Aeroelastic assessment of a highly loaded high pressure compressor exposed to pressure gain combustion disturbances

Almeida, Victor Bicalho Civinelli de; Peitsch, Dieter

doi:10.22261/jgpps.f72ouu

Cited by 5 publications

(1 citation statement)

References 47 publications

(52 reference statements)

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“…Bayindir 15 conducted numerical investigations to study the flow field of the compressor by applying periodic pressure fluctuations (0.28-0.48 MPa, 80 Hz) at the compressor outlet. Many experimental and numerical studies had been done at TU Berlin [16][17][18][19] to describe the flow field of various compressor cascades with periodic non-steady boundary conditions. Flow control methods were utilized to stabilize the flow in the cascades.…”

Section: Introductionmentioning

confidence: 99%

Numerical studies on interactions between a centrifugal compressor and the back-propagated pressure waves originated from a pulse detonation combustor

Lü

Wang

Zhang

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part A:

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In order to investigate the influence of the back-propagated pressure waves originated from a pulse detonation combustor on the operating characteristics of the compressor in the pulse detonation turbine engine, a model consist of a centrifugal compressor and an isolation section which was usually utilized to decrease the peak value of the back-propagated pressure waves was set up. Numerical simulations were carried out to study the interactions between the centrifugal compressor and the back-propagated pressure waves under different operating conditions. The matching characteristics of the compressor under the influence of the back-propagated pressure waves were analyzed in a detonation cycle. The results showed that the back-propagated pressure waves would push the shock wave in the isolator towards the throat position, but the shock wave did not pass through the throat for the compressor corrected speed of n = 100% and n = 105%. For these two cases, the back-propagated pressure waves were completely isolated and the operating characteristics of the compressor were the same as those under the steady outlet conditions. For the corrected speed of n = 50% and n = 90%, the shock wave in the isolator section was pushed out of the throat and the supersonic flow in the isolator section was destroyed under the influence of the back-propagated pressure waves. The back-propagated pressure waves would propagate upstream into the compressor. Consequently, the instantaneous mass flow rate and the torque acting on the centrifugal impeller was decreased. The work required by the compressor was also reduced. The equivalent isentropic efficiency of the compressor was decreased. The separation or backflow in the compressor caused by the back-propagated pressure waves would results in an equivalent isentropic efficiency loss of 3.2% points for the case of n = 90% and 15.6% points for the case of n = 50%.

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