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Job Record #19125 | |
Title | Design and development a modular aircraft model |
Category | PhD Studentship |
Employer | IFAS, TU Braunschweig |
Location | Germany, Lower Sexony, Braunschweig |
International | Yes, international applications are welcome |
Closure Date | Friday, May 10, 2024 |
Description: | |
The Technical University of Braunschweig has over 16,000 students and 3,800 employees one of the leading technical universities in Germany. It stands for strategic and performance-oriented thinking and acting, relevant research, committed teaching and successful Transfer of knowledge and technologies in business and society. We consistently stand up for Family friendliness and equal opportunities. Our research focuses on mobility, engineering for health, metrology and the city Future. Strong engineering and natural sciences form our core disciplines. This are closely linked to economics, social sciences, education and the humanities. Our campus is located in the middle of one of the most research-intensive regions in Europe. With those over 20 We work just as successfully with research institutions in our neighborhood as we do with them our international partner universities. We are looking for the Institute of Aircraft Propulsion and Turbomachinery as soon as possible a Research assistant Employees (m/f/d) on the topic: design and development a modular aircraft model for investigation integrated drives (EG 13 TV-L, full-time) The position is temporary and is expected to be filled for 3 years. It is intended to qualify the serve young academics and offers the opportunity to do a doctorate. With the major goal of climate-neutral flying, we are conducting research in the new DFG/TRR SynTrac research network potentials and synergies through one Aircraft design with highly integrated drives in numerous sub-projects. In the Subproject A1 at the Institute of Aircraft Propulsion and Turbomachinery is intended for this The entire consortium developed a versatile wind tunnel model to validate the Models and numerical results are developed and tested. With help of a modular structure, the solution approaches should be different Technologies are determined in a unique overall model and thus novel methods for calculating the performance of aircraft be validated within SynTrac. The engines can z. B. very close to the fuselage arranged or even completely integrated. All drives in the model should be considered active Thrust generators with electric drives are being implemented, which makes the project particularly exciting and makes it unique. There will be very close cooperation with the project throughout the entire project period Project A02 takes place as model design data, instrumentation data and the most important experimental results to validate the power balance in A02 will be made available. Your tasks • You are conducting research on the subject of engine integration in the SynTrac special research area • You present research results at national and international conferences • You support university teaching by supervising student work your qualification • You have completed a scientific university education (Master or equivalent) in the field of mechanical engineering, aerospace engineering. • You have a very good knowledge of German and English • You can be enthusiastic about actively taking on the challenge of climate-neutral flying work and are open to working in an interdisciplinary, cross-location team SynTrac• You are flexible, resilient and can work well in a team We offer • Working on exciting, future-oriented research topics in an inspiring environment Working environment as part of the university community • a lively campus life in an international atmosphere with numerous intercultural Offers and international collaborations • Remuneration according to TV-L (annual special payment, company pension plan comparable to a Company pension in the private sector) including 30 days of annual vacation • flexible working and part-time models and a family-friendly university culture, since 2007 awarded the “Family Friendly University” audit • Special training opportunities for young scientists, a postdoc program as well as other offers from the central personnel development and sports offers. More information We look forward to applicants of all nationalities. At the same time, we welcome your interest severely disabled people and give preference to their applications if they are equally qualified. Please advise Please mention this when you apply and provide proof. Furthermore, we work based on the Lower Saxony Equality Act (NGG) on the fulfillment of the Equality mandate and strive to avoid underrepresentation in all areas and positions. S. of the NGG to be dismantled. We are therefore particularly happy to receive applications from women. We store personal data to carry out the application process. Through By submitting your