1245695019use of Rock Properties
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Transcript of 1245695019use of Rock Properties
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1International Society for Rock Mechanics
Rock Properties and Their Role in RockCharacterization, Modelling and Design
Prof. Dr. Reat UlusayHacettepe University, Turkey
President of the ISRM Commission on Testing Methods
CONTENT
- ROCK MATERIAL, ROCK MASS AND SIZE OF THE PROBLEM IN ROCK ENGINEERING
- MAIN DESIGN AND MODELLING METHODOLOGIES IN ROCK ENGINEERING
- ACCESS TO THE ROCK
- THE USE OF ROCK PROPERTIES IN CHARACTERIZATION, DESIGN AND MODELLING IN ROCK ENGINEERING
Despite the global nature of todays problems, Geotechnology alsoincluding ROCK ENGINEERING has remained divided into disciplinessuch as mining, civil and petroleum engineering, geology andgeophysics.
REMIFICATINOS OF GEOTECHNOLOGY
(Amadei et al., 2000)
MAIN ARAES OF INTEREST IN ROCK ENGINEERING
) y Rock Slopes Shafts & Tunnels Foundations Dams
Caverns Mining Geothermal EnergyRadioactive Waste
Disposal
(Rearranged from Hudson, 1989)
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2Historical and recent man-made underground and semi-underground rockstructures and settlements in the soft tuffs of the Cappadocia Region of Turkey
Church
Congress center under constructionPoliceofficein a fairychimney
Cliff settlement
Rock-hewnhotel
Underground city
Rocks and rock-hewn openings have been used as a construction materialand settlement since down of civilization.
(Photos: R. Ulusay)
Different structures have been built on, in or of rock, includinghouses, bridges, dams, tunnels and caverns.
Millau Viaduct (France)Vaiont dam (Italy)
Hoosac Tunnel (USA)Saint Gotthardt Tunnel (Alps)
Rocks differ from most engineering materials because they containdiscontinuities. Therefore, a clear distinction must be madebetween rock material and rock mass.
When dealing with the mechanical behaviour of solids, a commomassumption is that they are:
. Homogeneous
. Continuous
. Isotropic
But rocks are much more complex and their physical andmechanical properteis vary according to scale.
(Eberhartd, 2009)
ROCK MATERIAL A continium or polycrystalline solid betweendiscontinuities consisting of an aggregate of minerals or grains.
Its properties are governed by the physical properties of the materialsof which it is composed.
Terzaghis intact rock
Tunnel
Rock massROCK MASS An assemblageof rock blocks separated bydifferent types of geologicaldiscontinuities.
Intact rock
Discontinuity
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3MASSIVE ROCK
. Rock masses with few discontinuities, OR
. Excavation dimension < discontinuity spacing
Because rock masses are discontinuous and varibale in space, it is important to choose the right domain that is representative of therock mass affected by the structure analyzed.
JOINTED OR BLOCKY ROCKJOINTED OR BLOCKY ROCK Rock masses with moderate number of Rock masses with moderate number of
discontinuitiesdiscontinuities Excavation dimension Excavation dimension >> discontinuity discontinuity
spacingspacing
HEAVILY JOINTED ROCKHEAVILY JOINTED ROCK Rock masses with a large number of Rock masses with a large number of
discontinuitiesdiscontinuities Excavation dimension Excavation dimension >>>> discontinuity discontinuity
spacingspacing
When the problem domain ismuch smaller than rock blocks(excavation of rock by drilling)
Intact rock material
When the structure is much largerthan the blocks
Rock mass properties
Discontinuity propertiesgovern
Relation of Discontinuity Spacing and Size of the Problem
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MAIN DESIGN AND MODELLING METHODOLOGIES IN ROCK ENGINEERING
OBSERVATIONAL APPROACH
EMPIRICAL METHODS
ANALYTICAL METHODS
NUMERICALMETHODS/ MODELLING
KINEMATIC ANALYSIS
If necessary, as a Logistic Tool
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4The term observational method appears to have been coined by Terzaghi in the 1940s.
