Delay of Rotating Stall in Compressors Using Plasma Actuators

Ashrafi, Farzad; Michaud, Mathias; Vo, Huu Duc

doi:10.1115/gt2015-42559

Cited by 4 publications

(2 citation statements)

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“…One approach is using active flow control techniques such as using plasma actuators. Saddoughi et al 17 studied the tip clearance flow in a transonic compressor with and without plasma actuators and Ashrafi et al 18 investigated the effect of the actuator plasma on the delaying the rotating stall in compressors. Blowing air from the tip or casing wall is another type of active control techniques that can be applied to reduce the tip leakage flows.…”

Section: Introductionmentioning

confidence: 99%

Effect of in-service burnout effect on the transonic leakage flows over cavity tip model

Saleh

Avital

Korakianitis

2021

Proceedings of the Institution of Mechanical Engineers, Part A:

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Increasing the gas temperature at the inlet to the high pressure turbine of gas turbine engines is known as a proven method to increase the efficiency of these engines. However, this will expose the blades’ surface to very high heat load and thermal damages. In the case of the un-shrouded turbine blades, the blade tip will be exposed to a significant thermal load due to the developed leakage flows in the tip gap, this leads to in-service burnout which degrades the blade tip and shortens its operational life. This paper studies the in-service burnout effect of the transonic tip flows over a cavity tip which is a configuration commonly used to reduce the tip leakage flows. This investigation is carried out experimentally within a transonic wind tunnel and computationally using steady and unsteady Reynolds Averaged Navier Stokes approaches. Various flow measurements are established and different flow behaviour including separation bubbles, shockwave development and distinct flow interactions are captured and discussed. It is found that when the tip is exposed to the in-service burnout, leakage flow behaves in a significantly different way. In addition, the effective tip gap becomes much larger and allows higher leakage mass flow rate in comparison to the sharp-edge tip (i.e. a tip at the beginning of its operational life). The tip leakage losses are found much higher for the round-edge cavity tip (i.e. a tip exposed to burn-out effect). Experimental and computational flow visualisations, surface pressure measurements and discharge coefficient variation are given and analysed for several pressure ratios across the tip gap.

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Section: Introductionmentioning

confidence: 99%

Effect of in-service burnout effect on the transonic leakage flows over cavity tip model

Saleh

Avital

Korakianitis

2021

Proceedings of the Institution of Mechanical Engineers, Part A:

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“…Generally, the geometrical modification always works among the whole operating range for passive flow control methods, such as casing treatment, 19–23 blade tip modifications, 24–27 and blade tip winglet, 28–30 which may result in a reduction of performance near design point. While the active flow control can be imposed on the flow fields flexibly either all the time or only when the compressor’s operating point moves dangerously close to the stall line, such as plasma actuation, 31–33 tip injection, 34–38 and aspiration/suction techniques. 39–44 At present, the researches about aspiration mainly focus on the control of the boundary layer separation on blade SS or the 3D separation in the hub corner, 45–50 and the results show that the performance of compressor cascade can be improved significantly by applying the suction method.…”

Section: Introductionmentioning

confidence: 99%

Effect of casing aspiration on the tip leakage flow in the axial flow compressor cascade

Mao

Liu

Tang

2017

Proceedings of the Institution of Mechanical Engineers, Part A:

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Tip leakage flow is usually responsible for the deterioration of compressor performance and stability. The current paper conducts numerical simulations on the impact of casing aspiration on the axial compressor cascade performance. Three aspiration schemes with different chordwise coverage are studied and analyzed. It is found that the cascade performance can be effectively improved by the appropriate casing aspiration, and the optimum aspiration scheme should cover the area including the onset point of tip leakage vortex and its vicinity. The control mechanisms are different for the aspiration schemes located at different blade chord ranges. For the aspiration scheme covering the onset point of tip leakage vortex, the improvement of the cascade performance is mainly due to that the starting point of the tip leakage vortex is shifted downstream. The original tip leakage vortex structure is divided into two parts if the aspiration scheme is located behind the onset point of tip leakage vortex and the final control effect is the combination of the influence from the two different parts of tip leakage vortex. Additionally, the casing aspiration redistributes the blade loading along the chord near blade tip. The results of these investigations may offer guidance for the appropriate design of aspiration scheme in the future updated compressors and the overall total pressure loss coefficient caused by aspiration slot should be considered in the design process.

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Undergraduate Project in Compressor Rig Design, Fabrication, and Testing for Complete Engineering Training

Trépanier

2015

Journal of Engineering for Gas Turbines and Power

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An ambitious project in propulsion was introduced as part of the final-year integrator project offerings of the mechanical and aerospace engineering programs at École Polytechnique de Montréal in 2011–2012. It has been running successfully for the past three academic years. The project consists in the design, fabrication, and placement into service of a functional instrumented multistage compressor test rig, including the compressor, for research in compressor aerodynamics. A team of 15–17 senior-year undergraduate engineering students is given a set of design and performance specifications and measurement requirements, an electric motor and drive, a data acquisition system, and some measurement probes. They must complete the project in two semesters with a budget on the order of Can$15,000. The compressor is made from rapid prototyping to keep production cost and time reasonable. However, the required rotation speed of 7200 rpm stretches the limits of the plastic material and presents the same structural challenges as industrial compressors running at higher speeds. The students are split into subteams according to the required disciplines, namely, compressor aerodynamics, general aerodynamics, structures, dynamics, mechanical design and integration, instrumentation, and project management. For the initial phase, which covers the first two months, the students receive short seminars from experts in academia and industry in each discipline and use the knowledge from fundamental engineering courses to analytically model the different components to come up with a preliminary design. In the second phase, covering three to six, the students are trained at commercial simulation tools and use them for detailed analysis to refine and finalize the design. In each of the first two phases, the students present their work in design reviews with a jury made up of engineers from industry and supervising professors. During the final phase, the compressor is built and tested with data acquisition and motor control programs written by the students. Finally, the students present their results with comparison of measured performance with numerical and analytical predictions from the first two phases and hand over their compressor rig with design and test reports as well as a user manual and an assembly/maintenance manual. This complete project allows the students to put into practice virtually all the courses of their undergraduate engineering curriculum while giving them an extensive taste of the rich and intellectually challenging environment of gas turbine and turbomachinery engineering.

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Delay of Rotating Stall in Compressors Using Plasma Actuators

Cited by 4 publications

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Effect of in-service burnout effect on the transonic leakage flows over cavity tip model

Effect of in-service burnout effect on the transonic leakage flows over cavity tip model

Effect of casing aspiration on the tip leakage flow in the axial flow compressor cascade

Undergraduate Project in Compressor Rig Design, Fabrication, and Testing for Complete Engineering Training

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