Shear Pull-Tests for a Hybrid Bolt in PFC3D
Note
To view this project in PFC3D, use the menu command . Choose “rblocksel/hybrid/shear_pull” and select “shear_pull_pfc3d.prj” to load. The data files used are shown at the end of this example.
Simple Shear Test
A simple shear test is simulated using two blocks of zones (Figure 1). The bottom of the left block is prevented from moving in the vertical direction and the top of the right block is moved downwards at a constant velocity. A hybrid bolt spans the joint from left to right. A normal stress of 1 MPa is applied. The friction angle of the joint is set to 40º and the cohesion is 0.
For the hybrid bolt, the dowel segment is assigned a yield strength of 0.063 MN and a strain limit of 0.3. Figure 2 shows the bolt contribution versus shear displacement. The bolt contribution is essentially the shear force minus the frictional strength (\(\sigma_n \tan \phi\)). At about 7 mm of shear displacement, the dowel segment yields. At about 2.1 cm, the cable itself yields in tension. Finally after about 3 cm of shear, the dowel ruptures and the bolt fails.
blocks.dat
;
;Build model for hybrid bolt calibration
;
model new
fish automatic-create off
model large-strain on
;
fish define params
; block dimensions
global block_lenH = 0.95
global block_lenV = 2.0
; block properties
global ymod_=40e9
global pratio_=0.25
global dens_=2500
; joint properties
global jfric_=40.0
;hybrid bolt parameters
global area_=201e-6
global e_=1.4e11
global grout_stiff_=3e8
global grout_strength_=2e5
global cable_yield_=100e3
global cable_strain_limit_=0.2 ; tensile
global dowel_stiffness_=1.0e7
global dowel_yield_=62.8e3
global dowel_strain_limit_=0.3 ; shear
global dowel_length_=0.1
global segment_length_=0.1
; calculated parameters
global bolt_len=block_lenH*2.
end
[params]
=====================================================
;
;make 2 blocks with interface
; make left block bigger in -z direction to account for large strain
model domain extent [-2.0*block_lenH] [4.0*block_lenH] ...
[-1.0*block_lenH] [2.0*block_lenH] ...
[-1.0*block_lenV] [2.0*block_lenV] ...
rblock create box 0.0 [2.0*block_lenH] ...
0.0 [block_lenH] ...
0.0 [block_lenV] ...
rblock cut plane point [block_lenH] [block_lenH/2] [block_lenV/2] normal 1 0 0 radius [block_lenV]
;rblock cut plane point [block_lenH/2] [block_lenH/2] [block_lenV/2] normal 1 0 0 radius [block_lenV]
;rblock cut plane point [3*block_lenH/2] [block_lenH/2] [block_lenV/2] normal 1 0 0 radius [block_lenV]
rblock group 'left' slot 'side' range position-x 0.0 [block_lenH]
rblock group 'right' slot 'side' range position-x 0.0 [block_lenH] not
rblock hide range group 'right'
rblock facet group 'joint-left' slot 'joint' range pos-x [block_lenH] by rblock-vertex
rblock hide off
rblock hide range group 'left'
rblock facet group 'joint-right' slot 'joint' range pos-x [block_lenH] by rblock-vertex
rblock hide off
rblock facet group '-x' slot 'boundary' range position-x 0.0 by rblock-vertex
rblock facet group '+x' slot 'boundary' range position-x [block_lenH*2.0] by rblock-vertex
rblock facet group '-y' slot 'boundary' range position-y 0.0 by rblock-vertex
rblock facet group '+y' slot 'boundary' range position-y [block_lenH*2.0] by rblock-vertex
rblock facet group '-z' slot 'boundary' range position-z 0.0 by rblock-vertex
rblock facet group '+z' slot 'boundary' range position-z [block_lenV] by rblock-vertex
; Scale the rigid blocks so that they overlap initially. This
; is important as the contact position for the bonds is based
; on the original overlap volume. This contact position is
; incrementally updated when bonded.