1. OBSERVATIONAL APPROACH
OBSERVATIONAL APPROACH provides a Learnas you go alternative.
-The procedure is to base the design on whateverinformation can be secured
- Make note of all possible diferrences betweenreality and the assumptions, then
- Based on the original assumptions, computevarious quantities that can be measured in the field
- Based on the results of the measurements, gradually close the gaps in knowledge and, ifnecessary, modify the design during construction
Example: Numerical modelling and performance monitoring for a tunnel.
(www.gpiko.ru)
IF NECESSARY CHANGE IN
DESIGN
(www.finesoftware.eu)
Monitoring
Modelling
Mainly based on previous experience as derived fromconstruction of rock structures having similar characteristicsas the one to be designed ROCK MASS CLASSIFICATION(such as RMR, Q, GSI)
2. EMPIRICAL METHODS
RMCS today form an integral part of the most predominantdesign approach INDIRECT METHODS
Rock Mass Characterization, Classification and Design
Rock massclassification
DescribeDescribe thethediscontnuitiesdiscontnuities
RMR RMR oror QQ
ClassifyClassify thethe rockrockmassmass usingusing:: EmpiricalEmpirical databasedatabase
SupportSupport requirementsrequirements
DESIGNDESIGN
Rock massbehaviour
H&B H&B FailureFailure CriterionCriterion-- mm
-- SS-- cici
GSIGSINumericalNumerical ModellingModelling, LEM, LEM
AnalysisAnalysis
DESIGN DESIGN
Stand-up time (RMR)
Line survey/Boring
(Bieniawski, 1989,
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53. ANALYTICAL METHODS
Complexity of the nature of stress has to be fully considered in thedesign of underground excavations.
The problem can be initilally simplified through the assumptions of Continuous, Homogenous, Isotropic, Linear Elastic behaviour
(CHILE)
However
Successfully used solutions, especially in those excavations at depth, where high stresses have closed the fractures and the rock mass is relatively homogeneous and isotropic.
However, for near surfaceexcavations, where the rock stressesare lower, their fractures are morefrequent,and the rock mass is disturbed and weathered, there is more concern about the validity of the CHILE.
(a) CHILE
Deep UG openings
EXAMPLES: Estimation of Radius of Plastic Zone
(Hoek & Brown, 1980)
Rock-support InteractionAnalysis
(b) LIMIT EQUILIBRIUM METHODS (LEM)
The most widely applied analytical technique used for slope stabilityassessments.
Force and/or moment equilibrium conditions for different modes offailure are examined on the basis of statics.
The typical output from LEM analyses is the Factor of Safety
FS = Resisting forces
Driving forces
FS = Shear strength
Shear stress
Tansiyon atlaev
aynasnda
Kayma dzlemi
H
ZZwv
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wpf
(a) Tansiyon atla ev tepesinin gerisinde
Slope face
Failure surface
Tension crack
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Circular F.
Planar F.Wedge F.
Toppling F.
R
These methods consist in applying the state of stress-strain in the engineering structure, with consideration given to the strength and deformability properties of the rock mass and of the discontinuities.
4. NUMERICAL METHODS / MODELLING
- A way to gain understanding of governing deformation andfailure mechanisms- Exploring alternatives rather than making absolute predictions- Making changes in the input data to see how the changes affectthe overall response of rock structure (e.g. parametric studies).
STRESS STRAIN
DISPL. u
Useful for analysis and design in cases where analytical solutions arenot available Examples
Design of high slopes, rock burst prone tunnels, soft rock slopes
MAIN PURPOSES
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6Numerical methods of stress and deformation analysis fall into two categories
INTEGRAL METHODS- Only problem boundary is definedand discretized- Restricted to elastic analyses
DIFFERENTIAL METHODS-Problem domain is defined and
discretized-Non-linear and heterogeneous
material properties accomodated
As a continuum, the failure path passes throughthe rock mass.
