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Zeitschriftenartikel zum Thema „ANSYS FLUEN“

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Veröffentlicht am 11. September 2023

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1

Pawłucki, Mateusz. „Multiple objective shape optimization in Ansys Fluent Solver“. Mechanik, Nr. 11 (November 2015): 893–95. http://dx.doi.org/10.17814/mechanik.2015.11.587.

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2

Евсеев, Д. Ю., und О. К. Овчинникова. „PROBLEM SOLUTION ON MOVABLE GRIDS IN ANSYS FLUENT“. ВЕСТНИК ОБРАЗОВАНИЯ И РАЗВИТИЯ НАУКИ РОССИЙСКОЙ АКАДЕМИИ ЕСТЕСТВЕННЫХ НАУК, Nr. 1 (15.03.2023): 9–16. http://dx.doi.org/10.26163/raen.2023.61.15.002.

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Рассматриваются возможности использования универсального программного комплекса Аnsys Fluent для моделирования движения твердых тел под воздействием газодинамических сил. Даны примеры, реализующие возможные при решении таких задач подходы для моделирования вращательного и поступательного движения твердого тела. The possibilities of using the universal software package AnsysFluent for modeling the motion of solids under the influence of gas-dynamic forces are considered. We provide examples illustrating the use of approaches to modeling the rotational and translational motion of a solid body to solve the problems in question.
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Djodikusumo, Indra, I. Nengah Diasta und Iwan Sanjaya Awaluddin. „Geometric Modeling of a Propeller Turbine Runner Using ANSYS BladeGen, Meshing Using ANSYS TurboGrid and Fluid Dynamic Simulation Using ANSYS Fluent“. Applied Mechanics and Materials 842 (Juni 2016): 164–77. http://dx.doi.org/10.4028/www.scientific.net/amm.842.164.

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This paper aims to demonstrate how to model, mesh and simulate a hydraulic propeller turbine runner based on the geometrical specification of the runner blade. Modeling process is divided into preparation and implementation phase. Preparation phase illustrates how to develop stream surfaces and passages, how to create and transform meanline and how to create an rtzt file. The profile in rtzt file has a certain fix thickness which has to be altered later. Implementation phase describes operations necessary in creating a propeller runner model in ANSYS BladeGen which consist of importing rtzt file, modifying the trailing edge properties and altering profile thickness distribution to that of 4 digits NACA airfoil standard. Grid is generated in ANSYS TurboGrid utilizing ATM Optimized topology. CFD simulation is done using the ANSYS Fluent with pressure inlet and pressure outlet boundary conditions and k-ε turbulence model. Hydraulic efficiency of the runner is calculated utilizing Turbo Topology module in ANSYS Fluent. The authors will share the advantages that may be obtained by using ANSYS BladeGen compared with the use of general CAD Systems.
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Jading, Abadi, Paulus Payung und Reniana Reniana. „ansys fluent; CFD; PCRD; simulation; sago starch“. Jurnal Ilmiah Rekayasa Pertanian dan Biosistem 10, Nr. 1 (24.03.2022): 1–13. http://dx.doi.org/10.29303/jrpb.v10i1.279.

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The mini-scale pneumatic conveying ring dryer (PCRD) type sago starch dryer with a capacity of 80 kg / day has been applied to the processing of sago starch to produce dry sago starch. To increase the production capacity of the PCRD dryer, a recirculation pipe was modified. The modified pipe section is the venturi pipe diameter and the upriser vertical pipe increased. The diameter of the vertical upriser pipe is 2.5 times larger than that of the ubend pipe and the downcomer vertical pipe so that a buffer is formed. In addition, the difference in the diameter of the recirculation pipe can increase the residence time of the material. The purpose of this study was to simulate using ansys fluent to determine the temperature profile, air flow velocity, and pressure in the pneumatic conveying ring dryer (PCRD) type sago starch dryer pipe with a capacity of 1 ton per day. Simulations were carried out using the Computational Fluid Dynamics (CFD) technique using ansys fluent software package. The simulation results show that the temperature along the pipe has decreased by about 2oC at various variations of the input air velocity and variations in the outlet at the boundary conditions. Likewise, the air velocity at the end of the outlet pipe (vertical downcomer pipe) increases due to the difference in diameter with the inlet pipe. The pressure on the vertical upriser pipe is higher than the pressure on the ubend pipe and downcomer vertical pipe. The simulation results show that the recirculation pipe design is very well used so that it can be continued for the manufacture of PCRD-type sago starch dryer on a scale of 1 ton per day.
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Vyroubal, Petr, und Martin Mačák. „Investigation of Cyclic Voltammetry in Ansys Fluent“. ECS Transactions 95, Nr. 1 (18.11.2019): 467–74. http://dx.doi.org/10.1149/09501.0467ecst.

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Popovici, Cătălin George. „HVAC System Functionality Simulation Using ANSYS-Fluent“. Energy Procedia 112 (März 2017): 360–65. http://dx.doi.org/10.1016/j.egypro.2017.03.1067.

