CO2 - CH4 sorption induced swelling of gas shales: An experimental study on the Silurian shales from the Baltic Basin, Poland

• Autorzy: Miedzińska D. , Lutyński M.

Identyfikatory

DOI

10.5277/ppmp1851

• Języki publikacji: EN

Abstrakty

EN

The main aim of the research presented in the paper was to study the phenomena of shale swelling induced by CH4 and CO2 sorption. In the study, a Silurian gas shale sample from the Baltic Basin in Poland was used. Samples represented typical characteristic features of polish shale gas formations with relatively low total organic carbon (0.8%) and high clay mineral content. The first part of the study was devoted to competitive adsorption of CO2 and CH4. The second part was devoted to observation of the sorption induced swelling phenomena, where sample linear strains were monitored with the use of strain gauges. Swelling tests were conducted up to the pressure of approximately 8 MPa with CO2, CH4 and helium as the baseline. Experimental results were compared with the Seidle and Huitt model where Langmuir constants where determined with volumetric sorption tests. Results of the study showed that matrix swelling in case of CO2 adsorption was greater than in the case of CH4 adsorption. The swelling value was directly proportional to adsorption and was about 5 to 10 times smaller than in the case of coal. Sorption of methane and carbon dioxide in the gas-bearing shale was about 10-times lower than in hard coals. The Seidle and Huitt model developed for coals was equally suitable to describe the processes of shale swelling.

Słowa kluczowe

EN

shale rock; swelling; methane; carbon dioxide; sorption

• Wydawca: Oficyna Wydawnicza Politechniki Wrocławskiej
• Czasopismo: Physicochemical Problems of Mineral Processing
• Rocznik: 2018
• Tom: Vol. 54, iss. 2
• Strony: 415--427
• Opis fizyczny: Bibliogr. 32 poz., rys., tab.

Twórcy

autor

Miedzińska D.

• Military University of Technology, Faculty of Mechanical Engineering, Kaliskiego St. 2, 00-908 Warsaw, Poland

autor

Lutyński M.

• Silesian University of Technology, Faculty of Mining and Geology, Akademicka St. 2, 44-100 Gliwice, Poland

