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518 results on '"Acharya, Sumanta"'

1. An Experimental and Computational Study of a Swirl-Stabilized Premixed Flame

Author

De, Ashoke, Zhu, Shengrong, and Acharya, Sumanta

Subjects
Physics - Fluid Dynamics
Abstract

An unconfined strongly swirled flow is investigated for different Reynolds numbers using particle image velocimetry (PIV) and Large Eddy Simulation (LES) with a Thickened Flame (TF) model. Both reacting and non-reacting flow results are presented. In the LES-TF approach, the flame front is resolved on the computational grid through artificial thickening and the individual species transport equations are directly solved with the reaction rates specified using Arrhenius chemistry. Good agreement is found when comparing predictions with the experimental data. Also the predicted RMS fluctuations exhibit a double-peak profile with one peak in the burnt and the other in the un-burnt region. The measured and predicted heat release distributions are in qualitative agreement with each other and exhibit the highest values along the inner edge of the shear layer. The precessing vortex core (PVC) is clearly observed in both the non-reacting and reacting cases. However, it appears more axially-elongated for the reacting cases and the oscillations in the PVC are damped with reactions., Comment: arXiv admin note: substantial text overlap with arXiv:2102.05183, arXiv:2102.04855; text overlap with arXiv:2102.13279

Published
2021
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2. Large Eddy Simulation of Premixed Combustion with a Thickened Flame Approach

Author

De, Ashoke and Acharya, Sumanta

Subjects
Physics - Fluid Dynamics
Abstract

A Thickened Flame (TF) modeling approach is combined with a Large Eddy Simulation (LES) methodology to model premixed combustion and the accuracy of these model predictions is evaluated by comparing with the piloted premixed stoichiometric methane-air flame data of Chen et al. [Combust. Flame 107 (1996) 233-244] at a Reynolds number Re = 24,000. In the TF model, the flame front is artificially thickened to resolve it on the computational LES grid and the reaction rates are specified using reduced chemistry. The response of the thickened flame to turbulence is taken care of by incorporating an efficiency function in the governing equations. The efficiency function depends on the characteristics of the local turbulence and on the characteristics of the premixed flame such as laminar flame speed and thickness. Three variants of the TF model are examined: the original Thickened Flame model, the Power-law flame wrinkling model, and the dynamically modified TF model. Reasonable agreement is found when comparing predictions with the experimental data and with computations reported using a probability distribution function (PDF) modeling approach. The results of the TF model are in better agreement with data when compared with the predictions of the G-equation approach, Comment: arXiv admin note: substantial text overlap with arXiv:2101.09200; text overlap with arXiv:2102.05183, arXiv:2102.04855

Published
2021
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3. Parametric study of upstream flame propagation in hydrogen-enriched premixed combustion: effects of swirl, geometry and premixedness

Author

De, Ashoke and Acharya, Sumanta

Subjects
Physics - Fluid Dynamics
Abstract

The effect of swirl, premixedness and geometry has been investigated for hydrogen enriched premixed flame using Large Eddy Simulation (LES) with a Thickened Flame (TF) model. Swirl strength has been varied to study the effects of swirl on flame behavior in a laboratory-scale premixed combustor operated under atmospheric conditions. In addition, the levels of premixedness and geometry have also been changed to study the role of these quantities on flame behavior. The turbulent flow field and the chemistry are coupled through TF model. In the LES-TF approach, the flame front is resolved on the computational grid through artificial thickening and the individual species transport equations are directly solved with the reaction rates specified using Arrhenius chemistry. Good agreement is found when comparing predictions with the published experimental data including the predicted RMS fluctuations. Also, the results show that higher swirl strength and increase in level of premixedness make the system more susceptible to upstream flame movement due to higher combustibility of hydrogen, which increases the reaction along the flame front, thereby raises temperature in the reaction zone and leads to combustion induced vortex breakdown (CIVB). Moreover, upstream flame movement is always observed at higher swirl strength irrespective of level of premixedness and burner geometry, whereas the premixed systems exhibit stable behavior while operating at low swirl., Comment: arXiv admin note: substantial text overlap with arXiv:2102.04855; text overlap with arXiv:2101.09200