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7

BOJKO, MARIAN, LUKAS HERTL und SYLVA DRABKOVA. „METHODS OF CFD MODELLING OF TWIN-SCREW PUMPS FOR NON-NEWTONIAN MATERIALS“. MM Science Journal 2021, Nr. 6 (15.12.2021): 5366–72. http://dx.doi.org/10.17973/mmsj.2021_12_2021103.

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The twin-screw pump is designed for pumping highly viscous materials in the food industry. Rheological characteristics of materials are important in the specification of design parameters of screw pumps. Analysis of flow in the twin-screw pumps with definition of non-newtonian materials can be made by numerical modelling. CFD generally oriented software ANSYS Fluent and ANSYS Polyflow has been used for modelling. In this study those software’s (ANSYS Fluent and ANSYS Polyflow) were defined for solution of flow in the twin-screw pumps. Results were compared for the same boundary conditions on the inlet and outlet of the 3D model. For definition of the viscosity were used the Nonnewtonian power law. Parameters as consistency coefficient and flow exponent for Nonnewtonian power law were analysed by software ANSYS Fluent and ANSYS Polyflow. Postprocessing form ANSYS Fluent and ANSYS Polyflow were made by contours of field and by graphs.
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Amosov, Pavel V., Sergey А. Kozirev und Oleg V. Nazarchuk. „CREATING COMPUTER MODEL OF ATMOSPHERE AERTMDNAMICS OF OPEN PIT IN ANSYS FLUENT“. Bulletin of the Saint Petersburg State Institute of Technology (Technical University) 44, Nr. 70 (September 2018): 121–25. http://dx.doi.org/10.15217/issn1998984-9.2018.44.121.

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9

Aurybi, Mohammed A., Hussain H. Al-Kayiem, Syed I. U. Gilani und Ali A. Ismaeel. „CFD Analysis of Hybrid Solar Chimney Power Plant“. MATEC Web of Conferences 225 (2018): 04011. http://dx.doi.org/10.1051/matecconf/201822504011.

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In this study, a novel approach has been proposed as a solar chimney integrated with an external heat source to extend the system operation during the absence of solar energy. Flue gas channels have been utilized to exchange heat with the air inside the collector of the solar chimney. The hybrid solar chimney has been investigated numerically by ANSYS-Fluent software, using discrete ordinates radiation model. The hybrid system was simulated in 3D, steady-state by solving Navier-Stokes and energy equations. The numerical results have been validated using experimental measurements of a conventional solar chimney. The influence of flue channels on the system performance was predicted and analyzed in hybrid mode. With 0.002 kg/s of flue gas at 100°C injected in flue channels during the daytime; hybrid mode results demonstrated enhancement of 24% and 9 % for velocity and temperature, respectively. The power generation was enhanced by 56%. It has been proved that the proposed technique is able to resolve the set back of night operation problem of the solar chimney plants.
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Huang, Dennis, Zhigang Yang und Randolph Chi Kin Leung. „Implementation of Direct Acoustic Simulation using ANSYS Fluent“. INTER-NOISE and NOISE-CON Congress and Conference Proceedings 263, Nr. 5 (01.08.2021): 1243–52. http://dx.doi.org/10.3397/in-2021-1787.

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Direct Acoustic Simulation (DAS) is a powerful Computational Aero Acoustics method that obtains hydrodynamic and acoustic solutions simultaneously by solving compressible Navier-Stokes equation together with state equation of ideal gas. Thus, DAS has advantages for cases with flow acoustic coupling and high Mach numbers (). With an increasing demand of massive-scale calculations, a robust numerical solver for DAS is required. ANSYS Fluent is a suitable CFD platform with proven robustness. However, there is no direct implementation of DAS in the current version of ANSYS Fluent. The present study, therefore, aims to investigate an approach for implementing DAS using ANSYS Fluent. Given the acoustic part of fluctuations is much smaller than the hydrodynamic part in amplitude, a DAS solver requires high accuracy and low dissipation. Based on these needs, proper solution methods, spatial discrete methods and boundary conditions are firstly determined through simple calculations of two dimensional propagating plane waves. Afterwards aeroacoustics of a two-dimensional cavity flow at 0.6 is calculated to verify the capability for solving separating flow with the aforementioned set-up. Finally, aeroacoustics of a cylindrical bluff body at a turbulent regime and 0.2 is calculated in three-dimensions to verify the capability for solving turbulent flow using Monotonically Integrated Large Eddy Simulation.
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Agrawal, Sandeep, Premanand S. Chauhan und Prem Prakash Pandit. „Design optimisation of air filters using ANSYS fluent“. IOP Conference Series: Materials Science and Engineering 1136, Nr. 1 (01.06.2021): 012077. http://dx.doi.org/10.1088/1757-899x/1136/1/012077.

