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Master thesis (2021)

Authors

B.M. de Jong Mechanical Engineering

Contributors

R.L.J. Helmons Offshore and Dredging Engineering - Mechanical, Maritime and Materials Engineering (supervisor 1)
Faculty
Mechanical Engineering
Copyright: © 2021 bart de Jong
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Published Date

19-07-2021

Language

English

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Faculty

Mechanical Engineering

Abstract

Growing populations, high-technology applications and the energy transition raise the demand for rare earth elements. As a secure supply in the future is all but certain, opportunities arise for deep-sea mining. Polymetallic nodules
that are located on the vast, sediment-covered ocean floors, are one of the more promising deep-sea mineral occurrences. Large amounts of unwanted surrounding water and sediment are collected along with the nodules in the
harvesting process. Separating the sediment and excessive water from the nodules before transportation toward the surface could mitigate sediment plumes and be beneficial for energy consumption. In this research, the feasibility of a hydrocyclone inspired machine is investigated for this process. With model experimentation, the key performance parameters are studied using varying particle fractions, adjusting split ratio and conical angle. Timescale ratios are
used for particle scaling, and to describe their behaviour. The cyclones’ separation shows great potential. However, large particles can be problematic, and the energy consumption is too high for deep-sea operation. Therefore, topside utilisation is recommended.


Keywords: Polymetallic nodules, separation, hydrocylone, performance parameters, topside.