As a discontinuum, the failure surface is dictatedmore directly by the presence of pre-existingdiscontinuities.
BoundaryElement Method(BEM)
FEM, FDM,DEM
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DIFFERENTIAL METHODSContinuum Methods
- Rock mass bahaviour is representedas a continuum- Approximations to the connectivity of elements, and continuity of displacements and stresses betweenelements
Discontinuum Methods
Rock mass is represented as assemblageof distinct interacting blocks or bodiesthat are subjected to external loads andare expected to undergo significantmotion with time.
Blocks are subdivided into finite-difference mesh which follows linaeror non-linear stress-strain laws
Finite Element Method-FEM (PHASE)Finite Difference Method-FDM (FLAC)
Distinct Element Method-DEM (UDEC)
Time step 1 Time step 2 Time step 3
Time step 4 Time step 5
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Numerical methods include consideration of the followings, dependingon the type of the model used (continuum or discontinuum):
GeologyDiscontinuities (spacing/persistence)
Constitutive equations & failure criteriaGroundwater pressure/Seismic loadingIn-situ stresses and external loads
Material and mass properties (intact/discontinuity)ROCK
PROPERTIES
FEM-FDM DEM FEM-BEM
Continuum Discontinuum Continuum
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METHOD OF KINEMATIC ANALYSIS(A Logistic Tool)
Rock Mass Failure MechanismsStructurally-controlled
Stress-controlled
Structurally-controlled instability: Blocks formed by discontinuitiesmay be free to either fall or slide from the excavation under a set of body forces.
Analysis of kinematic addmissibility of poteantial wedges or planesintersecting the excavation face(s) KINEMATICAL ANALYSIS
Wedge failure in slopes
Block falls in underground openings
J1
J2
J1J2
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7Stereographic Projection Technique:
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Discontinuity
Slope
Kinematic analysis of blocks in U/Gopenings
Kinematic analysis for rock slopes
(Hoek & Brown, 1980)
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ACCESS TO THE ROCK
KZ
KZ
Rock Exposures Borehole Cores Borehole Wall Images
Intact rockBlock samples for testing
Intact rockCores for testing
Discontinuity masurementsfor Rock Mass
Characterization
Measurement of disconttinuityproperties is limited and no possibility
of measuring rock mass properties
Flat-jack stress determination,larger-scale modulus and
permeability tests
In situ stress on corescan not be measured
Indirect methodsare nedded forassessing the
rock massproperties
There are always limitations on resources Therefore, when optimizing the rockcharacterization procedures it is necessary to consider the requirements and to choosethe rock access method and testing techniques in accordance with the engineeringobjective.
INTACT ROCK AND ROCK MASS PROPERTIESCOMMONLY USED IN ROCK ENGINEERING
1. Determined from laboratory tests (Intact Rock and Discontinuites):
(a) Classification and characterization of intact rock(i) Porosity, unit weight, water content, absorbtion
(ii) Hardness, abrasivity(iii) Durability(iv) Point load strength index(v) BPI
(vi) UCS and deformability(viii) Sound velocity (vp, vs)(ix) Permeability
(b) Rock engineering design(i) Shear strength of intact rock
(ii) UCS and deformability (E, , G, K) (iii) Shear strength and stiffness of
discontinuities(iv) Tensile strength (direct or indirect)
.
(www.sfu.ca/~tafgrc/Courses/Easc313)
2. Determined from in-situ measurements and tests (Rock Mass)
(a) Characterization of rock mass(i) Properties of discontinuities(ii) In-situ sound velocity(iii) Properties obtained from geophysical borehole tests
(b) Design(i) In-situ deformability(ii) Rock mass strength(iii) Field permeability(iv) In-situ stresses
(www.sfu.ca/~tafgrc/Courses/Easc313)
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8TAILORING TESTING TO ENGINEERING REQUIREMENT
Objective: To tailor the testing to the engineering objective by consideringa number of testing methods.
