Skip to main content
Fachgebiete
Automobil + Motoren Bauwesen + Immobilien Business IT + Informatik Elektrotechnik + Elektronik Energie + Nachhaltigkeit Finance + Banking Management + Führung Marketing + Vertrieb Maschinenbau + Werkstoffe Versicherung + Risiko
DE
EN
Bücher
Zeitschriften
Themenseiten
Organisationspsychologie Projektmanagement Marketing Smart Manufacturing
Weitere Formate
Podcasts Webinare Technik Webinare Wirtschaft Kongresse Veranstaltungskalender Awards
Jetzt Einzelzugang starten
Zugang für Unternehmen
Referenzkunden
SLX-Digitalkonferenz: Zukunftswerkstatt 2024

Mehr Umsatz mit Top-Kontakten

Am 7. Mai erfahren Sie, wie Vertriebsteams Leadgenerierung, Leadnurturing und Leadstrategien effizient steuern können.
Erweiterte Suche
Anmelden
nach oben
Rock Mechanics and Rock Engineering
Erschienen in: Rock Mechanics and Rock Engineering 8/2021

26.04.2021 | Original Paper

The Effective Stress Coefficient of Coal: A Theoretical and Experimental Investigation

verfasst von: Adelina Lv, Mohammad Ali Aghighi, Hossein Masoumi, Hamid Roshan

Erschienen in: Rock Mechanics and Rock Engineering | Ausgabe 8/2021

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config
loading …

Abstract

The effective stress coefficient (ESC) is a key parameter in the linear poroelastic effective stress formulation. In fluid-bearing porous media, the effective stress is the difference between total stress and a fraction of the pore fluid pressure controlled by the ESC. The ESC is either measured in the laboratory or estimated by empirical models using field data. Among different techniques, sonic velocity measurements are widely used to estimate the ESC. The structure of coal, however, has some inherent differences to other porous rocks which in turn affect its hydromechanical behavior. For instance, there is no clear definition of grains and matrix in coal making it unclear whether coal, even when saturated by a non-sorbing gas, follows the same principles of sonic-based estimation of the ESC applicable to other rocks. In this study, we develop a model based on the percolation theory and ultrasonic measurements of coal samples saturated with non-sorbing gases to obtain the ESC. To assess the assumptions used in the development of this model, we measured the ESC of different coal samples through two independent, extensive sets of hydromechanical experiments: static and dynamic (ultrasonic). We then compared the results of these experiments with each other and with some of the existing models and evaluated the performance of the percolation-based model in depth.
Vorheriger Artikel Fracture Extraction from Smooth Rock Surfaces Using Depth Image Segmentation
Nächster Artikel An Improved Analytical Model for the Elastic and Plastic Strain-hardening Shear Behaviour of Fully Grouted Rockbolts

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

  • über 102.000 Bücher
  • über 537 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Finance + Banking
  • Management + Führung
  • Marketing + Vertrieb
  • Maschinenbau + Werkstoffe
  • Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

  • über 67.000 Bücher
  • über 390 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Maschinenbau + Werkstoffe




 

Jetzt Wissensvorsprung sichern!

