Acoustic characteristics of a ported shroud turbocompressor operating at design conditions

Sharma, Sudhaa; Broatch, A.; García-Tíscar, J.; Allport, John; Nickson, A.K.

doi:10.1177/1468087418814635

Cited by 15 publications

(28 citation statements)

References 38 publications

(75 reference statements)

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“…As mentioend before, the tonal features like Blade Pass Frequency (BPF), harmonics of BPF and the harmonics of rotor shaft speed ('buzz-saw' tones) are observed in the spectrum. The strength of the tonal features in the near impeller spectrum are relatively weaker for near surge operation as compared to the design operation [28]. It is interesting to note that the faint 'mid-tones' [28] that are present between the 'buzz-saw' tones in the near impeller spectrum for the design operation are not existent in the spectrum of the compressor operating near surge.…”

Section: Compressor Spectral Signaturementioning

confidence: 92%

“…The strength of the tonal features in the near impeller spectrum are relatively weaker for near surge operation as compared to the design operation [28]. It is interesting to note that the faint 'mid-tones' [28] that are present between the 'buzz-saw' tones in the near impeller spectrum for the design operation are not existent in the spectrum of the compressor operating near surge. The broadband in the frequency range corresponding to characteristic 'whoosh' noise region is not seen in the spectrum of the near impeller probe as observed in the close-up sections presented in Figure 8 and Figure 9.…”

Section: Compressor Spectral Signaturementioning

confidence: 92%

“…The fluid with high circumferential velocity is removed from the impeller passages and recirculated to the main flow via PS cavity. In contrast to the constant pull and push behaviour of the fluid along the impeller blades at the PS slot for design operation [28], a unidirectional radially outward flow is seen at the PS slot for the near surge operation as shown in Figure 13. The flow exits PS cavity in form of high speed jets corresponding to the structural struts.…”

Section: Flow Field Characteristicsmentioning

confidence: 93%

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Acoustic and pressure characteristics of a ported shroud turbocompressor operating at near surge conditions

et al. 2019

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The operation of compressor at lower mass flow rates is limited by surge which is marked by large fluctuations in operational variables and accompanied by significant increase in noise. Ported shroud casing treatment is a widely used method to control the flow near unstable conditions in order to obtain a stable operation and enhance deep surge margin. The research on the acoustic effects of the ported shroud design is limited. Therefore, this paper numerically characterises the acoustic features of a turbocharger compressor with ported shroud design operating at marginal or soft surge conditions and investigates the correlation between acoustic characteristics and the spatial flow structures. The acoustic and the flow field features are analysed using spectral signatures obtained from an experimentally validated numerical model using both performance and acoustic measurements. Propagation of the frequency content through the ducts has been estimated with the aid of the beamforming and method of characteristics to enhance the content coming from the compressor. Expected acoustic phenomena such as rotating order tones and blade passing peaks are correctly identified in the modelled spectrum with the limitation to capture the specific broadband features. Hence, the numerical model can be used to further the research encompassing the impact these flow enhancement solutions have on the noise emission of the turbocharger. Inspection of the flow field shows radially exiting fluid at the ported shroud slot leading to the formation of the high-speed jets exiting the ported shroud cavity. Circumferential propagation of the stall cells is also identified in the impeller. Further inspection of the pressure field through modal decomposition implies the localisation of the energetic noise sources in the impeller downstream components. The influence of the ported shroud cavity on the acoustic characteristic of the compressor is not significant and is limited to the propagation of the tonal noise in the direction of impeller upstream.

