Oxygen Production Technologies for Oxy

Authors

  • H. Katalambula University of Dar es Salaam

DOI:

https://doi.org/10.52339/tjet.v32i1.440

Abstract

Carbon dioxide, a dominating contributor to global warming is emitted to the atmosphere from power plants
during combustion of coal. Oxy-fuel combustion is a new technology leading to a simplified sequestration
of CO2. In this technology, fossil fuel is combusted with oxygen (instead of air) in such a way that the flue
gas primarily consists of CO2, which can then be sequestered without significant processing. Part of the flue
gas is used to dilute the oxygen in order to maintain the temperatures in the combustion process. The main
energy penalty in oxy-fuel combustion is the cost of oxygen production. There are three major processes for
air separation to produce oxygen, these are: cryogenic distillation, membrane separation and gas adsorption.
Cryogenic distillation is well established process for large scale production but high energy consumption is
the main disadvantage of this process. Membrane and adsorption processes are common for small and medium
scale production. In gas adsorption, there are air separation techniques such as pressure and temperature
swing methods. The production of oxygen with 90-95% purity and 5000+tpd production is the main challenge
for this technology. At present the technology that can supply oxygen in large quantity is the cryogenic
separation of oxygen from air. The papers aims at presenting a comprehensive review of the air separation
technologies and identify areas that need attention so that oxy-firing can be achieved. The paper therefore
looks at different technologies used for oxygen production, economic concepts as well as integration issues in
the existing plants.

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Author Biography

H. Katalambula, University of Dar es Salaam

Department of mechamical and industrial Engineering

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Published

2009-06-30

How to Cite

Katalambula, H. (2009). Oxygen Production Technologies for Oxy. Tanzania Journal of Engineering and Technology, 32(1), 127-138. https://doi.org/10.52339/tjet.v32i1.440
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