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2012-09-14
1
Ground Support in “Deep” Underground Mines Brad Simser – Ground Control EngineerNote – photos are from various mines from past 20 years – content represents viewpoint of the author
What is deep?
“if observations indicate that a mine experiences stress-driven failures in a significant proportion of its excavations” Potvin, Hadjigeorgiou, Stacey, Challenges in Deep and High Stress mining.
standard safety factor design calculations – e.g. weight of the wedge versus capacity of the bars – doesn’t cater for all the potential problems…. B.S.
- Deformation driven failure (especially squeezing ground), bursting (dynamic loads),Shearing for bolts designed as pure tensional elements, un-raveling around the bolts…
Intense stress fracturing of hard igneous rock Pre-mining sigma1 ~ 70 MPa but stress raiser from local faulting
~1.5km
Stress fracturing exposed by underhand c & f
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Example of fracturing/looseningAround shallow opening
Open cut exposed old room &Pillar coal mine
Stress/strength
Mining layouts can create “deep”Conditions in otherwise decentGround
Sill pillars, NPV designs….
“Deep” mining is a relativeterm
Deep in the Ground Control context - ? Stuff that accelerates hair loss
Don’t want updated photo
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Ground Support Design
• need some calcs/rational behind the support design• reality is numerous assumptions go into the calcs
support element static dynamic characteristic deformation limit source of informationbolt/liner kN kN/m2 kJ kJ/m2 mm#6 gauge mesh 26 5.0 187 Canadian Rockburst Support Handbook 1996#4 gauge mesh 38 7.5 212 Canadian Rockburst Support Handbook 1996#6 gauge reinforced SC 50 7.5 80 Canadian Rockburst Support Handbook 1996fibrecrete 25 2.5 40 Canadian Rockburst Support Handbook 1996rebar 20mm 180 9.5 31 CANMET average split tube and plate hit for dynamicrebar 22mm 232 12.2 31 estimated by ratioing up 20mm resultssoft yielding bolt 55 30.0 695 CANMET mid stiffness yielding bolt 95 43.0 750 CANMET steel stretch bolt 1 256 45.0 187 CANMET steel stretch bolt 2 279 56.0 225 CANMET friction type 1 50 10.0 140 Canadian Rockburst Support Handbook 1996inflatable type 1 85 10.0 125 Canadian Rockburst Support Handbook 1996
Sample factor of safety calculations for support systems – component capacities• have to decide whether you use averages, lower limits, take it to max displacement…
Numbers used to be very hard to find – CANMET, WASM dynamic testing programsGoing a long way to fill in the blanks, as well as earlier work by Ortlepp/StaceyKaiser/Tannant etc….
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bolt spacing elements system capacity F of S F of S shear failure in boltm m kN/m2 kJ/m2 static dynamic static dynamic
1 1 22mm rebar, #4 gauge mesh 270.0 19.7 6.1 1.0 4.0 0.71.2 1.2 22mm rebar, #4 gauge mesh 199.1 16.0 4.5 0.8 3.1 0.61.5 1.5 22mm rebar, #4 gauge mesh 141.1 12.9 3.2 0.6 2.3 0.5
1 1 22mm steel stretch, #4 gauge mesh 317.0 63.5 7.2 3.1 4.7 2.01.2 1.2 22mm steel stretch, #4 gauge mesh 231.8 46.4 5.2 2.3 3.5 1.51.5 1.5 22mm steel stretch, #4 gauge mesh 162.0 32.4 3.7 1.6 2.5 1.1
1 1 22mm rebar, #4 gauge mesh, +SC first 295.0 22.2 6.7 1.1 4.6 0.91.2 1.2 22mm rebar, #4 gauge mesh, +SC first 224.1 18.5 5.1 0.9 3.6 0.71.5 1.5 22mm rebar, #4 gauge mesh, +SC first 166.1 15.4 3.8 0.8 2.8 0.7
1 1 friction1/#4gauge second pass 22mm rebar 320.0 29.7 7.2 1.5 4.7 1.01.2 1.2 friction1/#4gauge second pass 22mm rebar 233.8 22.9 5.3 1.1 3.5 0.81.5 1.5 friction1/#4gauge second pass 22mm rebar 163.3 17.4 3.7 0.9 2.6 0.7
1 1 inflatable1/#4gauge second pass 22mm rebar 355.0 29.7 8.0 1.5 5.2 1.01.2 1.2 inflatable1/#4gauge second pass 22mm rebar 258.1 22.9 5.8 1.1 3.9 0.81.5 1.5 inflatable1/#4gauge second pass 22mm rebar 178.9 17.4 4.1 0.9 2.8 0.7
1 1 softyield/#4gauge/22mm rebar 325.0 49.7 7.4 2.5 4.8 1.61.2 1.2 softyield/#4gauge/22mm rebar 237.3 36.8 5.4 1.8 3.6 1.21.5 1.5 softyield/#4gauge/22mm rebar 165.6 26.3 3.8 1.3 2.6 0.9
1 1 midyield/#4gauge/22mm rebar 365.0 62.7 8.3 3.1 5.3 2.01.2 1.2 midyield/#4gauge/22mm rebar 265.1 45.9 6.0 2.3 3.9 1.51.5 1.5 midyield/#4gauge/22mm rebar 183.3 32.1 4.2 1.6 2.8 1.1
Sample calculations – numbers all open to debate
Safety factor – load/capacity
Load is educated guess – in this example 4.5 t/m2 dead weight20 kJ/m2 dynamic load
Roughly 5x5 opening with fracture zone ~1/3 span (dead weight)Whack that at 3m/s
Ortlepp & Stacey drop testing on supportsystems
Lots of issues with safety factorApproach, especially for dynamic Support
-Soft retention (mesh, TSL…)-Relatively stiff bolts-Can’t act in perfect unison- so how do you add up the capacities?