Published
2021
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4. Dynamics of upstream flame propagation in a hydrogen-enriched premixed flame

Author

De, Ashoke and Acharya, Sumanta

Subjects
Physics - Fluid Dynamics
Abstract

An unconfined strongly swirled flow is investigated to study the effect of hydrogen addition on upstream flame propagation in a methane-air premixed flame using Large Eddy Simulation (LES) with a Thickened Flame (TF) model. A laboratory-scale swirled premixed combustor operated under atmospheric conditions for which experimental data for validation is available has been chosen for the numerical study. In the LES-TF approach, the flame front is resolved on the computational grid through artificial thickening and the individual species transport equations are directly solved with the reaction rates specified using Arrhenius chemistry. Good agreement is found when comparing predictions with the published experimental data including the predicted RMS fluctuations. Also, the results show that the initiation of upstream flame propagation is associated with balanced maintained between hydrodynamics and reaction. This process is associated with the upstream propagation of the center recirculation bubble, which pushes the flame front in the upstream mixing tube. Once the upstream movement of the flame front is initiated, the hydrogen-enriched mixture exhibits more unstable behavior; while in contrast, the CH4 flame shows stable behavior., Comment: arXiv admin note: text overlap with arXiv:2101.09200

Published
2021
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5. Large Eddy Simulation of a Premixed Bunsen flame using a modified Thickened-Flame model at two Reynolds number

Author

De, Ashoke and Acharya, Sumanta

Subjects
Physics - Fluid Dynamics
Abstract

A modified Thickened Flame (TF) model based on Large Eddy Simulation methodology is used to investigate premixed combustion and the model predictions are evaluated by comparing with the piloted premixed stoichiometric methane-air flame data (Chen et al., 1996) for Reynolds numbers Re = 24,000 (flame F3) and Re=52,000 (flame F1). The basic idea of Thickened-Flame approach is that the flame front is artificially thickened to resolve on the computational LES grid while keeping the laminar flame speed ( ) constant. The artificially thickening of the flame front is obtained by enhancing the molecular diffusion and decreasing the pre-exponential factor of the Arrhenius law. Since the flame front is artificially thickened, the response of the thickened flame to turbulence is affected and taken care of by incorporating an efficiency function (E) in the governing equations. The efficiency function (E) in the modified TF model is proposed based on the direct numerical simulations (DNS) data set of flame-vortex interactions (Colin et al., 2000). The predicted simulation results are compared with the experimental data and with computations reported using RANS based probability distribution function (PDF) modeling approach (Lindstedt, R. P. and Vaos, E. M., 2006, Transported PDF modeling of high-Reynolds-number premixed turbulent flames, Combustion and Flame, 145, 495) and RANS based G-equation approach (Herrmann, M., 2006). It is shown that the results with the modified TF model are generally in good agreement with the data, with the TF predictions consistently comparable to the PDF model predictions and superior to the results with the G-equation approach.

Published
2021
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11. Visualization of Convective Heat Transfer

Author

Panigrahi, Pradipta K., Muralidhar, K., Acharya, Sumanta, Section Editor, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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12. Free Convection: Cavities and Layers

Author

Kuznetsov, Andrey V., Kuznetsov, Ivan A., Acharya, Sumanta, Section editor, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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13. Full-Coverage Effusion Cooling in External Forced Convection: Sparse and Dense Hole Arrays

Author

Ligrani, Phil, Acharya, Sumanta, Section editor, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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14. Turbulence Effects on Convective Heat Transfer

Author

Ames, Forrest E., Acharya, Sumanta, Section Editor, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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15. Electrohydrodynamically Augmented Internal Forced Convection

