An In-mass Transducer for Measuring the Static Pressure Ratio (K) in Grain Storage Bins

Lighter weight, simpler structure, higher vectoring efficiency and faster vector response are recent trends in development of aircraft engine exhaust system. To meet these new challenges, a concept of hybrid SVC nozzle was proposed in this work to achieve thrust vectoring by adopting a rotatable valve and by introducing a secondary flow injection. In this paper, we numerically investigated the flow mechanism of the hybrid SVC nozzle. Nozzle performance (e.g. the thrust vector angle and the thrust coefficient) was studied with consideration of the influence of aerodynamic and geometric parameters, such as the nozzle pressure ratio (NPR), the secondary pressure ratio (SPR) and the deflection angle of the rotatable valve (θ). The numerical results indicate that the introductions of the rotatable valve and the secondary injection induce an asymmetrically distributed static pressure to nozzle internal walls. Such static pressure distribution generates a side force on the primary flow, thereby achieving thrust vectoring. Both the thrust vector angle and vectoring efficiency can be enhanced by reducing NPR or by increasing θ. A maximum vector angle of 16.7 ° is attained while NPR is 3 and the corresponding vectoring efficiency is 6.33 °/%. The vector angle first increases and then decreases along with the elevation of SPR, and there exists an optimum value of SPR for maximum thrust vector angle. The effects of θ and SPR on the thrust coefficient were found to be insignificant. The rotatable valve can be utilized to improve vectoring efficiency and to control the vector angle as expected.

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Performance of Strongly Bowed Stators in a Four-Stage High-Speed Compressor

Journal of Turbomachinery ◽

10.1115/1.1649743 ◽

2004 ◽

Vol 126 (3) ◽

pp. 333-338 ◽

Cited By ~ 28

Author(s):

Axel Fischer ◽

Walter Riess ◽

Joerg R. Seume

Keyword(s):

Mass Flow ◽

High Speed ◽

Static Pressure ◽

Pressure Ratio ◽

Axial Compressor ◽

Pressure Rise ◽

Maximum Pressure ◽

Controlled Diffusion ◽

Stage 4 ◽

The University

The FVV sponsored project “Bow Blading” (cf. acknowledgments) at the Turbomachinery Laboratory of the University of Hannover addresses the effect of strongly bowed stator vanes on the flow field in a four-stage high-speed axial compressor with controlled diffusion airfoil (CDA) blading. The compressor is equipped with more strongly bowed vanes than have previously been reported in the literature. The performance map of the present compressor is being investigated experimentally and numerically. The results show that the pressure ratio and the efficiency at the design point and at the choke limit are reduced by the increase in friction losses on the surface of the bowed vanes, whose surface area is greater than that of the reference (CDA) vanes. The mass flow at the choke limit decreases for the same reason. Because of the change in the radial distribution of axial velocity, pressure rise shifts from stage 3 to stage 4 between the choke limit and maximum pressure ratio. Beyond the point of maximum pressure ratio, this effect is not distinguishable from the reduction of separation by the bow of the vanes. Experimental results show that in cases of high aerodynamic loading, i.e., between maximum pressure ratio and the stall limit, separation is reduced in the bowed stator vanes so that the stagnation pressure ratio and efficiency are increased by the change to bowed stators. It is shown that the reduction of separation with bowed vanes leads to a increase of static pressure rise towards lower mass flow so that the present bow bladed compressor achieves higher static pressure ratios at the stall limit.

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Pack Factor Measurements for Corn in Grain Storage Bins

Transactions of the ASABE ◽

10.13031/trans.58.11033 ◽

2015 ◽

pp. 879-890

Keyword(s):

Grain Storage ◽

Storage Bins

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Some Studies on Low Solidity Vaned Diffusers of a Centrifugal Compressor Stage

Volume 6: Turbo Expo 2005, Parts A and B ◽

10.1115/gt2005-68972 ◽

2005 ◽

Author(s):

T. Ch. Siva Reddy ◽

G. V. Ramana Murty ◽

Prasad Mukkavilli ◽

D. N. Reddy

Keyword(s):

Centrifugal Compressor ◽

Static Pressure ◽

Pressure Ratio ◽

Pressure Recovery ◽

Compressor Stage ◽

Recovery Coefficient ◽

Vaned Diffuser ◽

Flow Angle ◽

Centrifugal Compressor Stage ◽

Pressure Recovery Coefficient

Numerical simulation of impeller and low solidity vaned diffuser (LSD) of a centrifugal compressor stage is performed individually using CFX- BladeGen and BladeGenPlus codes. The tip mach number for the chosen study was 0.35. The same configuration was used for experimental investigation for a comparative study. The LSD vane is formed using standard NACA profile with marginal modification at trailing edge. The performance parameters obtained form numerical studies at the exit of impeller and the diffuser have been compared with the corresponding experimental data. These parameters are pressure ratio, polytropic efficiency and flow angle at the impeller exit where as the parameters those have been compared at the exit of diffuser are the static pressure recovery coefficient and the exit flow angle. In addition, the numerical prediction of the blade loading in terms of blade surface pressure distribution on LSD vane has been compared with the corresponding experimental results. Static pressure recovery coefficient and flow angle at diffuser exit is seen to match closely at higher flows. The difference at lower flows could be due to the effect of interaction between impeller and diffuser combinations, as the numerical analysis was done separately for impeller and diffuser and the effect of impeller diffuser interaction was not considered.

