CN107560776A - Multi-interface shear stress joint test method for non-metal anti-floating anchor rod - Google Patents
Multi-interface shear stress joint test method for non-metal anti-floating anchor rod Download PDFInfo
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- CN107560776A CN107560776A CN201710938206.2A CN201710938206A CN107560776A CN 107560776 A CN107560776 A CN 107560776A CN 201710938206 A CN201710938206 A CN 201710938206A CN 107560776 A CN107560776 A CN 107560776A
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Abstract
The invention belongs to the technical field of civil engineering in-situ tests, and relates to a multi-interface shear stress joint test method for a non-metal anti-floating anchor rod, which is used for synchronously measuring the axial force and the shear stress of a rod body, an anchoring body and an interface of the rock body and the anchoring body of the non-metal anti-floating anchor rod in real time, and simultaneously obtaining the pull-up amount of the rod body and the anchoring body by using a novel test device so as to research the mechanical transmission mechanism and the deformation characteristic of the anti-floating anchor rod; the method has the advantages of simple and convenient process, simple structure, high testing precision, strong operability, direct and accurate numerical value result, capability of obtaining multi-interface shear stress of the non-metal anti-floating anchor rod, and strong applicability and feasibility.
Description
Technical field:
The invention belongs to civil engineering in-situ test technical field, is related to a kind of nonmetallic anti-float anchor rod multiple solutions shear stress
Joint test method, simple to operate, test is accurate, can synchronously draw nonmetallic the anti-float anchor rod body of rod, anchoring body and second contact surface
The axle power of (rock mass and anchoring body interface), shear stress, foundation is provided for the research and application of non-metallic rock.
Background technology:
Glass fiber reinforced polymer (Glass Fiber Reinforced Polymer, GFRP) anchor pole has tension strong
The advantages that degree is high, corrosion resistance is good, slackness is low and anti-electromagnetic interference capability is strong, being applied can not only in anti-floating engineering field
Solve the problems, such as that conventional metals anchor pole rust aging in offshore engineering and unfavorable geology environment is serious, moreover it is possible to break underground rail
Conventional metals anchor pole must not be used to carry out the limitation of anti-floating in transport development, it can be seen that, the application to nonmetallic anti-float anchor rod
Research has stronger applicability and advance.
In anti-floating anchor rod structure, the body of rod, anchoring body and surrounding Rock And Soil play structural anti-buoyancy effect, each of which jointly
Bearing capacity, mutual mechanics pass through mechanism and adhesive property determine structural damage form and bearing capacity size.
It is general only to be answered by body of rod axle during stress test device acquisition anchor rod drawing in existing GFRP anti-float anchor rods stress studies
Power and shearing stress distribution form and size, understand anchor pole load bearing mechanism, be not related to but in anchoring body, the mechanical property of bonding interface
Matter research.Therefore, seek a kind of nonmetallic anti-float anchor rod multiple solutions shear stress joint test method, utilize more advanced self compensation
Mini optical fibre grating (Fiber Bragg Gating, FBG) strain transducer, in the body of rod, anchoring body and second contact surface while cloth
Self-compensating miniature FBG strain transducer strings are put, its strain variation is obtained during anchor rod drawing, so as to obtain corresponding axle power
And value of shearing, so as to study GFRP anti-float anchor rod mechanics pass through mechanism and anchoring property comprehensively.
The content of the invention:
The shortcomings that it is an object of the invention to overcome prior art to exist, seek to design a kind of more boundaries of nonmetallic anti-float anchor rod
Face shear stress joint test method, realize the nonmetallic anti-float anchor rod body of rod of synchronous real-time measurement, anchoring body and second contact surface (rock mass
With anchoring body interface) axle power, shear stress, while utilize novel test device to obtain the amount of pulling out on the body of rod and anchoring body, Jin Eryan
Study carefully anti-float anchor rod mechanics transport mechanism and deformation characteristic.
