THE USE OF INTERMEDIATE HYDROPHOBIC SILICA NANOPARTICLES FOR STABILIZATION OF WATER-IN-CO2 EMULSION AT TEMPERATURE 120 OC AND VARIOUS WATER SALINITIES
Surfactant-stabilized CO2 foam is usually not stable at very high temperature. Applications of nanotechnology have been developing fast in many disciplines. Petroleum industry quickly responds to such a technology and the efforts are being focused to the research areas such as EOR nanoparticle- C...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/43962 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Surfactant-stabilized CO2 foam is usually not stable at very high temperature.
Applications of nanotechnology have been developing fast in many disciplines.
Petroleum industry quickly responds to such a technology and the efforts are being
focused to the research areas such as EOR nanoparticle- CO2 foam. Types of the
foam generated depend on wettability of the nanomaterial employed and the
wettability may influence stability of the CO2 foam at certain conditions,
particularly at high salinity and very high temperature. High salinity may cause the
nanoparticle to coagulate and very high temperature can result in instability of the
nanoparticles due to higher mobility and agitation. These all cause the foam to
become unstable.
The previous works on such areas rarely consider extreme reservoir conditions
such as high salinity and very high temperature. The common temperature used is
not more than 95 oC. Therefore, the present research is directed to investigating the
performance of intermediate wet silica nanoparticles that is expected to have high
resistance at various values of water salinity and very high temperature as the
stabilizing agent. The salinity and temperature used in this work is as high as 6.5%
and 120 oC, respectively.
Herein, both the nanosilica concentration and salinity are varied. In the first stage
of experiments, tube tests are conducted to ensure capability of the nanosilica to
form stable emulsion. Iso-octane is employed to replace supercritical CO2 at
atmospheric conditions and therefore we use iso-octane during tube tests. It was
obtained that ethanol and ethylene glycol at certain ratio are needed to disperse
the nanoparticles in brine and the water-in-iso-octane emulsion was stable. For a
given nanosilica concentration, it was found that the emulsion volume formed was
slightly affected by water salinity.
Generation of CO2 foam at high pressure and high temperature is performed by
injecting the nanoparticle suspension and supercritical CO2 alternately into 30-
inch Berea sandstone which serves as the foam generator. The foams are than
collected in the sight glass at pressure and temperature of 1500 psi and 120 oC,
respectively. The CO2 foam column in the sight glass was then observed and
recorded for 24 hours.
Results obtained demostrate that stable CO2 foam at 120 oC can be generated for
at least 24 hours by employing intermediate wet silica nanoparticles. The stability
of CO2 foam is not affected by either salinity of 10000 - 65000 ppm NaCl or
nanosilica concentration used 5000 - 12500 ppm. This indicates that the high
adsorption energy of the silica stimulates the formation of solid lamella at the CO2-
water interface to protect the emulsion/foam from breaking. This research
demostrates that such a silica has its potential as emulsion/foam stabilizer to be
used in the application of CO2 flooding. Promoting CO2 as an EOR fluid offers
contribution to carbon capture and sequestration program in reducing green house
effect.
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