Author

Talmor, Michal, Seyed-Yagoobi, Jamal, Acharya, Sumanta, Section Editor, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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16. Single-Phase Convective Heat Transfer: Basic Equations and Solutions

Author

Acharya, Sumanta, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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17. Free Convection: External Surface

Author

Oosthuizen, Patrick H., Acharya, Sumanta, Section editor, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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18. Enhancement of Convective Heat Transfer

Author

Manglik, Raj M., Acharya, Sumanta, Section Editor, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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19. Natural Convection in Rotating Flows

Author

Vadasz, Peter, Acharya, Sumanta, Section editor, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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20. Heat Transfer in Rotating Flows

Author

aus der Wiesche, Stefan, Acharya, Sumanta, Section Editor, Kulacki, Francis A., Editor-in-Chief, Acharya, Sumanta, Section Editor, Chudnovsky, Yaroslav, Section Editor, Cotta, Renato Machado, Section Editor, Devireddy, Ram, Section Editor, Dhir, Vijay K., Section Editor, Mengüç, M. Pinar, Section Editor, Mostaghimi, Javad, Section Editor, and Vafai, Kambiz, Section Editor

Published
2018
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21. IN MEMORIAM: PROFESSOR DARRELL W. PEPPER – A TRIBUTE TO AN EXCEPTIONAL ENGINEERING EDUCATOR AND RESEARCHER

Author

Runchal, Akshai K., primary, Carrington, David B., additional, Sherif, S. A., additional, Chiu, Wilson K. S., additional, Longtin, Jon P., additional, Battaglia, Francine, additional, Tao, Yongxin, additional, Jaluria, Yogesh, additional, Plesniak, Michael W., additional, Klausner, James F., additional, Prasad, Vish, additional, Kassab, Alain J., additional, Lloyd, John R., additional, Shafeyeva, Yelena, additional, Strasser, Wayne, additional, Cremaschi, Lorenzo, additional, Shih, Tom I-P., additional, Abdel-Salam, Tarek, additional, Amano, Ryoichi Samuel, additional, Gupta, Ashwani K., additional, Ozalp, Nesrin, additional, Wang, Ting, additional, Anderson, Kevin R., additional, Aggarwal, Suresh K., additional, Acharya, Sumanta, additional, Mashayek, Farzad, additional, Michaelides, Efstathios E., additional, Khandelwal, Bhupendra, additional, Wang, Xiuling, additional, Hajimirza, Shima, additional, Dowding, Kevin J., additional, Mazumder, Sandip, additional, Divo, Eduardo A., additional, Douglass, Rod, additional, Hogan, Roy E., additional, Hansen, Glen, additional, Beale, Steven B., additional, Nithiarasu, Perumal, additional, Vanka, Surya Pratap, additional, Cotta, Renato M., additional, Reizes, John A., additional, Timchenko, Victoria, additional, De, Ashoke, additional, Woodbury, Keith A, additional, Tencer, John T., additional, Wemhoff, Aaron P., additional, Jones, Gerard F., additional, Chen, Leitao, additional, Fisher, Timothy S., additional, Boetcher, Sandra K. S., additional, Oosthuizen, Patrick H., additional, Najafi, Hamidreza, additional, Webb, Brent W., additional, Sadhal, Satwindar Singh, additional, and Abdelmessih, Amanie, additional

Published
2024
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24. In Memoriam: Professor Essam E. Khalil —A Tribute to An Outstanding Educator and Researcher

Author

Awad, Mohamed M., primary, Sherif, S. A., additional, Khalil, Heba Allah Essam E., additional, Khalil, Adel, additional, Shih, Tom I-P., additional, Abdelaziz, Omar, additional, Abdel-Salam, Tarek, additional, Amano, Ryo S., additional, Gupta, Ashwani K., additional, Brooks, Michael, additional, Khandelwal, Bhupendra, additional, Ozalp, Nesrin, additional, Carrington, David, additional, Aggarwal, Suresh K., additional, Acharya, Sumanta, additional, Mashayek, Farzad, additional, Wang, Xiuling, additional, and Lear, William E., additional