To achieve these goals, the present invention is real using nonmetallic anti-float anchor rod multiple solutions shear stress joint test device
Existing, its detailed process is:
(1) it will be implanted on the anchor rod body of self-compensating miniature FBG strain transducer strings and be inserted in anchor pole bracket every 0.5m, and
Fixing nut is tightened, ensures anchor pole bracket in body of rod anchoring section firm stable, it is ensured that not move up and down, the self compensation in the body of rod is micro-
Type FBG strain transducers string examines its survival rate respectively before and after anchor rod body is implanted into, and survival rate must not be less than 90%;
(2) hard steel wire is fixed on anchor pole bracket with tied silk on request, ensures that hard steel wire anchors positioned at mortar respectively
The centre position and second contact surface position of body radial direction, second contact surface are anchoring body outer surface and surrounding rock-soil layer contact surface, so
Self-compensating miniature FBG strain transducers string, second contact surface self-compensating miniature FBG strains in anchoring body prefabricated in advance are passed afterwards
Sensor string on hard steel wire, now connects fiber Bragg grating (FBG) demodulator with tied silk lashing, examines self compensation in anchoring body micro-
The survival rate of type FBG strain transducers string, second contact surface self-compensating miniature FBG strain transducer strings, survival rate must not be less than
90%;
(3) above-mentioned prefabricated anchor pole is transferred in the bolthole being drilled, and pours into commodity mortar, conserved 28 days and reach
To after the 75% of required intensity, self-control displacement tester is symmetrically bonded in higher than anchoring body surface 0.5cm's with structure glue
On anchor pole, it is ensured that it is stable, vertical;
(4) two I-steel pedestal beams are symmetrically disposed at anchor rod body both sides, are located on pea gravel concreten bed course,
Ensure that distance is 25~30cm among it, anchor rod body is ensured anchor pole axial tension positioned at the center of two I-steel;It will wear
Heart reaction beam is placed on I-steel pedestal beam through anchor rod body, it is ensured that and the centre of form of punching reaction beam overlaps with anchor bar body, and
3rd punching billet, punching jack, the second punching billet, loading biography are installed successively from down to up on punching reaction beam
Sensor, the first punching billet, it is ensured that each part is vertical with anchor rod body, and the centre of form is coaxial with anchor pole, makes the anchor in loading procedure
Bar axial tension;
(5) stress spread pallet is threadedly secured on anchor rod body, is then inserted in locking anchorage, it is bigger to provide
Counter-force, can according to be actually needed by several locking anchorage be connected and locking anchorage and anchor rod body thread gaps
Between instill good fluidity AB glue, so as to ensure that anchor has enough coupling mechanism forces, when preventing from being further applied load lock anchorage with should
Power diffusion pallet produces failure by shear;
(6) in self-control displacement tester and anchoring body exposed face right angle setting Optical Fiber Grating Displacement Meter, fiber grating position
Move on the Magnetic gauge stand of meter and be arranged on datum line beam, ensure that it does not shake;Self-compensating miniature FBG strains in the body of rod are passed again
Self-compensating miniature FBG strain transducers string in sensor string, anchoring body, second contact surface self-compensating miniature FBG strain transducers string with
And on the external connector incoming fiber optic grating demodulation instrument of Optical Fiber Grating Displacement Meter, and setting relevant parameter is debugged, ensure accurate steady
Surely related data is gathered, so far nonmetallic anti-float anchor rod multiple solutions shear stress test device installation, and to punching jack
Demarcated with load sensor, the accuracy of the every grade of amount of being further applied load during guarantee test;
(7) loaded with punching jack, and control the ascending amount of punching jack to be less than 10cm, punching jack
Counter-force effect cause anchor rod body and anchoring body on the amount of pulling out, and recorded automatically with Optical Fiber Grating Displacement Meter, will measured by each lotus
The amount of pulling out S on anchor rod body and anchoring body under load effectBar、SAnchorFormula (1) is substituted into, that is, draws anchor pole and anchoring body Relative sliding
Amount,
S=(SBar-SBar bullet)-(SAnchor-SAnchor bullet) (1)
In formula:SBarTo measure body of rod displacement (mm) in experiment;SBar bulletFor body of rod anchoring section elastic elongation amount (mm);SAnchorFor examination
Anchoring displacement body (mm) is measured in testing;SAnchor bulletFor anchoring body elastic elongation amount (mm), because of SBar bullet、SAnchor bulletCalculated value is relatively small, can
Ignore;
The body of rod, anchoring body and second contact surface position strain variation value measured by fiber Bragg grating (FBG) demodulator are substituted into respectively
Formula (2), produce out the body of rod, axle power at anchoring body and second contact surface any position,
Ni=π D2EΔε/4 (2)
In formula:NiFor the axle power (kN) by geodesic structure (in the body of rod, anchoring body and at second contact surface) at any section i;E is
By the modulus of elasticity (GPa) of geodesic structure;Δ ε is the variable quantity strained by geodesic structure (in the body of rod, anchoring body and at second contact surface),
Tried to achieve by formula (3);D is the value on D by the diameter (mm) of geodesic structure:The diameter of the body of rod is taken for anchor rod body, for
The diameter of anchoring body is taken at second contact surface, for taking the body of rod centre of form to be passed to self-compensating miniature FBG strains in anchoring body in anchoring body
2 times of sensor string horizontal range,
Δ ε=Δ λ/K (3)
In formula:Wavelength variable quantity (nm) centered on Δ λ;K is self-compensating miniature FBG strain transducer strain sensitivity coefficients.
