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Geotechnical and Geological Engineering

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06-07-2020 | Original Paper

A New Model for Calculation of the Plastic Compression Index and Porosity and Permeability of Gob Materials in Longwall Mining

Authors: Hossein Arasteh, Gholamreza Saeedi, Mohammad Ali Ebrahimi Farsangi, Kamran Esmaeili

Published in: Geotechnical and Geological Engineering | Issue 6/2020

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Abstract

In coal longwall mining the accuracy of gob methane drainage system design, control of methane leakage into the longwall stope, and control of spontaneous combustion potential all depend on the porosity and permeability of the gob material. However, longwall mining conditions do not allow for any direct measurements of the gob material characteristics. Therefore, the simulation of gob material as a granular medium contributes to the ability to predict gob porosity. Many features of a granular medium, like gob material, are directly and indirectly affected by its particle size distribution. Fractal models are commonly used for porosity prediction which allows for a better understanding of how porosity can change with stress states based on the fragmentation size distribution of gob material. The plastic compression index (PCI), which describes the degree of compression of the broken material in gob, can be calculated using the physical properties of the broken material. However, using the existing fractal models, it is difficult to determine this parameter because of the multiplicity of parameters. In this research, a new fractal model was developed to facilitate the calculation of the PCI parameter and to increase the accuracy and validity of the results. Using data from the Tabas coal mine, the porosity-stress and permeability-stress curves were investigated for the gob material. The porosity results from this study agreed with those of Fan's gob compression model in a comparison. Although the obtained permeability results were within the range of previous studies, Berg's permeability model provided a better tool for estimation of the gob permeability.

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Ashby MF, Jones DR (1986) Engineering Materials 2. Int Ser Mater Sci Technol, 39–41

Bouzeboudja A, Melbouci B, Bouzeboudja H (2016) Characterization of aggregates fragmentation using the calculation of fractal dimension. In: 16th international conference on new trends in fatigue and fracture (NT2F16), May 24–27 Dubrovnik, Croatia

Brunner DJ (1985) Ventilation models for longwall leakage simulation. In: 2nd US mine ventilation symposium, 23–25 September, Reno, NV

Carman PC (1956) Flow of gases through porous media. Academic Press Inc, New York

Comegna V, Damiani P, Somella A (1988) Use of fractal model for determining soil water retention curves. Geoderma 85:307–323CrossRef

Esterhuizen GS, Karacan CÖ (2007) A methodology for determining gob permeability distributions and its application to reservoir modeling of coal mine longwalls. 2007 SME Annual Meeting, Denver, CO

Fan L, Liu S (2017) A conceptual model to characterize and model compaction behavior and permeability evolution of broken rock mass in coal mine gobs. Int J Coal Geol 172:60–70CrossRef

Filgueira RR, Fournier LL, Cerisola CI, Gelati P, García MG (2006) Particle-size distribution in soils: a critical study of the fractal model validation. Geoderma 134(3–4):327–334CrossRef

Griffith AA (1920) The phenomena of rupture and flow in solids. Philos Trans R Soc Lond A 221:163–198

Guo H, Yuan L, Shen B, Qu Q, Xue J (2012) Mining-induced strata stress changes, fractures and gas flow dynamics in multi-seam longwall mining. Int J Rock Mech Min Sci 54:129–139CrossRef

Hosseini N, Goshtasbi K, Oraee-Mirzamani B, Gholinejad M (2013) Calculation of periodic roof weighting interval in longwall mining using finite element method. Arab J Geosci 7(5):1951–1956CrossRef

Hunt AG, Gee GW (2001) Application of critical path analysis to fractal porous media: comparison with examples from the Hanford site. Adv Water Resour 25:129–146CrossRef

Hwang SI, Lee KP, Lee DS, Powers SE (2002) Models for estimating soil particle-size distributions. Soil Sci Soc Am J 66(4):1143–1150CrossRef

IRITEC (1992) Internal reports of Tabas coal mine, pp 110–135

Jacquin CG, Adler PM (1988) Fractal porous media II: geometry of porous geologic structures. Transp Porous Media 2:571–596

Karacan CÖ (2010) Prediction of porosity and permeability of caved zone in longwall gobs. Transp Porous Media 82(2):413–439CrossRef

Karacan CÖ, Esterhuizen GS, Schatzel SJ, Diamond WP (2007) Reservoir simulation-based modeling for characterizing longwall methane emissions and gob gas venthole production. Int J Coal Geol 71(2–3):225–245CrossRef

Kozak E, Pachepsky YA, Sokolowski S, Sokolowska Z, Stepniewski W (1996) A modified number-based method for estimating fragmentation fractal dimension of soils. Soil Sci Soc Am J 60:1291–1297CrossRef

Kozeny J (1927) Uber kapillare leitung der wasser in boden. R Acad Sci Vienna Proc Class I 136:271–306

Li B, Zou Q, Liang Y (2019) Experimental research into the evolution of permeability in a broken coal mass under cyclic loading and unloading conditions. Appl Sci 9(4):762CrossRef

Liu R, Jiang Y, Li B, Wang X (2015) A fractal model for characterizing fluid flow in fractured rock masses based on randomly distributed rock fracture networks. Comput Geotech 65:45–55CrossRef

