graduate of the U.S. Marine Corps Command and Staff College. He is the owner and president of EFA Technologies, Inc., manufacturer of the LeakNet family of pipeline leak detection products.