The axle power value of the body of rod, anchoring body and second contact surface position that formula (2) is obtained brings formula (4) into, produces
Go out the shear stress of the body of rod, anchoring body and second contact surface position,
τi=(Ni-Ni-1)/πDΔL (4)
In formula:NiFor by the axle power (kN) at a certain section i of geodesic structure;Ni-1For by the next section i-1 of geodesic structure
Axle power (kN);Δ L is section i to the distance between next section i-1 (mm);τiThe shear stress of midpoint between two sections,
It is approximately considered average shearing stress (MPa).
The agent structure of nonmetallic anti-float anchor rod multiple solutions shear stress joint test device of the present invention includes anchor pole bar
Body, locking anchorage, stress spread pallet, the first punching billet, load sensor, the second punching billet, punching jack,
3rd punching billet, punching reaction beam, self-control displacement tester, Optical Fiber Grating Displacement Meter, Magnetic gauge stand, datum line beam, work
Word bridle iron beam, anchor pole bracket, self-compensating miniature FBG strain transducers string in the body of rod, self-compensating miniature FBG strains in anchoring body
Sensor string, second contact surface self-compensating miniature FBG strain transducers string, commodity mortar, fiber Bragg grating (FBG) demodulator, tied silk, hard
Steel wire and pea gravel concreten bed course;Anchor rod body is solid glass fiber-reinforced polymer anchor pole;Lock anchorage, stress spread support
The size of disk and anchor rod body is supporting, and locking anchorage installation by adhering locks anchorage and stress spread on stress spread pallet
Pallet is closely connected to provide counter-force by way of screw thread couple with anchor rod body;Below stress spread pallet from upper and
Under be sequentially installed with the first punching billet, load sensor, the second punching billet, punching jack and the 3rd punching steel pad
Plate, the external pressure display instrument of load sensor, real-time display jack provide pulling capacity size;3rd punching billet is installed
On punching reaction beam, self-control displacement tester is welded by semicircle steel pipe and angle bar, is symmetrically bonded in using structure glue
Slightly above on the anchor rod body on anchoring body surface, self-control displacement tester is vertical with anchoring body surface;Anchor rod body both sides pair
Claim to place two I-steel pedestal beams, I-steel pedestal beam is located on pea gravel concreten bed course, between two I-steel pedestal beams
Away from for 25~30cm;Punching reaction beam is placed on I-steel pedestal beam through anchor rod body, makes displacement tester and anchor by oneself
Right angle setting Optical Fiber Grating Displacement Meter on solid exposed face, it is arranged on datum line beam on the Magnetic gauge stand of Optical Fiber Grating Displacement Meter,
Anchor pole bracket is spliced by four a quarter band pin annulus iron with nut, and according to the size Control of anchor rod body, its aperture is big
It is small and be uniformly arranged on anchor rod body bottom implantation soil body part;Self-compensating miniature FBG strain transducers string, anchoring body in the body of rod
Interior self-compensating miniature FBG strain transducers string and second contact surface self-compensating miniature FBG strain transducer strings enter according to test requirements document
Row is made, and self-compensating miniature FBG strain transducers string is implanted into anchor rod body to be tested wherein in the body of rod, self compensation in the body of rod
Self-compensating miniature FBG strain transducers string and second contact surface self-compensating miniature FBG in miniature FBG strain transducers string, anchoring body
Strain transducer string takes the principle of upper tightly lower sparse to arrange, three self-compensating miniature FBG strain transducers in each cross section
In identical depth;Commodity mortar is poured into pre-drilled bolthole, and its intensity determines according to the strength grade of test requirements document;
Hard steel wire is fixed on anchor pole bracket using tied silk, and self-compensating miniature FBG strain transducers string, second contact surface are self-complementary in anchoring body
Miniature FBG strain transducers string tied silk lashing is repaid on hard steel wire;Fiber Bragg grating (FBG) demodulator respectively with fiber grating
Self-compensating miniature FBG strain transducers string in displacement meter, the body of rod, self-compensating miniature FBG strain transducers string and in anchoring body
Second interface self-compensating miniature FBG strain transducer strings are connected.