Bibliografia

• TSANG, C.-F., APPS, J.A., 2005, Underground Injection Science and Technology, Elsevier B.V.
• BATTISTUTTA, E., VAN HEMERT, P., LUTYNSKI, M., BRUINING, H., WOLF, K.-H., 2010. Swelling and sorption experiments on methane, nitrogen and carbon dioxide on dry Selar Cornish coal. Int. J. Coal Geol., 84, 39-48.
• BRIGGS, D., 2003. Environmental pollution and the global burden of disease. British Medical Bulletin, 68, 1-24.
• CIPOLLA, C.L., LOLON, E.P., ERDLE, J.C., RUBIN, B., 2009. Reservoir modeling in shale gas reservoirs. SPE125530, Charleston, West Virginia.
• CROSDALE, P.J., BEAMISH, B.B., VALIX, M., 1998. Coalbed methane sorption related to coal composition. Int. J. Coal Geol., 35, 147-158.
• DAHAGHI, K.A., 2010. Numerical Simulations and Modeling of Enhanced Gas Recovery and CO2 Sequestration in Shale Gas Reservoirs. SPE, West Virginia University.
• DAY, S., DUFFY, G., SAKUROVS, R., WEIR S., 2008. Effect of coal properties on CO2 sorption capacity under supercritical conditions. Int. J. Greenhouse Gas Control, 2, 342-352.
• DURUCAN, S., AHSANB, M., SHIA, J.-Q., 2008. Matrix shrinkage and swelling characteristics of European coals. Energy Proc., 3055-3062.
• DUTTA, P., HARPALANI, S., PRUSTY, B., 2008. Modeling of CO2 sorption on coal. Fuel, 87, 2023-2036.
• EPA, 2016. Study of Hydraulic Fracturing and Its Potential Impact on Drinking Water Resources. www.epa.gov.pl.
• HILDENBRAND, A., KROOSS, B.M., BUSCH, A., GASCHNITZ, R., 2006. Evolution of methane sorption capacity of coal seams as a function of burial history — a case study from the Campine Basin, NE Belgium. Int. J. Coal Geol., 66, 179-203.
• HOL, S., GENSTERBLUM, Y., MASSAROTTO, P., 2014. Sorption and changes in bulk modulus of coal - experimental evidence and governing mechanisms for CBM and ECBM applications. Int J. Coal Geol., 128-129, 119-133.
• HOLLOWAY, S., KARIMJEE, A., AKAI, M., PIPATTI, R., RYPDAL., K., 2006. Carbon Dioxide Transport, Injection and Geological Storage. IPCC Guidelines for National Greenhouse Gas Inventories.
• JOUBERT, J.I., GREIN, C.T., BIENSTOCK, D., 1973. Sorption of methane in moist coal. Fuel, 52, 181-185.
• KHOSROKHAVAR, R., WOLF, K.-H., BRUINING, H., 2014. Sorption of CH4 and CO2 on a carboniferous shale from Belgium using a manometric setup. Int. J. Coal Geol., 128-129, 153-161.
• KUILA, U., MCCARTY, D.K., DERKOWSKI, A., FISCHER, T.B., TOPÓR, T., PRASAD, M., 2014. Nano-scale texture and porosity of organic matter and clay minerals in organic-rich mudrocks. Fuel, 135, 359-373.
• MAJEWSKA, Z., CEGLARSKA-STEFAŃSKA, G., MAJEWSKI, S., ZIETEK, J., 2009. Binary gas sorption/desorption experiments on a bituminous coal: Simultaneous measurements on sorption kinetics, volumetric strain and acoustic emission. Int. J. of Coal Geol., 77, 90-102.
• MAZUMDER, S., WOLF, K.H., 2008. Differential swelling and permeability change of coal in response to CO2 injection for ECBM. SPE Asia Pacific Oil and Gas Conference and Exhibition “Gas Now: Delivering on Expectations”, 267-298.
• MCCARTY, R.D., ARP, V.D., 1990. A New Wide Range Equation of State for Helium. Adv. Cryogen. Eng., 35, 1465-1475.
• REUCROFT, P.J., SETHURAMAN, A.R., 1987. Effect of pressure on carbon dioxide induced coal swelling. Energy Fuels, 1, 72-75.
• ROGALA, A., KRZYSIEK, J., BERNACIAK, M., HUPKA, J., 2013. Non-Aqueous Fracturing Technologies for Shale Gas Recovery. Physicochem. Probl. Miner. Process., 49, 313-322.
• RUTTER, P., KEIRSTEAD, J., 2012. A brief history and the possible future of urban energy systems. Energy Policy, 50, 72-80.
• SEIDLE, J.P., HUITT, L.G., 1995. Experimental Measurement of Coal Matrix Shrinkage due to Gas Desorption and Implications for Cleat Matrix Increases. SPE Paper 30010.
• SHOVKUN, I., ESPINOZA, D.N., 2017. Coupled fluid flow-geomechanics simulation in stress-sensitive coal and shale reservoirs: Impact of desorption-induced stresses, shear failure, and fines migration. Fuel, 195, 260–272.
• SPAN, R., WAGNER, W., 1995. A New Equation of State for Carbon Dioxide Covering the Fluid Region from the Triple-point Temperature to 1100 K at Pressures up to 800 MPa. J. Phys. Chem. Ref. Data, 25, 1509-1596.
• STAIB, G., SAKUROVS, R., GRAY, E.M., 2014. Kinetics of coal swelling in gases: Influence of gas pressure, gas type and coal type. Int. J. Coal Geol., 132, 117-122.
• SWAMI, V., SETTARI, A., 2013. A Numerical Model for Multi-mechanism flow in Shale Gas Reservoirs with Application to Laboratory Scale Testing. SPE Paper 164840.
• WAGNER, W., SPAN, R., 1993. Special Equations of State for Methane, Argon, and Nitrogen for the Temperature Range from 270 to 350 K at Pressures up to 30 MPa. Int. J. Thermophys., 14, 699-725.
• WANG, H.F., 2016. Theory of Linear Poroelasticity with Applications to Geomechanics and Hydrogeology. Princeton University Press.
• WANG, K., WANG, G., REN, T., CHENG, Y., 2014. Methane and CO2 sorption hysteresis on coal: A critical review. Int. J. Coal Geol., 132, 60-80.
• YAN, C., DENG, J., CHENG, Y., LI, M., FENG, Y., LI, X., 2017. Mechanical Properties of Gas Shale During Drilling Operations. Rock Mech. Rock Eng., 50, 1-13.
• ZHENG, H., LIUA, D., ZHENGA, Y, LIANG, S., LIUA, Y., 2009. Sorption isotherm and kinetic modeling of aniline on Cr-bentonite. J. Hazard. Mater., 167, 141-147.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).