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12

Hidayat, M. Fajri. „ANALISA AERODINAMIKA AIRFOIL NACA 0021 DENGAN ANSYS FLUENT“. JURNAL KAJIAN TEKNIK MESIN 1, Nr. 1 (04.04.2016): 43–59. http://dx.doi.org/10.52447/jktm.v1i1.332.

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Analisa performa aerodinamika suatu penampang airfoil sangatlah diperlukan untuk menerntukan gaya angkat maksimum yang terjadi serta gaya-gaya yang bekerja pada penampang airfoil seperti Gaya Drag dan Gaya Lift. Dalam penelitian ini suatu desain penampang airfoil seri NACA 0021 suatu airfoil simetris di test dengan menggunakan software ANSYS Fluent dengan input kecepatan, viskositas dan densitas fluida sehingga dapat diketahui sebaran kecepatan dan sebaran tekanan di sepanjang airfoil. Untuk mendapatkan performa yang maksimal dari airfoil ini, diberi variasi sudut serang yang berbeda-beda sehingga nantinya di dapatkan sudut serang maksimal untuk menghasilkan gaya angkat yang maksimal juga. Dari kontur kecepatan dan kontur tekanan yang terbaca di ANSYS Fluent sepanjang permukaan atas dan permukaan bawah airfoil diambil harga rata-ratanya dan kemudian di plot dalam grafik untuk menunjukkan besarnya gaya lift dan gaya drag yang terjadi serta dari distribusi kecepatan dan distribusi temperatur tersebut diperoleh harga koefisien drag dan koefisien lift. Penelitian ini diharapkan bisa bermanfaat di dunia aerodinamika khususnya yang berhubungan dengan sayap pesawat sehingga permodelan ini bisa memaksimalkan performa terbang suatu pesawat dan memungkinkan pengembangan desain sayap-sayap pesawat yang sesuai dengan pemilihan desain totalnya dengan standar-standar NACA.Keywords : Aerodinamika, Airfoil, Sudut Serang, Gaya angkat
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Ni, Hong Jun, Qing Qing Hu, Xing Xing Wang und Zhi Yang Li. „Simulation Researches of PEMFC Based on ANSYS / FLUENT“. Advanced Materials Research 287-290 (Juli 2011): 2500–2505. http://dx.doi.org/10.4028/www.scientific.net/amr.287-290.2500.

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The internal mass transfer and the distribution of each component in proton exchange membrane fuel cell (PEMFC), including the hydrogen-oxygen proton exchange membrane fuel cell (H2-O2PEMFC) and direct methanol fuel cell (DMFC), have great effects on the life and performance of cell. Simulation with software is one of the most important research methods. In this paper, the recent researches on the working conditions of PEMFC modeled with commercial software ANSYS / FLUENT are summarized, and on the basis, new visions for further study about abnormal fuel cells are brought forward.
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Singh, Amardeep. „Simulation Of Coffee Stain Effects Using ANSYS Fluent“. Journal of Physics: Conference Series 1276 (August 2019): 012004. http://dx.doi.org/10.1088/1742-6596/1276/1/012004.

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Herrmann, Stephan, Zhan Zhoon Ong, Maximilian Hauck, Michael Hauser, Felix Fischer, Jeremias Weinrich, Matthias Gaderer und Hartmut Spliethoff. „Modelling of a Reversible SOC in Ansys Fluent“. ECS Transactions 91, Nr. 1 (10.07.2019): 2065–74. http://dx.doi.org/10.1149/09101.2065ecst.

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Vorobyev, Vladimir, Ravshan Ibatulin und Artem Ignattsev. „VALIDATION OF ANSYS FLUENT SOFTWARE PACKAGE MODELS TO DETERMINE THE PARAMETERS OF PETROLEUM PRODUCTS SPILL FIRES“. Fire and Emergencies: prevention, elimination, Nr. 3 (2018): 15–20. http://dx.doi.org/10.25257/fe.2018.3.15-20.

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Cejpek, Ondrej, Milan Maly, Miloslav Bělka, Jaroslav Slama, Ondrej Hajek, Frantisek Prinz und Jan Jedelský. „Spray in cross–flow: comparison of experimental and numerical approach“. EPJ Web of Conferences 264 (2022): 01007. http://dx.doi.org/10.1051/epjconf/202226401007.

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The spray behaviour and droplet trajectories in realistic conditions are of crucial importance in many industrial, agricultural and chemical applications. Droplet characteristics and spray trajectory in chemical applications (e. g. flue gas scrubbing, CO2 capture in spray column) determine the amount of mass involved in the gas scrubbing process, mass trapped by the flow or attached to the walls. Knowledge of the droplet behaviour can improve a nozzle design and scaling, increase the process efficiency, minimize the process liquid and blow away the fraction. In this study, experiments with pressure swirl nozzle in cross–flow of air were performed at one nozzle injection pressure (0.5 MPa) and several cross–flow velocities (8, 16, 32 m/s). The results on droplet trajectories are compared with numerical results obtained by ANSYS Fluent. Two Lagrange approaches for spray modelling were used. Injection of droplet groups and Linearized Instability Sheet Atomization (LISA) model incorporated within ANSYS Fluent were used to represent the spray. The CFD results of spray penetration and droplet trajectories are compared with experimental data. A simple analytical model is able to well predict trajectories of large droplets, but fails to predict trajectories of small droplets. The LISA model yields a better accuracy for spray in cross-flow prediction.
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Sheikh Suleimany, Jehan M. Fattah, Tara H. Aurahman und Bruska S. Mamand. „Flow simulation over semicircular labyrinth weir using ANSYS -fluent“. Tikrit Journal of Engineering Sciences 29, Nr. 1 (05.04.2022): 83–98. http://dx.doi.org/10.25130/tjes.29.1.7.