Self-compensating miniature FBG strain transducers external diameter of the present invention is 1.5mm, length 10mm, utilizes optical fiber
Fusion techniques realize that quasi- distribution is connected, influence of the temperature to test data in energy elimination test drawing process;Due to anchor rod body
Axle power be not to be uniformly distributed, greatest around in anchor pole aperture, in aperture, certain depth below significantly reduces, and is finally reduced to
0 (relevant with the physical and mechanical parameter of ground), therefore, three self-compensating miniature FBG strain transducer strings take upper tightly lower sparse
Arrangement form, i.e., away from 1.5m at aperture in the range of, self-compensating miniature FBG strain transducers arrangement comparatively dense it is a little, spacing 0.1
~0.3m, away from aperture 1.5m lower ends, self-compensating miniature FBG strain transducers arrangement is relatively sparse, spacing control for 0.4~
0.8m, the number of self-compensating miniature FBG strain transducers are determined by the anchorage length of anchor pole;Making and work progress because of anchor pole
It is larger to self-compensating miniature FBG strain transducer damage risks in anchor rod body, anchoring body, so should in self-compensating miniature FBG
When becoming the making of sensor string, each self-compensating miniature FBG strain transducers are entered with miniature steel bushing packaging protection, cascaded fiber
Row armouring is protected, and these forms of protection will not impact to the property of self-compensating miniature FBG strain transducers itself;It is defined
The really stress value at the test GFRP anti-float anchor rods body of rod, anchoring body and second contact surface, self-compensating miniature FBG strains used in the present invention
Sensor, which need to shift to an earlier date, is connected in factory, is demarcated and core inspection, passes a string of self-compensating miniature FBG strains in anchor pole workshop
Sensor is implanted to body of rod center, testing ground with it is supporting to medium-height trestle, hard wire and band by two string self compensations it is micro-
Type FBG strain transducers are accurately fixed at anchoring body center and second contact surface.
The present invention passes through screw thread couple using the supporting stress spread pallet of new non-metallic rock and locking anchorage
Mode is directly closely connected with non-metallic rock, there is provided counter-force needed for experiment, this method is convenient, reliable, overcomes because nonmetallic
Anti-float anchor rod shear resistance is poor, in conventional anchor rod drawing device, need to pass through weldering in anchor pole loading end bonded metal sleeve pipe
Iron plate anchorage is connect to implement pull-out test, test method, the shortcomings that device is more complicated.
The present invention pastes the amount of pulling out on the displacement tester record body of rod in body of rod position near anchoring body, while in anchoring body
Self-control displacement tester (iron plate) is pasted on exposed surface, sets up on iron plate and is pulled out on Optical Fiber Grating Displacement Meter record anchoring body
Amount, and then anchor rod body is obtained relative to the amount of pulling out on anchoring body, the interfacial adhesion for preferably studying nonmetallic anti-float anchor rod is special
Property;In structural anti-buoyancy system, the cohesive force between anchor rod body and anchoring body is larger to structural bearing performance impact, conventional
Anchor pole displacement measurement when, the displacement of general record anchor head reflects bolt deformation characteristic, and measurement data accuracy is low.
The present invention compares in prior art, in existing test device, adds anti-float anchor rod anchoring body and second contact surface
Stress test, eliminate non-metallic rock and bond steel sleeve, weld the drawing means of punching iron plate anchorage;Improve anti-float anchor rod
Displacement tester, it is proposed that the body of rod and the method for testing of the amount of pulling out on anchoring body;Its simple process, the apparatus structure letter of use
Single, measuring accuracy is high, workable, draw numerical result directly, it is accurate, can obtain nonmetallic anti-float anchor rod multiple solutions and cut and answer
Power, applicability and feasibility are strong.
Brief description of the drawings:
Fig. 1 is the agent structure principle of nonmetallic anti-float anchor rod multiple solutions shear stress joint test device of the present invention
Figure.
Fig. 2 is the amount of pulling out test device structure chart on anchor rod body of the present invention and anchoring body.
Fig. 3 is the counterforce device structure chart of locking anchorage and stress spread pallet composition of the present invention.
Fig. 4 is self-compensating miniature FBG strain transducers string mounting structure principle schematic of the present invention.
Fig. 5 is self-compensating miniature FBG strain transducers string schematic cross-sectional view of the present invention.
Fig. 6 is anchor pole carrier structure principle schematic of the present invention.
Fig. 7 is the graph of relation of the anti-float anchor rod body of rod described in the embodiment of the present invention and anchoring body relative slippage.
Fig. 8 is G8-28-1 anchor rod body axle powers of the embodiment of the present invention with depth change curve.
Fig. 9 is G8-28-1 of embodiment of the present invention anchor rod bodies (the first interface) shear stress with depth change curve.
Figure 10 is axial stress in G8-28-1 anchoring bodys of the embodiment of the present invention with depth change curve.
Figure 11 is shear stress in G8-28-1 anchoring bodys of the embodiment of the present invention with depth change curve.