Importance of rock mechanics parameters for HYDROELECTRIC SCHEME PRESSURE TUNNEL design
(Hudson & Harrison, 2000)
In situ stress is most important and should be determined
Slope or surface blasting case: Not an importantparameter
Rock engineersmust decide
Whether theyare going to
make particularmeasurementson the basis of
the overallobjective
ANOTHER IMPORTANT ISSUE !
Rock engineer should consider whether emphasis is to be placed on INDEX TESTS, FUNDAMENTAL TESTS or COMBINATION OF THE TWO
INDEX TESTS Cheap, performed quickly Do not determine an intrinsicproperty
UCS= k Is50
Point LoadTest FUNDAMENTAL TESTS
More expensive, time consuming
Measure the property directly
UCS
Carry out a few UCS tests and more PLT, and use the calibrated values
HOW WE CAN CHARACTERIZE ROCK MASSESAND ESTIMATE THEIR STRENGTH?
For the determination of rock mass properties we have two alternative ways:
(a) via the properties of the intact rock and the properties of the discontinui-ties which together make up the rock mass properties OR
(b) Via the properties of the rock mass as measured or estimated directly(STRENGTH, DEFORMABILITY & PERMEABILITY)
A) ROCK MASS PROPERTIES DETERMINED FROM IN-SITU MEASUREMENTS
Because rock masses are usually anisotropic, essential device must bothapply load and measure displacement in different radial directions.
Install some form of loading within the borehole to obtain force-displacementcurve and estimate the associated elastic parameters of the rock
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(Hudson & Harrison, 2000)
Testing of strength of rock mass is difficultbecause of the high loads involved. Alsotime consuming and expansive tests
GOODMAN BOREHOLE JACK
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9PLATE LOADING TEST
On a surface of rock exposure Underground
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Hysteresis is directly associatedwith discontinuities
B) CHARACTERIZATION OF ROCK MASSES AND CLASSIFICATION
Depending on the rock mass classification used, determinediscontinuity properties
Scan-line survey
(Hudson, 1989)
BoreholeOutcrop
S
KZ
KZ
Orientation Spacing
AperturePersistence
Roughness (JRC)
Joint wall strength(JCS)
Weathering
Block size
RQD
ROCK MASSCLASSIFICATION(RMR, Q and others)
Set number
>10 cm
A Basic RMR = R ( ci) + R (RQD) + R (spacing) + R (JC) + R (GW)RMR SYSTEM
Adjustments(Orientation, blasting etc.)
Final RMR
Q=(RQD/Jn) (Jr/Ja) (Jw/SRF)Q SYSTEM
Q
(Support & Span)
RMR
Estimation of Erm fromclassification
(Support)
Stand-up time
JRC, JCS
Disc. Stiffness
(Serafim & Pereira, 1983)
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(Bienaiwski, 1989)
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C) ROCK MASS STRENGTH (Hoek & Brown Failure Criterion)
a
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'3
bc'3
'1 sm
+
+=
Generalized H&B equation
=
mib b
100GSIexpmm
=
sb100GSIexps
D1428bm =
D39bs =
( )3/2015/GSI ee61
21a +=
(Barla & Barla, 2005)
GEOLOGICAL STRENGTH INDEX (GSI)(Hoek, 1999) (Snmez & Ulusay, 2002)Quantitative GSI ChartOriginal GSI Chart
ROCK MASS
Ground response
ROCK MASS
Ground response
How to incorporate modeof failure and rock massstrength
Slope
UG
UG
Slope
IN SITU SOUND VELOCITY
Closely reated to rock mass characteristics and one of the most importantindex properties Seismic Characterization Method
(www.winona.edu)
(Whitley, 1990)
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Vp-Q-RQD- relationships for hard, near-surface, low porosity rock masses
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Relationships between Vp androck mass characteristics
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Intact samples of rock may be selected for index testing
- To further aid in geological classification and as indicators of rock massbehavior
- To provide a measure of the quality of the rock,- To indirectly estimate fundamental properties by empirical relationships- They are not directly used in design.