Jetzt informieren
Literatur
Agudo ÒC, da Silva NV, Warner M, Morgan J (2018) Acoustic full-waveform inversion in an elastic world. Geophysics 83:R257–R271
Akaike H (1974) A new look at the statistical model identification. IEEE Trans Autom Control 19:716–723
Amiri M, Lashkaripour GR, Ghabezloo S, Moghaddas NH, Tajareh MH (2019) 3D spatial model of Biot’s effective stress coefficient using well logs, laboratory experiments, and geostatistical method in the Gachsaran oil field, southwest of Iran. Bull Eng Geol Environ 78:4633–4646
Avseth P, Mukerji T, Mavko G, Dvorkin J (2010) Rock-physics diagnostics of depositional texture, diagenetic alterations, and reservoir heterogeneity in high-porosity siliciclastic sediments and rocks—a review of selected models and suggested work flows. Geophysics 75:75A31-75A47
Bauer A, Bhuiyan MH, Fjær E, Holt RM, Lozovyi S, Pohl M, Szewczyk D (2016) Frequency-dependent wave velocities in sediments and sedimentary rocks: laboratory measurements and evidences. Lead Edge 35:490–494
Biot MA (1941) General theory of three-dimensional consolidation. J Appl Phys 12:155–164
Boadu FK (2018) Regression models to estimate critical porosity of soils from basic soil properties based on percolation theory. Geotech Geol Eng 36:1207–1216
Bourbié T, Coussy O, Zinszner B, Junger MC (1992) Acoustics of porous media. Acoustical Society of America
Boutéca M, Sarda J-P, Laurent J (1991) Rock mechanics contribution to the determination of fluid flow properties. In: Second European core analysis symposium (Eurocas II), Bruxelles
Broadbent SR, Hammersley JM (1957) Percolation processes: I. Crystals and mazes. In: Mathematical proceedings of the Cambridge Philosophical Society, vol 3. Cambridge University Press, pp 629–641
Cheadle M, Elliott M, McKenzie D (2004) Percolation threshold and permeability of crystallizing igneous rocks: the importance of textural equilibrium. Geology 32:757–760
Chen Z, Liu J, Pan Z, Connell LD, Elsworth D (2012) Influence of the effective stress coefficient and sorption-induced strain on the evolution of coal permeability: model development and analysis. Int J Greenh Gas Control 8:101–110
Cheng AH-D (2016) Poroelasticity, vol 27. Springer
Christensen N, Wang H (1985) The influence of pore pressure and confining pressure on dynamic elastic properties of Berea sandstone. Geophysics 50:207–213
Detournay E, Cheng AHD (1988) Poroelastic response of a borehole in a non-hydrostatic stress field. Int J Rock Mech Min Sci Geomech Abstr 25:171–182
Dvorkin J, Nur A (1996) Elasticity of high-porosity sandstones: theory for two North Sea data sets. Geophysics 61:1363–1370
Eberhart-Phillips D, Han D-H, Zoback M (1989) Empirical relationships among seismic velocity, effective pressure, porosity, and clay content in sandstone. Geophysics 54:82–89
Engstrøm F (1992) Rock mechanical properties of Danish North Sea chalk. In: Fourth north sea chalk symposium, Deauville
Fabre D, Gustkiewicz J (1998) Influence of rock porosity on the Biot’s coefficient. In: Poromechanics-a tribute to Maurice A. Biot”, Proc. of the Biot Conf. on Poromech., Louvain-la-Neuve (Belgium), pp 14–16
Fang Y, Shi Y, Sheng Y, Zhang Z (2018) Modeling of Biot’s coefficient for a clay-bearing sandstone reservoir. Arab J Geosci 11:302
Fjær E (2019) Relations between static and dynamic moduli of sedimentary rocks. Geophys Prospect 67:128–139
Fritzsche H (1974) Electronic properties of amorphous semiconductors. In: Amorphous and liquid semiconductors. Springer, pp 221–312
Hashin Z, Shtrikman S (1961) Note on a variational approach to the theory of composite elastic materials. J Franklin Inst 271:336–341
Hornby BE (1996) An experimental investigation of effective stress principles for sedimentary rocks. In: SEG Technical program expanded abstracts 1996. Society of Exploration Geophysicists, pp 1707–1710
Hovem JM (1995) Acoustic waves in finely layered media. Geophysics 60:1217–1221
Hunt A (2005) Percolation theory for flow in porous media. Springer, Berlin
Jasinge D, Ranjith P, Choi S (2011) Effects of effective stress changes on permeability of latrobe valley brown coal. Fuel 90:1292–1300
Kalkan E (2016) An automatic P-phase arrival-time picker. Bull Seismol Soc Am 106:971–986
Khaksar A, Griffiths C, McCann C (1999) Effective stress coefficient for P- and S-wave velocity and quality factor in sandstone, example from Cooper Basin-Australia. In: SEG technical program expanded abstracts 1999. Society of Exploration Geophysicists, pp 192–195
Kováčik J (2001) Correlation between shear modulus and porosity in porous materials. J Mater Sci Lett 20:1953–1955