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This study investigates the flow of a semicircular labyrinth weir in an open channel by experimental and numerical methods. The experiments were carried out in a channel with a length of 3.5m and width of 0.25m and 0.3m height under five different flow rates. Five different discharge values over the weir were used. In each experiment, flow rate and flow depth were measured. Numerical processes solved using mathematical equations of fluid flow through the computational fluid dynamics using ANSYS FLUENT code. The Volume of Fluid (VOF) model is designed for the case of water and air-immiscible faces. Standard k-epsilon turbulence models were tested. A mass balance result indicates that the maximum error between the inlet and outlet discharges of the main channel does not exceed 12% for discharge values of 4.31 L/sec. The results indicate that by increasing the discharge flow rate, the percentage of error decreased to 0.4% for discharge, 14.6 L/sec. The findings show that the free water surface profile obtained from the numerical model compared to experimental values complies well with the experimental results.
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Pashchenko, D. I. „ANSYS Fluent CFD Modeling of Solar Air-Heater Thermoaerodynamics“. Applied Solar Energy 54, Nr. 1 (Januar 2018): 32–39. http://dx.doi.org/10.3103/s0003701x18010103.

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Sheikh Suleimany, Jehan M. Fattah, Tara H. Aurahman und Bruska S. Mamand. „Flow simulation over semicircular labyrinth weir using ANSYS -fluent“. Tikrit Journal of Engineering Sciences 29, Nr. 1 (23.04.2022): 59–74. http://dx.doi.org/10.25130/tjes.29.1.6.

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This study investigates the flow of a semicircular labyrinth weir in an open channel by experimental and numerical methods. The experiments were carried out in a channel with a length of 3.5m and width of 0.25m and 0.3m height under five different flow rates. Five different discharge values over the weir were used. In each experiment, flow rate and flow depth were measured. Numerical processes solved using mathematical equations of fluid flow through the computational fluid dynamics using ANSYS FLUENT code. The Volume of Fluid (VOF) model is designed for the case of water and air-immiscible faces. Standard k-epsilon turbulence models were tested. A mass balance result indicates that the maximum error between the inlet and outlet discharges of the main channel does not exceed 12% for discharge values of 4.31 L/sec. The results indicate that by increasing the discharge flow rate, the percentage of error decreased to 0.4% for discharge, 14.6 L/sec. The findings show that the free water surface profile obtained from the numerical model compared to experimental values complies well with the experimental results.
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Anilkumar, G., G. R. Krishna, G. V. Brahmendra Kumar und K. Palanisamy. „Performance analysis of solar updraft tower using Ansys fluent“. IOP Conference Series: Materials Science and Engineering 937 (02.10.2020): 012022. http://dx.doi.org/10.1088/1757-899x/937/1/012022.

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Montazeri Saniji, Mahdi, Sahar Noori und Amir AzadManesh. „Numerical Simulation in Atmospheric Water Generator By Ansys Fluent“. Journal of Renewable and New Energy 10, Nr. 1 (21.03.2023): 32–45. http://dx.doi.org/10.52547/jrenew.10.1.32.

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Krukovsky, P. G., A. S. Polubinskiy, O. Y. Tadlia und V. N. Kovalenko. „CFD- МОДЕЛИРОВАНИЕ СОПРЯЖЕННОГО ТЕПЛОВЛАГОПЕРЕНОСА МЕЖДУ ПОРИСТЫМИ СТРОИТЕЛЬНЫМИ МАТЕРИАЛАМИ И ПАРОВОЗДУШНОЙ СРЕДОЙ“. Industrial Heat Engineering 37, Nr. 4 (16.11.2017): 93–102. http://dx.doi.org/10.31472/ihe.4.2015.11.

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Разработана CFD-модель в программной среде ANSYS-FLUENT для моделирования сопряженного тепловлагопереноса между твердой поверхностью ограждения помещения и паровоздушной средой прослойки с учетом радиационного и конвективного теплообмена. Сопряженный тепловлагоперенос реализован с помощью специально созданных функций, что расширило расчетные возможности программы ANSYS-FLUENT. Полученные распределения температур и абсолютных влажностей в ограждающей конструкции с достаточной точностью совпадают с экспериментальными данными.
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Li, Nan, Bao Wei Song und Kai Wei. „An Analysis Method of Torpedo Shell Fluid-Structure Interaction Based on Fluent and ANSYS“. Applied Mechanics and Materials 256-259 (Dezember 2012): 2844–48. http://dx.doi.org/10.4028/www.scientific.net/amm.256-259.2844.

