Geometry optimization through flow simulation and module design
Background and Motivation:
The development of sustainable Direct Air Capture technologies is critical to solve the global warming
problem as the increasing the amount of emitted carbon dioxide in the atmosphere is one of the main
factors for more than half of the global warming variance. Therefore, it became the main target of GHG
capture research recently. Thus, fast mitigation of greenhouse gases emissions has been one of the most
urgent scientific problems in the global arena over the last decades. To this end, capturing carbon
dioxide not only from the point source is important but also the trapped one in the atmosphere is quite
urgent and necessary. Direct air capture (DAC) is a carbon dioxide removal technology which separates
CO2 directly from the air using an engineered system. As it is known, the concentration of CO2 in air is
ultra-diluted which makes this technology be challenging especially in presence of high concentrations
of dioxygen and water in air.
My project in IMVT is focused on DAC technology through designing and preparing the module based on
Electro-Swing Adsorption method. So the test rig was set up in order to evaluate the module
In order to optimize the geometry of module, simulation should be performed by using related
software. Effect of module’s design on the module’s efficiency is planned to be studied.
This position is aimed at students from the faculties of chemical engineering - KIT.
1. based on the experimental data, flow simulation is desired to perform the modules geometry
2. using Multiphysics simulation to study the performance module in operation and compare
the result with the experimental data resulting from optimized module.
- Students of chemical engineering / process engineering.
- Language: German or Language
Start: by arrangement
Supervisor: Mohanna Hosseini
Email: ( Seyedehfatemeh.email@example.com)
Phone: +49 721 608-26754