Abstract
In this study the methodology of life cycle assessment has been used to assess the environmental impacts of three pulverized coal fired electricity supply chains with and without carbon capture and storage (CCS) on a cradle to grave basis. The chain with CCS comprises post-combustion CO 2 capture with monoethanolamine, compression, transport by pipeline and storage in a geological reservoir. The two reference chains represent sub-critical and state-of-the-art ultra supercritical pulverized coal fired electricity generation. For the three chains we have constructed a detailed greenhouse gas (GHG) balance, and disclosed environmental trade-offs and co-benefits due to CO 2 capture, transport and storage. Results show that, due to CCS, the GHG emissions per kWh are reduced substantially to 243 g/kWh. This is a reduction of 78 and 71% compared to the sub-critical and state-of-the-art power plant, respectively. The removal of CO 2 is partially offset by increased GHG emissions in up- and downstream processes, to a small extent (0.7 g/kWh) caused by the CCS infrastructure. An environmental co-benefit is expected following from the deeper reduction of hydrogen fluoride and hydrogen chloride emissions. Most notable environmental trade-offs are the increase in human toxicity, ozone layer depletion and fresh water ecotoxicity potential for which the CCS chain is outperformed by both other chains. The state-of-the-art power plant without CCS also shows a better score for the eutrophication, acidification and photochemical oxidation potential despite the deeper reduction of SO x and NO x in the CCS power plant. These reductions are offset by increased emissions in the life cycle due to the energy penalty and a factor five increase in NH 3 emissions.
Highlights
Worldwide emissions of greenhouse gasses (GHG’s) due to human activities are increasing and with it the concentration of GHG’s in the atmosphere, resulting in climatic change
Over the full life cycle case 3 shows to have the highest level of coal and other resource consumption, waste formation and the lowest atmospheric emissions of CO2, hydrogen fluoride (HF) and hydrogen chloride (HCl)
The results show that potential impacts in the categories marine aquatic ecotoxicity, abiotic depletion, global warming and acidification are of more relative importance compared to the remaining impact categories human toxicity, fresh water aquatic ecotoxicity, terrestrial ecotoxicity, photochemical oxidation potential and eutrophication
Summary
Worldwide emissions of greenhouse gasses (GHG’s) due to human activities are increasing and with it the concentration of GHG’s in the atmosphere, resulting in climatic change. The use of fossil fuels for electricity generation contributes to the greenhouse effect. It has other environmental impacts, for instance: acidification, eutrophication and the depletion of natural resources. In the IPCC1 Special Report on CO2 capture and storage it is already discussed that adding CO2 capture to a pulverized coal fired power plant will result in a reduction of net generating efficiency and will proportionally increase: emissions to air of substances not affected by the capture process, the use of resources (limestone and ammonia for respectively SOx and NOx reduction) and the formation of by-products It is to be expected that the amount and composition of direct emissions to air, water and soil will change when a coal fired power plant will be equipped with CO2 capture
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