Experimental Investigation of Vane Clocking in a One and 1/2 Stage High Pressure Turbine

Haldeman, Charles W.; Dunn, Michael G.; Barter, John W.; Green, Brian R.; Bergholz, Robert F.

doi:10.1115/gt2004-53477

Cited by 12 publications

(1 citation statement)

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“…Measurements done by Huber et al [13] demonstrate that a clocking position delivered 0.8% higher efficiency than the others. At Ohio State University, Haldeman ([14] and [15]), completed an aero-thermal experimental investigation of the clocking effects on a HP turbine stage followed by a LP vane placed in a S-duct. He reported an overall efficiency increase of about 2-3% using a variety of independent methods, but the authors conclude that substantial effects have to be taken into account, namely cooling and high-cycle fatigue issues during the design process.…”

Section: Introductionmentioning

confidence: 99%

Impact of clocking on the aero-thermodynamics of a second stator tested in a one and a half stage HP turbine

2008

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This paper focuses on the experimental investigation of the time-averaged and time-accurate aero-thermodynamics of a second stator tested in a 1.5 stage high-pressure turbine. The effect of clocking on aerodynamic and heat transfer are investigated. Tests are performed under engine representative conditions in the VKI compression tube CT3. The test program includes four different clocking positions, i.e. relative pitch-wise positions between the first and the second stator. Probes located upstream and downstream of the second stator provide the thermodynamic conditions of the flow field. On the second stator airfoil, measurements are taken around the blade profile at 15, 50 and 85% span with pressure sensors and thin-film gauges. Both time-averaged and time-resolved aspects of the flow field are addressed. Regarding the time-averaged results, clocking effects are mainly observed within the leading edge region of the second stator, the largest effects being observed at 15% span. The surface static pressure distribution is changed locally, hence affecting the overall airfoil performance. For one clocking position, the thermal load of the airfoil is noticeably reduced. Pressure fluctuations are attributed to the passage of the upstream transonic rotor and its associated pressure gradients. The pattern of these fluctuations changes noticeably as a function of clocking. The time-resolved variations of heat flux and static pressure are analyzed togethershowing that the major effect is due to a potential interaction. The time-resolved pressure distribution integrated along the second stator surface yields the unsteady forces on the vane. The magnitude of the unsteady force is very dependent on the clocking position.

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Section: Introductionmentioning

confidence: 99%