Figure 12 is G8-28-1 second contact surface axial stress of the embodiment of the present invention with depth change curve.
Figure 13 is G8-28-1 second contact surface shear stress of the embodiment of the present invention with depth change curve.
Embodiment:
The present invention will be further described by way of example and in conjunction with the accompanying drawings.
Embodiment:
The present embodiment realizes that its detailed process is using nonmetallic anti-float anchor rod multiple solutions shear stress joint test device:
(1) it will be implanted on the anchor rod body 1 of self-compensating miniature FBG strain transducers string 16 and be inserted in anchor pole bracket every 0.5m
15, and fixing nut is tightened, ensure anchor pole bracket 15 in body of rod anchoring section firm stable, it is ensured that not move up and down (in the body of rod
Self-compensating miniature FBG strain transducers string 16 examines its survival rate respectively before and after anchor rod body 1 is implanted into, and (survival rate is not
It must be less than 90%));
(2) hard steel wire 22 is fixed on anchor pole bracket 15 with tied silk 21 on request, ensures that hard steel wire 22 is located at respectively
The centre position of mortar anchoring body radial direction and second contact surface (anchoring body outer surface and surrounding rock-soil layer contact surface) position, then
Self-compensating miniature FBG strain transducers string 17, second contact surface self-compensating miniature FBG strains in anchoring body prefabricated in advance are passed
Sensor string 18 on hard steel wire 22, now connects fiber Bragg grating (FBG) demodulator 20 with the lashing of tied silk 21, examines in anchoring body
Self-compensating miniature FBG strain transducers string 17, the survival rate of second contact surface self-compensating miniature FBG strain transducers string 18 (survive
90%) rate must not be less than;
(3) above-mentioned prefabricated anchor pole is transferred in the bolthole being drilled, and pours into commodity mortar 19, conserve 28 days simultaneously
After the 75% of intensity needed for reaching, self-control displacement tester 10 is symmetrically bonded in higher than anchoring body surface with structure glue
On 0.5cm anchor pole, it is ensured that it is stable, vertical;
(4) two I-steel pedestal beams 14 are symmetrically disposed at the both sides of anchor rod body 1, are located at pea gravel concreten bed course
On 23, it is ensured that distance be 25~30cm among it, makes anchor rod body 1 positioned at the center of two I-steel, guarantee anchor pole axle center by
Draw;Punching reaction beam 9 is placed on I-steel pedestal beam 14 through anchor rod body 1, it is ensured that the centre of form and anchor of punching reaction beam 9
The body of rod 1 is overlapped, and the 3rd punching billet 8 of installation, punching jack 7, second are worn successively from down to up on punching reaction beam 9
Heart billet 6, load sensor 5, the first punching billet 4, it is ensured that each part is vertical with anchor rod body 1, and the centre of form is same with anchor pole
Axle, make the anchor pole axial tension in loading procedure;
(5) stress spread pallet 3 is threadedly secured on anchor rod body 1, is then inserted in locking anchorage 2, to provide
Bigger counter-force, several locking anchorages 2 can be connected and in locking anchorage 2 and anchor rod body 1 according to being actually needed
The AB glue of good fluidity is instilled between thread gaps, so as to ensure that anchor has enough coupling mechanism forces, is locked when preventing from being further applied load
Anchorage 2 produces failure by shear with stress spread pallet 3;
(6) in self-control displacement tester 10 and anchoring body exposed face right angle setting Optical Fiber Grating Displacement Meter 11, optical fiber light
It is arranged on the Magnetic gauge stand 12 of grid displacement meter 11 on datum line beam 13, ensures that it does not shake;It is again that self compensation in the body of rod is micro-
Self-compensating miniature FBG strain transducers string 17, second contact surface self-compensating miniature FBG in type FBG strain transducers string 16, anchoring body
On the external connector incoming fiber optic grating demodulation instrument 20 of strain transducer string 18 and Optical Fiber Grating Displacement Meter 11, and debug setting
Relevant parameter, ensure accurate stable collection related data, so far nonmetallic anti-float anchor rod multiple solutions shear stress test device installation