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Contributing Factors to Engulfments in On-Farm Grain Storage Bins

Journal of Agromedicine ◽

10.1300/j096v09n01_06 ◽

2003 ◽

Vol 9 (1) ◽

pp. 39-63 ◽

Cited By ~ 3

Author(s):

Douglas M. Kingman ◽

Gail R. Deboy ◽

William E. Field

Keyword(s):

Grain Storage ◽

Contributing Factors ◽

On Farm ◽

Storage Bins

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Interpreting Aerodynamics of a Transonic Impeller from Static Pressure Measurements

International Journal of Rotating Machinery ◽

10.1155/2018/7281691 ◽

2018 ◽

Vol 2018 ◽

pp. 1-9

Author(s):

Fangyuan Lou ◽

John Charles Fabian ◽

Nicole Leanne Key

Keyword(s):

Flow Field ◽

High Speed ◽

Static Pressure ◽

Pressure Ratio ◽

Leading Edge ◽

Pressure Measurements ◽

High Loss ◽

Supersonic Inlet ◽

Mach Numbers ◽

Inlet Conditions

This paper investigates the aerodynamics of a transonic impeller using static pressure measurements. The impeller is a high-speed, high-pressure-ratio wheel used in small gas turbine engines. The experiment was conducted on the single stage centrifugal compressor facility in the compressor research laboratory at Purdue University. Data were acquired from choke to near-surge at four different corrected speeds (Nc) from 80% to 100% design speed, which covers both subsonic and supersonic inlet conditions. Details of the impeller flow field are discussed using data acquired from both steady and time-resolved static pressure measurements along the impeller shroud. The flow field is compared at different loading conditions, from subsonic to supersonic inlet conditions. The impeller performance was strongly dependent on the inducer, where the majority of relative diffusion occurs. The inducer diffuses flow more efficiently for inlet tip relative Mach numbers close to unity, and the performance diminishes at other Mach numbers. Shock waves emerging upstream of the impeller leading edge were observed from 90% to 100% corrected speed, and they move towards the impeller trailing edge as the inlet tip relative Mach number increases. There is no shock wave present in the inducer at 80% corrected speed. However, a high-loss region near the inducer throat was observed at 80% corrected speed resulting in a lower impeller efficiency at subsonic inlet conditions.

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A Correction to the Barotropic Model of Gaseous Cavitation in Choked Converging-Diverging Nozzle Flows

Volume 2: Fluid Mechanics; Multiphase Flows ◽

10.1115/fedsm2020-20301 ◽

2020 ◽

Author(s):

Michael Waldrop ◽

Flint Thomas

Keyword(s):

Static Pressure ◽

Pressure Ratio ◽

Normal Shock ◽

Inlet Pressure ◽

Maximum Pressure ◽

Prediction Errors ◽

Cavitation Model ◽

Static Pressure Distribution ◽

Shock Solution ◽

Nozzle Inlet

Abstract The Barotropic Cavitation Model describes the behavior of a homogeneous mixture of liquid and gas bubbles (gaseous cavitation) as it traverses a converging-diverging (CD) nozzle. Its normal shock formulation makes reliable and accurate predictions of streamwise static pressure distribution from the nozzle inlet to just downstream of the throat and in the diverging section as the flow approaches the nozzle outlet. It fails in the intermediate portion of the divergence with maximum pressure prediction errors (as a fraction of nozzle inlet pressure) roughly equivalent to the back pressure ratio (as high as 0.46). A correction to the streamwise static pressure distributions predicted by the normal shock solution of the Barotropic Cavitation Model is proposed, applied and compared to experiments with aerated and non-aerated cavitation in several fluids. When used to simulate aerated cavitation of dodecane in a CD nozzle it predicts the location of first disagreement between the normal shock solution and experimental static pressure measurements within 4% of nozzle length. A polynomial curve fit between this predicted point (xcorr) and the normal shock location (xshock) then reduces maximum prediction error for static pressure in the correction region to no more than 0.11 (as a fraction of inlet pressure) for the aerated dodecane cases examined. For non-aerated gaseous cavitation in dodecane, water or JP8 jet fuel this error ratio does not exceed 0.13 and typical values are less than 0.07.