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At present, the torpedo shell analysis includes fluid analysis and structural analysis. The fluid pressure distribution of torpedo surface is the results of the fluid analysis, and it is the outer load input of torpedo shell analysis. Meanwhile the results of torpedo shell structure analysis also play a important role in binding. So torpedo shell structure analysis is a fluid-structure interaction analysis. With the development of engineering analysis software, Fluid analysis software Fluent and structural analysis software ANSYS are able to analyze torpedo fluid and structural. But there has not been a specialized software to handle fluid-structure interaction analysis. This paper coupled Fluent and ANSYS, and got an analysis method for torpedo shell fluid-structure interaction analysis base on Fluent and ANSYS
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Park, J., Q. D. T. Pham und S. Choi. „A COMPARATIVE STUDY OF TWO-PHASE FLOW SIMULATIONS BETWEEN A COMMERCIAL SOFTWARE (ANSYS FLUENT) AND AN OPEN SOURCE-BASED (OPENFOAM) COMPUTATIONAL FLUID DYNAMICS“. Journal of Computational Fluids Engineering 26, Nr. 2 (30.06.2021): 31–38. http://dx.doi.org/10.6112/kscfe.2021.26.2.031.

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Pajcin, Miroslav, Aleksandar Simonovic, Toni Ivanov, Dragan Komarov und Slobodan Stupar. „Numerical analysis of a hypersonic turbulent and laminar flow using a commercial CFD solver“. Thermal Science 21, suppl. 3 (2017): 795–807. http://dx.doi.org/10.2298/tsci160518198p.

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Computational fluid dynamics computations for two hypersonic flow cases using the commercial ANSYS FLUENT 16.2 CFD software were done. In this paper, an internal and external hypersonic flow cases were considered and analysis of the hypersonic flow using different turbulence viscosity models available in ANSYS FLUENT 16.2 as well as the laminar viscosity model were done. The obtained results were after compared and commented upon.
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Lenhard, Richard, Milan Malcho und Katarína Kaduchová. „Numerical simulation of induction heating thick-walled tubes“. MATEC Web of Conferences 168 (2018): 02004. http://dx.doi.org/10.1051/matecconf/201816802004.

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In the paper is shown the connection of two toolboxes in an Ansys Workbench solution for induction heating. In Ansys Workbench, Maxwell electromagnetism programs and Fluent have been linked. In Maxwell, a simulation of electromagnetic induction was performed, where data on the magnetic field distribution in the heated material was obtained and then transformed into the Fluent program in which the induction heating simulation was performed.
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Rodríguez, C. D., und J. S. De Plaza. „Flow hydraulic simulation through two sand traps, using Ansys fluent“. Journal of Physics: Conference Series 2118, Nr. 1 (01.11.2021): 012002. http://dx.doi.org/10.1088/1742-6596/2118/1/012002.

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Abstract Computational fluid dynamics is a tool that allows to simulate and observe the behavior of any fluid, based on a physical, hydraulic, and hydrodynamic analysis. This research analyses the behavior of the flow in a sand trap, which is a structure used to remove sand particles with a minimum size of 0.10 mm, prior to treatment in a drinking-water plant. The objective of this study is to determine the highest efficiency between two sand traps, one with a double smooth screen and the other with a double perforated screen (with diffusers), based on the simulation and analysis behavior of the flow inside each sand trap. The methodology used includes the traditional design of each unit based on Hazen’s model and Stokes viscosity law, to later carry out the numerical model simulation from Ansys Fluent (pre-processing, processing, and post-processing). The result shows that perforated double screen sand trap generates a removal efficiency of 78%, while the smooth double screen 28%. In addition, other four units of interleaved screens are proposed, in these cases efficiencies of up to 50% are observed and it is shown that it is necessary to implement at least two perforated screens (with diffusers) to guarantee an efficiency greater than 70%. Hydraulic simulation has a broad impact on infrastructure works and consulting.
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Shrivastava, Devansh. „CFD Modelling of Underground Coal Gasification using ANSYS Fluent Simulator“. International Journal of Scientific & Engineering Research 12, Nr. 07 (25.07.2021): 505–19. http://dx.doi.org/10.14299/ijser.2021.07.02.

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Underground Coal Gasification is a non-traditional, in-situ combustion process for converting coal into product gases. In this process coal is combusted and the produced syngas which basically contains CO2, H2, CO and CH4 is extracted to the surface with the help of drilled wells. In this study, with reference to a lab-scaled UCG experiment [1] and taking the experimental data as the basis for the research a two dimensional CFD reactor model was created and further studies were done to establish the activity at the different locations of the reactor.
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Zahariea, D. „Numerical analysis of eccentric orifice plate using ANSYS Fluent software“. IOP Conference Series: Materials Science and Engineering 161 (November 2016): 012041. http://dx.doi.org/10.1088/1757-899x/161/1/012041.