Kováčik J, Emmer Š (2013) Correlation between shear wave velocity and porosity in porous solids and rocks. J Powder Technol 2013:1–3
Krief M, Garat J, Stellingwerff J, Ventre J (1990) A petrophysical interpretation using the velocities of P and S waves (full-waveform sonic) The Log Analyst. 31
Küperkoch L, Meier T, Lee J, Friederich W, Group EW (2010) Automated determination of P-phase arrival times at regional and local distances using higher order statistics. Geophys J Int 181:1159–1170
Lee MW (2002) Biot-Gassmann theory for velocities of gas hydrate-bearing sediments. Geophysics 67:1711–1719
Liu Q, Cheng Y, Zhou H, Guo P, An F, Chen H (2015) A mathematical model of coupled gas flow and coal deformation with gas diffusion and Klinkenberg effects. Rock Mech Rock Eng 48:1163–1180
Luo X, Were P, Liu J, Hou Z (2015) Estimation of Biot’s effective stress coefficient from well logs Environ. Earth Sci 73:7019–7028
Lv A, Ramandi HL, Masoumi H, Saadatfar M, Regenauer-Lieb K, Roshan H (2019b) Analytical and experimental investigation of pore pressure induced strain softening around boreholes. Int J Rock Mech Min Sci 113:1–10
Lv A, Masoumi H, Walsh SD, Roshan H (2019a) Elastic-softening-plasticity around a borehole: an analytical and experimental study. Rock Mech Rock Eng 52:1149–1164
Ma X, Zoback MD (2017) Laboratory experiments simulating poroelastic stress changes associated with depletion and injection in low-porosity sedimentary rocks. J Geophys Res Solid Earth 122:2478–2503
Mari J-L, Coppens F, Gavin P (1994) Full waveform acoustic data processing. Editions Technip
Marion DP, Coudin P (1992) Fram ray to effective medium theories in stratified media: an experimental study. In: SEG technical program expanded abstracts 1992. Society of Exploration Geophysicists, pp 1341–1343
Martin LP, Dadon D, Rosen M (1996) Evaluation of ultrasonically determined elasticity-porosity relations in zinc oxide. J Am Ceram Soc 79:1281–1289
Miller MN (1969) Bounds for effective bulk modulus of heterogeneous materials. J Math Phys 10:2005–2013
Morcote A, Mavko G, Prasad M (2010) Dynamic elastic properties of coal. Geophysics 75:E227–E234
Murphy W, Reischer A, Hsu K (1993) Modulus decomposition of compressional and shear velocities in sand bodies. Geophysics 58:227–239
Njiekak G, Schmitt DR (2019) Effective stress coefficient for seismic velocities in carbonate rocks: effects of pore characteristics and fluid types. Pure Appl Geophys 176:1467–1485
Nur A, Byerlee JD (1971) An exact effective stress law for elastic deformation of rock with fluids. J Geophys Res 76:6414–6419
Nur A, Mavko G, Dvorkin J, Galmudi D (1998) Critical porosity: a key to relating physical properties to porosity in rocks. Lead Edge 17:357–362
Olsen C, Hedegaard K, Fabricius IL, Prasad M (2008) Prediction of Biot’s coefficient from rock-physical modeling of North Sea chalk. Geophysics 73:E89–E96
Ovshinsky SR, Fritzsche H (1973) Amorphous semiconductors for switching, memory, and imaging applications. IEEE Trans Electron Dev 20:91–105
Pan J, Meng Z, Hou Q, Ju Y, Cao Y (2013) Coal strength and Young’s modulus related to coal rank, compressional velocity and maceral composition. J Struct Geol 54:129–135
Pappalardo G (2015) Correlation between P-wave velocity and physical–mechanical properties of intensely jointed dolostones, Peloritani mounts, NE Sicily. Rock Mech Rock Eng 48:1711–1721
Parrott L, Patel R, Killoh D, Jennings H (1984) Effect of age on diffusion in hydrated alite cement. J Am Ceram Soc 67:233–237
Pickett GR (1963) Acoustic character logs and their applications in formation evaluation. J Pet Technol 15:659–667
Pirzada MA, Zoorabadi M, Ramandi HL, Canbulat I, Roshan H (2018) CO2 sorption induced damage in coals in unconfined and confined stress states: a micrometer to core scale investigation. Int J Coal Geol 198:167–176
Plapous C, Marro C, Scalart P (2006) Improved signal-to-noise ratio estimation for speech enhancement. IEEE Trans Audio Speech Lang Process 14:2098–2108
Powers TC (1958) Structure and physical properties of hardened Portland cement paste. J Am Ceram Soc 41:1–6
Radke M, Schaefer RG, Leythaeuser D, Teichmüller M (1980) Composition of soluble organic matter in coals: relation to rank and liptinite fluorescence. Geochim Cosmochim Acta 44:1787–1800
Raymer L, Hunt E, Gardner JS An improved sonic transit time-to-porosity transform. In: SPWLA 21st annual logging symposium, 1980. Society of Petrophysicists and Well-Log Analysts
Roshan H, Aghighi MA (2012) Formation of plastic zone and resulted stresses around a borehole drilled in chemically active rock from 2D and 3D finite element modeling. Int J Geomech (Under revision)