application, you agree that your data will be processed Stored electronically for application purposes in compliance with data protection regulations are processed. For further information on data protection, please see our Data protection declaration at https://www.tu-braunschweig.de/datenschutzerklaerung-bewerbungen. We do not reimburse application costs. questions and answers Do you have any questions? Mr. Daniel Kessler will answer this by telephone at this number +4953139194210 or by email to d.kessler@ifas.tu-braunschweig.de. Apply using the keyword: “A01” If we have aroused your interest, send your application with meaningful documents in PDF format, preferably by email to d.kessler@ifas.tu-braunschweig.de or by post Technical University of Braunschweig Institute of Aircraft Propulsion and Turbomachinery Hermann-Blenk-Str. 37 38108 Braunschweig Your application documents should include: • Cover letter (max. 1 page) • CV stating professional experience and university education, language and computer skills • Copies of final certificates and an overview of the subjects taken |
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Contact Information: | |
Please mention the CFD Jobs Database, record #19125 when responding to this ad. | |
Name | Daniel Kessler, M.Sc. |
d.kessler@ifas.tu-braunschweig.de | |
Email Application | Yes |
Phone | +4953139194210 |
URL | https://www.tu-braunschweig.de/ifas/institut/team/daniel-kessler-msc |
Address | Technische Universität Braunschweig Institut für Flugantriebe und Strömungsmaschinen Hermann-Blenk-Str. 37 38108 Braunschweig |
Record Data: | |
Last Modified | 16:26:31, Friday, April 26, 2024 |
Job Record #19124 | |
Title | optimisation of compact heat exchangers |
Category | PhD Studentship |
Employer | ISM, TU Braunschweig |
Location | Germany, Lower Saxony, Braunschweig |
International | Yes, international applications are welcome |
Closure Date | Friday, May 10, 2024 |
Description: | |
PhD in optimization of compact heat exchangers at ISM, TU Braunschweig PhD opportunity to explore fluid topology optimization for heat exchange systems using high-fidelity CFD. The goal of the work is to develop novel compact heat exchangers by combining the capabilities of additive manufacturing and the greater degree of freedom offered by optimization techniques. Engineering applications: - Hydrogen fuel systems - Turbine blade cooling - Thermal management of electric parts Please contact Anadika Paul Baghel (a.baghel@tu-braunschweig.de) for an informal query about this studentship. Requirements: The candidate will have an Undergraduate or Master’s degree (or equivalent) in Mechanical Engineering, Aerospace Engineering, Mathematics, Physics, Computer Science, or a related discipline. You would be highly motivated, and able to work independently as well as collaborate with others with effective written/oral communication skills. Knowledge of fluid mechanics or CFD is essential. Experience in programming (Fortran/C++/Python) would be an advantage. Applicants should have strong skills or interests in CFD, fluid mechanics, numerical methods, and programming. How to apply: Please email Anadika Paul Baghel at a.baghel@tu-braunschweig.de with the subject line "Ph.D. Application", including a brief cover letter, your CV, and unofficial transcripts in a single PDF file. I receive a large amount of applications and please only use the above subject line in your email. Otherwise, I will not be able to locate your email and review your application. |
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Contact Information: | |
Please mention the CFD Jobs Database, record #19124 when responding to this ad. | |
Name | Anadika Paul Baghel |
a.baghel@tu-braunschweig.de | |
Email Application | Yes |
Phone | +49 (0)531 391 94281 |
Fax | +49 (0)531 391 94254 |
URL | https://www.tu-braunschweig.de/en/ism/research/multiphase-flow-and-icing/team/baghel |
Address | Technische Universität Braunschweig, Institute of Fluid Mechanics, Hermann-Blenk-Str. 37, 38108 Braunschweig |
Record Data: | |
Last Modified | 15:42:43, Friday, April 26, 2024 |
Job Record #19123 | |
Title | High-fidelity CFD & data-driven modelling of aerodynamic noise |
Category | PhD Studentship |
Employer | Stony Brook University |
Location | United States, New York, New York |
International | Yes, international applications are welcome |
Closure Date | Friday, May 10, 2024 |
Description: | |