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Afif, A. A., P. Wulandari und A. Syahriar. „CFD analysis of vertical axis wind turbine using ansys fluent“. Journal of Physics: Conference Series 1517 (April 2020): 012062. http://dx.doi.org/10.1088/1742-6596/1517/1/012062.

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32

Wei, Guodong, Xin Qi und Lei Yang. „Modeling of an argon cascaded arc plasma by ANSYS FLUENT“. Journal of Physics: Conference Series 488, Nr. 15 (10.04.2014): 152013. http://dx.doi.org/10.1088/1742-6596/488/15/152013.

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33

Dixit, Shivanshu, Arvind Kumar, Suraj Kumar, Nitin Waghmare, Harish C. Thakur und Sabah Khan. „CFD analysis of biodiesel blends and combustion using Ansys Fluent“. Materials Today: Proceedings 26 (2020): 665–70. http://dx.doi.org/10.1016/j.matpr.2019.12.362.

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34

Krusch, S., V. Scherer, R. Solimene und O. Senneca. „Assessment of coal pyrolysis kinetics for Barracuda or Ansys Fluent“. Energy Procedia 158 (Februar 2019): 1999–2004. http://dx.doi.org/10.1016/j.egypro.2019.01.459.

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35

Muhammad Shehzad Arif, M. Javaid Afzal, Farah Javaid, Shahzadi Tayyaba, M. Waseem Ashraf, G. F. Ishraque Toki und M. Khalid Hossain. „Laminar Flow Analysis of NACA 4412 Airfoil Through ANSYS Fluent“. Proceedings of International Exchange and Innovation Conference on Engineering & Sciences (IEICES) 8 (20.10.2022): 394–99. http://dx.doi.org/10.5109/5909123.

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36

Mačák, M., P. Vyroubal, T. Kazda, D. Capkova und Jiří Maxa. „Numerical Modelling of Discharging the Lithium-Sulphur Batteries in Ansys Fluent“. Advances in Military Technology 17, Nr. 2 (25.08.2022): 163–77. http://dx.doi.org/10.3849/aimt.01525.

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Lithium-sulfur batteries appear to be an exciting technology for energy storage due to their many advantageous properties. Due to its low weight and high energy, this technology could be used in aviation, aerospace or in heavy electric vehicles or even for mobile applications. This article investigates possible approaches for modelling of lithium-sulfur batteries. A new method using Ansys Fluent add-on Multi-Scale Multi-Domain battery module, originally designed for lithium-ion batteries, is presented. Battery characteristics are described through an equivalent circuit model, which can capture its complex characteristics. The results suggest that the built-in Ansys Fluent model can be successfully extended for 3D modelling of lithium-sulfur batteries. The critical point of the simulation is the precise definition of equivalent circuit model parameters.
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Kondakov, B. I. „Numerical modeling of the impact of tsunami in ANYS19.2 program“. Вестник гражданских инженеров 19, Nr. 1 (2022): 24–28. http://dx.doi.org/10.23968/1999-5571-2022-19-1-24-28.

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Аt present, there is observed a need to model natural processes in order to clarify the impacts caused by them. In this work, the author has modeled the roll of the boron wave (tsunami) on a conditional obstacle, namely, a structure in the form of a parallelepiped. The calculation was performed in the ANSYS Fluent module of the ANSYS 19.2 program through numerical solution of the Navier-Stokes differential equation of fluid flow using the finite volume method. Eventually, based on the results obtained in the ANSYS 19.2 program, a graph of changes in the total horizontal force over time was plotted and the load dynamism factor from the boron wave was calculated.
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Novianarenti, Eky, Muhammad Anis Mustaghfirin und Achmad Fardiansyah Abdillah. „Effect Stress and Vibration Analysis at NACA Airfoil towards Axial Fan Blade Performance“. Journal of Mechanical Engineering, Science, and Innovation 2, Nr. 1 (29.05.2022): 28–43. http://dx.doi.org/10.31284/j.jmesi.2022.v2i1.2994.

