Abstract

Carbon dioxide (CO2) emissions and their association with climate change are currently a major discussion point in government and amongst the public at large in South Africa, especially because of the country’s heavy reliance on fossil fuels for electricity production. Here we review the current situation regarding CO2 emissions in the South African power generation sector, and potential process engineering solutions to reduce these emissions. Estimates of CO2 emissions are presented, with the main sources of emissions identified and benchmarked to other countries. A promising mid-term solution for mitigation of high CO2 emissions, known as CO2 capture and storage, is reviewed. The various aspects of CO2 capture and storage technology and techniques for CO2 capture from pulverised coal power plants are discussed; these techniques include processes such as gas absorption, hydrate formation, cryogenic separation, membrane usage, sorbent usage, enzyme-based systems and metal organic frameworks. The latest power plant designs which optimise CO2 capture are also discussed and include integrated gasification combined cycle, oxy-fuel combustion, integrated gasification steam cycle and chemical looping combustion. Each CO2 capture technique and plant modification is presented in terms of the conceptual idea, the advantages and disadvantages, and the extent of development and applicability in a South African context. Lastly, CO2 transportation, storage, and potential uses are also presented. The main conclusions of this review are that gas absorption using solvents is currently most applicable for CO2 capture and that enhanced coal bed methane recovery could provide the best disposal route for CO2 emissions mitigation in South Africa.

Highlights

  • There has been a nearly 100% increase in worldwide CO2 emissions since 1971

  • The dry flue gas is moderately compressed and sent to a heat exchanger where its temperature is lowered to just above the CO2 solidification point. This temperature varies depending on the operating pressure, which depends on the flue gas conditions from the coal power plant

  • The advantage is that the process can potentially obtain 100% CO2 recovery and increase power plant output by 60% compared to conventional pulverised coal (PC) power plants.[48]

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Summary

Introduction

There has been a nearly 100% increase in worldwide CO2 emissions since 1971. This increase is of great concern to scientists, governments and the public in general as there is general consensus from the greater scientific community that CO2 – a greenhouse gas – is one of the main contributors to rapid climate change[1] experienced globally, especially in the last few decades. The dry flue gas is moderately compressed and sent to a heat exchanger where its temperature is lowered to just above the CO2 solidification point This temperature varies depending on the operating pressure, which depends on the flue gas conditions from the coal power plant. A separation process which makes use of CO2 and H2O phase behaviour, as well as molecular size and bond lengths, is hydrate formation This technique entails passing flue gas through a unit containing chilled water at optimum temperature and pressure, causing some components of the flue gas to freeze together with water molecules to form hydrates, which are ice-like crystals in which the gas molecules are trapped inside a cage of water molecules, through hydrogen bonding.

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