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Section: Compressor Spectral Signaturementioning

confidence: 92%

Section: Compressor Spectral Signaturementioning

confidence: 92%

Section: Flow Field Characteristicsmentioning

confidence: 93%

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Acoustic and pressure characteristics of a ported shroud turbocompressor operating at near surge conditions

et al. 2019

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“…Details on the gas stand measurement are described in Sharma et al 11,36 . Schematic diagrams of the acoustic flow bench with the position of various sensors is shown in Fig.…”

Section: Assessment Of the Numerical Configurationmentioning

confidence: 99%

“…Recent attempts to understand the relationship between flow and acoustic features of a PS compressor are made by decomposing the numerical flow field using proper orthogonal decomposition 11,12 and dynamic mode decomposition 13 Order (RO) tones or 'buzz-saw' tones 11,18 and Blade Pass Frequency (BPF) while broadband features include the so called 'whoosh' noise which is observed within the plane wave frequency range and Tip Clearance Noise (TCN) 18,19 seen beyond the plane wave frequency.…”

Section: Introductionmentioning

confidence: 99%

Evolution of flow characteristics in a centrifugal compressor with an increase in operating speed

Sharma

García-Tíscar

Allport

et al. 2020

International Journal of Engine Research

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Developments in materials, manufacturing and computing methods have catalysed the generation of efficient compressor designs with higher specific power outputs. Centrifugal compressors have become pervasive in environments demanding a combination of higher power with smaller sizes such as unmanned aerial vehicles, micro gas turbines and turbochargers. These compressors are expected to perform optimally in a range of operational speeds and mass flow states with low acoustic emissions. The impact of operating speed on the flow and acoustic characteristics of a ported shroud compressor has been explored in this work. The operation of the open and blocked configurations of the compressor at the design and near surge points each of a lower and a higher speedline was numerically and experimentally investigated. Comparing the results, the model was shown to predict the operation of the compressor for both configurations at the investigated operating points satisfactorily in terms of both performance and dominant acoustic features. With an increase in the velocity and the Mach number due to increased operational speed, changes in the flow behaviour in the inducer and diffuser were observed. An increase in operational speed was shown to generally increase the overall acoustic emission of the compressor for both configurations. The number of distinct tones in the acoustic output and their magnitude were also seen to be a function of operating speed.

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Acoustic characterisation of a small high-speed centrifugal compressor with casing treatment: An experimental study

Sharma

Broatch

García-Tíscar

et al. 2019

Aerospace Science and Technology

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With the advancements in manufacturing, materials and computational methods, turbomachinery designs have become more efficient providing higher specific power and reliability with lower weight and cost. The rotational speed of turbomachines has increased while the overall machine size has decreased for a similar power output leading to the pervasive presence of small, high-speed turbomachines, specifically centrifugal compressors in helicopters, unmanned aerial vehicles (UAVs), auxiliary power units (APUs), turbochargers and micro gas turbines. In addition to superior aerodynamic performance over a wide range, increased operating speeds have made the acoustic emissions of small centrifugal compressors a critical aspect of design. Therefore, this work presents an experimental campaign to characterise the acoustic behaviour of a compressor with an intent to quantify the dominant features of the flow-induced noise for design and near surge operating conditions. Furthermore, the campaign is extended to establish the impact of the ported shroud casing treatment and operating speed on the acoustic emission of the compressor. The induct noise measurement method is used in this work to quantify the noise generated in the compressor by measuring pressure fluctuations near the inducer and diffuser while the propagation of the generated noise to the ducts is computed from an array of piezoelectric sensors. Spectra at the design operating point are dominated by tonal noise while broadband noise content is the dominant feature of spectra for near surge operation. Although the ported shroud cavity does not significantly alter the overall noise levels of the compressor operating at design condition, it does seem to propagate tonal noise. For near surge operation, the casing treatment positively impacts the acoustic emission with a reduction of approximately 10 dB in the range up to the blade pass frequency. Furthermore, various broadband features are also observed to be alleviated by the casing treatment.

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Acoustic characteristics of a ported shroud turbocompressor operating at design conditions

Cited by 15 publications

References 38 publications

Acoustic and pressure characteristics of a ported shroud turbocompressor operating at near surge conditions

Acoustic and pressure characteristics of a ported shroud turbocompressor operating at near surge conditions

Evolution of flow characteristics in a centrifugal compressor with an increase in operating speed

Acoustic characterisation of a small high-speed centrifugal compressor with casing treatment: An experimental study

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