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Axial fans are widely applied in the industrial sector. Axial fans are used for ventilation systems and other cooling systems. The blade design of the axial fan requires an airfoil study. Unfortunately, there are not many articles that discuss in detail about airfoils, especially on noise and vibration that can have an impact on axial fan performance using computational fluid methods or software. This study performs axial fan analysis using computational methods with ANSYS Fluent, Static Structural, Modal and Harmonic Response software to obtain the values of stress, vibration and fluid flow. The experimental design used is using NACA 1412, 4142, and 6412 airfoils on the tip with variations in angles of 60, 74, and 80. While on the hub uses NACA 9312, 9412, and 9512 airfoils with angle variations of 20, 30, and 60 and simulated to find the value of vibration and stress analysis. The 3D axial fan design is imported into the ANSYS Fluent, Static Structural, Modal and Harmonic Response software. The simulation results using Ansys Fluent, shows the pressure contour with a maximum value of 198.424 Pa and Velocity streamline with a maximum value of 28.8669 m/s. the results of the Ansys Static Structural simulation show that the average total deformation is 9.9275e-008 m. The simulation results using Ansys Modal, show that there is a natural frequency of 287.8 Hz and the simulation results of Ansys Harmonic Response obtained an average total deformation of 5.0809e-012 m and the equivalent stress value with a maximum value of σ y, max = 0.20186 Pa.
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Roslim, M. K., Suhaimi Hassan und K. Izzati. „Experimental and Simulation Study on the Effects of Twisted Coil Plates on the Performance of Fire Tube Boiler“. Applied Mechanics and Materials 564 (Juni 2014): 234–39. http://dx.doi.org/10.4028/www.scientific.net/amm.564.234.

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Influences of twisted coil plate insert on the performance of fire tube boiler using were experimentally investigated. In this study, the twisted coil plate was placed inside the tube to illustrate boiler performance. The performances of boiler were studied in terms of operating time taken, exhaust flue gas temperature, steam temperature and boiler efficiency. The boiler was operated with 50%, 100% and without tube coil plate inserts at low and high fire burner setting. Based on the results obtained, effect of twisted plate insert and without insert were observed. There is an enhancement in boiler performance in terms of boiler efficiency. The ANSYS Fluent simulation showed the effect of width ratio and twist ratio. Therefore, the experimental results indicate that using twisted coil plate in the boiler is one of the best ways to improve boiler performance.
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40

Hrudka, Jaroslav, Dušan Rusnák und Réka Csicsaiová. „INCREASING THE EFFICIENCY OF SEPARATING RAINWATER IN THE CSO CHAMBER BY MATHEMATICAL MODELING“. Czech Journal of Civil Engineering 3, Nr. 2 (31.12.2017): 73–78. http://dx.doi.org/10.51704/cjce.2017.vol3.iss2.pp73-78.

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The paper shows the essence of CFD modeling in sanitary and environmental engineering. Paper includes practical example of assessment of CSO chamber, by using ANSYS Fluent software. This paper also explains the principles, upon which the ANSYS FLUENT software works. Then explains the methodology in creating the model, which is composed of: creating 3D geometry, creating computer mesh, entering of boundary conditions, defining input parameters and finally the actual simulations. In this paper there are also explained methods of modeling, which we use for solving the simulations at the Department of Sanitary and Environmental Engineering.
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Stęchły, Katarzyna, Gabriel Wecel und Derek B. Ingham. „CFD modelling of air and oxy-coal combustion“. International Journal of Numerical Methods for Heat & Fluid Flow 24, Nr. 4 (29.04.2014): 825–44. http://dx.doi.org/10.1108/hff-02-2013-0066.

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Purpose – The main goal of this work was the CFD analysis of air and oxy-coal combustion, in order to develop a validated with experimental measurements model of the combustion chamber. Moreover, the purpose of this paper is to provide information about limitations of the sub-models implemented in commercial CFD code ANSYS Fluent version 13.0 for the oxy-coal combustion simulations. The influence of implementation of the weighted sum of gray gas model (WSGGM) with coefficients updated to oxy-coal combustion environment has been investigated. Design/methodology/approach – The sub-models validated with experimental measurements model for the air combustion has been used to predict the oxy-coal combustion case and subsequently the numerical solutions have been compared with the experimental data, which enclose the surface incident radiation (SIR) and the flue gas temperature. To improve the numerical prediction of the oxy-coal combustion process the own routine for calculating properties of the oxy-combustion product has been implemented. Findings – The results of numerical simulation of combustion in the air environment fitted within the experimental measurements accuracy. However, the air combustion sub-models implemented for the oxy-coal combustion simulations does not predict the SIR within the experimental data accuracy. The implementation of own routine, which uses the coefficients calculated for oxy-coal combustion environment shows improvement in numerical prediction of oxy-coal combustion. Originality/value – The radiative properties of gases in the combustion chamber during oxy-coal combustion calculated using the WSGGM implemented in ANSYS Fluent 13.0 do not predict the SIR within experimental measurement accuracy, however, implementation of WSGGM with updated coefficients provide a reasonable improvement in numerical prediction of SIR in the oxy-coal combustion.
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Song, Xiao Yan, und Qin Fan. „The Analysis of Rotary Kiln Thermal Characteristics Based on ANSYS and FLUENT“. Advanced Materials Research 834-836 (Oktober 2013): 1523–28. http://dx.doi.org/10.4028/www.scientific.net/amr.834-836.1523.

