Abstract
Chimney subsidence can cause surface subsidence (ground settlement) in the form of a pit or sag when there is a mine roof collapse in a mine entry. Surface subsidence occurs when the roof collapse propagates upward and does not choke itself off due to the associated volume expansion of the rubblized fallen materials and where no sufficiently competent rock is present to bridge the cavity. This paper contains a review and evaluation of reported case history data associated with occurrences of surface subsidence related to chimney subsidence. This analysis included investigating the chimney subsidence height potential including relative to the overburden rock conditions, extraction height, mine depth, the width of entry and the roof rock fall distance. Also, this paper provides a summary of the results of an assessment of the bridging capacity of various more common competent coal measures in the roof. This numerical analysis was performed considering linear arch conditions. Parameters which were investigated in this analysis included the competent roof rock strength, thickness, depth, and spanning distance.
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References
Al-Hashemi HM, Al-Amoudi OSB (2018) A Review on the angle of repose of granular materials. Powder Technol 330:397–417
American Institute of Mining Engineers (AIME) (1926) Report of Sub-Committee on Coal Mining to Committee on Ground Movement and Subsidence. AIME Trans 74:734–809
Barczak TM (2006) A retrospective assessment of longwall roof support with a focus on challenging accepted roof support concepts and design premises. In: Proceedings: 25th international conference on ground control in mining, Morgantown, WV, Aug. 1–3, 2006, pp 336–343
Bauer RA, Hunt SR (1981) Profile strain and time characteristics of subsidence from coal mining in Illinois. In: Proceedings. Workshop on surface subsidence due to underground mining, Morgantown, WV, pp 207–218
Bradford IDR, Fuller J, Thompson PJ, Walsgrove TR (1998) Benefits of assessing the solids production risk in a North Sea reservoir using elastoplastic modeling. In: SPE/ISRM Eurock '98 held in Trondheim, Norway, 8–10 July, 1998, pp 261–269
Chang C, Zoback MD, Khaksar A (2006) Empirical relations between rock strength and physical properties in sedimentary rocks. J Pet Sci Eng 51(3–4):223–237. ISSN 0920-4105
Church HK (1981) Excavation handbook. McGraw-Hill, New York, p 1024
Dunrud CR (1984) Coal mine subsidence Western United States. In: Holzer TL (ed) Man-induced land subsidence. Geological Society of America, Boulder
Dyne LA (1998) The prediction and occurrence of chimney subsidence in Southwestern Pennsylvania. Virginia Polytechnic Institute and State University
Ege JR (1979) Surface subsidence and collapse in relation to extraction of salt and other soluble evaporit4es, United States Geological Survey (USGS) Open-File Report 79-1666
Esterhuizen G, Karacan C (2007) A methodology for determining gob permeability distributions and its application to reservoir modeling of coal mine Longwalls. In: 2007 SME annual meeting and exhibit, Denver, Colorado, February 25–28, preprint 07-78. NIOSHTIC-2 No. 20031652. Society for Mining, Metallurgy, and Exploration, Inc., Littleton, Colorado, pp 1–6
Itasca Consulting Group (2021) FLAC3D finite difference program
Froehlich D (2011) Mass angle of repose of open-graded rock riprap. J Irrig Drain Eng Am Soc Civ Eng 137:454–461
Garrad GFG, Taylor RK (1988) Collapse mechanisms of shallow coal-mine workings from field measurements. Geol Soc Lond Eng Geol Spec Publ 5:181–192
Gibson R (2020) Personnel communication. Dated August 3, 2020
Goodman RE (1989) Introduction to rock mechanics, 2nd edn. Wiley, New York
Gray RE, Bruhn RW (1984) Coal mine subsidence – eastern united states. In: Holzer TL (ed) Man-Induced Land Subsidence. United States
Gray RE, Bruhn RW, Turka RJ (1977) Study and analysis of surface subsidence over the mined coal bed: U.S. Bureau of Mines Open-File Report 25-78, 362 p. Available from U.S. Department of Commerce, National Technical Information Service, Springfield, VA, as report PB 281 511. 374 pp
Guo W, Zhao G, Bai E, Guo M, Wang Y (2021) Effect of overburden bending deformation and alluvium mechanical parameters on surface subsidence due to longwall mining. Bull Eng Geol Enviton 80:2751–2764
