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Job ID: 186609

PhD position: Experimental Assessment of Supersonic Jet Dispersion
von Karman Institute for Fluid Dynamics


Date Posted Jun. 1, 2022
Title PhD position: Experimental Assessment of Supersonic Jet Dispersion
University von Karman Institute for Fluid Dynamics
Rhode Saint Genèse, Belgium
Department Environmental and Applied Fluid Dynamics
Application Deadline Jun. 30, 2022
Position Start Date Available Immediately
 
 
  • Graduate Student
  • Engineering Mechanics
    Mechanical Engineering
 
 

Careers at the von Karman Institute: Construct the future together!

 

For 65 years as international center of excellence in fluid dynamics, the von Karman Institute brings together young engineers and scientists from all over the world to study, improve their skills and perform their research.

Construct the future together! Besides its mission of education, the von Karman Institute gathers the top-level scientists and engineers to work on very challenging projects as the next generation of engines, new propulsion concepts, the new green energy, the safety of industry, solutions for a cleaner space, the Mission to Mars and many other fields of research which can make the difference for the human kind. Those scientists have access to more than 50 wind tunnels and test rigs, some of them unique in the world to help them in their projects.

VKI is a team of people looking in the same direction, for a better future, not only scientists and engineers but also students, PhD candidates, PostDocs, IT, Human Resources, accountants, librarians, designers and technicians and more....

 

“A scientist studies what is, whereas an engineer creates what never was“, Théodore von Kármán

 

Duration of the postdoc: 4 years

Deadline: 15 June 2022

 

About the Research Topic

Industrial risks management is of primary importance in chemical plants. In particular, gas leakage coming from an explosion in a pressurized reservoir is highly concerning. The ejection of the pollutants at high velocity in the atmosphere would lead to a supersonic jet.

While literature on supersonic jets can be found, the effect of the atmospheric wind conditions on such dispersion is still unclear. The SHADE project (Supersonic Hot Atmospheric DispErsion) enters in the collaboration with the CEA Gramat research center. It aims to continue research efforts to characterize the supersonic jet dispersion under atmospheric wind conditions. During the project, an extensive experimental dataset will have to be provided and confronted with numerical simulations from the CEA. Optical measurement techniques will need to be developed and validated to measure the velocity and the concentration fields of the dispersion. To improve the understanding of the dispersion, measurements need to be conducted in the near field and far from the release point, in the self-similar region. The other main key challenge of the PhD will be to adapt the experimental setup and measurement techniques for a high temperature jet. In addition to the experimental technique’s development, the research project envisions to test the supersonic jet as submitted to an atmospheric boundary layer provided by a wind tunnel and to study unsteady effects of the jet.

The project can be divided into five main work packages. First, an extensive bibliographical review will have to be conducted on the supersonic jet dispersion and experimental methods to characterize such a flow. During this phase, the candidate will be guided by the expertise of VKI and will be taught advanced measurement techniques regularly used at the institute. The second work package consists in developing new experimental methods to characterize the dispersion. LS-PIV (Large Scale Particle Image Velocimetry) has been successfully applied to measure the velocity field. For the concentration, a technique based on the Mie Scattering was adapted and allowed to measure a concentration field, as observed in the image above, but a proper reference is needed as this technique provides the concentration field as compared to a reference value. Therefore, the idea is to use another technique, such as the Light Extinction spectroscopy, to give an absolute value of the reference concentration.

The third work package involves designing a new experimental setup to simulate the supersonic jet. The work will be conducted in tight collaboration with the drawing office and the technical team of the von Karman Institute. The measurements will be performed in the VKI Wind Engineering facility L-1B. The 2 m high, 3m wide, and 20 m long wind tunnel is used to simulate a wind condition similar in nature to the lower part of the atmospheric neutral boundary layer with a roughened floor allowing the growth of a turbulent layer. Special care is taken in the proper simulation of turbulence parameters, namely intensity of fluctuation and power spectra. Optimal similarity conditions are obtained in the scale range 1/250 to 1/350. Flow velocity can be varied between 2 and 50 m/s making it one of the most powerful facilities of this type as far as Reynolds simulation is concerned.

The fourth WP will be the experimental campaigns. The first experimental campaigns will focus only on the dispersion (concentration and velocity fields) for selected wind and jet conditions. Therefore, the effect of temperature will be investigated by heating the jet up to 300 Celcius before the release. The main challenge of the project comes from the large scale of the dispersion, the high temperature, and the unsteady behavior of the release. Results will be analyzed and compared with numerical simulations. Finally, the last work package consists of the dissemination of the results. Regular meetings with the CEA will be conducted to discuss the results. Conclusions will be drawn and published via peer-reviewed papers and international conferences to bring new insight into the supersonic release in the atmosphere.

 

Requirements

- Master’s in mechanical engineering with specialization in fluid dynamics

- Enthusiasm for experimental research and experimental techniques development

- Open mindset and willingness to learn

- Basic knowledge of Particle Image Velocimetry is a plus

- Basic knowledge in image processing and elementary laboratory experience in measurement techniques for fluid dynamics is another plus

 

The candidates are expected to:

- have a very good knowledge of English (spoken and written); Basic knowledge of French is a plus;

- work effectively in an international multi-cultural working environment that emphasizes on collaboration;

- be able to work accurately, methodically, and take initiatives;

- should be willing to present research findings at national and international conferences and publish in international journals.

 

Benefits

- Employed by the von Karman Institute for Fluid Dynamics in one of the most attractive areas of central Europe in the neighborhood of Brussels;

- Work at the internationally renowned von Karman Institute in a key role advancing technologies for future energy systems;

- Work in close collaboration with Belgian universities as well as an industrial network;

- Become part of the VKI network with global access to industry experts and academics in the field of fluid dynamics, aerospace, propulsion, and energy conversion;

- Experience the unique international workshop character of the VKI working environment;

- Access to specialized seminars and lecture series and to world-unique facilities.


  • VKI does strictly adhere to the ethical standards of the European Charter for Researchers and Code of Conduct for the Recruitment of Researchers ( https://euraxess.ec.europa.eu/jobs/charter).


    A strict equal opportunity, gender-neutral and internationally comparable recruitment procedure is implemented.

    Please refer to the general eligibility criteria for all VKI students and employees.


 
Please reference AcademicKeys.com in your cover letter when
applying for or inquiring about this job announcement.
 
 

Contact Information

 
  • Prof. Delphine Laboureur
    Environmental and Applied Fluid Dynamics
    Von Karman Institute for Fluid Dynamics
    Chaussée De Waterloo 72
    Rhode Saint Genèse
    Belgium
  •  
  • + 32 2 359 96 29
  • delphine.laboureur@vki.ac.be

 

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