INDEX PROPERTIES OF ROCK MATERIAL
Water Content: Indirect indication of porosity of intact rock or clay content of sedimentary rock.
Unit Weight: Indirect indication of weathering and soundness, and is usedto estimate vertical stress
h v = h
Porosity: Indirect indication of weatheringand soundness, and governs permeability
Rebound Number:- Index of relative hardness and quality of rock mass on the exposedsurface when the rock is fragmented- Relative hardness and indirect strength of intact rock
Weak and highly weatheredrocks
Care is necessary
Abrasivity: Measures the abrasiveness of a rock material against other materialse.g., steel. It is an important measure toestimate wear of rock drilling and boringequipment.
(Deere & Miller, 1966)
Point Load Strength Index: Indirect method to determine unconfinedcompressive strength (UCS)
c = kIs50 k=5-52 (?)
As a classification parameter in RMR system
(Bieniawski, 1989)
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Block Punch Strength Index (BPI): To indirectly estimate the UCS
UCS= 5.1BPIc
BPI (MPa) < 1 Very weak1 - 5 Weak5 - 10 Moderate10 - 20 Medium20 - 50 High> 50 Very high
c Strength Class
(Ulusay et al., 2001)
Durability: Index of weatherability (degradability) of rock exposed in excavations.
Particularly important in soft andclay-bearing rocks (may cause collapse)
Outcrop
UG opening
Pillar
The loss of sample weight is a measure of the susceptibility of the rock to the combinedaction of slaking and mechanical erosion.
SLAKE DURABILITY TEST
Sound velocity: Closely reated to rock properties and one of the mostimportant index properties. They provide estimates of rock properties and/orare used as an index in their own right indicating anisotropy and/or inhomogenity
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Estimation of dynamic elastic properties:
(Vp)
(Vs)
(Sassa et al., 1988)
NON-DESTRUCTIVE TEST
(field / lab)2 = velocity index (an indicator of intensity of discontinuities)
UNIAXIAL COMPRESSIVE STRENGTH (Intact Rock)
- UCS is a rock property most oftenly used to characterize the mechanicalbehavior of rock. - It is most useful as a means for comparing rocks and classifying theirlikely behavior as an index property.
1. CLASSIFICATION OF INTACT ROCK
ci = F/A
F
Primary index testfor strength and
deformability of intactrock
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2. CHARACTERIZATION(a) Input Parameter for Rock Mass Classification
RMR System(Bieniawaski,
1989)
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(b) As an intact rock parameter to be used by the empirical rockmass failure criteria (ci)
Generalized Hoek-Brown failure criterion:
1= 3+ ci (mb (3/ ci)+s))a
(c) First estimate of the tensile strength
t = - ci /10
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(d) Estimation of UCS and deformation modulus of rock masses:
crm = (sci)0.5UCS of rock mass:Deformation modulus of rock masses:
Erm= (ci / 10)0.5 10(GSI-10)/40 (Hoek & Brown, 1997)Erm = (1-(D/2)) (ci / 100)0.5 10(GSI-10)/40 (Hoek et al., 2002)Erm= 0.001 [ ((Ei/ ci) ((1+RQD/)100) /WD]1.5828(Gkeoglu et al., 2003)
(e) Estimation of the tensile strength of intact rock with the H-Bstrength criterion:
t = 0.5ci [mi- (mi2 + 4)0.5]
Erm = 10 (Qci /100) 1/3 (Barton, 2002)
3. IN DESIGN AND MODELLING
(a) As a design parameter of rockstructures subjected to uniaxialcompressive stresses, such as pillars (intact or rock mass UCS)Strength of pillar is a function of material strength anddistribution of stresses in pillar.