Title: High-fidelity CFD and data-driven modeling of aerodynamic noise sources About the Project: Applications are invited for three funded 3-year PhD studentships for the project titled “High-fidelity CFD and data-driven modeling of aerodynamic noise sources” in the group of Prof. Georgios Moutsanidis at Stony Brook University. The research of Prof. Georgios Moutsanidis’s group is focused on developing high-fidelity CFD and data-driven approaches for aerodynamics and aeroacoustics. The PhD project is expected to start in 2024 (but can be flexible). The successful applicant will be able to work within a vibrant and multidisciplinary aerospace team under the Department of Civil Engineering at Stony Brook University and also have opportunities to engage with researchers at other national and international leading academic institutions, and industries, such as Rolls-Royce and Airbus, via established collaboration. Project details: Noise pollution is a growing environmental issue and has become the second-largest environmental cause of health problems in the US, just after air pollution. As the volume of air traffic keeps growing, aviation noise becomes of great concern to society. Thus, noise is now an important factor in certificating newly developed civil aircraft as well as future urban unmanned air vehicles (UAV). Aviation noise is primarily generated by unsteady turbulent flows. Most of the current technologies are to absorb noise rather than reduce it at the source, which is inefficient. One example of reducing noise at the source is to serrate jet nozzle or airfoil leading/trailing edges. The serrated edge can reduce noise emissions. However, the design is largely trial-and-error and heavily depends on expensive rig testing, because the mechanisms of turbulence noise generation are not fully clear yet. In this project, we will employ high-fidelity CFD to provide full details of noise generation processes in unsteady turbulent flows. The data-driven method will be developed to explore noise-generation dynamics and inform low-order modeling, which will eventually lead to optimal control of reducing noise emissions. The application will be initially focused on jet noise, but the method to be developed in the project is general, so it can be used to tackle a broad range of aero-acoustic problems. Please contact Prof. Georgios Moutsanidis (Georgios.Moutsanidis@stonybrook.edu) for an informal query about this studentship. Requirements: The candidate will have an Undergraduate or Master’s degree (or equivalent) in Mechanical Engineering, Aerospace Engineering, Mathematics, Physics, Computer Science, or a related discipline. You would be highly motivated, and able to work independently as well as collaborate with others with effective written/oral communication skills. Knowledge of fluid mechanics or CFD is essential. Experience in programming (Fortran/C++/Python) would be an advantage. How to apply: Please email Prof. Georgios Moutsanidis at Georgios.Moutsanidis@stonybrook.edu with the subject line "Ph.D. Application", including a brief cover letter, your CV, and unofficial transcripts in a single PDF file. I receive a large amount of applications and please only use the above subject line in your email. Otherwise, I will not be able to locate your email and review your application. |
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Contact Information: | |
Please mention the CFD Jobs Database, record #19123 when responding to this ad. | |
Name | Georgios Moutsanidis |
Georgios.Moutsanidis@stonybrook.edu | |
Email Application | Yes |
Phone | (631) 632-2606 |
URL | https://www.stonybrook.edu/commcms/civileng/people/_core_faculty/moutsanidis |
Address | Address 2433 Computer Science Department of Civil Engineering Stony Brook University Stony Brook, NY 11794-4424 |
Record Data: | |
Last Modified | 15:26:52, Friday, April 26, 2024 |
Job Record #19116 | |
Title | Phd position |
Category | PhD Studentship |
Employer | Portland State University |
Location | United States, OR, Portland |
International | Yes, international applications are welcome |
Closure Date | Saturday, February 01, 2025 |
Description: | |
https://www.dropbox.com/scl/fi/imzx3ouus3zo6yq53xxiq/PSU_PhD_Apr2024.pdf? rlkey=vonzy5lf05hjfor0avcprc1aw&st=1ivyvxos&dl=0 Fall 2024/Spring 2025 Computational Fluid Dynamics (CFD) Ph.D. Position at Portland State University (Published: April 2024) Professor:Dr. Xiaowei Zhu Email:xz3@pdx.edu Website:https://www.pdx.edu/profile/xiaowei-luke-zhu About Portland State University (PSU): Established in 1946, Portland State University (PSU) is a beacon of educational excellence in Portland, Oregon, USA. As the largest and most culturally diverse institution in the Oregon university system, PSU is uniquely situated in an urban center, offering a rich, vibrant academic experience. Currently, the university boasts a dynamic student body of approximately 27,000, including over 2,000 international students. In the prestigious 2020-2021 QS World University Rankings, PSU is ranked 110th in the United States, reflecting its commitment to academic excellence and innovation. About Portland, Oregon: Known as the "City of Roses," Portland is the most populous city in Oregon and the 19th most populous metropolitan area in the United States. It is the second largest city in the Pacific Northwest, following Seattle. Renowned for its pleasant climate and high per capita income, Portland has consistently been rated as one of the