Predictive Maintenance Testbed

Aug. 13, 2015
National Instruments and IBM are currently conducting a detailed predictive maintenance testbed with the Industrial Internet Consortium to determine specific best practices.

Predictive maintenance has been a key focus area for many Industrial Internet of Things (IIoT) initiatives because of its direct bottom line impacts. So it’s no surprise that Industrial Internet Consortium (IIC) members IBM and National Instruments (NI) have partnered to develop a Condition Monitoring and Predictive Maintenance Testbed (CM/PM).

The ultimate purpose of this testbed is to prove how IIoT-related technologies and concepts are a critical and practical part of an effective predictive maintenance strategy. After all, there’s little need these days to prove the cost benefits of predictive maintenance in and of itself. Numerous studies have already done that, such as the one by EPRI (Electrical Power Research Institute) that shows a predictive maintenance strategy costs just $9 per pump motor HP, compared to a reactive maintenance strategy which costs $17 per pump motor HP, and a preventative maintenance strategy which costs $24 per pump motor HP. Calculated out to 2000 HP of use, this translates into a $48,000 cost for preventative maintenance, a $34,000 cost for reactive maintenance, and $18,000 for predictive maintenance.

At National Instruments’ NIWeek 2015, I had the opportunity to speak with Greg Gorman, director of product management and design for IBM Analytics’ Internet of Things, and Jamie Smith, director of embedded systems at NI. Smith explained that the IBM/NI testbed with IIC started with fans and motors connected to NI CompactRIO (control and monitoring) units, with the acquired data being passed onto NI InsightsCM software for analysis and then into historians for storage. From the historians, the processed data is then passed on to Bluemix, IBM’s platform for app-centric runtimes, app containers and virtual machines—all built on open source computing technologies—for further analysis.

“We started this testbed with fans because they rotate (a common aspect of machinery monitored for predictive maintenance purposes) and are easy to throw off spec,” said Smith.

A key aspect of the testbed is to show how “we can take processing and analytics to the edge for predictive maintenance applications,” said Gorman, “and even correlate machine data with social data so that maintenance can be optimally scheduled around production requirements.”

To facilitate this kind of high-level analysis at greater scale, IBM brings its Watson cognitive services technology into play. This means that, no matter the level of complexity encountered through a vast array of capital equipment data conveyed through sensors, controllers, and analysis software, “bandwidth is not an issue with Watson’s 44 cloud-based data centers,” said Gorman.

And that kind of computing power is necessary when considering the scalability needed for all the potential uses of predictive maintenance strategies across industry. “Think about all the companies with thousands of diesel engines to monitor in their fleet,” Gorman noted.

That’s also why openness is essential, Smith added. “Some of the systems being used in industry today for PM/CM are not open and can’t adapt to all the new sensors being created. InsightsCM is open to implement new capabilities as needed, and Bluemix is wide open—it can even handle the interplay of non-traditional data from sources like Twitter and weather forecasts” to correlate with production or operations data.

Another major area of concentration of this PM/CM testbed is around the connectivity, interoperability, and security of the technologies. “We’re focusing on securing the pathways of data transfer to evaluate each security threat—including physical threats,” Smith added.

With Phase I of the testbed currently being conducted with motors, fans, and the IBM and NI technologies listed above, Phase II will involve moving from simple assets like fans and basic motors to “heavy duty assets at energy generation facilities, such as Southern California Edison,” said Smith. “Phase III will focus on moving the knowledge gained from energy generation tests to an adjacent industry, such as mining or oil and gas.”

Participants in this testbed are confident that, by proving out these technologies in a couple of critical industries, the findings will prove relevant and useful across industry. “We don't need to test this in every industry” to prove the concept and technologies’ value and viability, said Smith.

About the Author

David Greenfield, editor in chief | Editor in Chief

David Greenfield joined Automation World in June 2011. Bringing a wealth of industry knowledge and media experience to his position, David’s contributions can be found in AW’s print and online editions and custom projects. Earlier in his career, David was Editorial Director of Design News at UBM Electronics, and prior to joining UBM, he was Editorial Director of Control Engineering at Reed Business Information, where he also worked on Manufacturing Business Technology as Publisher. 

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