- component testing can’t addressthis in isolation
-System testing very expensiveAnd difficult, how do you accountfor load/transfer energy loss?
-Blasting always tough to get right(ACG Heal et al probably came closest)
-In situ – shearing, local strain energy,deformation sucks up system capacity, QA/QC, corrosion………
Excellent work but can’t get clean kJ/m2
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Some of the assumptions / issues buried in the safety factor approach
tunnel
Zone of influence around each boltSo there is a practical bolt spacing to ensure liner doesn’t get over loaded
1 giga J bolt can satisfy the math…. But one bolt won’t work
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Load/deformation characteristics of retaining elements (screen) and holdingElements (bolts) very different – reality is mesh will balloon outWell beyond the bolts, especially chainlink
Stiffness contrast between bolt and surface support can be problematic- Case for yielding tendons Thanks rick
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FS46in 33mm holeoops
Some safety factor erosion factors
-Installation quality
-corrosion
Heavily wrapped post pillar with remote scoop inadvertently scraping off support
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Speed wobbles in three different bursts, three different mines, three distinctly different rockmasses
Shearing in the stress induced fracture zone pre-dynamic loading can cause bar lock up – for example many yielding bolts use toe anchor plowing mechanism which is verified by 900 tensile testing.
Never a perfect world underground.
Hand model = rick
In the “deep” mine context, more than just gravity loading, also have to cater for on going deformation, in situ stresses plus the influence of mining…
Planned back
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Rockmass bulkingSlowly uses upDeformation capacityOf support systems
Shotcrete and rebarGood at resistingBulking, limitdilation
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However S/C notoriouslyLimited under highdeformation or bursting
Fibres only go so far, material is fundamentallybrittle
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Mesh can handle a fair amount ofBulking
However – the problem is a fundamental change in how the ground support interacts
Most bolts are friction bolts, dilatedmaterial puts low confinement on the tendon… so you end up with glorifiedrockbolts, anchor to solid, hold at theplate….
Thanks rick
For more extremeGround movement150x150mm platesAnd fibrecrete notEnough retainmnet
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Clearly the use of better load spreaders such as mesh plates, straps, butterfly plates canMake a huge improvement
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Rebar and cables are still essentially friction bolts, shaking loose rock around themWithout excellent retainment system, results in more naked tendons than broken tendons
Use of mixed mode ground support
-Stiff support to limit dilation / bulking- keep laminated beam- confinement around the bolts
- yielding support to handle bursting / squeezing
-S/C is expensive, limited in deformation capacity- but 100% coverage and very effective at resisting dilation, blast damage, equipment damage…
- more work to do to quantify the cost/benefits of different approaches- tight bolting? Mix of soft + stiff bolts, different surface support….
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Mesh reinforced S/C one step upExample of blow out where the screenReinforcement stopped
Some deep mines are going to screenOver shotcrete – S/C to keep groundTight, mesh to take over if bursting orHigh deformation takes place
Example of bolterMining, S/C stopsThis in most cases
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ACG (Potvin) High energy absorption mesh
Old school safety nets = chainlink or expanded metal mesh combined with lacing, empirically works well but expensive because difficult to automate
Upper right – ACG newer version (easier to mechanize)
Dynamic loading is more complex – more guess work in SF calculation required
Potentially over looked phenomenon
Stored strain energy local to the drive• damage is often not closest opening to the event• often can’t explain observed ejection velocity versus ppv predicted from magnitude / distance relationships• coiled spring that gets released by far field seismic wave
wave amplification around fracture zone interface & free surface• observe the effects, but may not have good enough understanding to quantify• likely some earthquake engineering literature to delve into…
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A recognized omission from the 1996Canadian Rockburst Support HandbookIs the influence of strain energy around the excavation (coiled spring)
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Sub level cave
Eventually gets deep enoughWhere high stresses hitMain haulages
Upper left/lower rightCorner of strike drivesHigh stress
Coil spring (strain energy released by seismic event) Examples…..
