Computational Fluid Dynamics Performance Estimation of Turbo Booster Vacuum Pump

H.-P. Cheng; C.-J. Chen ,; P.-W. Cheng ,

doi:10.1115/1.1566042

Centrifugal Compressor Stall Control by the Application of Engineered Surface Roughness on Diffuser Shroud Using Numerical Simulations

Materials ◽

10.3390/ma14082033 ◽

2021 ◽

Vol 14 (8) ◽

pp. 2033

Author(s):

Amjid Khan ◽

Muhammad Irfan ◽

Usama Muhammad Niazi ◽

Imran Shah ◽

Stanislaw Legutko ◽

...

Keyword(s):

Surface Roughness ◽

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

Centrifugal Compressor ◽

Control Method ◽

Flow Instability ◽

Passive Flow Control ◽

Passive Flow ◽

Low Mass

Downsizing in engine size is pushing the automotive industry to operate compressors at low mass flow rate. However, the operation of turbocharger centrifugal compressor at low mass flow rate leads to fluid flow instabilities such as stall. To reduce flow instability, surface roughness is employed as a passive flow control method. This paper evaluates the effect of surface roughness on a turbocharger centrifugal compressor performance. A realistic validation of SRV2-O compressor stage designed and developed by German Aerospace Center (DLR) is achieved from comparison with the experimental data. In the first part, numerical simulations have been performed from stall to choke to study the overall performance variation at design conditions: 2.55 kg/s mass flow rate and rotational speed of 50,000 rpm. In second part, surface roughness of magnitude range 0–200 μm has been applied on the diffuser shroud to control flow instability. It was found that completely rough regime showed effective quantitative results in controlling stall phenomena, which results in increases of operating range from 16% to 18% and stall margin from 5.62% to 7.98%. Surface roughness as a passive flow control method to reduce flow instability in the diffuser section is the novelty of this research. Keeping in view the effects of surface roughness, it will help the turbocharger manufacturers to reduce the flow instabilities in the compressor with ease and improve the overall performance.

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Aerodynamic Performance Evaluation of Axial Flow Fan Using Numerical Techniques

10.1115/gtindia2021-76443 ◽

2021 ◽

Author(s):

Raghuvaran D. ◽

Satvik Shenoy ◽

Srinivas G

Keyword(s):

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

Rotational Speed ◽

Total Pressure ◽

Axial Flow ◽

High Mass ◽

Ansys Fluent ◽

Industrial Sectors ◽

Mass Flow Rates

Abstract Axial flow fans (AFF) are extensively used in various industrial sectors, usually with flows of low resistance and high mass flow rates. The blades, the hub and the shroud are the three major parts of an AFF. Various kinds of optimisation can be implemented to improve the performance of an AFF. The most common type is found to be geometric optimisation including variation in number of blades, modification in hub and shroud radius, change in angle of attack and blade twist, etc. After validation of simulation model and carrying out a grid independence test, parametric analysis was done on an 11-bladed AFF with a shroud of uniform radius using ANSYS Fluent. The rotational speed of the fan and the velocity at fan inlet were the primary variables of the study. The variation in outlet mass flow rate and total pressure was studied for both compressible and incompressible ambient flows. Relation of mass flow rate and total pressure with inlet velocity is observed to be linear and exponential respectively. On the other hand, mass flow rate and total pressure have nearly linear relationship with rotational speed. A comparison of several different axial flow tracks with the baseline case fills one of the research gaps.

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Design and Testing of a Can Combustor for a Small Gas Turbine Application

ASME 2013 Gas Turbine India Conference ◽

10.1115/gtindia2013-3691 ◽

2013 ◽

Author(s):

K. V. L. Narayana Rao ◽

N. Ravi Kumar ◽

G. Ramesha ◽

M. Devathathan

Keyword(s):