Marts JA, Gilmore RC, Brune JF, Bogin GE Jr, Grubb JW, Saki S (2014) Dynamic gob response and reservoir properties for active longwall coal mines. Min Eng 66(12):59–66

McDowell GR, Amon A (2000) The application of Weibull statistics to the fracture of soil particles. Soils Found 40(5):133–141CrossRef

McDowell GR, Bolton MD, Robertson D (1996) The fractal crushing of granular materials. J Mech Phys Solids 44(12):2079–2101CrossRef

McPherson MJ (1975) The occurrence of methane in mine workings. Journal of Mine Ventilation Society of South Africa 28(8):118–128

Pappas DM, Mark C (1993) Behavior of simulated longwall gob material. Report of Investigations/1993. Bureau of Mines, Pittsburgh, PA (United States). Pittsburgh Research Center

Parent LE, Parent SE, Kätterer T, Egozcue JJ (2011) Fractal and compositional analysis of soil aggregation. Proceedings of the CoDaWork 2011 4th international workshop on compositional data analysis, Girona, Spain, 9–13 May 2011, p 1–14

Park JH, Koumoto T (2004) New compression index equation. Journal of Geotechnical and Geoenvironmental Engineering 130(2):223–226CrossRef

Peng SS, Chiang HS (1984) Longwall mining. Wiley, New York

Perfect E (1997) Fractal models for the fragmentation of rocks and soils: a review. Eng Geol 48:185–198CrossRef

Pirmoradian N, Sepaskhah AR, Hajabbasi MA (2005) Application of fractal theory to quantify soil aggregate stability as influenced by tillage treatments. Biosys Eng 90(2):227–234CrossRef

Poulsen BA, Adhikary D, Guo H (2018) Simulating mining-induced strata permeability changes. Eng Geol 237:208–216CrossRef

Rawls WJ, Brakensiek DL, Logsdon SD (1993) Predicting saturated hydraulic conductivity utilizing fractal principles. Soil Sci Soc Am J 57(5):1193–1197CrossRef

Ren TX, Edwards JS, Josefowicz RR (1997) CFD modeling of methane flow around longwall coal faces. In: 6th international mine ventilation congress, 17–22 May, Pittsburgh, PA

Rieu M, Sposito G (1991) Fractal fragmentation, soil porosity and soil water properties: theory. Soil Sci Soc Am J 55:1231–1238CrossRef

Salamon MD (1990) Mechanism of caving in longwall coal mining. In: InRock mechanics contributions and challenges: proceedings of the 31st US symposium, vol 18 Golden, Colorado, pp 161–168

Seidle JR and Huitt LG (1995) Experimental measurement of coal matrix shrinkage due to gas desorption and implications for cleat permeability increases. In: International meeting on petroleum Engineering. Society of Petroleum Engineers

Sepaskhah AR, Tafteh A (2013) Pedotransfer function for estimation of soil-specific surface area using soil fractal dimension of improved particle-size distribution. Arch Agron Soil Sci 59(1):93–103CrossRef

Si G, Shi JQ, Durucan S, Korre A, Lazar J, Jamnikar S, Zavšek S (2015) Monitoring and modelling of gas dynamics in multi-level longwall top coal caving of ultra-thick coal seams Part II: numerical modelling. Int J Coal Geol 144:58–70CrossRef

Szlązak J (2001) The determination of a co-efficient of longwall gob permeability. Arch Min Sci 46(4):451–468

Turcotte DL (1986) Fractals and fragmentation. J Geophys Res 91:1921–1926CrossRef

Tyler SW, Wheatcraft SW (1992) Fractal scaling of soil particle-size distributions: analysis and limitations. Soil Sci Soc Am J 56(2):362–369CrossRef

Wang F, Zhang C, Liang N (2017) Gas permeability evolution mechanism and comprehensive gas drainage technology for thin coal seam mining. Energies 10(9):1382CrossRef

Wendt M, Balusu R (2002) CFD modeling of longwall goaf gas flow dynamics. Coal Saf 20:17–34

Whittles DN, Lowndes IS, Kingman SW, Yates C, Jobling S (2006) Influence of geotechnical factors on gas flow experienced in a UK longwall coal mine panel. Int J Rock Mech Min Sci 43:369–387CrossRef

Yavuz H (2004) An estimation method for cover pressure re-establishment distance and pressure distribution in the goaf of longwall coal mines. Int J Rock Mech Min Sci 41(2):193–205CrossRef

Zhang C, Tu S, Zhang L, Bai Q, Yuan Y, Wang F (2016) A methodology for determining the evolution law of gob permeability and its distributions in longwall coal mines. J Geophys Eng 13(2):181–193CrossRef

Title: A New Model for Calculation of the Plastic Compression Index and Porosity and Permeability of Gob Materials in Longwall Mining
Authors: Hossein Arasteh
Gholamreza Saeedi
Mohammad Ali Ebrahimi Farsangi
Kamran Esmaeili
Publication date: 06-07-2020
Publisher: Springer International Publishing
Published in: Geotechnical and Geological Engineering / Issue 6/2020
Print ISSN: 0960-3182
Electronic ISSN: 1573-1529
DOI: https://doi.org/10.1007/s10706-020-01444-w

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