Engine Test Cells have been around for the aviation industry since the dawn of the industry.  The Wright Brothers performed extensive testing on their small piston engine to verify performance with their belt driven propeller system.  As mechanics, they understood not only that a motor is only as good as the parts and the people who put those parts together, but that a motor must be tested as a working system prior to installation.  Why is that, you ask?  Because once you’re in the air, the time for verifying performance is over.   Over 100 years after that historic flight at Kitty Hawk, the song remains the same, so to speak.  Whether an engine is being built for the first time or thousandth, it has to be tested for performance verification prior to flight.

As such, Engine Test Cells are a necessary evil.  The Test Cells are typically not a profit center, even for an MRO.  That being said, heaven help you if you don’t test an engine and your aircraft falls from the sky due to engine-related failure. Engine Test Cells—you can’t live with them, and you certainly can’t live without them!

(more…)

In the old days, your test cell had an engine mount, a few gauges, a few hoses and cables, a start system, a fuel system and a pad of paper, and you were ready to fire up.  However, since the inception of powered flight, engine power and complexity have increased at an exponential rate, especially with the advent of the jet engine in the years after WWII, and then again with the introduction of digital controls.

Enter the economy.  The last few years have wreaked havoc with the aviation industry.  Rising fuel costs have made it even more expensive to operate aircraft.  Specific fuel consumption is now of paramount importance.  Flight readiness of an aircraft—whether for private fleets, military, corporate or commercial air operators—is critical.  If an aircraft is on the ground, it is not performing its mission or making money, plain and simple.   The economics of maintenance have come under increased scrutiny for both the military and commercial sectors.  “Give me the safest, most reliable engines you can for the least amount of money,” has become the standard for MRO.

Enter the environment.  By their nature, Engine Test Cells are not cut out to be nice, earth-friendly neighbors in the community.  No one ever wakes up and says “Gee, I hope we get a turbine engine test cell built next to us, because that would sure help our property values increase.”  Test Cells are smelly, dirty, noisy neighbors full of fuel, oil, and grease—commonly referred to as hydrocarbons—and they literally emit tons of combustion by-products into the air with every engine test.

Enter the FAA and OSHA.   Worldwide guidelines for aircraft safety and the health and safety of maintenance employees have also increased significantly over the past few decades.  Fire systems are rarely simple, hand-held extinguishers anymore, for example, but are fully automated release systems that automatically notify the fire department.  Fire retardant agents have become more expensive as the standard oxygen-depleting fire systems, like Halon, have been deemed environmentally unfriendly.   Control rooms have to allow the personnel inside to carry on conversations to protect users from hearing loss.  These are all good things, but they come with a price tag.

Let’s go back to the economics for a minute. As a test cell, being a good neighbor costs money—lots of it.  Acoustic treatments and environmental containment also drive a tremendous amount of cost into test cells.  As we are all aware, any noisy activity, be it a rock concert or a NASCAR race, is always compared to the noise of a jet engine.  Everyone is geared from birth to think of jet engines as the noisiest thing on the planet.  Test Cells have migrated from outdoor operations to indoor, fully acoustic isolated structures.  A new test cell to test the 100K+ thrust engines that power large commercial jet liners can now cost upwards of $40-50 million dollars.  Building construction and acoustical measures account for over half the cost. Depending on location, another 10-15% of cost can be wrapped up in environmental containment and safety issues.

Test Cells still have the same mission as they did with the Wright Brothers: verifying engine performance prior to flight.  How that mission gets accomplished however is very different  today.

• The hand-loaded engine mount and cables/hoses have been replaced by automated coupling systems that join fuel and electrical connections.
• The engine adapter connections are intertwined with the Test Cell Control system through PLCs to maximize safety.
• The open area around the engine test system has been surrounded by complex acoustic enclosures, with extensive sound treatment for inlet and exhaust noise control.
• High volume/velocity air flows are critical to performance measurement.
• Computerized Data Acquisition and Control Systems must be constantly maintained and updated to handle the latest engines.
• Fuel System containment
• Safety and Training are now key elements of successful performance verification.

On one hand, you could argue from a safety and operational readiness standpoint that test cells should be your most appreciated asset, but, on the other you could say that Test Cells are the single biggest sunk cost for an MRO; they are pure overhead and a pain in the neck to maintain.

So how does today’s Director of Maintenance balance their shop mission and engine test cell requirements, and incorporate all the latest gadgets to handle the ever increasing complexity of engines all on a slashed budget?  Terms like sunk costs, fixed assets, contribution, tooling charges, consumables, re-test, qualifications, etc., have turned the operation into a full-on business enterprise.

The challenges of Engine Test Cells for 2012 and beyond are balancing cost and schedule against capability, reliability and performance.  The days of “the sky’s the limit”are past.  Today’s MROs have to be both technically as well as business savvy.

*****

The purpose of this post area is to discuss the challenges posed by the Test Cells of today and tomorrow in both generalities and in specific details.  Please feel free to comment on our cover post or start your own thread regarding how you see the Challenges of Test Cells.