Industrial facilities such as refineries and chemical processing plants rely heavily on the use of compressed air for a variety of purposes, such as actuating valves as materials flow through vessels, reactors and pipes.
Compressed air is also used in these facilities to purge enclosures housing electronic equipment of hazardous vapours. The financial and safety risks associated with failure or malfunction of these pneumatic devices are substantial.
An instrumentation and controls engineer for ExxonMobil, Zain Sheikh has designed the Instrument Air Monitoring & Control System (IAMCS) to support industrial compressors by providing sensing, control, anti-surge protection and equipment health-monitoring capabilities to optimise a facility’s instrument air production.
Sheikh is a graduate of the online and part-time Johns Hopkins Engineering for Professionals programme where he graduated with a Masters in Systems Engineering.
“Part of my responsibilities as an engineer supporting an operating facility include working through reliability improvement initiatives; these initiatives are broken down into annual identification, planning, and execution efforts,” said Sheikh, of Beaumont, Texas, about his final Systems Engineering project.
“I thought this particular problem would be an interesting case study to work through the systems engineering methodology.”
To design the IAMCS, he leveraged a variety of resources, including model-based systems engineering tools that provided tight integration between requirements, functions, components as well as risk management tools to track mitigation activities and credits.
His solution comprises a variety of subsystems to maintain safe operation, prevent dangerous surge conditions and monitor overall system health. For instance, the IAMCS’s safety subsystem interfaces with various sensors and controls the compressor’s valves through startup and steady-state operation, he says.
“The system’s true value stems from how it was designed. More often than not, typical project execution can miss details such as interfaces, physical components and quantitative performance criteria. The robust and thorough design of the IAMCS is its defining characteristic which provides a competitive advantage and potential for further development,” he explains.
The online and part-time Systems Engineering programme at Johns Hopkins University, was the first civilian Systems Engineering Master’s degree programme to earn ABET accreditation and was recently ranked third in the nation for online Systems Engineering by US News and World Report. As one of the nation’s largest Systems Engineering Master’s degree programmes, courses are taught by expert faculty who are technical leaders from well-known government, industry and private organisations.
For more information visit engineering.jhu.edu
This editorial is sponsored by Johns Hopkins University, written by Lisa Ercolano