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

Gas Turbines ◽

Pressure Loss ◽

High Energy ◽

Experimental Results ◽

High Mass ◽

Test Facility ◽

Design Requirements

Can type combustors are robust, with ease of design, manufacturing and testing. They are extensively used in industrial gas turbines and aero engines. This paper is mainly based on the work carried out in designing and testing a can type combustion chamber which is operated using JET-A1 fuel. Based on the design requirements, the combustor is designed, fabricated and tested. The experimental results are analysed and compared with the design requirements. The basic dimensions of the combustor, like casing diameter, liner diameter, liner length and liner hole distribution are estimated through a proprietary developed code. An axial flow air swirler with 8 vanes and vane angle of 45 degree is designed to create a re-circulation zone for stabilizing the flame. The Monarch 4.0 GPH fuel nozzle with a cone angle of 80 degree is used. The igniter used is a high energy igniter with ignition energy of 2J and 60 sparks per minute. The combustor is modelled, meshed and analysed using the commercially available ansys-cfx code. The geometry of the combustor is modified iteratively based on the CFD results to meet the design requirements such as pressure loss and pattern factor. The combustor is fabricated using Ni-75 sheet of 1 mm thickness. A small combustor test facility is established. The combustor rig is tested for 50 Hours. The experimental results showed a blow-out phenomenon while the mass flow rate through the combustor is increased beyond a limit. Further through CFD analysis one of the cause for early blow out is identified to be a high mass flow rate through the swirler. The swirler area is partially blocked and many configurations are analysed. The optimum configuration is selected based on the flame position in the primary zone. The change in swirler area is implemented in the test model and further testing is carried out. The experimental results showed that the blow-out limit of the combustor is increased to a good extent. Hence the effect of swirler flow rate on recirculation zone length and flame blow out is also studied and presented. The experimental results showed that the pressure loss and pattern factor are in agreement with the design requirements.

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Data Analysis of 64 Rod Bundles Reflood Heat Transfer Experiment

Volume 6: Thermal-Hydraulics ◽

10.1115/icone25-67296 ◽

2017 ◽

Author(s):

Lv Yufeng ◽

Chen Yuzhou ◽

Zhang Dongxu ◽

Zhao Minfu ◽

Duan Minghui

Keyword(s):

Heat Transfer ◽

Mass Flow Rate ◽

Test Data ◽

Mass Flow ◽

Flow Rate ◽

High Mass ◽

Rod Bundles ◽

Transfer Experiment ◽

System Pressure ◽

Injection Water

The test data of 64 rod bundles reflood heat transfer experiment performed by China Institute of Atomic Energy are analyzed. The heater rods are electrically powered and have a diameter of 9.5 mm and a length of 4.3 m arranged in a 8 × 8 array with a 12.6 mm pitch. The test parameter is in the range of 10–500 kg/(m2 · s) for injection water mass flux, 20–80°C for injection water temperature, 500–600°C for initial heater rod temperature, 0–1.1 kW/m for heating power, respectively. The system pressure is atmosphere pressure. Two kinds of spacer grids with and without mixing vanes are adopted to investigate their effect on heat transfer. The result shows that rod wall temperature downstream the spacer grid with mixing vanes is lower than that without mixing vanes, which indicates that the heat transfer is enhanced with mixing vanes. The rewetting velocity is nearly a constant under a certain test condition. The experimental values of rewetting velocity are compared with heat conduction controlled theories. At low mass flow rate, one-dimensional conduction gives agreement with experiment; while at high mass flow rate, the two-dimensional conduction theory is shown to be in agreement with experiment data. The RELAP5/ MOD3.3 reflood model is assessed against the test data. Comparison of code prediction and measured data indicates that the code predicts quench time relatively well but the peak rod temperature differs.

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The Liftoff Properties of Dimethyl Ether Jet Diffusion Flames With Preheating

Volume 1B: Combustion, Fuels and Emissions ◽

10.1115/gt2013-95287 ◽

2013 ◽

Author(s):

Jie Zhou ◽

Yuhua Ai ◽

Wenjun Kong

Keyword(s):

Ambient Temperature ◽

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

Diffusion Flames ◽

Thermal Buoyancy ◽

Jet Diffusion Flames ◽

Lifted Flames ◽

Low Mass ◽

Jet Velocity

Liftoff properties of DME laminar axisymmetric diffusion flames were investigated experimentally with emphasis on the preheating effects. At room temperature, DME presented a different liftoff phenomenon from the non-oxygenated hydrocarbon fuels. It could not be lifted off directly by increasing the jet velocity except for far field ignition at relatively low mass flow rate. When fuel and dilution were preheated, the DME flame could be lifted off directly by increasing the jet velocity. The range of the mass flow rate of stabilized DME liftoff flames became much narrower and the liftoff height became much smaller at fuel preheating than that at ambient temperature. With the increase of the jet temperature, the DME liftoff flames exhibited as one of the following three types: stationary lifted flames, stable oscillating lifted flames and unstable oscillating lifted flames. Stationary lifted flames existed when the initial temperature was relatively low (less than 350 K). Stable oscillating lifted flames were observed at relatively high preheated temperature (about 350 K ∼ 750 K), and the trajectory of the liftoff flame base was nearly sinusoidal. Both the oscillating frequency and amplitude increased with the preheating temperature. The oscillating lifted flames were caused by thermal buoyancy effect, inertia and the instability in the inner flow. When the jet temperature exceeded 750 K, the oscillating lifted flames became unstable and easily to be blown out. The flame base of the stabilized DME liftoff flame had a tribrachial structure at both ambient temperature and elevated temperature.

