Hydrogeochemical modelling of corrosive environment contributing to premature failure of anchor bolts in underground coal mines

Ya Peng; Wendy Timms

doi:10.1007/s11771-020-4393-z

Journal of Central South University ›› 2020, Vol. 27 ›› Issue (5) : 1599 -1610. DOI: 10.1007/s11771-020-4393-z

Article

Hydrogeochemical modelling of corrosive environment contributing to premature failure of anchor bolts in underground coal mines

Ya Peng ¹^,²
, Wendy Timms ³^,^b

Author information +

History +

PDF

Abstract

Anchor bolts are commonly used throughout underground mining and tunnelling operations to improve roof stability. However, premature failures of anchor bolts are significant safety risks in underground excavations around the world due to susceptible bolt materials, a moist and corrosive environment and tensile stress. In this paper, laboratory experiments and hydrogeochemical models were combined to investigate anchor bolt corrosion and failure associated with aqueous environments in underground coal mines. Experimental data and collated mine water chemistry data were used to simulate bolt corrosion reactions with groundwater and rock materials with the PHREEQC code. A series of models quantified reactions involving iron and carbon under aerobic and anaerobic conditions in comparison with ion, pH and pE trends in experimental data. The models showed that corrosion processes are inhibited by some natural environmental factors, because dissolved oxygen would cause more iron from the bolts to oxidize into solution. These interdisciplinary insights into corrosion failure of underground anchor bolts confirm that environmental factors are important contributors to stress corrosion cracking.

Cite this article

Download citation ▾

Ya Peng, Wendy Timms. Hydrogeochemical modelling of corrosive environment contributing to premature failure of anchor bolts in underground coal mines. Journal of Central South University, 2020, 27(5): 1599-1610 DOI:10.1007/s11771-020-4393-z

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	YanH, HeF-l, LiL-y, FengR-m, XingP-fei. Control mechanism of a cable truss system for stability of roadways within thick coal seams [J]. Journal of Central South University, 2017, 24(5): 1098-1110

[2]	WangQ, LuanY-c, JiangB, LiS-c, YuH-chang. Mechanical behaviour analysis and support system field experiment of confined concrete arches [J]. Journal of Central South University, 2019, 26(4): 970-983

[3]	ZhaoZ-h, GaoX-j, TanY-l, MaQing. Theoretical and numerical study on reinforcing effect of rock-bolt through composite soft rock-mass [J]. Journal of Central South University, 2018, 25(10): 2512-2522

[4]	VandermaatD, SaydamS, HaganP C, CroskyA. Examination of rockbolt stress corrosion cracking utilising full size rockbolts in a controlled mine environment [J]. International Journal of Rock Mechanics and Mining Sciences, 2016, 81: 86-95

[5]	LiS-c, WangH-t, WangQ, JiangB, WangF-q, GuoN-b, LiuW-j, RenY-xi. Failure mechanism of bolting support and high-strength bolt-grouting technology for deep and soft surrounding rock with high stress [J]. Journal of Central South University, 2016, 23(2): 440-448

[6]	WangH, ZhengP-q, ZhaoW-j, TianH-ming. Application of a combined supporting technology with U-shaped steel support and anchor-grouting to surrounding soft rock reinforcement in roadway [J]. Journal of Central South University, 2018, 25(5): 1240-1250

[7]	KangH-p, WuY-z, GaoF-q, LinJ, JiangP-fei. Fracture characteristics in rock bolts in underground coal mine roadways [J]. International Journal of Rock Mechanics and Mining Sciences, 2013, 62: 105-112

[8]	HadjigeorgiouJ, DorionJ, GhaliE. Support system performance under different corrosion conditions [J]. Journal of the Southern African Institute of Mining and Metallurgy, 2008, 108(6): 359-365

[9]	VandermaatD, SaydamS, HaganP C, CroskyA. Back-calculation of failure stress of rockbolts affected by stress corrosion cracking in underground coal mines [J]. International Journal of Rock Mechanics and Mining Sciences, 2017, 100: 310-317

[10]	WuS-s, ChenH-h, CraigP, RamandiH, TimmsW, HaganP C, CroskyA, HebblewhiteB, SaydamS. An experimental framework for simulating stress corrosion cracking in cable bolts [J]. Tunnelling and Underground Space Technology, 2018, 76: 121-132

[11]	KovacJ, AlauxC, MarrowT J, GovekarE, LegatA. Correlations of electrochemical noise, acoustic emission and complementary monitoring techniques during intergranular stress-corrosion cracking of austenitic stainless steel [J]. Corrosion Science, 2010, 52(6): 2015-2025

[12]	ToribioJ, ValienteA. Failure analysis of cold drawn eutectoid steel wires for prestressed concrete [J]. Engineering Failure Analysis, 2006, 13(3): 301-311

[13]	GrayP. Stress corrosion cracking of rock bolts [C]//Coal 1998: Coal Operator’ conference. University of Wollongong & the Australasian Institute of Mining and Metallurgy, 1998

[14]	WinzerN, AtrensA, SongG, GhaliE, DietzelW, KainerK U, HortN, BlawertC. A critical review of the stress corrosion cracking (SCC) of magnesium alloys [J]. Advanced Engineering Materials, 2005, 7(8): 659-693

[15]	MaH, LiuZ, DuC, WangH, LiX, ZhangD, CuiZ. Stress corrosion cracking of E690 steel as a welded joint in a simulated marine atmosphere containing sulphur dioxide [J]. Corrosion Science, 2015, 100: 627-641

[16]	WanH-x, DuC-w, LiuZ-y, SongD-d, LiX-gang. The effect of hydrogen on stress corrosion behavior of X65 steel welded joint in simulated deep sea environment [J]. Ocean Engineering, 2016, 114: 216-223

