4.7 Article

CCUS scenarios for the cement industry: Is CO2 utilization feasible?

期刊

JOURNAL OF CO2 UTILIZATION
卷 61, 期 -, 页码 -

出版社

ELSEVIER SCI LTD
DOI: 10.1016/j.jcou.2022.102015

关键词

CCUS; Cement industry; Ethanol; Polyols; Geological storage

资金

  1. European Union [641185]

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This study investigates the economic feasibility of CO2 capture, utilization, and storage (CCUS) technologies in connection to the cement industry. The results show that integrating the production of ethanol, polyols, or food-grade CO2 into the CCUS chain is feasible, but utilization alone is unlikely to be applied. The study also reveals that the cement industry emits more CO2 than can be utilized in a single CO2 utilization plant due to market constraints and limited availability of raw materials.
In this work, four illustrative CO2 capture, utilization and storage chains are investigated in order to evaluate the economic feasibility of CCUS technologies in connection to the cement industry. A CCS reference chain in which 90% of the CO2 emissions (or 0,694 MtCO(2)/y) are stored in a saline aquifer is first studied. Due to emissions related to energy usage in the capture, conditioning and transport processes, a total of 0,504 MtCO(2)/y are avoided, or 65% of the CO2 emitted by the cement plant at a cost of 114 (sic)/t CO2 avoided. Then, production of ethanol, polyols or food-grade CO2 is integrated to the chain, composing three alternative CCUS chains. These products are chosen based on an assessment of market, energy demand, and technology readiness level of technologies. For CCUS, we show that the economic feasibility is case dependent. The cost of producing blue ethanol is estimated as 656 (sic)/t, slightly above the market value of 633 (sic)/t. The cost per tonne of CO2 avoided drops from 114(sic) (CCS) to 111(sic) (sugarcane-based displacement) and the amount of CO2 avoided increases by 3%, to 0,518 MtCO(2)/y. In the second CCUS scenario, we have evaluated the integrated production of polyols. The entire CCUS chain avoids 0,708 MtCO(2)/y, and produces 288 kt/y of polyols, generating a profit of 18 (sic)/t CO2 avoided. In the third CCUS scenario, we show that the production of food-grade CO2 is feasible as long as it is used to replace fossil-derived CO2, with a total CO2 avoidance of 0,504 MtCO(2)/y at a cost of 108 (sic)/t. A general conclusion from this work is that the average cement plant emits much more CO2 than can be utilized in a single CO2 utilization plant. That is either due to market constrains or limited availability of raw materials. For the routes evaluated in this work, the fraction of the emitted CO2 directed to the utilization plant was always below 10%. Therefore, when connected to the cement industry, utilization is not likely to be applied as a stand-alone solution, but as an integrated link in the CCUS chain.

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