Roshan H, Masoumi H, Hagan P (2016) On size-dependent uniaxial compressive strength of sedimentary rocks in reservoir geomechanics. In: 50th US rock mechanics/geomechanics symposium. American Rock Mechanics Association
Roshan H, Masoumi H, Regenauer-Lieb K (2017) Frictional behaviour of sandstone: a sample-size dependent triaxial investigation. J Struct Geol 94:154–165
Sakurovs R, He L, Melnichenko YB, Radlinski AP, Blach T, Lemmel H, Mildner DF (2012) Pore size distribution and accessible pore size distribution in bituminous coals. Int J Coal Geol 100:51–64
Sang G, Elsworth D, Liu S, Harpalani S (2017) Characterization of swelling modulus and effective stress coefficient accommodating sorption-induced swelling in coal. Energy Fuels 31:8843–8851
Sarker R, Batzle M (2008) Effective stress coefficient for North Sea shale: an experimental study. In: SEG technical program expanded abstracts 2008. Society of Exploration Geophysicists, pp 1620–1624
Saurabh S, Harpalani S, Singh V (2016) Implications of stress re-distribution and rock failure with continued gas depletion in coalbed methane reservoirs. Int J Coal Geol 162:183–192
Siggins AF, Dewhurst DN (2003) Saturation, pore pressure and effective stress from sandstone acoustic properties. Geophys Res Lett 30:61-1–61-4
Skempton A, Bishop A (1954) Building materials: their elasticity and inelasticity edited by M. Reiner. North Holland Publishing Co., Amsterdam
Smiley RA, Jackson HL (2016) Chemistry and the chemical industry: a practical guide for non-chemists. CRC Press
Stadtmuller M, Lis-Śledziona A, Słota-Valim M (2018) Petrophysical and geomechanical analysis of the Lower Paleozoic shale formation, North Poland. Interpretation 6:SH91–SH106
Sulem J, Ouffroukh H (2006) Shear banding in drained and undrained triaxial tests on a saturated sandstone: Porosity and permeability evolution. Int J Rock Mech Min Sci 43:292–310
Terzaghi K (1923) Die brechnung der durchlassigkeitsziffer des tones aus dem verlauf der hydrodynamischen spannungserschinungen Sitz Akad Wissen. Wien Math Naturwiss Kl, Abt IIa 132:105–124
Todd T, Simmons G (1972) Effect of pore pressure on the velocity of compressional waves in low-porosity rocks. J Geophys Res 77:3731–3743
Vardakis JC, Chou D, Tully BJ, Hung CC, Lee TH, Tsui P-H, Ventikos Y (2016) Investigating cerebral oedema using poroelasticity. Med Eng Phys 38:48–57
Wirth B, Sobey I (2006) An axisymmetric and fully 3D poroelastic model for the evolution of hydrocephalus. Math Med Biol J IMA 23:363–388
Wyllie MRJ, Gregory AR, Gardner LW (1956) Elastic wave velocities in heterogeneous and porous media. Geophysics 21:41–70
Yu H (2015) Dynamic effective pressure coefficient calibration. Geophysics 80:D65–D73
Zhang Z, Zhang R, Wu S, Deng J, Zhang Z, Xie J (2019) The stress sensitivity and porosity sensitivity of coal permeability at different depths: a case study in the Pingdingshan mining area. Rock Mech Rock Eng 52:1539–1563
Zhu M, Wang L, Liu X, Zhao J (2018) Accurate identification of microseismic P- and S-phase arrivals using the multi-step AIC algorithm. J Appl Geophys 150:284–293
Zimmerman RW (1990) Compressibility of sandstones. Elsevier
Zimmerman RW, Somerton WH, King MS (1986) Compressibility of porous rocks. J Geophys Res Solid Earth 91:12765–12777
Metadaten
Titel
The Effective Stress Coefficient of Coal: A Theoretical and Experimental Investigation
verfasst von
Adelina Lv
Mohammad Ali Aghighi
Hossein Masoumi
Hamid Roshan
Publikationsdatum
26.04.2021
Verlag
Springer Vienna
Erschienen in
Rock Mechanics and Rock Engineering / Ausgabe 8/2021
Print ISSN: 0723-2632
Elektronische ISSN: 1434-453X
DOI
https://doi.org/10.1007/s00603-021-02476-1

Weitere Artikel der Ausgabe 8/2021

Rock Mechanics and Rock Engineering 8/2021 Zur Ausgabe

Original Paper

Experimental and Numerical Investigations on the Macro-Meso Shear Mechanical Behaviors of Artificial Rock Discontinuities with Multiscale Asperities

Original Paper

Quantifying and Modeling of In Situ Stress Evolutions of Coal Reservoirs for Helium, Methane, Nitrogen and CO2 Depletions

Technical Note

Influence of Water Saturation and Real-Time Testing Temperature on Mechanical Behavior of Sandstone Under Conventional Triaxial Compression

Original Paper

Fracture Height Growth Prediction Using Fluid Velocity Based Apparent Fracture Toughness Model

Original Paper

Hydro-mechanical Coupling Response Behaviors in Tunnel Subjected to a Water-Filled Karst Cave

Technical Note

Water-Weakening Effects on the Strength of Hard Rocks at Different Loading Rates: An Experimental Study