most livable cities in the United States. Faculty Profile - Dr. Zhu: Dr. Zhu, an esteemed assistant professor in the Department of Mechanical and Materials Engineering at PSU, boasts an impressive academic background. With a bachelor's degree from Xi'an Jiaotong University, a master's from Chongqing University, and a PhD from the University of Texas at Dallas, Dr. Zhu has also completed postdoctoral research at Johns Hopkins University and Princeton University. His research primarily focuses on computational fluid dynamics, particularly in turbulence modeling, urban turbulence, and wind energy. Dr. Zhu has made significant contributions to his field, with publications in leading journals such as the Journal of Fluid Mechanics and Physical Review Fluids. PhD Recruitment - Research on Urban Environmental Turbulence: We are excited to announce the recruitment of a PhD candidate to explore the application of turbulence in urban environments. This includes atmospheric turbulence, heat islands, and pollutant diffusion. The Urban Environment Lab at PSU utilizes advanced numerical simulations to tackle the complexities of modern urban environments. Our research delves into fluid dynamics, heat transfer, and air pollution within cities, aiming to enhance our understanding of human- environment interactions and contribute to the development of sustainable urban designs. Admissions Requirements: *Has a master degree; *Ideal candidates should possess a passion for scientific research, a strong drive, and enthusiasm for problem-solving. We welcome applicants from related science and engineering fields, particularly those with a background in mechanical engineering, physics, thermal energy/fluids, atmospheric sciences, or environmental studies. *Priority will be given to candidates with expertise in fluid mechanics, heat transfer, and programming. *Interested individuals should submit a cover letter, personal CV, and transcript to our email address. Recruitment Period: Enrollment is open for Fall 2024 and Spring 2025. We offer a comprehensive scholarship package, including tuition assistance and a living stipend. |
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Contact Information: | |
Please mention the CFD Jobs Database, record #19116 when responding to this ad. | |
Name | Xiaowei Luke Zhu |
xz3@pdx.edu | |
Email Application | Yes |
URL | https://www.dropbox.com/scl/fi/imzx3ouus3zo6yq53xxiq/PSU_PhD_Apr2024.pdf?rlkey=vonzy5lf05hjfor0avcprc1aw&st=1ivyvxos&dl=0 |
Address | xz3@pdx.edu |
Record Data: | |
Last Modified | 03:14:03, Friday, April 26, 2024 |
Job Record #19024 | |
Title | Postdoc or PhD in ROM coupled to OPENFOAM |
Category | Job in Academia |
Employer | BTU Cottbus Senftenberg |
Location | Germany, Brandenburg, Cottbus |
International | Yes, international applications are welcome |
Closure Date | Sunday, April 21, 2024 |
Description: | |
The Scientific Computing Lab (SCL) at BTU Cottbus-Senftenberg has open positions for a Postdoc, Ph.D. and/or M.Sc. in coupling reduced order models (ROM) and/or stochastic turbulence models to OpenFoam type open source tool boxes to investigate energy related problems. This project is a part of ongoing activities within the newly-created SCL which is part of the Energy Innovation Center (EIZ) at BTU. The project focuses on developing and coupling advanced numerical low order approaches in a model adaptive way to OpenFoam or similar CFD tool boxes. The main responsibilities will lie in: - coupling different ROMs to OpenFoam - validation against DNS or experiments The potential candidates should have: - a strong background in fluid mechanics and CFD (DNS or LEs preferred) - experience with Linux and strong hands-on experience with computing in at least one programming language (e.g. C/C++, Python, ...) - experience in developing numerical models, codes, and computational algorithms - familiarity with OpenFoam The position is available from now on (the actual starting date can be negotiated). Please send the following documents only via email to heischmi@protonmail.com using the subject "SCL_ROM": - Recent CV - Relevant Transcripts - Two-page cover letter including a motivation Please ensure you submit all required documents. Only qualified candidates might be contacted for an online-interview. |
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Contact Information: | |
Please mention the CFD Jobs Database, record #19024 when responding to this ad. | |
Name | Heiko Schmidt |
heischmi@protonmail.com | |
Email Application | Yes |
Record Data: | |
Last Modified | 23:53:27, Thursday, April 25, 2024 |
Job Record #19023 | |
Title | Postdoc/PhD/Master in lower order wind energy modeling |
Category | Job in Academia |
Employer | BTU Cottbus Senftenberg |
Location | Germany, Brandenburg, Cottbus |
International | Yes, international applications are welcome |
Closure Date | Sunday, April 21, 2024 |
Description: | |