rblock scale relative 1.01 keep-inertial
rblock attribute damp 0.7 density [dens_]
; Use the contact area
[global facetTotal = 0.05]
rblock contact-resolution update-area true accumulate-stress true ...
facet-total [facetTotal]
; Specify the springnetwork model properties. Initially
; all bonded contacts have infinite strength. This is
; useful when equilibrating the model.
contact cmat default model springnetwork ...
method compute-stiffness emod [ymod_] poisson [pratio_] ...
property fric [math.tan(jfric_*math.degrad)] ...
sn_ten 1e100 sn_coh 1e100
model clean
contact method area
contact method bond range group 'left' match 2
contact method bond range group 'right' match 2
; apply common boundary conditions
rblock hide range position-x 0 [block_lenH] not
rblock fix velocity-z range group '-z' by rblock-facet
rblock hide off
;
model save 'blocks'
shear_test.dat
;;-----------------------------------------------------------------------------
;; Shear test
;;-----------------------------------------------------------------------------
model restore 'blocks'
; define parameters for shear loading
fish define params_shear
; boundary conditions
global normal_stress = 1.0e6
global zvel_=-2e-7
end
[params_shear]
; boundary conditions
rblock facet apply stress-normal [-1.*normal_stress] range group '-x' by rblock-facet
rblock facet apply stress-normal [-1.*normal_stress] range group '+x' by rblock-facet
;
rblock fix spin
model mechanical timestep scale
model solve
;
rblock attribute displacement 0 0 0
; apply shear load
rblock attribute velocity-z 0.0 range group '-z' by rblock-facet
rblock fix velocity-z range group '-z' by rblock-facet
rblock attribute velocity-z [zvel_] range group 'right'
;
; Function to calculate bolt contribution to resisting shear load
[global monitor = rblock.near(2*block_lenH,0.5*block_lenH,0.5*block_lenV)]
[global max_force = 0.0]
[global bolt_contribution = 0.0]
[global cpnt = contact.find('rblock-rblock',2,3)]
fish define reaction_force
local temp_ = rblock.force.unbal.z(monitor)
reaction_force = temp_
global friction_force = math.abs(contact.force.global(cpnt)->z)
global bolt_contribution = temp_ - friction_force
end
;
fish history name 'reaction_force' reaction_force
fish history name 'bolt_contribution' bolt_contribution
rblock history name 'zdisp' displacement-z ...
position [1.5*block_lenH] [0.5*block_lenH] [0.5*block_lenV]
model history name 'unbal-max' mechanical unbalanced-maximum
history interval 100
;
;to run the test - stop when rupture
fish def run_it
local test_ = true
local max_force = -1e12
loop while test_ = true
command
model cycle 10000
end_command
if max_force < bolt_contribution
max_force = bolt_contribution
else
if bolt_contribution < max_force/10.
test_ = false
end_if
end_if
end_loop
end
model save 'ini_shear.sav'
=================================================================
; Test perpendicular bolt 90 degrees
; Change dincl_ to test other bolt angles
;
model restore 'ini_shear'
[global dincl_=90.]
;To create bolt
[global x1 = block_lenH-0.5*bolt_len*math.sin(dincl_*math.degrad)+0.001]
[global y1 = 0.5*block_lenH]
[global z1 = 0.5*block_lenV+0.5*bolt_len*math.cos(dincl_*math.degrad)]
[global x2 = block_lenH+0.5*bolt_len*math.sin(dincl_*math.degrad)-0.001]
[global y2 = y1]
[global z2 = 0.5*block_lenV-0.5*bolt_len*math.cos(dincl_*math.degrad)]
[global bolt_beg=vector(x1,y1,z1)]
[global bolt_end=vector(x2,y2,z2)]
struct hybrid create by-line [bolt_beg] [bolt_end] max-length [segment_length_]
; cable properties
struct hybrid prop cross-sectional-area [area_] young [e_] ...
grout-stiffness [grout_stiff_] grout-cohesion [grout_strength_] ...