Complete, and punching jack 7 and load sensor 5 are demarcated, every grade of amount of being further applied load is accurate during guarantee test
Property;
(7) loaded with punching jack 7, and control the ascending amount of punching jack 7 to be less than 10cm, punching jack
7 counter-force effect cause anchor rod body 1 and anchoring body on the amount of pulling out, and recorded, will be surveyed automatically with Optical Fiber Grating Displacement Meter 11
Obtain the amount of pulling out S on the anchor rod body 1 and anchoring body under each load actionBar、SAnchorFormula (1) is substituted into, that is, draws anchor pole and anchoring body phase
To slippage,
S=(SBar-SBar bullet)-(SAnchor-SAnchor bullet) (1)
In formula:SBarTo measure body of rod displacement (mm) in experiment;SBar bulletFor body of rod anchoring section elastic elongation amount (mm);SAnchorFor examination
Anchoring displacement body (mm) is measured in testing;SAnchor bulletFor anchoring body elastic elongation amount (mm), because of SBar bullet、SAnchor bulletCalculated value is relatively small, can
Ignore;
By the generation respectively of the body of rod, anchoring body and second contact surface position strain variation value measured by fiber Bragg grating (FBG) demodulator 20
Enter formula (2), produce out the body of rod, axle power at anchoring body and second contact surface any position,
Ni=π D2EΔε/4 (2)
In formula:NiFor the axle power (kN) by geodesic structure (in the body of rod, anchoring body and at second contact surface) at any section i;E is
By the modulus of elasticity (GPa) of geodesic structure;Δ ε is the variable quantity strained by geodesic structure (in the body of rod, anchoring body and at second contact surface),
Tried to achieve by formula (3);D is the value on D by the diameter (mm) of geodesic structure:The diameter of the body of rod is taken for anchor rod body, for
The diameter of anchoring body is taken at second contact surface, for taking the body of rod centre of form to be passed to self-compensating miniature FBG strains in anchoring body in anchoring body
2 times of the horizontal range of sensor string 17,
Δ ε=Δ λ/K (3)
In formula:Wavelength variable quantity (nm) centered on Δ λ;K is self-compensating miniature FBG strain transducer strain sensitivity coefficients.
The axle power value of the body of rod, anchoring body and second contact surface position that formula (2) is obtained brings formula (4) into, produces
Go out the shear stress of the body of rod, anchoring body and second contact surface position,
τi=(Ni-Ni-1)/πDΔL (4)
In formula:NiFor by the axle power (kN) at a certain section i of geodesic structure;Ni-1For by the axle power at the next section i-1 of geodesic structure
(kN);Δ L is section i to the distance between next section i-1 (mm);τiThe shear stress of midpoint between two sections, it is approximate
Think average shearing stress (MPa).
The agent structure of nonmetallic anti-float anchor rod multiple solutions shear stress joint test device includes anchor pole described in the present embodiment
The body of rod 1, locking anchorage 2, stress spread pallet 3, the first punching billet 4, load sensor 5, the second punching billet 6, wear
Heart jack 7, the 3rd punching billet 8, punching reaction beam 9, self-control displacement tester 10, Optical Fiber Grating Displacement Meter 11, magnetic
Property gauge stand 12, datum line beam 13, I-steel pedestal beam 14, anchor pole bracket 15, self-compensating miniature FBG strain transducer strings in the body of rod
16th, self-compensating miniature FBG strain transducers string 17, second contact surface self-compensating miniature FBG strain transducers string 18, business in anchoring body
Product mortar 19, fiber Bragg grating (FBG) demodulator 20, tied silk 21, hard steel wire 22 and pea gravel concreten bed course 23;Anchor rod body 1 is solid
Glass fiber reinforced polymer anchor pole;It is supporting to lock anchorage 2, the size of stress spread pallet 3 and anchor rod body 1, locks anchorage 2
Installation by adhering locks anchorage 2 and stress spread pallet 3 by way of screw thread couple and anchor on stress spread pallet 3
Club shaft 1 is closely connected to provide counter-force;The lower section of stress spread pallet 3 is sequentially installed with the first punching billet from top to bottom
4th, load sensor 5, the second punching billet 6, the punching billet 8 of punching jack 7 and the 3rd, 5 external pressure of load sensor
Power display instrument, real-time display jack provide pulling capacity size;3rd punching billet 8 is arranged on punching reaction beam 9, from