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In this paper, the FLUENT finite element software is used to simulation analyze the rotary kiln, kiln gas combustion process and gas-solid coupling effect. The kiln and rotary kiln of gas temperature field is calculated and then imported into the ANSYS software as an initial condition to complete the reconstruction of the temperature field and using the node interpolation method to carry out thermal stress analysis. Through the joint simulation analysis based on FLUENT and ANSYS finite element software, the analysis of rotary kiln combustion process, the heat transfer and the mechanical response of the structure can be implemented under the same condition, making the simulation results of rotary kiln more related to practical operation conditions. The method and results presented have significant theoretical guidance for the research and development of new types of rotary kiln.
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Mouhsin, Nidal, Mariam Bouzaid und Mourad Taha-Janan. „Experimental, Analytical and ANSYS Computation of Novel Cascade Solar Desalination Still“. International Journal of Heat and Technology 40, Nr. 2 (30.04.2022): 397–404. http://dx.doi.org/10.18280/ijht.400206.

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This study presents a simple device using solar radiation as a source of energy to convert brackish water to freshwater. To enhance the productivity of the cascade of solar stills, a new structure of the absorber plate with sloped surfaces and baffles was proposed to present a slight water layer thickness and improve the amount of solar radiation incident. A physical model is developed taking into account various parameters which affect the distillate yield of solar sills. In the present work, the modeling of the cascade solar still uses ANSYS Fluent V18 to investigate the yield. A three-dimensional model was considered to simulate the temperature of the water, absorber plate, and freshwater productivity. A comparison was conducted based on the CFD simulation results, experimental and approximate analytical model data. It showed a reasonable agreement of the results obtained using the analytical model with the experimental and the simulation using ANSYS Fluent of different working parameters especially the productivity. The best performance was obtained on 15/07/2018, with a productivity rate of more than 1.67 kg/m2.hr.
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Thakur, Neha, und Hari Murthy. „Simulation study of droplet formation in inkjet printing using ANSYS FLUENT“. Journal of Physics: Conference Series 2161, Nr. 1 (01.01.2022): 012026. http://dx.doi.org/10.1088/1742-6596/2161/1/012026.

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Abstract Flow simulations of jetting of inkjet drops are presented for water and ethylene glycol. In the inkjet printing process, droplet jetting behaviour is the deciding parameter for print quality. The multiphase volume of fluid (VOF) method is used because the interaction between two phases (air and liquid) is involved in the drop formation process. The commercial inkjet printer has a nozzle diameter of ∼73.2μm. In this work, a simulation model of inkjet printer nozzles with different diameters 40μm, 60μm, and 80μm are developed using ANSYS FLUENT software. It is observed that when water is taken as solvent then the stable droplets are generated at 60μm nozzle diameter till 9μs because of its low viscosity. For higher diameter, the stamen formation is observed. Ethylene glycol stable droplets are achieved at 80μm nozzle diameter till 9μs because of their high viscosity (∼10 times that of water). Along with the droplet formation, the sustainability of the droplet in the air before reaching the substrate is also important. The simulation model is an inexpensive, fast, and flexible alternative to study the ink characteristics of the real-world system without wasting resources.
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Awan, Asifa, Mahmood Saleem und Abdul Basit. „Simulation of Proton Exchange Membrane Fuel Cell by using ANSYS Fluent“. IOP Conference Series: Materials Science and Engineering 414 (13.09.2018): 012045. http://dx.doi.org/10.1088/1757-899x/414/1/012045.

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46

Liu, Enbin, Shikui Yan, Shanbi Peng, Liyu Huang und Yong Jiang. „Noise silencing technology for manifold flow noise based on ANSYS fluent“. Journal of Natural Gas Science and Engineering 29 (Februar 2016): 322–28. http://dx.doi.org/10.1016/j.jngse.2016.01.021.

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47

Patel, A., und R. Bhattacharyay. „Application of ANSYS FLUENT MHD code for liquid metal magnetohydrodynamic studies“. Nuclear Fusion 59, Nr. 9 (25.07.2019): 096024. http://dx.doi.org/10.1088/1741-4326/ab26c9.

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48

Rybdylova, O., M. Al Qubeissi, M. Braun, C. Crua, J. Manin, L. M. Pickett, G. de Sercey, E. M. Sazhina, S. S. Sazhin und M. Heikal. „A model for droplet heating and its implementation into ANSYS Fluent“. International Communications in Heat and Mass Transfer 76 (August 2016): 265–70. http://dx.doi.org/10.1016/j.icheatmasstransfer.2016.05.032.

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49

., S. Parimala Murugaveni. „ANALYSIS OF FORCED DRAFT COOLING TOWER PERFORMANCE USING ANSYS FLUENT SOFTWARE“. International Journal of Research in Engineering and Technology 04, Nr. 04 (25.04.2015): 217–29. http://dx.doi.org/10.15623/ijret.2015.0404039.

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50

Kirpo, Maksims. „Global simulation of the Czochralski silicon crystal growth in ANSYS FLUENT“. Journal of Crystal Growth 371 (Mai 2013): 60–69. http://dx.doi.org/10.1016/j.jcrysgro.2013.02.005.

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