Hallman D (2013) Statistical analysis of rubble height development over historic room and pillar coal mines at Rock Springs, Wyoming, 38 pp
Hunt SR (1980) Surface subsidence due to coal mining in Illinois. Ph.D. thesis presented to the University of Illinois at Urbana-Champaign
Karfakis MG (1986) Chimney subsidence – A case study. In: Proceedings of the 27th U.S. smyposium on rock mechanics, rock mechanics: key to energy production, 3–25 June, AIME, Tuscaloosa, pp 275–282
Karfakis Mario G (1987) Mechanism of chimney subsidence over abandoned coal mines. In: Proceedings of the 6th international conference on ground control in mining, 9–11 June, Morgantown, WV, pp 195–203
Maize ER, Greenwald HP (1939) Studies of roof movement in coal mines, Crucible Mine of the Crucible Fuel Co., US Bureau of Mines Report of Investigations 3506
Marino GG (1985) Subsidence damaged houses over Illinois room and pillar mines. Ph.D. thesis, University of Illinois at Urbana-Champaign, Urbana, IL
Marino GG (1988) Analysis of the initial collapse of the overburden over longwall panels using subsidence data. In: 7th international conference on ground control in mining, West Virginia University
Marino GG, Zamiran S, Talebi M (2020) Investigation of the horizontal displacement of ground surface due to longwall mining. Geotech Geol Eng 38:5373–5387
Matheson GM (1990) A probabilistic function for prediction of chimney subsidence sinkhole development. In: Proceedings, mine subsidence-prediction and control, AEG 33rd annual meeting, October 1–5, Pittsburgh, PA, pp 233–246
Ofoegbu G, Read R, Ferrante F (2008) Bulking factor of rock for underground openings. Draft prepared for U.S. Nuclear Regulatory Commission Contract NRC 02-07-006, February 2008
Pappas DM, Mark C (1993) U.S. Department of the Interior, Bureau of Mines, report of investigations 9458, 1993 Jan, pp 1–39
Peng SS, Chiang HS (1984) Longwall mining. Wiley, New York City
Piggott RJ, Eynon P (1977) Ground movements arising from the presence of shallow abandoned mine workings. In: Geddes JD (ed) Large ground movements and structures. Halsted Press, New York, pp 749–780
Poulos HG, Davis EH (1973) Elastic solutions for soil and rock mechanics (Series in soil engineering). Wiley
Price DG, Malkin NB et al (1969) Foundations of multi-story blocks with special reference to old mine workings. J Eng Geol 1(4):271–322
Sahu P, Lokhande RD (2015) An investigation of sinkhole subsidence and its preventive measures in underground coal mining. Procedia Earth Planet Sci 11:63–75
Salmi EF, Karakus M, Nazem M (2019) Assessing the effects of rock mass gradual deterioration on the long-term stability of abandoned mine workings and the mechanisms of post-mining subsidence—a case study of Castle Fields mine. Tunn Undergr Space Technol 88:169–185
Trueman R (1990) A finite element analysis for the establishment of stress development in a coal mine caved waste. Min Sci Technol 10:247–252
United States Department of Interior Bureau of Reclamation (USBR) (1963) Hydraulic model of studies of the river outlet works at Oroville Dam, October 11. https://www.usbr.gov/tsc/techreferences/hydraulics_lab/pubs/HYD/HYD-299.pdf
Unrug KF (1982) Roof falls and caving in longwall mining operations. In: Proceedings of the 2nd conference on ground control in mining. Department of Mining Engineering, West Virginia University, Morgantown, West Virginia, pp 45–52
Waltham T, Bell F, Culshaw M (2005) Sinkholes and subsidence, karst and cavernous rocks in engineering and construction. Praxis Publishing, Chichester
Whittaker BN, Reddish DJ (1989) Subsidence occurrence, prediction and control. Elsevier, Amsterdam
Young LE, Stoek HH (1916) Subsidence resulting from mining. University of Illinois Engineering Experiment Station, Bulletin 91
Zamiran S, Osouli A (2015) Subsidence and stability investigation of an Illinois Coal Mine. In: 13th international congress on rock mechanics, Montréal, QC
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Marino, G.G., Zamiran, S. & Almiron, F. An Overview of Chimney Subsidence Above Coal Mines. Geotech Geol Eng 40, 5701–5715 (2022). https://doi.org/10.1007/s10706-022-02242-2
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DOI: https://doi.org/10.1007/s10706-022-02242-2