Displacement tester 10 processed is welded by semicircle steel pipe and angle bar, and slightly above anchoring body surface is symmetrically bonded in using structure glue
Anchor rod body 1 on, self-control displacement tester 10 it is vertical with anchoring body surface;Symmetrically placed two works in the both sides of anchor rod body 1
Word bridle iron beam 14, I-steel pedestal beam 14 are located on pea gravel concreten bed course 23, and the spacing of two I-steel pedestal beams 14 is
25~30cm;Punching reaction beam 9 is placed on I-steel pedestal beam 14 through anchor rod body 1, makes the He of displacement tester 10 by oneself
Right angle setting Optical Fiber Grating Displacement Meter 11 on anchoring body exposed face, base is arranged on the Magnetic gauge stand 12 of Optical Fiber Grating Displacement Meter 11
On quasi- beam 13, anchor pole bracket 15 is spliced by four a quarter band pin annulus iron with nut, according to the size of anchor rod body 1
Control its pore size and be uniformly arranged on the bottom of anchor rod body 1 implantation soil body part;Self-compensating miniature FBG strains pass in the body of rod
Self-compensating miniature FBG strain transducers string 17 and second contact surface self-compensating miniature FBG strain transducers in sensor string 16, anchoring body
String 18 is made according to test requirements document, and self-compensating miniature FBG strain transducers string 16 is implanted into anchor to be tested wherein in the body of rod
In club shaft 1, self-compensating miniature FBG strain transducers string 16 in the body of rod, self-compensating miniature FBG strain transducer strings in anchoring body
17 and second contact surface self-compensating miniature FBG strain transducers string 18 take the principle of upper tightly lower sparse to arrange, each cross section
Three self-compensating miniature FBG strain transducers are in identical depth;Commodity mortar 19 is poured into pre-drilled bolthole, and its is strong
Degree determines according to the strength grade of test requirements document;Hard steel wire 22 is fixed on anchor pole bracket 15 using tied silk 21, and anchoring body is interior certainly
Compensate miniature FBG strain transducers string 17, the lashing of tied silk 21 of second contact surface self-compensating miniature FBG strain transducers string 18
On hard steel wire 22;Fiber Bragg grating (FBG) demodulator 20 strains with self-compensating miniature FBG in Optical Fiber Grating Displacement Meter 11, the body of rod respectively
Self-compensating miniature FBG strain transducers string 17 and second contact surface self-compensating miniature FBG strain sensings in sensor string 16, anchoring body
Device string 18 is connected.
The present embodiment is tested different anchor poles, and its specific test result is as shown in table 1:
Table 1:
Anchor pole is numbered | Anchorage length | Failing load | The amount of pulling out on anchor rod ultimate | The amount of pulling out in the anchoring body limit | Failure mode |
G8-28-1 | 6.5m | 395kN | 14.02mm | 12.63mm | Pull off destruction |
G8-28-2 | 6.5m | 378kN | 16.47mm | 12.64mm | Shearing slip destroys |
G8-28-3 | 6.5m | 412kN | 14.89mm | 12.25mm | Pull off destruction |
G8-28-4 | 6.5m | 387kN | 18.26mm | 13.27mm | Shearing slip destroys |
G8-28-5 | 6.5m | 398kN | 15.16mm | 12.445mm | Pull off destruction |
G6-28-1 | 4.5m | 407kN | 15.86mm | 12.035mm | Pull off destruction |
G6-28-2 | 4.5m | 381kN | 17.03mm | 12.67mm | Shearing slip destroys |
G6-28-3 | 4.5m | 394kN | 15.21mm | 11.47mm | Pull off destruction |
G6-28-4 | 4.5m | 375kN | 16.74mm | 11.35mm | Shearing slip destroys |
G6-32-1 | 4.5m | 467kN | 15.87mm | 12.31mm | Shearing slip destroys |
G6-32-2 | 4.5m | 453kN | 17.69mm | 12.64mm | Extract and destroy |
G represents GFRP anti-float anchor rods in wherein G8-28-1;8 represent that anchor pole overall length is 8m;28 represent that bolt diameters are
28mm, G8-28-1 ... G8-28-5 represent 5 parallel tests;By that analogy;The anti-float anchor rod body of rod and anchoring body Relative sliding
The test result of amount is as shown in fig. 7, wherein G8-28 represents that five parallel tests of G8-28-1 ... G8-28-5 are averaged in table 1
Value G6-28 represent table 1 in tetra- parallel tests of G6-28-1 ... G6-28-4 average, G6-32 represent table 1 in G6-32-1,
Two parallel tests of G6-32-2 are averaged;The multiple solutions shear stress result of anchor pole described in G8-28-1 is as shown in figures 8-13.