Compare the computed stresses with estimated rock massstrength in discontiuum media or intact rock strength in weakand not jointed media
c Pillar stresses
Pillar
Pillar
(Hoek & Brown, 1980)
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(b) In numerical codes such as UDEC, simulating the response of discontinuous media (jointed rock mass) subjected to either staticor dynamic loading UCS is as one of the parameters used by Barton-Bandis model.
For estimation of initial normal stiffness
Kni= -7.15+1.75 JRC+0.02 (JCS/e)
e (JRC (0.04 ci)-0.02) Discontinuity aperture (mm)
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(Zhang, 2005)
(c) Rock fragmentation and rock cutting
Fractures by disc cutters:-Effect of rock strength on tool forces Fnormal/c =0.15p-0.21(Snowdoown et al., 1982) (p:Penetration, mm)
-The thrust force affecting penetration (Roxborough & Philips, 1975):
Ft= 4 c tan (/2)(Dp3-p4))0.5(D: Disc diameter, mm)
In rock indentation assessments
(d) Rock-support interaction analysis (as an input parameter)
(Hoek & Brown, 1980)
TENSILE STRENGTH
(a) Analysis of rock structures subjected to tensile stresses, such as wide roof spans
ti = P/AFor underground stability, the tensile strength is not assignificant parameter as the UCS for rocks. Generally, tensile rock strength is low enough when rock is in tension,it splits and tensile stresses are relieved.
In jointed rock masses, the jointing may very well eliminate the tensilestrength of the rock mass, in which case the in situ rock should be considered as having zero tensile strength.
1) DESIGN
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(b) Input parameter in numerical analyses:
- In analysis of flexural toppling:As an input parameter Bending of the slabs induces tensile cracking in their upper face.
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- Continuum models such as FLAC (Mohr-Coulomb model )- Discontinuous model such as UDEC (Mohr-Coulomb model)
(Hoek & Bray, 1977)
DEFORMABILITY PROPERTIES
1. CLASSIFICATION (Intact rock)
A) MODULUS OF ELASTICITY OF INTACT ROCK AND MODULUS OF DEFORMATION OF THE ROCK MASS
(Deere & Miller, 1966)
Modulus Ratio
(b) Estimation of rock mass deformation modulus from that ofintact rock
Nicholson & Bieniawski (1983)
Mitri et al. (1994)
Sonmez et al. (2004)
Hoek and Diederichs (2006)
Sonmez et al. (2006)
Em = f(Ei)
2. DESIGN
(a) Estimation of deformations in various rock engineering designs
- Estimation of deformations around underground openings/Rock-support(analytical) interaction analysis (Analytical solutions)
If the medium is jointed rock mass Use Erm
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-Settlement for founadtions in homogeneous, isotropic rockconditions v = (CdqB(1-2))/E
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(b) An important input parameter in numerical methods:
Depending on the continuum and discontinuum media under investigation,Youngs modulus of the intact rock or deformation modulus of rockmass is used by all models for stress and deformation analyses such as PHASE, FLAC and UDEC for different types of rock engineering problems
- Other Elastic Properties:
G (Shear modulus)= E/2(1+) K (Bulk modulus)= E/(3(1-2)Describes the material's responseto shearing strains.
G
dx
y
Shear strain
Shear stressMeasures the substance's resistance to uniform compression
(B) POISSONS RATIO
It is a mechanical property playing a role in the deformation of elasticmaterials and utilized in rock engineering problems associated withthe deformation of rocks such as an input parameter for the numericalstress analyses.
