The Turbomachinery Laboratory at Texas A&M University is a 35k ft2 research facility dedicated to conduct research in turbomachinery performance and reliability (http://turbolab.tamu.edu). The Laboratory, located 1.5 miles away from main Campus, is known world-wide as the most advanced of its class, with multi-million dollar facilities supported by the oldest university-industry consortium in the US (TAMU Turbomachinery Research Consortium) and revenue from the International Turbomachinery Symposium and International Pump Symposium. The annual Symposia, the largest in the world, are continuing education events attracting thousands of engineers, vendors and suppliers of rotating machinery.
Facilities at The Turbomachinery Laboratory
The Laboratory contains 12 test cells, three of which are dedicated to research high-speed seal and bearing technologies (129, 134 & 140). Each test cell is a 20′ x 25′ x 12′ air conditioned space with a separate control room, 20′ x 25′. Each test cell has acoustical isolation walls and ceiling; a sealed concrete floor with isolation slabs; one 480V 400A buss bar electric power supporting the following circuits: five 120V (30A), four 208V (20A), two 208V (50A) single and three-phase. Each cell can be supplied with 30 gallon/minute water supply; 4″ floor drain with oil separator. The whole laboratory has a fireproof water sprinkler system, flame retardant floors and walls, etc. Laboratory compressor facilities deliver dry and oil-free pressurized air: (a) 4″ at 300 psi and 1350 cfm, (b) 4″ at 125 psi and 1800 cfm, and (c) 3″ 2,375 psi. The laboratory 40′ x 125′ x 25′ air conditioned high bay is equipped with a 20-ton overhead crane. The Laboratory also includes a fully equipped machine shop, a welding shop, a sheet metal fabrication shop, an electronics repair facility, and a woodworking shop.
Test rigs for High Speed Bearings and Seals at The Turbomachinery Laboratory
The TurboLab hosts the Rotordynamics Laboratory in three test cells that accommodate a number of test rigs for the experimental validation of the dynamic response of fluid film bearing and seal (liquid and gas) elements used in high performance turbomachinery, including micro turbomachinery (MTM).
Test rig for static and dynamic performance of radial gas foil bearings
Unique test facility to measure the static and dynamic load performance of gas (oil-free) bearings for advanced turbochargers, micro turbines and fuel cells as applied to microturbomachinery. The test rig design allows the easy installation and dismantling of test bearings, 35 mm OD. The rig consists of a ball-bearing T25 turbocharger modified by replacing the compressor wheel with a test bearing section. The maximum shaft speed is 75 krpm (cold air supply). Two 100 N (20 lbf) electromagnetic shakers apply dynamic load excitations to 600 Hz on the bearing and an ad-hoc mechanism applies static loads on the test bearing mounted atop a precise positioning electronic system. The instrumentation includes eddy current sensors, load cells and accelerometers to delver the test system frequency response and identification of force coefficients over a frequency range. Facility used to measure (for the first time) the force coefficients of metal mesh foil bearings, shimmer bump-type foil bearings, as well as to quantify the effect of coatings on foil bearing performance.
Test rig for static and dynamic performance of radial gas foil bearings
Unique test facility to measure the static and dynamic load performance of gas (oil-free) bearings for advanced turbochargers, micro turbines and fuel cells as applied to microturbomachinery. The test rig design allows the easy installation and dismantling of test bearings, 35 mm OD. The rig consists of a ball-bearing T25 turbocharger modified by replacing the compressor wheel with a test bearing section. The maximum shaft speed is 75 krpm (cold air supply). Two 100 N (20 lbf) electromagnetic shakers apply dynamic load excitations to 600 Hz on the bearing and an ad-hoc mechanism applies static loads on the test bearing mounted atop a precise positioning electronic system. The instrumentation includes eddy current sensors, load cells and accelerometers to delver the test system frequency response and identification of force coefficients over a frequency range. Facility used to measure (for the first time) the force coefficients of metal mesh foil bearings, shimmer bump-type foil bearings, as well as to quantify the effect of coatings on foil bearing performance.
