Reducing cost of CO₂ injection and storage is important challenge for applying to commercialization. It is very important to establish the advanced CO₂ dissolution technology which controls the reservoir pressure during CO₂ injection to inject and store CO₂ in reservoir efficiently. In this study, we focused the technology of CO₂ injection as the microbubble (MB) and have proceeded the unraveling the efficiency of increase of CO₂ storage and the mechanism by MB-CO₂ from experiment and flow simulation to apply to CCS fields.

From core flooding test by using Berea sand stones with length of 7cm and 30 cm, it was indicated that not only CO₂ saturation was increased but CO₂ Storage was increased in core and CO₂ dissolution to water was advanced by MB-CO₂ injection technology. Moreover, CO₂ was injected in area of small pore size, in which it was difficult to inject by normal injection technology, by MB-CO₂ injection technology.

We proceed to make the 3D flow simulation model based on core flooding tests by normal and MB CO₂ injection and evaluate the parameters which indicate characteristics of MB injection. As a result of these simulation studies, it was indicated that capillary pressure curves calculated based on core flooding tests were different between normal and MB injection and were also related to the differences of injection area between normal and MB injection in spite of same sample (Berea sand) , fluids (brine and CO₂) and condition (pressure, temperature and flow rate).



Acknowledgements

This study is part of an R&D project “the Development of Safety Management Technology for Large-Scale CO₂ Geological Storage”, commissioned to the Geological Carbon Dioxide Storage Technology Research Association by the Ministry of Economy, Trade and Industry (METI) of Japan and attributed to basic study for micro bubble CO₂ injection technology by Tokyo-gas Co., Ltd. and RITE. We deeply appreciate them.