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Design and Optimization of the Restrictor of a Race Car

Volume 7B: Fluids Engineering Systems and Technologies ◽

10.1115/imece2015-52940 ◽

2015 ◽

Author(s):

Prithvi Raj Kokkula ◽

Shashank Bhojappa ◽

Selin Arslan ◽

Badih A. Jawad

Keyword(s):

Fluid Dynamics ◽

Pressure Drop ◽

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

Air Flow ◽

Intake Manifold ◽

Maximum Pressure ◽

Cross Sectional ◽

Formula Sae

Formula SAE is a student competition organized by SAE International. The team of students design, manufacture and race a car. Restrictions are imposed by the Formula SAE rules committee to restrict the air flow into the intake manifold by putting a single restrictor of 20 mm. This rule limits the maximum engine power by reducing the mass flow rate flowing to the engine. The pull is greater at higher rpms and the pressure created inside the cylinder is low. As the diameter of the flow path is reduced, the cross sectional area for flow reduces. For cars running at low rpm when the engine requires less air, the reduction in area is compensated by accelerated flow of air through the restrictor. Since this is for racing purpose cars here are designed to run at very high rpms where the flow at the throat section reach sonic velocities. Due to these restrictions the teams are challenged to come up with improved restrictor designs that allow maximum pressure drop across the restrictor’s inlet and outlet. The design considered for optimizing a flow restrictor is a venturi type having 20 mm restriction between the inlet and the outlet complying with the rules set by Formula SAE committee. The primary objective of this work is to optimize the flow restriction device that achieves maximum mass flow and minimum pull from the engine. This implies the pressure difference created due to the cylinder pressure and the atmospheric pressure at the inlet should be minimum. An optimum flow restrictor is designed by conducting analysis on various converging and diverging angles and coming up with an optimum value. Venturi type is a tubular pipe with varying diameter along its length, through which the fluid flows. Law of governing fluid dynamics states that the “Velocity of the fluid increases as it passes through the constriction to satisfy the principle of continuity”. An equation can be derived from the combination of Bernoulli’s equation and Continuity equation for the pressure drop due to venturi effect. [1]. A Computational Fluid Dynamics (CFD) tool is used to calculate the minimum pressure drop across the restrictor by running a series of analysis on various converging and diverging angles and calculating the pressure drop. As a result, an optimum air flow restrictor is achieved that maximizes the mass flow rate and minimizes the engine pull.

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Analysis and Optimization of Steam Duct for Improving Performance of Steam Cleaner

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.195-196.52 ◽

2012 ◽

Vol 195-196 ◽

pp. 52-55

Author(s):

Jian Hua Wang ◽

Yun De Shen ◽

Dong Ji Xuan ◽

Tai Hong Cheng ◽

Zhen Zhe Li

Keyword(s):

Fluid Dynamics ◽

Computational Fluid Dynamics ◽

Quadratic Programming ◽

Numerical Method ◽

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

Optimization Algorithm ◽

Sequential Quadratic Programming ◽

High Performance

Not only the price of a steam cleaner but also the performance of it should be considered to improve the competitive power of the products. In this study, a steam duct was optimized by changing the length of guide line for compensating the drawback of the unbalanced mass flow rate of steam from each outlet. For evaluating the mass flow rate of each outlet, a commercial CFD(computational fluid dynamics) code was used. In the process of the optimization, SQP(sequential quadratic programming) optimization algorithm was applied. The numerical method in this study can be widely used to develop a high performance domestic steam cleaner.