Test rig for evaluation of radial gas foil bearings operating at high temperature
Built with funds from NASA Glenn RC, the facility allows the evaluation of radial foil bearings operating at high temperature (300C). A 10 kW motor drives a rotor supported on gas foil bearings, and an electric cartridge heater increases the temperature of the hollow test rotor. Measurements include rotor displacements using optical and infrared sensors and temperatures in the bearing cartridges. The rotor imbalance response to 50 krpm reveals the test system response, linear and nonlinear, with a parameter estimation to deliver the bearings’ effective stiffness and damping coefficients. Tests conducted to evaluate survivability of high temperature coatings for foil bearings as well as shimmed foil bearings for MTM.
Test rig for dynamic response of rotor-motor supported on gas bearings
Built with NSF funds, the facility quantifies the response of gas bearings, flexure pivot type and porous type. An AC high frequency motor integral to the rotor with speed of 100 krpm. A pair of bearings support the test rotor (29 mm OD) to conduct tests recording the imbalance response due to a number of external excitations including road conditions (intermittent impacts) as well as base support (IC engine excitations) at low frequencies.
Test rig for static and dynamic performance of lubricated high speed bearings and seals
State of the art industrial facility with years of service to the turbomachinery industry. Sponsors (users) include various compressor manufacturers and bearing / seal makers. Air turbine (50 kW) drives a rigid rotor supported on ball bearings. Test bearing/seal element flexibly supported at rotor middle span and connected to two shakers with maximum dynamic load of 1,000 lbf @ 320 Hz and a hydraulic static loader with maximum load of 10,000 lbf (specific load=350 psi). Rotor top surface speed is 80 m/s at 16 krpm. Instrumentation includes an in-line torquemeter, sensors for rotor displacement, and bearing accelerations and loads, and flowmeters. Bearings instrumented with up to 40 thermocouples. Operation of test rig automated with various control systems.
Test rig for static and dynamic performance of gas seals for advanced turbomachinery
Test rig to measure the performance of gas labyrinth seals for steam turbines and compressors. A variable frequency drive motor turns a heavy shaft (250 lbf) that is supported on magnetic bearings. These bearings also serve to excite dynamically the rotor to whirl inside the seal test section. The housing and tests seals are split in two for easy assembly of interlocking labyrinth seals. The rig architecture takes advantage of additive manufacturing to produce inlet swirl vanes, swirl brakes and exit labyrinth seals. The rotor 150 mm in diameter at the seal section spins to a top speed of 10 krpm (surface speed of 80 m/s). Pressurized air to 300 psi and a controlled exit pressure determine the test conditions for measurement of seal leakage and pressure cavities, static and dynamic. Sponsors include steam turbine manufactures.
Test rig for dynamic performance of advanced squeeze film dampers for aircraft engines
Test rig to measure the dynamic forced performance of advanced squeeze film dampers used in aircraft engines, commercial and military. A major jet engine manufacturer funded the test program during ten years to produce ultra-short dampers with unsurpassed energy dissipation characteristics. This research facility is top in the world. The test rig comprises a massive bearing cartridge (BC) supported on four elastic rods that provide a centering stiffness. The journal is solid and affixed to a heavy table. Two orthogonally positioned shakers and stingers connect to the BC and deliver excitation forces (max. 500 lbf). Engineered squeeze film damper sections are tested under a myriad of operating conditions. Measurements include film dynamic pressures, and applied forces and displacements for identification of damping and inertia force coefficients over large frequency ranges (to 200 Hz). The facility continues to produce test results for high frequency operation with natural air ingestion that degrades the performance of dampers and also while operating under severe maneuver loads and high altitude conditions.
Other test rigs
- High temperature brush seals (leakage)
- Water thrust hydrostatic and radial bearings for turbopumps (rotordynamic response)
- Carbon-graphite gas bearings – characterization of rotordynamic response
- Test rig for evaluation of gas/wet seals for the subsea industry
Computational Facilities
A cluster of high speed networked PCs to conduct CFD analyses for turbomachinery components