The Scientific Computing Lab (SCL) at BTU Cottbus-Senftenberg has open positions for a Postdoc, Ph.D. and/or M.Sc. in Numerical Modeling of Wind Farms. This project is a part of ongoing activities within the newly-created SCL which is part of the Energy Innovation Center (EIZ). The project focuses on developing and coupling advanced numerical tools for integral wind farm modeling in complex environmental terrains and under realistic atmospheric conditions. During this process, fundamental questions related to the incoming wind field, wake-structure interaction, wake mitigation strategies and wake control, influence of the atmospheric stability and roughness effects, will be explored. During the project the application of stochastic models, ROM and physics-informed NN will play a key role. The main responsibilities will lie in: - coupling different modules of the code to perform an integral simulation of the wind park in complex terrain interacting with stratified flows - validation - incorporation of control strategies - coupling weather models - comparison to field data The potential candidates should have: - a strong background in fluid mechanics and CFD (DNS, LES preferred) - experience with Linux and strong hands-on experience with computing in C/C++ or Python - experience in developing numerical models, codes, and computation algorithms - experience with CFD using FEM and/or FVM - familiarity with OPENFAST or QBlade The position is available from now on. Please send the following documents only via email to heischmi@protonmail.com using "SCL": - Recent CV - Relevant Transcripts - Two-page cover letter including a motivation Please ensure you submit all required documents. Only qualified candidates might be contacted for an online-interview. |
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Contact Information: | |
Please mention the CFD Jobs Database, record #19023 when responding to this ad. | |
Name | H. Schmidt |
heischmi@zedat.fu-berlin.de | |
Email Application | Yes |
URL | https://www.researchgate.net/profile/Heiko-Schmidt-2 |
Record Data: | |
Last Modified | 22:22:53, Thursday, April 25, 2024 |
Job Record #19122 | |
Title | Senior Software Engineer (LBM Solver Development) |
Category | Job in Industry |
Employer | Tridiagonal Software Incorporated |
Location | United States, Texas, San Antonio |
International | Yes, international applications are welcome |
Closure Date | * None * |
Description: | |
Position: Sr. Software Engineer (LBM Solver Development) - Reports To: Solver Development Manager Tridiagonal Software is a leading Software OEM developing and licensing highly automated Engineering Analysis tools powered by CFD as well as Knowledge Management Software tools to the global chemicals and pharmaceutical industry. Our flagship products MixIT and SimSight are licensed by some of the World’s largest corporations based in US and Europe. (https://mixing-solution.com/) and (https://simsight.tridiagonalsoftware.com/) We are on a fast-track growth mode and are looking for young, dynamic people to join this exciting journey with us to contribute to their own and company’s growth. We provide an accelerated career growth path to individuals with tremendous opportunity to learn, execute and excel. Essential Duties and Responsibilities: ● LBM solver development for software products and services o Development and maintenance of solver o Adding new physics model to existing solvers o Development of solution strategy for customer specific problems ● Work on file writing, GUI development for solver ● Work with development team, product management and QA • Participate in internal and customer meetings Key Competencies: ● Willingness to be part of software development team, developing the next generation solutions for manufacturing & chemical industry using the latest technologies • Good understanding of basic fluid dynamics and heat transfer o Exposure to reaction modelling, multiphase modelling or compressible flows will be an added advantage • Formal course work and good understanding of numerical methods and computational fluid dynamics (CFD) is a critical requirement • Experience/project work in LBM solver development required • Proficiency in any one of programming language like C, C++ or Fortran etc. (C++ is preferred) • Good verbal and written communication skills • Strong Presentation Skills Knowledge • Willing to learn new tools and technologies • Should be a self-starter, quick learner with sense of project ownership Education & Experience: • Ph.D. / M. E. / MTech in Mechanical / Chemical/ Aerospace/ Thermal Engineering having keen interest in Solver development with 0 to 3 years of experience. • Master’s or Ph.D. project in CFD solver development preferred. Location: San Antonio, Texas or Pune, India or Remote if not a resident of US or India Remuneration: • Compensation as per industry standards. • Benefits would be detailed in the final offer. Contact Details: Christina Castillo – christina.castillo@tridiagonal.com |
