Abstract
The Paris agreement compels CO2 intensive industries, such as the cement industry to significantly decrease the CO2
emissions. The source of the CO2 emissions from the cement industry is related to the calcination and the combustion
process, which is why innovative measures have to be implied to reach the CO2 reduction goal. According to previous
studies, the oxyfuel technology to facilitate the carbon capture and storage technology is the most economically
feasible potential to solve the issue. In frame of the AC²OCem project, a European consortium has come together to
reduce the knowledge gap and the time to market of the oxyfuel technology in the cement industry. Experimental and
analytical work on the oxyfuel technology for retrofitting existing cement plants will be focused on optimizing the
calciner and the oxyfuel burner with 100 % alternative fuels. In addition to the experimental and analytical tests
regarding the burner technology in pilot-scale facilities, design and optimization of retrofitting existing plants is
performed, taking into consideration the boundary condition of two demonstration plants located in Slite, Sweden and
Lägerdorf, Germany. For the retrofit design, the heat integration in oxyfuel condition and the effect of false air ingress
for both plants is studied and it is found that a heat exchanger system would adequately supply the energy to the drying
unit. A realistic value for false air has been set at 6 % as an initial design parameter of the CPU. Within the scope of
the AC²OCem project, the kiln and calciner oxyfuel burners will be promoted to higher technology readiness levels
for newly-build and up-to 100 % oxygen combustion cement plants. A techno-economic analysis and life cycle
assessment for retrofitted existing and new-build cement plants will also be performed.
Keywords: Alternative fuel, CCS, Cement, Oxyfuel, SRF
emissions. The source of the CO2 emissions from the cement industry is related to the calcination and the combustion
process, which is why innovative measures have to be implied to reach the CO2 reduction goal. According to previous
studies, the oxyfuel technology to facilitate the carbon capture and storage technology is the most economically
feasible potential to solve the issue. In frame of the AC²OCem project, a European consortium has come together to
reduce the knowledge gap and the time to market of the oxyfuel technology in the cement industry. Experimental and
analytical work on the oxyfuel technology for retrofitting existing cement plants will be focused on optimizing the
calciner and the oxyfuel burner with 100 % alternative fuels. In addition to the experimental and analytical tests
regarding the burner technology in pilot-scale facilities, design and optimization of retrofitting existing plants is
performed, taking into consideration the boundary condition of two demonstration plants located in Slite, Sweden and
Lägerdorf, Germany. For the retrofit design, the heat integration in oxyfuel condition and the effect of false air ingress
for both plants is studied and it is found that a heat exchanger system would adequately supply the energy to the drying
unit. A realistic value for false air has been set at 6 % as an initial design parameter of the CPU. Within the scope of
the AC²OCem project, the kiln and calciner oxyfuel burners will be promoted to higher technology readiness levels
for newly-build and up-to 100 % oxygen combustion cement plants. A techno-economic analysis and life cycle
assessment for retrofitted existing and new-build cement plants will also be performed.
Keywords: Alternative fuel, CCS, Cement, Oxyfuel, SRF