Published
2023
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41. An experimental and computational study of a swirl-stabilized premixed flame

Author

Zhu, Ashoke De Shengrong and Acharya, Sumanta

Subjects
Gas-turbines -- Properties, Eddies -- Models, Engineering and manufacturing industries, Science and technology
Abstract

An unconfined strongly swirled flow is investigated for different Reynolds numbers using particle image velocimetry (PIV) and large eddy simulation (LES) with a thickened-flame (TF) model. Both reacting and nonreacting flow results are presented. In the LES-TF approach, the flame front is resolved on the computational grid through artificial thickening and the individual species transport equations are directly solved with the reaction rates specified using Arrhenius chemistry. Good agreement is found when comparing predictions with the experimental data. Also the predicted root mean square (rms) fluctuations exhibit a double-peak profile with one peak in the burnt and the other in the unburnt region. The measured and predicted heat release distributions are in qualitative agreement with each other and exhibit the highest values along the inner edge of the shear layer. The precessing vortex core (PVC) is clearly observed in both the non-reacting and reacting cases. However, it appears more axially elongated for the reacting cases and the oscillations in the PVC are damped with reactions. [DOI: 10.1115/1.4000141] Keywords: large eddy simulation, thickened-flame, swirl, premixed combustion, gas turbine, unconfined configuration

Published
2010

42. Large eddy simulation of premixed combustion with a thickened-flame approach

Author

De, Ashoke and Acharya, Sumanta

Subjects
Eddies -- Research, Combustion -- Models, Stoichiometry -- Research, Gas-turbines -- Chemical properties, Gas-turbines -- Mechanical properties, Engineering and manufacturing industries, Science and technology
Abstract

A thickened-flame (TF) modeling approach is combined with a large eddy simulation (LES) methodology to model premixed combustion, and the accuracy of these model predictions is evaluated by comparing with the piloted premixed stoichiometric methane-air flame data of Chen et al. (1996, 'The Detailed Flame Structure of Highly Stretched Turbulent Premixed Methane-Air Flames,' Combust. Flame, 107, pp. 233-244) at a Reynolds number Re = 24,000. In the TF model, the flame front is artificially thickened to resolve it on the computational LES grid and the reaction rates are specified using reduced chemistry. The response of the thickened-flame to turbulence is taken care of by incorporating an efficiency function in the governing equations. The efficiency function depends on the characteristics of the local turbulence and on the characteristics of the premixed flame such as laminar flame speed and thickness. Three variants of the TF model are examined: the original thickened-flame model, the power-law flame-wrinkling model, and the dynamically modified TF model. Reasonable agreement is found when comparing predictions with the experimental data and with computations reported using a probability distribution function modeling approach. The results of the TF model are in better agreement with data when compared with the predictions of the G-equation approach. [DOI: 10.1115/1.3094021] Keywords: thickened-flame, flame-wrinkling, turbulence, gas turbine emission, large eddy simulation

Published
2009

43. Mass/heat transfer in rotating smooth, high-aspect ratio (4:1) coolant channels with curved walls

Author

Sethuraman, Eashwar, Acharya, Sumanta, and Nikitopoulos, Dimitris E.