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Contact Information: | |
Please mention the CFD Jobs Database, record #19122 when responding to this ad. | |
Name | Christina Castillo |
christina.castillo@tridiagonal.com | |
Email Application | Yes |
Phone | 2104878343 |
Address | 8632 Fredericksburg Road, Suite 101 San Antonio, Texas 78240 |
Record Data: | |
Last Modified | 22:04:30, Thursday, April 25, 2024 |
Job Record #19121 | |
Title | Influence of Boundary Layers on the Measurement of IDT |
Category | PhD Studentship |
Employer | Laboratoire DRIVE - Université de Bourgogne |
Location | France, Nevers |
International | Yes, international applications are welcome |
Closure Date | Saturday, May 25, 2024 |
Description: | |
Thesis Title: Influence of Boundary Layers on the Measurement of Auto-Ignition Delays in High- Pressure Shock Tubes – Application to the Kinetics of Biomass-Derived Fuels – Simulation and Experimentation Host Laboratory: Laboratoire DRIVE 49 rue Mademoiselle Bourgeois 58000 Nevers – France Specialization of the Doctorate : Energetics Keywords: Shock tube, auto-ignition delay, biomass, boundary layers, CFD, kinetics Detailed Description of the Thesis: The depletion of fossil fuels and climate change, partly caused by emissions from their combustion, represent major societal challenges. Alternative fuels derived from bioresources (biofuels, hydrogen, ammonia) appear as promising solutions to overcome these challenges, particularly in the transportation sector, especially for heavy-duty vehicles and energy processes. Although the combustion of certain alternative fuels at high temperatures and low pressures has been extensively studied in the literature using fundamental reactors such as laminar flames and perfectly stirred reactors [1-2], research is limited under high temperature and high pressure conditions similar to those operating in thermal reactors such as internal combustion engines, gas turbines, and turbojets (400-2000K, 1-100Bar) [3]. The shock tube is one of the fundamental reactors that allows the study of the combustion of alternative fuels under such conditions by measuring auto-ignition delays [4], profiling intermediate species [5], and validating kinetic models to understand the degradation of these fuels [6]. One of our recent studies [7] showed that the auto-ignition delay measured in the shock tube can be affected by boundary layers [8] under certain conditions and impact the prediction of kinetic models. From this observation, the thesis objective will be to characterize the impact of boundary layers on the auto-ignition delay measurements in the DRIVE laboratory's shock tube. This characterization will then allow to more precisely investigate the combustion kinetics of biomass-derived compounds under high pressure condition. The work will be carried out in four stages: 1. A comprehensive literature review will be conducted, relying on databases such as Web of Sciences, to examine previous work on laboratory experiments and both CFD (Computational Fluid Dynamics) and kinetic modeling. 2. CFD modeling will be performed using Ansys Fluent software to evaluate the impact of boundary layers on the auto-ignition delay in the DRIVE shock tube. 3. A series of experiments will be conducted at the DRIVE laboratory to measure the auto-ignition delay of a bio-fuel/O2/Ar mixture in a shock tube at high pressure (20-40Bar) and high temperature (900-1600K). 4. Based on the data obtained, kinetic modeling will be carried out using Ansys Chemkin-Pro, integrating the results of CFD modeling to deepen the understanding of the oxidation kinetics of biofuel. Bibliographic References [1] L.-S. Tran, P.-A. Glaude, R. Fournet, F. Battin-Leclerc, Experimental and Modeling Study of Premixed Laminar Flames of Ethanol and Methane, Energy Fuels 27 (2013) 2226–2245. [2] P. Dagaut, C. Togbé, Experimental and Modeling Study of the Kinetics of Oxidation of Ethanol−Gasoline Surrogate Mixtures (E85 Surrogate) in a Jet- Stirred Reactor, Energy Fuels 22 (2008) 3499–3505. [3] L.-S. Tran, O. Herbinet, H.-H. Carstensen, F. Battin-Leclerc, Chemical kinetics of cyclic ethers in combustion, Progress in Energy and Combustion Science 92 (2022) 101019. [4] Y. Uygun, S. Ishihara, H. Olivier, A high pressure ignition delay time study of 2-methylfuran and tetrahydrofuran in shock tubes, Combustion and Flame 161 (2014) 2519–2530. [5] A. Hamadi, L. Piton Carneiro, F.-E. Cano Ardila, S. Abid, N. Chaumeix, A. Comandini, Probing PAH Formation from Heptane Pyrolysis in a Single-Pulse Shock Tube, Combustion Science and Technology 195 (2023) 1526–1542. [6] Y. Zhang, H. El-Merhubi, B. Lefort, L. Le Moyne, H.J. Curran, A. Kéromnès, Probing the low-temperature chemistry of ethanol via the addition of dimethyl ether, Combustion and Flame 190 (2018) 74–86. [7] H.