M.Sc. Neda Kazemi

Research Associate

M.Sc. Neda Kazemi

Institute of Process Engineering
Chair of Thermal Process Engineering
Universitätsplatz 2, 39106 Magdeburg, G10-243
Vita

Born 1990 in Shiraz, Iran

Education

Since April 2022

M.Sc. Chemical and Energy Engineering, Otto-von-Guericke-University Magdeburg, Germany

January 2014 - January 2016

M.Sc. Chemical Engineering, Shiraz University, Shiraz, Iran

Master thesis: Thermodynamic optimization of organic Rankin cycle for energy production from geothermal resources

October 2009 - June 2013

B.Sc. Chemical Engineering (Gas, Oil, and Petrochemical), Fars University of Science and Research, Fars, Iran

Bachelor thesis: Modifying Hansen Won and thermodynamic model for more accurate prediction of wax deposit formation

Experience

Since August 2024

Research Associate, Chair of Thermal Process Engineering, Otto-von-Guericke-University Magdeburg, Germany

October 2023 - January 2024

Project management and personal productivity training for researchers, Magdeburg, Germany

September 2021 - July 2022

University lecturer at shiraz university of applied science and technology.

January 2021 - March 2022

HSE plan training, Petrochemical Industries Erection Construction Company, Shiraz, Iran.

Research Topics

Contact heat transfer and heat conduction in packed beds of edged particles

A central parameter of thermal DEM is the particle-particle heat transfer coefficient during binary contacts. Contact heat transfer is always important when heat is transmitted between particles of the bed in order to conduct thermochemical processes, but in presence of steep temperature profiles, it can also be significant when heat is supplied from the gas phase. Despite of its central role, simplified models, the validity of which is questionable even in the case of equally sized spheres, are used to calculate contact heat transfer. Despite many practical applications, any reliable background is missing in the case of edged, polyhedral particles.

Particle-particle heat transfer coefficients, αpp, that can be used in DEM (or DEM/CFD) for static, moving, or mechanically agitated particle systems, can be derived from the effective thermal conductivity of respective packed beds, λbed, but the pre-factor of the linear relationship between those two quantities needs to be tuned. In this research, it is needed to use measured or simulated λbed data in order to expand a standard model for λbed to applicability with arbitrarily non-spherical particles, and then apply relationships that connect λbed with αpp on theoretical grounds in order to calculate values of αpp for use in thermal DEM. This will be done in two stages. First, for beds of monodisperse particles of different shapes; Second, for binary mixtures of particles that differ in shape, size, or material. In both cases, the results of thermal equilibration experiments will be used which will be conducted in a rotary drum. Mixing initially segregated fractions of hot and cold particles would ideally unveil the kinetics of interparticle heat transfer. Moreover, DEM simulations of the simultaneous mechanical and thermal mixing of particles in the drum are also necessary for this envisaged approach. The main goal of the research is based on the overarching idea of transcription from λbed, reliable rules for the computation of αpp for both homo-contacts between same as well as hetero-contacts between different particles.

This research is part of Collaborative Research Center/Transregios 287 "Bulk-Reaction." More information on the whole collaborative project can be found on site: https://bulk-reaction.de/.

Publications

2020

  • Samadi, F., & Kazemi, N. (2020). Exergoeconomic analysis of zeotropic mixture on the new proposed organic Rankine cycle for energy production from geothermal resources. Renewable Energy, 152, 1250–1265. https://doi.org/10.1016/j.renene.2020.01.038

2016

  • Karimi, S., Kazemi, S., & Kazemi, N. (2016). Syneresis measurement of the HPAM-Cr (III) gel polymer at different conditions: An experimental investigation. Journal of Natural Gas Science and Engineering, 34, 1027–1033. https://doi.org/10.1016/j.jngse.2016.08.011

  • Kazemi, N., & Samadi, F. (2016). Thermodynamic, economic and thermo-economic optimization of a new proposed organic Rankine cycle for energy production from geothermal resources. Energy Conversion and Management, 121, 391–401. https://doi.org/10.1016/j.enconman.2016.05.046

Confereces

  • Predicting the Refractive Index in Binary Systems of Ionic Liquids and Alcohol binary, 26th Regional Symposium of Chemical Engineering, Kuala Lumpur, Malaysia, October 2019.
  • Investigation into effect of different anionic surfactants on hydrate formation velocity and its storage capacity, The Third National Conference on Oil, Gas and Petrochemicals, Iran, Gachsaran, 2014.
  • Modifying Hansen Won and thermodynamic model for more accurate prediction of wax deposit formation, The Third National Conference on Oil, Gas and Petrochemicals, Iran, Gachsaran, 2014.

Letzte Änderung: 06.10.2024 - Ansprechpartner: Webmaster