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Large bump caused damage over Long section of strike drive(coiled spring triggered by fault slip event)
Hard to see butFloor heave in Lower right corner
Sill elevations in horizontal Stress field, steep deposit
Eventually get enough verticalLoad in draw point pillars asOverall extraction progresses
Can be ticking time bomb
Pillar burst mechanismIs about stored strainEnergy, bump sometimes Is just trigger
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Mn 2.0 32m away, had toBe significant strain energyStored locally, bump released coiledspring
Seismic Wave amplification
Google search yields loads of references in earthquake engineering
“frequency-dependent amplification of seismic waves by nearsurface low velocity layers is a well known phenomenon”
Mn2.4 30mAway
Often seemsLike fractureZone gets spit out
PPV’s estimated from Magnitude & distance usually low versus observed ejection velocity
e.g. HedleyFormula yields0.33m/s, but rockBlew off the wall(a few m/s)
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Lots of examples of seismic waves hitting underground openings (see “Rock Fracture and Rockbursts – an illustrative study” Dave Ortlepp) – but S/C posts provide some of the clearer visuals because they are stiff and connected to floor and back
Dynamic ucs testing
Contradictions
-Good to keep rubble in place to dampen the blow of a rockburst- in some cases better not to de-bag the screen and scrape to solid- rubble zone doesn’t store local strain energy- but bolts become glorified mechanical bolts hanging the loose to toe anchor
- How do the surface waves interact with both the fracture zone (low velocity layer) and the free surface (Raleigh & love waves…)
- how much amplification do we really get?
Ideally keeping the fracture zone tight (laminated beam) is best-Still fractured rock so won’t store local strain energy- reduces naked tendon potential- Help rock support itself
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Conclusion 1
Standard safety factor calculations for support design in deep mining
• ball park estimates
• Snapshots in time
• deformation eats up capacity• dynamic and static
Light at the end of the tunnel – empirical experience
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Dave Black photo
Empirical experience has some success stories (Kidd, Brunswick, Sudbury, others….) - In this case floor heaved +60cm, destroyed 1.8m diameter shotcrete posts, major cracks, Mn 3.3 ground motion hittingHigh stress area, but dynamic bolts, straps, chain-link over original rebar + shotcrete system survived
STRAPS ON SEAMS
1.6 Mn
Stiff bolts with heavy retainment (rebar, straps, mesh plates, small aperature mesh)
Thanks rick
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Late 90’s• really wasn’t off the shelf yielding bolts in Canada
• debonded cables probably closest thing
•Now a lot to choose from!
• database of dynamic testing building• CANMET
•WASM
Emerging technology
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Numerical modeling tools Getting sophisticated enough to give realistic load/displacementHistories of tendons in areas where significant mining induced stress change occurs-? Use to estimate strain energy store around openings ?- can simulate dynamic waves
3D laser scans and/or photographic methods getting accurate enough to do realConvergence monitoring – logistically a bit awkward but mm accuracy possible
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Wireless technology is now working underground to remotely measure ground controlInstruments (smart cables, extensometers, instrumented bolts…..)
Bulls eye for equipmentDamage
-Manual readings, slow- can miss critical changes between readings- improving logistics = easier to read more instruments
Enabling technology to estimate loss of support capacity with time/mining
High resolution seismic monitoring – MS-RAP type analysis to understand failingZones, failed zones (seismic dead zones), strain energy storing, sensitive structures….
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Beck/Westman image
Passive tomography utilizing recorded seismicity to track damage zones, high stress Areas (for example Westman – Virginia Tech, also Golders Montreal)
Currently some resolution problems – particularly with constant velocity model for Seismic location
Top left example – ray path goes through a significant fault (not shown) causingSlower effective velocity than constant velocity assumption, and location offsets
Top right example – blasts offset from actual drive due to ray path going around stopesAnd fractured ground causing slower velocity than assumed in location algorithm, also fringeOf array
Ray tracing algorithms (ESG, IMS), and variable velocity models are emerging, but notRoutinely applied to every event
Actual drive
Offset blast locations
Actual driveOffset blast locations
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102 t sulphides12 t fibrecrete
Thanks for your attention
Any questions?