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Using Optimization in Industrial Multi-Point Radial Compressor Design: Map Correction

Volume 2D: Turbomachinery ◽

10.1115/gt2019-91452 ◽

2019 ◽

Author(s):

Edward P. Childs ◽

Dimitri Deserranno ◽

Akshay Bagi

Keyword(s):

Mass Flow ◽

Static Pressure ◽

Pressure Ratio ◽

Base Case ◽

Design Specification ◽

Radial Compressor ◽

Surrogate Based Optimization ◽

Compressor Design ◽

Mass Flow Rates ◽

Operating Points

Abstract The application of Surrogate-Based Optimization (SBO) to the industrial design process for a radial compressor with two operating points is described. The design specification includes two operating points at mass flow rates differing by a factor of three, and efficiency and pressure ratio targets for each point. The base case, while roughly sized from 1D analysis, fails to achieve the pressure ratio targets. In this paper, the optimization focusses on correcting the two speed-line map of total to static pressure ratio vs. mass flow rate. “Smart parameterization”, combining independent and dependent geometric parameters, and yielding reasonable geometries for most input combinations, coupled with efficient SBO, with separate models for response surface modeling and failure prediction, yields a design achieving the targets in just 57 CFD runs. FINE/Turbo [1] is used as the CFD analysis code and FINE/Design3D [2] and MINAMO [3] as the multi-objective optimizer.

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Investigation of Self-Recycling-Casing-Treatment (SRCT) Influence on Stability of High Pressure Ratio Centrifugal Compressor With a Volute

Volume 7: Turbomachinery, Parts A, B, and C ◽

10.1115/gt2011-45065 ◽

2011 ◽

Cited By ~ 2

Author(s):

Mingyang Yang ◽

Ricardo Martinez-Botas ◽

Yangjun Zhang ◽

Xinqian Zheng ◽

Takahiro Bamba ◽

...

Keyword(s):

High Pressure ◽

Numerical Method ◽

Flow Rate ◽

Centrifugal Compressor ◽

Static Pressure ◽

Pressure Ratio ◽

Flow Distortion ◽

Casing Treatment ◽

High Pressure Ratio ◽

The Stability

Large feasible operation range is a challenge for high pressure ratio centrifugal compressor of turbocharger in vehicle engine. Self-Recycling-Casing-Treatment (SRCT) is a widely used flow control method to enlarge the range for this kind of compressor. This paper investigates the influence of symmetrical/asymmetrical SRCT (ASRCT) on the stability of a high pressure ratio centrifugal compressor by experimental testing and numerical simulation. Firstly, the performance of the compressor with/without SRCT is tested is measured investigate the influence of flow distortion on the stability of compressor as well as the numerical method validation. Then detailed flow field investigation is conducted by experimental measurement and the numerical method to unveil the reasons for stability enhancement by symmetrical/asymmetrical SRCT. Results show that static pressure distortion at impeller outlet caused by the volute can make passages be confronted with flow distortion less stable than others because of their larger positive slope of T-S pressure ratio performance at small flow rate. SRCT can depress the flow distortion and reduce the slope by non-uniform recycling flow rate at impeller inlet. Moreover, ASRCT can redistribute the recycling flow in circumferential direction according to the asymmetric geometries. When the largest recycling flow rate is imposed on the passage near the distorted static pressure, the slope will be the most effectively reduced. Therefore, the stability is effectively enhanced by the optimized recycling flow device.

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Time-Averaged and Time-Accurate Aerodynamic Effects of Rotor Purge Flow for a Modern, One and One-Half Stage High-Pressure Turbine—Part II: Analytical Flow Field Analysis

Journal of Turbomachinery ◽

10.1115/1.4024776 ◽

2013 ◽

Vol 136 (1) ◽

Cited By ~ 3

Author(s):

Brian R. Green ◽

Randall M. Mathison ◽

Michael G. Dunn

Keyword(s):

High Pressure ◽

Flow Field ◽

Film Cooling ◽

Gas Flow ◽

Static Pressure ◽

Pressure Ratio ◽

Three Dimensional ◽

Field Analysis ◽

High Pressure Turbine ◽

Purge Flow

The detailed mechanisms of purge flow interaction with the hot-gas flow path were investigated using both unsteady computationally fluid dynamics (CFD) and measurements for a turbine operating at design corrected conditions. This turbine consisted of a single-stage high-pressure turbine and the downstream, low-pressure turbine nozzle row with an aerodynamic design equivalent to actual engine hardware and typical of a commercial, high-pressure ratio, transonic turbine. The high-pressure vane airfoils and inner and outer end walls incorporated state-of-the-art film cooling, and purge flow was introduced into the cavity located between the high-pressure vane and disk. The flow field above and below the blade angel wing was characterized by both temperature and pressure measurements. Predictions of the time-dependent flow field were obtained using a three-dimensional, Reynolds-averaged Navier–Stokes CFD code and a computational model incorporating the three blade rows and the purge flow cavity. The predictions were performed to evaluate the accuracy obtained by a design style application of the code, and no adjustment of boundary conditions was made to better match the experimental data. Part I of this paper compared the predictions to the measurements in and around the purge flow cavity and demonstrated good correlation. Part II of this paper concentrates on the analytical results, looking at the primary gas path ingestion mechanism into the cavity as well as the effects of the rotor purge on the upstream vane and downstream rotor aerodynamics and thermodynamics. Ingestion into the cavity is driven by high static pressure regions downstream of the vane, high-velocity flow coming off the pressure side of the vane, and the blade bow waves. The introduction of the purge flow is seen to have an effect on the static pressure of the vane trailing edge in the lower 5% of span. In addition, the purge flow is weak enough that upon exiting the cavity, it is swept into the mainstream flow and provides no additional cooling benefits on the platform of the rotating blade.

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