yield-tension [cable_yield_] tensile-failure-strain [cable_strain_limit_]
; dowel properties
struct hybrid prop dowel-active-length [dowel_length_] dowel-stiffness [dowel_stiffness_] ...
dowel-yield [dowel_yield_] dowel-failure-strain [dowel_strain_limit_]
; to plate both ends:
struct link attach x rigid range pos-x [bolt_beg->x]
struct link attach y rigid range pos-x [bolt_beg->x]
struct link attach z rigid range pos-x [bolt_beg->x]
struct link attach x rigid range pos-x [bolt_end->x]
struct link attach y rigid range pos-x [bolt_end->x]
struct link attach z rigid range pos-x [bolt_end->x]
struct damp combined-local
struct hybrid history name 'dowel-strain' dowel-strain pos 0 0 0
struct hybrid history name 'dowel-force' dowel-force pos 0 0 0
;run the test - stop when rupture
[run_it]
model save 'shear-90'
program return
=================================================================
; Test bolt at 70 degrees
;
model restore 'ini_shear'
[global dincl_=70.]
;To create Inclined bolt
[global x1 = block_lenH-0.5*bolt_len*math.sin(dincl_*math.degrad)+0.001]
[global y1 = 0.5*block_lenH]
[global z1 = 0.5*block_lenV+0.5*bolt_len*math.cos(dincl_*math.degrad)]
[global x2 = block_lenH+0.5*bolt_len*math.sin(dincl_*math.degrad)-0.001]
[global y2 = y1]
[global z2 = 0.5*block_lenV-0.5*bolt_len*math.cos(dincl_*math.degrad)]
[global bolt_beg=vector(x1,y1,z1)]
[global bolt_end=vector(x2,y2,z2)]
struct hybrid create by-line [bolt_beg] [bolt_end] max-length [segment_length_]
; cable properties
struct hybrid prop cross-sectional-area [area_] young [e_] ...
grout-stiffness [grout_stiff_] grout-cohesion [grout_strength_] ...
yield-tension [cable_yield_] tensile-failure-strain [cable_strain_limit_]
; dowel properties
struct hybrid prop dowel-active-length [dowel_length_] dowel-stiffness [dowel_stiffness_] ...
dowel-yield [dowel_yield_] dowel-failure-strain [dowel_strain_limit_]
;to plate both ends:
struct link attach x rigid range pos-x [bolt_beg->x]
struct link attach y rigid range pos-x [bolt_beg->x]
struct link attach z rigid range pos-x [bolt_beg->x]
struct link attach x rigid range pos-x [bolt_end->x]
struct link attach y rigid range pos-x [bolt_end->x]
struct link attach z rigid range pos-x [bolt_end->x]
struct damp combined-local
struct hybrid history name 'dowel-strain' dowel-strain pos 0 0 0
struct hybrid history name 'dowel-force' dowel-force pos 0 0 0
;run the test - stop when rupture
model cycle 160000
model save 'shear-70'
Simple Pullout Test
The same block and bolt configuration from the simple shear test is used in the pullout test. In this case no normal stress is applied and the right boundary of the right block is moved to the right at a constant velocity.
Figure 3 shows the block and cable configuration at the end of the test. Figure 4 shows the bolt contribution in this test. Since there is no tensile strength on the joint, the bolt contribution is simply equal to the tensile force applied at the right boundary. This plot shows the initial elastic axial deformation, and then the start of grout failure at around 1.6 mm of displacement. Finally, the cable yields in tension after 2.5 mm of pull, at which time the bolt behaves plastically and the contribution no longer increases.