-Q. Do, B. Lefort, Z. Serinyel, L. LeMoyne, G. Dayma, Comparative study of the high-temperature auto-ignition of cyclopentane and tetrahydrofuran, International Journal of Chemical Kinetics 56 (2024) 199–209. [8] D. Nativel, S.P. Cooper, T. Lipkowicz, M. Fikri, E.L. Petersen, C. Schulz, Impact of shock-tube facility-dependent effects on incident- and reflected-shock conditions over a wide range of pressures and Mach numbers, Combustion and Flame 217 (2020) 200–211. Requested Profile: • Engineer/Master's in process engineering or fluid mechanics/energy with possible knowledge in chemical kinetics. • Fluent in English, ability to work in a team • Send CV, cover letter, letters of recommendation from supervisors, transcripts from the first and second year of Master's degree or last two years of engineering degree to the supervisors and thesis director. Funding: MESRI Establishment Application to be sent before May 25, 2024 (Interview at the end of May, beginning of June) Start of contract: October 1, 2024 Gross monthly salary: €1975 Thesis Direction: Benoîte Lefort, Full Professor Benoite.Lefort@u-bourgogne.fr Thesis Supervision: Co-Supervisors: Julien Jouanguy, Associate professor Julien.Jouanguy@u-bourgogne.fr Hong-Quan Do, Associate professor Hong-Quan.Do@u-bourgogne.fr |
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Contact Information: | |
Please mention the CFD Jobs Database, record #19121 when responding to this ad. | |
Name | Hong Quan Do |
Hong-Quan.Do@u-bourgogne.fr | |
Email Application | Yes |
URL | https://drive.u-bourgogne.fr/ |
Record Data: | |
Last Modified | 14:39:45, Thursday, April 25, 2024 |
Job Record #19120 | |
Title | Machine learning for formulation of wall laws in CFD |
Category | PhD Studentship |
Employer | IFPEN |
Location | France, Rueil-Malmaison |
International | Yes, international applications are welcome |
Closure Date | Sunday, December 01, 2024 |
Description: | |
The use of Artificial Intelligence in Computational Fluid Dynamics (CFD) is very promising to propose new physical models. Few studies have been done so far on the modeling of wall flows, for which the available physical models are facing great difficulties to be applicable and predictive. A recent PhD thesis at IFPEN has shown the ability of a neural network trained on high-fidelity wall-resolved data to reproduce the physics of a turbulent non-equilibrium boundary layer, accurately inferring wall friction from flow variables at a distance corresponding to the wall resolution of typical RANS coarse meshes. The present thesis aims at continuing this work to include the prediction of wall heat flux, a key element for many application areas at IFPEN involving thermal and cooling aspects. In particular, the objective is to formulate analytical thermal wall laws through the development of an adapted Gene Expression Programming (GEP) method. This symbolic regression approach allows to form interpretable analytical models, more regular and more robust than methods based on neural networks. This new approach will also have the advantage of being more easily implemented in any type of CFD code. In a first step, the PhD student will focus on the implementation of a GEP methodology with a first validation in terms of prediction of wall shear stress on single-phase turbulent canonical flows, and the results will be compared to those obtained with neural networks. The approach will then be extended to the prediction of wall heat flux from high- fidelity test cases representative of liquid cooling of electric drive train components. |
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Contact Information: | |
Please mention the CFD Jobs Database, record #19120 when responding to this ad. | |
Name | Adele Poubeau |
adele.poubeau@ifpen.fr | |
Email Application | Yes |
URL | https://theses.ifpen.fr/en/thesis/development-symbolic-regression-method-formulation-wall-laws-cfd |
Record Data: | |
Last Modified | 08:32:39, Thursday, April 25, 2024 |
Job Record #19119 | |
Title | CFD Developer |
Category | Job in Industry |
Employer | Innovative Numerix |
Location | Canada, Alberta, Calgary |
International | Yes, international applications are welcome |
Closure Date | Wednesday, May 22, 2024 |
Description: | |
CFD DeveloperRole DescriptionThis is a full-time remote role for a Computational Fluid Dynamics (CFD) Developer.The CFD Developer will develop, implement, and maintain numerical algorithms and software for simulating fluid dynamics and heat transfer. They will work with cross- functional teams to evaluate performance, troubleshoot issues, and develop innovative CFD solutions for flow in the porous media. Qualifications
What we offer
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Contact Information: | |
Please mention the CFD Jobs Database, record #19119 when responding to this ad. | |
Name | Carolina Diaz-Goano |
jobs@inumerix.com | |
Email Application | Yes |
URL | https://inumerix.com/ |
Address | 1 Cedar Springs Gardens SW Calgary, AB T2W5J9 Canada |
Record Data: | |
Last Modified | 20:39:20, Tuesday, April 23, 2024 |