Subjects
Channels (Hydraulic engineering) -- Heating, cooling and ventilation, Science and technology
Abstract

The paper presents an experimental study of heat/mass transfer coefficient in 4:1 aspect ratio smooth channels with nonuniform cross sections. Curved leading and trailing edges are studied for two curvatures of 9.06 [m.sup.-1] (0.23 [in.sup.-1]) and 15.11 [m.sup.-1] (0.384 [in.sup.-1]) and for two different curvature configurations. One configuration has curved walls with curvature corresponding to the blade profile (positive curvature on both leading and trailing walls) and the other configuration has leading and trailing walls that curve inward into the coolant passage (negative curvature on the leading surface and positive curvature on the trailing surface). A detailed study at Re=10,000 with rotation numbers in the range of 0-0.07 is undertaken for the two different curvature configurations, All experiments are done for a 90 deg passage orientation with respect to the plane of rotation. The experiments are conducted in a rotating two-pass coolant channel facility using the naphthalene sublimation technique. Only the radially outward flow is considered for the present study. The spanwise mass transfer distributions of fully developed regions of the channel walls are also presented. The mass transfer data from the curved wall channels are compared to those from a smooth 4:1 rectangular duct with similar flow parameters. The local mass transfer data are analyzed mainly for the fully developed region, and area-averaged results are presented to delineate the effect of the rotation number. Heat transfer enhancement especially in the leading wall is seen for the lower curvature channels, and there is a subsequent reduction in the higher curvature channel when compared to the 4:1 rectangular smooth channel. This indicates that an optimal channel wall curvature exists for which heat transfer is the highest. [DOI: 10.11151/1.2812327]

Published
2009

47. Computations of turbulent flow and heat transfer through a three-dimensional nonaxisymmetric blade passage

Author

Saha, Arun K. and Acharya, Sumanta

Subjects
Turbulence -- Evaluation, Turbines -- Blades, Turbines -- Thermal properties, Turbines -- Mechanical properties, Numerical analysis -- Methods, Science and technology
Abstract

The design of a three-dimensional nonaxisymmetric end wall is carried out using three-dimensional numerical simulations. The computations have been conducted both for the flat and contoured end walls. The performance of the end wall is evaluated by comparing the heat transfer and total pressure loss reduction. The contouring is done in such a way to have convex curvature in the pressure side and concave surface in the suction side. The convex surface increases the velocity by reducing the local static pressure, while the concave surface decreases the velocity by increasing the local pressure. The profiling of the end wall is done by combining two curves, one that varies in the streamwise direction, while the other varies in the pitchwise direction. Several contoured end walls are created by varying the streamwise variation while keeping the pitchwise curve constant. The flow near the contoured end wall is seen to be significantly different from that near the flat end wall The contoured end wall is found to reduce the secondary flow by decreasing radial pressure gradient. The total pressure loss is also lower and the average heat transfer reduces by about 8% compared to the flat end wall. Local reductions in heat transfer are significant (factor of 3). This study demonstrates the potential of three-dimensional endwall contouring for reducing the thermal loading on the end wall.

Published
2008

49. Deposition of particles on ocular tissues and formation of Krukenberg spindle, hyphema, and hypopyon

Author

Kumar, Satish, Acharya, Sumanta, and Beuerman, Roger

Subjects
Eye diseases -- Risk factors, Eye diseases -- Research, Aqueous humor -- Research, Leukocytes -- Research, Engineering and manufacturing industries, Science and technology
Abstract

Eye diseases, such as Krukenberg's spindle, hyphema, and hypopyon, are related to the deposition of specific particles such as pigmentary cells, leukocytes, and erythrocytes. These particles are circulated by the aqueous humor (AH) and tend to deposit in regions of low velocities or high resistance. In the present paper, numerical simulations are reported of the AH flow and particle transport, and the particle concentration predictions are qualitatively compared to clinical images. The particle concentration distributions provide an understanding of the likely sources of deposition and the origin of the deposited particles. Pigmentary cells are seen to concentrate in a vertical band on the corneal surface consistent with clinical observations of Krukenberg's spindle. Leukocytes and erythrocytes are seen to collect at the bottom of the anterior chamber similar to the observations made for hypopyon and hyphema. These results confirm the potential of using numerical calculations in order to obtain a better understanding of the particle transport and deposition patterns in the anterior chamber of the eye. [DOI: 10.1115/1.2472380]

Published
2007

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