[17]	HaaseR J, HankeL D. Alkaline carbonate SCC failures at a refinery [J]. Journal of Failure Analysis and Prevention, 2018, 18(1): 153-161

[18]	CroskyA, FabjanczykM, GrayP, HebblewhiteB. Premature rock bolt failure: Stage 2 [R]. Sydney, ACARP Project, 2004

[19]	AzizN, CraigP, NemcikJ, HaiF. Rock bolt corrosion An experimental study [J]. Mining Technology, 2014, 123(2): 69-77

[20]	CraigP, SerkanS, HaganP C, HebblewhiteB, VandermaatD, CroskyA, EliasE. Investigations into the corrosive environments contributing to premature failure of Australian coal mine rock bolts [J]. International Journal of Mining Science and Technology, 2016, 26(1): 59-64

[21]	VillalbaE, AtrensA. Hydrogen embrittlement and rock bolt stress corrosion cracking [J]. Engineering Failure Analysis, 2009, 16(1): 164-175

[22]	De MeoD, DiyarogluC, ZhuN, OterkusE, SiddiqM A. Modelling of stress-corrosion cracking by using peridynamics [J]. International Journal of Hydrogen Energy, 2016, 41(15): 6593-6609

[23]	ZhuL-k K, YanY, LiJ-x, QiaoL-j, VolinskyA A. Stress corrosion cracking under low stress: Continuous or discontinuous cracks? [J]. Corrosion Science, 2014, 80: 350-358

[24]	EqueenuddinS M, TripathyS, SahooP K, PanigrahiM K. Hydrogeochemical characteristics of acid mine drainage and water pollution at Makum Coalfield, INDIA [J]. Journal of Geochemical Exploration, 2010, 105(3): 75-82

[25]	BanwartS A, MalmstræmM E. Hydrochemical modelling for preliminary assessment of minewater pollution [J]. Journal of Geochemical Exploration, 2001, 74(1): 73-97

[26]	van StempvoortD R, van der KampG. Modeling the hydrogeochemistry of aquitards using minimally disturbed samples in radial diffusion cells [J]. Applied Geochemistry, 2003, 18(4): 551-565

[27]	JakobsenR, ColdL. Geochemistry at the sulfate reductionmethanogenesis transition zone in an anoxic aquifer—A partial equilibrium interpretation using 2D reactive transport modeling [J]. Geochimica et Cosmochimica Acta, 2007, 71(8): 1949-1966

[28]	TimmsW, HendryM. Quantifying the impact of cation exchange on long-term solute transport in a clay-rich aquitard [J]. Journal of hydrology, 2007, 332(12): 110-122

[29]	BozauE, van BerkW. Hydrogeochemical modeling of deep formation water applied to geothermal energy production [J]. Procedia Earth and Planetary Science, 2013, 7: 97-100

[30]	KlapperH, BartetzkoA, LehrJ. Hydrogeochemical modelling to monitor scaling and corrosion during geothermal energy production in the north german basin [C]. CORROSION 2017. NACE International, 2017

[31]	PeáaJ, TorresE, TurreroM J, EscribanoA, MartínP L. Kinetic modelling of the attenuation of carbon steel canister corrosion due to diffusive transport through corrosion product layers [J]. Corrosion Science, 2008, 50(8): 2197-2204

[32]	CraigP, AzizN I. Shear testing of 28 mm hollow strand “TG” cable bolt [C]. 29th International Conference on Ground Control in Mining, 2010, Morgantown, WEST Virginia

[33]	ParkhurstD L, AppeloC A JUser’s guide to PHREEQC (Version 2): A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations [M], 1999

[34]	VandermaatDStress corrosion cracking of rockbolts: a laboratory based approach utilising a controlled mine envrionment [D], 2014, Sydney, Australia, University of New South Wales

[35]	LiuH-w, ChengY Frank. Mechanistic aspects of microbially influenced corrosion of X52 pipeline steel in a thin layer of soil solution containing sulphate-reducing bacteria under various gassing conditions [J]. Corrosion Science, 2018, 133: 178-189

[36]	StipaničevM, RosasO, BasseguyR, TurcuF. Electrochemical and fractographic analysis of microbiologically assisted stress corrosion cracking of carbon steel [J]. Corrosion Science, 2014, 80: 60-70

[37]	SandW, GehrkeT. Microbially influenced corrosion of steel in aqueous environments [J]. Reviews in Environmental Science and Biotechnology, 2003, 2(2-4): 169-176

[38]	AppeloC A J, PostmaDGeochemistry, groundwater and pollution [M], 2004

[39]	BiezmaM V. The role of hydrogen in microbiologically influenced corrosion and stress corrosion cracking [J]. International Journal of Hydrogen Energy, 2001, 26(5): 515-520

[40]	Water Resources Research, 2007, 43(12

[41]	EnningD, GarrelfsJ. Corrosion of iron by sulfate-reducing bacteria: New views of an old problem [J]. Applied and Environmental Microbiology, 2014, 804): 1226-1236

[42]	WuS-s, ChenH-h, RamandiH L, HaganP C, CroskyA, SaydamS. Effects of environmental factors on stress corrosion cracking of cold-drawn highcarbon steel wires [J]. Corrosion Science, 2017, 132: 234-243

[43]	ChouC-lin. Sulfur in coals: A review of geochemistry and origins [J]. International Journal of Coal Geology, 2012, 100: 1-13

[44]	StackebrandtE, StahlD A, DevereuxRTaxonomic relationships. in In Sulfate-reducing bacteria [M], 19954987

[45]	DinhH T, KueverJ, MuïmannM, HasselA W, StratmannM, WiddelF. Iron corrosion by novel anaerobic microorganisms [J]. Nature, 2004, 427(6977): 829-832