Poissons ratio for rock masses is not required in majority of rock engineeringapplications. Indeed, in Overcoring Methods employing CSIR doorstopper,USBR borehole deformation gauge, CSIR triaxial strain cell and CSIROhollow incluison cell, the value of Poissons ratio of intact rock is requiredfor evaluation and interpretation of mesaurements.
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Lateral strain
Axial strain
- There is no correlation between the values of Poissons ratio of rockmass and intact rock.
- (rockmass) 1.2 (intact rock) (Kulatilake et al. (2004)
The intact rock value constitutes a limit for the values that may be assumed by the jointed rock mass (Gercek, 2008)
1. CHARACTERIZATION
Intact rock classification(Gercek, 2008) can be usefulfor a qualitative assessment of labortaory test results. Thisclassifications are applicableto isotropic rocks only.
(Gercek, 2008)
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2. DESIGN (Analytical-Numerical)
Poissons ratio of the medium influences the distribution of stresses in somesolutions that are widely applied to geomechanics problem.
(a) In analytical solutions: Estimation of deformations aroundunderground openings Rock-support (analytical) interactionanalysis ( of rock mass)
(Hoek & Brown, 1980)
(d) An important input parameter used by numerical methods:
Depending on the continuum and discontinuum media under investigation,Poissons ratio of the intact rock and/or deformation modulus of rockmass is used by all models for stress and deformation analyses such as PHASE, FLAC and UDEC.
Poissons ratio influences the normalized elastic radial displacements aroundthe excavation face of a circular tunnel located in a hydrostatic in-situ stressfield
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SHEAR STRENGTH
A) SHEAR STRENGTH OF INTACT ROCK
- DESIGN: Particularly those of weak rocks in numerical methods
B) SHEAR STRENGTH OF DISCONTINUITIES
Cohesion and Friction Angle: Commonly used properties in dicontinuum media (both as peak cp & p, and residual cr & p)
Planardiscontinuities
Peak
Residual
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Undulateddiscontinuities
Bartons criteria
In-situ shear strength determination
(ISRM, 1981)
Input parameter for analytical, numerical and kinematicmethods of analysis
200
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Discontinuity
Slope
(a) Kinematic Analysis of Structurally-Controlled Slopes
EXAMPLES
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6
)
(b) Analysis of Structurally-Controlled Instabilities in Underground Openings
(Hoeks Corner)
(Hoek & Brown, 1981)
(c) In Analytical Methods:
Example 1: Structurally-controlled rock slopes
Tansiyon atlaev
aynasnda
Kayma dzlemi
H
ZZwv
u
wpf
(a) Tansiyon atla ev tepesinin gerisindeTension crack in upper surfaceof slope
Failure surface
Slope face
Geometry of slope with tension crack in upper slope surface
pp
pp
vCossinWtan)vSinuWCos(cA
F ++=
Discontinuity Discontinuity(Hoek & Bray, 1977) (Ulusay, 1991)
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19
Example 2: Bearing capacity of shallow dipping bedded rocks
qa=3N1 + (c1/tan 1 ) (N1 -1)
F
3A = (B/2tan1) N2 + (c2/tan 1) (N2 - 1)c1, 1, c2, 2 Discontinuity shear strength parameters
(
W
y
l
l
i
e
,
1
9
9
2
)
(Allowable bearing capacity)
(d) In Numerical Analyses:
Particularly in the analysis of rock engineering structures such as underground openings and slopes in discontinuum media (UDEC) shearstrength of discontinuities are important parameters.
C) SHEAR STRENGTH OF ROCK MASS
(a) Analytical and numerical methods
ci
SLOPE
TUNNEL
Bearing capacity of foundations on rock masses:
The usual method to determine allowable bearing pressures
Use published tables or building codes
Where the rock conditions do not match descriptions in the codes
Use analytical or numerical methods and rock mass strength
HOWEVER
Fractured rock:
qa= Cf1s0.5u(r) [1+(ms0.5+1)0.5]
F
Weak rock with little fracturing:
qa= Cf1cNc + Cf2 (B/2) N + DNq
F
dependent( W yl
l
i
e
,
1
9
9
2
)
(D) JOINT STIFFNESS
The mechanical behaviour of discontinuities in generally plotted in theform of stress-displacement curves withthe result that discvontinuity stiffness(MPa/m) and strength (kPa) can be measured.
