Effect of Amphiphilic Polymer/Nano-Silica Composite on Shale Stability for Water-Based Muds
Abstract
:1. Introduction
2. Materials and Methods
2.1. Materials
2.2. Preparation of SMA/SiO2
2.3. Characterization of SMA/SiO2
2.4. Pressure Transmission Test
2.5. Pore Structure Characterization of Shale
2.6. Rolling Dispersion Experiment
2.7. Contact Angle Test
2.8. Compatible Test
3. Results and Discussion
3.1. Characterization of the SMA/SiO2
3.2. Pressure Transmission Test
3.3. Pore Structure Characterization of Shale
3.4. Rolling Dispersion Experiment
3.5. Contact Angle Test Results
3.6. Probable Shale Stabilization Mechanism
3.7. Compatible Test
4. Conclusions
Author Contributions
Acknowledgments
Conflicts of Interest
Nomenclature
WBMs | water-based muds |
St | styrene |
MMA | methyl methacrylate |
AM | acrylamide |
SMA | poly(St-MMA-AM) |
KH570 | 3-methacryloxypropyltrimethoxysilane |
SDS | sodium dodecyl sulfate |
OP-10 | octylphenol polyoxyethylene ether |
SMA/SiO2 | poly(St-MMA-AM)/nano-SiO2 composite |
JHC | polymeric alcohol |
FT-IR | Fourier transform infrared spectra |
NMR | nuclear magnetic resonance |
PSD | particle size distribution |
TEM | transmission electron microscope |
SEM | scanning electron microscopy |
TGA | thermogravimetric analysis |
AV | apparent Viscosity |
PV | plastic viscosity |
YP | yield Point |
API | American Petroleum Institute |
FLAPI | fluid loss |
K | shale permeability |
μ | viscosity of fluids |
β | static compression ratio of fluids |
V | enclosed volume |
L | length of shale core |
A | cross-sectional area of shale core |
t | experimental time |
Pm | upstream pressure |
Po | initial downstream pressure |
P(L, t) | realtime downstream pressure |
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Component | Content (wt%) | Component of Clay Mineral | Content (wt%) |
---|---|---|---|
Quartz | 20 | Illite | 12 |
Calcite | 28 | Chlorite | 3 |
Plagioclase | 29 | Kaolinite | 3 |
Iron dolomite | 2 | Illite/smectite mixed layer | 82 |
Potassium feldspar | 6 | ||
Clay mineral | 15 |
Parameter | Before adding SMA/SiO2 | After adding 2.0% SMA/SiO2 |
---|---|---|
θ at 600 rpm (lbf/100 ft2) | 70 | 74 |
θ at 300 rpm (lbf/100 ft2) | 44 | 46 |
AV (mPa.s) | 35 | 37 |
PV (mPa.s) | 26 | 28 |
YP (Pa) | 9 | 9 |
YP/PV | 0.35 | 0.32 |
FLAPI (mL) | 8.2 | 6.4 |
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Qiu, Z.; Xu, J.; Yang, P.; Zhao, X.; Mou, T.; Zhong, H.; Huang, W. Effect of Amphiphilic Polymer/Nano-Silica Composite on Shale Stability for Water-Based Muds. Appl. Sci. 2018, 8, 1839. https://doi.org/10.3390/app8101839
Qiu Z, Xu J, Yang P, Zhao X, Mou T, Zhong H, Huang W. Effect of Amphiphilic Polymer/Nano-Silica Composite on Shale Stability for Water-Based Muds. Applied Sciences. 2018; 8(10):1839. https://doi.org/10.3390/app8101839
Chicago/Turabian StyleQiu, Zhengsong, Jiangen Xu, Peng Yang, Xin Zhao, Tingbo Mou, Hanyi Zhong, and Weian Huang. 2018. "Effect of Amphiphilic Polymer/Nano-Silica Composite on Shale Stability for Water-Based Muds" Applied Sciences 8, no. 10: 1839. https://doi.org/10.3390/app8101839
APA StyleQiu, Z., Xu, J., Yang, P., Zhao, X., Mou, T., Zhong, H., & Huang, W. (2018). Effect of Amphiphilic Polymer/Nano-Silica Composite on Shale Stability for Water-Based Muds. Applied Sciences, 8(10), 1839. https://doi.org/10.3390/app8101839