pullout.dat
;;-----------------------------------------------------------------------------
;; Pull-out test
;;-----------------------------------------------------------------------------
model restore 'blocks'
;
; Define parameters for pullout test
[global xvel_ = 2e-8]
;
rblock fix velocity-x range group '-x' by rblock-facet
;
rblock group 'pull' range group '+x' by rblock-facet
rblock fix velocity-x range group 'pull'
rblock attribute velocity-x [xvel_] range group 'pull'
;
[global max_force = 0.0]
[global bolt_contribution = 0.0]
;
fish define reaction_force
local temp_ = 0.0
loop foreach local gi rblock.group.list('pull')
temp_ = temp_ + rblock.force.app.x(gi)
end_loop
reaction_force = math.abs(temp_)
bolt_contribution = math.abs(temp_); - friction_force
end
;
fish history reaction_force
fish history bolt_contribution
rblock history displacement-x ...
position [2*block_lenH] [0.5*block_lenH] [0.5*block_lenV]
model history mechanical unbalanced-maximum
history interval 500
;fish function to run the test - stop when rupture
[global monitor = rblock.near(2*block_lenH,0.5*block_lenH,0.5*block_lenV)]
fish def run_it
local test_ = true
loop while test_ = true
command
model cycle 10000
end_command
if math.mag(rblock.dis(monitor)) > 4e-3
test_ = false
endif
end_loop
end
;
model save 'ini_pull'
;
=================================================================
;
; Test perpendicular bolt 90 degrees
; Change dincl_ to test other bolt angles
;
model restore 'ini_pull'
[global dincl_=90.]
;To create bolt
[global x1 = block_lenH-0.5*bolt_len*math.sin(dincl_*math.degrad)+0.001]
[global y1 = 0.5*block_lenH]
[global z1 = 0.5*block_lenV+0.5*bolt_len*math.cos(dincl_*math.degrad)]
[global x2 = block_lenH+0.5*bolt_len*math.sin(dincl_*math.degrad)-0.001]
[global y2 = y1]
[global z2 = 0.5*block_lenV-0.5*bolt_len*math.cos(dincl_*math.degrad)]
[global bolt_beg=vector(x1,y1,z1)]
[global bolt_end=vector(x2,y2,z2)]
;[segment_length_ = 0.5*block_lenH]
struct hybrid create by-line [bolt_beg] [bolt_end] max-length [segment_length_]
; cable properties
struct hybrid prop cross-sectional-area [area_] young [e_] ...
grout-stiffness [grout_stiff_] grout-cohesion [grout_strength_] ...
yield-tension [cable_yield_] tensile-failure-strain [cable_strain_limit_]
; dowel properties
struct hybrid prop dowel-active-length [dowel_length_] dowel-stiffness [dowel_stiffness_] ...
dowel-yield [dowel_yield_] dowel-failure-strain [dowel_strain_limit_]
model mechanical timestep scale
[run_it]
model save 'pull-90'
program return
===============================================================================
;inclined bolt 70 degrees
model restore 'ini_pull'
[global dincl_=70.]
;To create inclined bolt
[global x1 = block_lenH-0.5*bolt_len*math.sin(dincl_*math.degrad)+0.001]
[global y1 = 0.5*block_lenH]
[global z1 = 0.5*block_lenV+0.5*bolt_len*math.cos(dincl_*math.degrad)]
[global x2 = block_lenH+0.5*bolt_len*math.sin(dincl_*math.degrad)-0.001]
[global y2 = y1]
[global z2 = 0.5*block_lenV-0.5*bolt_len*math.cos(dincl_*math.degrad)]
[global bolt_beg=vector(x1,y1,z1)]
[global bolt_end=vector(x2,y2,z2)]
struct hybrid create by-line [bolt_beg] [bolt_end] max-length [segment_length_]
; cable properties
struct hybrid prop cross-sectional-area [area_] young [e_] ...
grout-stiffness [grout_stiff_] grout-cohesion [grout_strength_] ...
yield-tension [cable_yield_] tensile-failure-strain [cable_strain_limit_]
; dowel properties
struct hybrid prop dowel-active-length [dowel_length_] dowel-stiffness [dowel_stiffness_] ...
dowel-yield [dowel_yield_] dowel-failure-strain [dowel_strain_limit_]
[run_it]
model save 'pull-70'
;------------------------------------------------------------------------------
;end of file
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