Normal stiffness:
kn= n/ un
Shear stiffness:
ks = / us
(
Z
h
a
n
g
,
2
0
0
5
)
-
20
Normal and shear joint stiffnes values are used in discontinuum modelssuch as UDEC (in Barton and Bandis Model)
DEM Terminology
(Eberhardt, 2009)
(Eberhardt, 2009)
PERMEABILITY
Hydraulicgradient
Permeability is concerned with fluid flowthrough a material or rocks and rockmasses, and is one of the most difficiulttopics facing the practicing rockengineers.
(a) Permeability of Intact Rock (PRIMARY PERMEABILITY):
Refers to matrix permeability and except in petroleum engineering, prime consideration is not paid to this type of permeability in rock engineering.
Because of the presence of discontinuities in rock mass, two types of permeability are considered: (i) PRIMARY, (ii) SECONDARY
Governed by
Porosity
Geological history
In-situ stress
K also varies with grain size
Permeability vs. porosity for intact rocks
(
w
w
w
.
s
e
a
r
c
h
a
n
d
d
i
s
c
o
v
e
r
y
.
c
o
m
)
PERMEAMETER
(b) Permeability of Discontinuities:
Infilled discontinuity Permeability of the infill material.
Unfilled discontinuities for a set of parallel discontinuities K:
K=g (e)3
12 vb
v: Kinematic viscosity (10-6 m2/s)b: Spacinge: Aperture
K is very sensitive to small changesin e
Variation of dfiscontinuity setpermeability as a function of the
aperture and discontiuityfrequencey
(Hoek & Bray, 1977)
-
21
(c) Permeability of Rock Mass (Secondary Permeability):
In rock masses consisting of discontinuities terminating against another,computatins are not only made for the permeability of a set of paralleldiscontinuties but also for the discontinuities meeting.
Commonly discontinuity permeability dominates over the intact rockpermeability, and therefore, the second term may often be neglected.
In-situ messurement of K
PackerTest
Single set
3 ortogonal setsK in x-direction
(Zhang, 2005)
(
H
o
e
k
&
B
r
a
y
,
1
9
7
7
)
WHY WE DETERMINE IN SITU STRESS?
The basic reasons for in situ stress determination
Engineering analyses require boundary conditions. In situ stress is one of the most important boundaryconditions for the analyses of U/G excavations
To have basic knowledge of the stress state(e.g. direction and magnitude of the majorprincipal stresses, the direction in which therock is most likely to fail)
In situ stressstate
Failure1
3
FOS=StrengthStress
13
2
Civil & Mining Engg.Stability of U/G excavationsDrilling & blastingPillar designDesign of support systemsPrediction of rock burstDamsSlope stability
Energy DevelopmentBorehole stabilityFracturing & fracture propogationFluid flow and geothermal problemsReservoir production managementEnergy extraction and storage
1
23
STANDARDIZED TESTS
Determination of properties of intact rock and rock mass is the integral partof rock engineering studies. Although the strategy of rock characterization isa function of the engineering objectives, the tactical approach to individualtests can be standardized. The advantages of standardization are as follows(Hudson & Harrison, 2000):
The standardization guidance is helpful to anyone conducting the test,The results obtained by different organizations on rocks at different sitescan be compared in the knowledge that like is being compared with like, There is a source of recommended procedures for use in contracts, ifrequired.
The use of some form of standard procedures provides rock engineersto determine the quality objectively
ISRM SUGGESTED METHODS produced by the ISRM Commission onTesting Methods for rock testing and characterization since 1978
Such as
THE END