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Evaluation of Variable Compressor Technologies

Frontiers in Mechanical Engineering ◽

10.3389/fmech.2020.600024 ◽

2021 ◽

Vol 6 ◽

Author(s):

Panagiotis Grigoriadis ◽

Alexander Hoffmann ◽

Chi Binh La

Keyword(s):

Fuel Cells ◽

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

High Mass ◽

Compressor Wheel ◽

Advantages And Disadvantages ◽

Performance Map ◽

Surge Line ◽

The Impact

A diverse set of technology solutions are in development for reducing vehicular CO2 emissions. Beside the conventional internal combustion engine, there are hybrid powertrains, fuel cells and full electric vehicles. The challenge is finding the right technology that can be quickly implemented into production as a cost effective solution. In addition to CO2 reduction during vehicle operation, the impact of CO2 in the production and recycling of future vehicles must also be considered. From this perspective, the role of turbocharging is evolving, becoming more important for the future. It is an enabler for mature technologies known to improve engine efficiency like Miller timing, lean burn, increased exhaust gas recirculation (EGR) dilution and exhaust heat recovery. As a boosting device, improved turbocharging can also benefit other powertrain types like fuel cells. All previously mentioned applications benefit from wider compressor maps and higher compressor ratios. To achieve an extension of the performance map to areas of low mass flow rate, different methods have been discussed with the two most promising being trim reduction introduced by IAV’s Variable Trim Compressor (VTC) and swirl generation. The most common device for inducing a swirl onto the incoming airflow is to use swirl generating wings in front of the compressor wheel. However, Iwakiri explained that putting a single plate in front of the compressor wheel disturbs the recirculating flow, which acts positively to extend the compressor map. On this basis, plates were developed that guide the strongly swirled back flowing air in such a way that they impose a swirl on the incoming air. Trim reduction is well known for its ability to shift the surge line and maintain compressor efficiency. To achieve this, a conical element before the compressor wheel guides the incoming flow to the inner area of the wheel resulting in reduced flow separation. An orifice can also achieve almost the same effect but with much less axial extension. The advantages and disadvantages of these measures are explained using numerical (CFD) and experimental (turbocharger test bench) to show the potential of each approach. In summary trim reduction using a conical geometry is still the best performing approach. However, considering package restrictions, an orifice is also a good choice. Whereas swirl producing principles have a moderate impact on shifting the surge line. The extension of high mass flow rate is also of interest and this study shows a simple method to improve the compressor performance map in this area. A combination of the measures to expand the map in both directions is conceivable and is presented here as a concept.

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Investigation of Flow Field at the Inlet of a Turbocharger Compressor Using Digital Particle Image Velocimetry

Journal of Turbomachinery ◽

10.1115/1.4044608 ◽

2019 ◽

Vol 141 (12) ◽

Cited By ~ 1

Author(s):

Deb Banerjee ◽

Rick Dehner ◽

Ahmet Selamet ◽

Kevin Tallio ◽

Keith Miazgowicz ◽

...

Keyword(s):

Particle Image Velocimetry ◽

Flow Field ◽

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

Particle Image ◽

Flow Reversal ◽

High Mass ◽

Reversed Flow ◽

Image Velocimetry

Abstract The flow field at the inlet of a turbocharger compressor has been studied through stereoscopic particle image velocimetry (SPIV) experiments under different operating conditions. It is found that the flow field is quite uniform at high mass flow rates; but as the mass flow rate is reduced, flow reversal from the impeller is observed as an annular ring at the periphery of the inlet duct. The inception of flow reversal is observed to occur in the mid-flow operating region, near peak efficiency, and corresponds to an incidence angle of about 15.5 deg at the inducer blade tips at all tested speeds. This reversed flow region is marked with high tangential velocity and rapid fluctuations. It grows in strength with reducing mass flow rate and imparts some of its angular momentum to the forward flow due to mixing. The penetration depth of the reversed flow upstream from the inducer plane is found to increase quadratically with decreasing flow rate.

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Factors of Influence on the Leakage of Brush Seals

Volume 7C: Heat Transfer ◽

10.1115/gt2020-14189 ◽

2020 ◽

Author(s):

Alexander Fuchs ◽

Johann Göttler ◽

Oskar J. Haidn

Keyword(s):

Fluid Dynamics ◽

Mass Flow Rate ◽

Mass Flow ◽

Flow Rate ◽

Interaction Model ◽

Structure Interaction ◽

Preliminary Results ◽

Mechanics Model ◽

Factors Of Influence ◽

Brush Seals

Abstract Based on previous research from the authors a modeling approach for brush seals is developed further. Each individual bristle is reproduced in both the fluid dynamics and the structural mechanics model. An investigation regarding the influence of the free bristle height and the sealing gap on the leakage mass flow rate is carried out. Results are compared to experimental and literature data. Furthermore, preliminary results of the segregated fluid-structure interaction model are presented briefly, and matched to literature data.

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