Claims (2)
1. a kind of nonmetallic anti-float anchor rod multiple solutions shear stress joint test method, it is characterised in that use nonmetallic anti-float anchor rod
Multiple solutions shear stress joint test device realizes that its detailed process is:
(1) it will be implanted on the anchor rod body of self-compensating miniature FBG strain transducer strings and be inserted in anchor pole bracket every 0.5m, and tighten
Fixing nut, ensure anchor pole bracket in body of rod anchoring section firm stable, it is ensured that not move up and down, the self-compensating miniature in the body of rod
FBG strain transducers string examines its survival rate respectively before and after anchor rod body is implanted into, and survival rate must not be less than 90%;
(2) hard steel wire is fixed on anchor pole bracket with tied silk on request, ensures that hard steel wire is located at mortar anchoring body footpath respectively
To centre position and second contact surface position, second contact surface is anchoring body outer surface and surrounding rock-soil layer contact surface, then will
Self-compensating miniature FBG strain transducers string, second contact surface self-compensating miniature FBG strain transducers in anchoring body prefabricated in advance
String on hard steel wire, now connects fiber Bragg grating (FBG) demodulator with tied silk lashing, examines self-compensating miniature FBG in anchoring body
The survival rate of strain transducer string, second contact surface self-compensating miniature FBG strain transducer strings, survival rate must not be less than 90%;
(3) above-mentioned prefabricated anchor pole is transferred in the bolthole being drilled, and pours into commodity mortar, conserved 28 days and reach institute
After need intensity 75%, displacement tester will be made by oneself and be symmetrically bonded in structure glue anchor pole higher than anchoring body surface 0.5cm
On, it is ensured that it is stable, vertical;
(4) two I-steel pedestal beams are symmetrically disposed at anchor rod body both sides, are located on pea gravel concreten bed course, it is ensured that
Distance is 25~30cm among it, anchor rod body is ensured anchor pole axial tension positioned at the center of two I-steel;Punching is anti-
Power beam is placed on I-steel pedestal beam through anchor rod body, it is ensured that the centre of form of punching reaction beam overlaps with anchor bar body, and is wearing
3rd punching billet, punching jack, the second punching billet, loading sensing are installed successively from down to up on heart reaction beam
Device, the first punching billet, it is ensured that each part is vertical with anchor rod body, and the centre of form is coaxial with anchor pole, makes the anchor pole in loading procedure
Axial tension;
(5) stress spread pallet is threadedly secured on anchor rod body, is then inserted in locking anchorage, it is bigger anti-to provide
Power, several locking anchorages can be connected and between locking anchorage and the thread gaps of anchor rod body according to being actually needed
The AB glue of good fluidity is instilled, anchorage is locked so as to ensure that anchor has enough coupling mechanism forces, when preventing from being further applied load and is expanded with stress
Dissipate pallet and produce failure by shear;
(6) in self-control displacement tester and anchoring body exposed face right angle setting Optical Fiber Grating Displacement Meter, Optical Fiber Grating Displacement Meter
Magnetic gauge stand on be arranged on datum line beam on, ensure that it does not shake;Again by self-compensating miniature FBG strain transducers in the body of rod
Self-compensating miniature FBG strain transducers string, second contact surface self-compensating miniature FBG strain transducers string and light in string, anchoring body
On the external connector incoming fiber optic grating demodulation instrument of fine grating displacement meter, and setting relevant parameter is debugged, ensure that accurate stable is adopted
Collect related data, so far nonmetallic anti-float anchor rod multiple solutions shear stress test device installation, and to punching jack and lotus
Retransmit sensor to be demarcated, the accuracy of the every grade of amount of being further applied load during guarantee test;
(7) loaded with punching jack, and control the ascending amount of punching jack to be less than 10cm, the counter-force of punching jack
Effect cause anchor rod body and anchoring body on the amount of pulling out, and recorded automatically with Optical Fiber Grating Displacement Meter, will measured by each load make
The amount of pulling out S on anchor rod body and anchoring body underBar、SAnchorFormula (1) is substituted into, that is, draws anchor pole and anchoring body relative slippage,
S=(SBar-SBar bullet)-(SAnchor-SAnchor bullet) (1)
In formula:SBarTo measure body of rod displacement (mm) in experiment;SBar bulletFor body of rod anchoring section elastic elongation amount (mm);SAnchorFor in experiment
Measure anchoring displacement body (mm);SAnchor bulletFor anchoring body elastic elongation amount (mm), because of SBar bullet、SAnchor bulletCalculated value is relatively small, ignores not
Meter;
The body of rod, anchoring body and second contact surface position strain variation value measured by fiber Bragg grating (FBG) demodulator are substituted into formula respectively
(2) body of rod, is produced out, axle power at anchoring body and second contact surface any position,
Ni=π D2EΔε/4 (2)
In formula:NiFor in the body of rod, anchoring body and at second contact surface by the axle power in geodesic structure at any section i, unit kN;E is
By the modulus of elasticity of geodesic structure, unit GPa;Δ ε is the body of rod, the change of structural strain is tested in anchoring body and at second contact surface
Amount, is tried to achieve by formula (3);D is by the diameter of geodesic structure, unit mm, the value on D:The body of rod is taken for anchor rod body
Diameter, the diameter for taking anchoring body at second contact surface, for taking the body of rod centre of form in anchoring body to self-compensating miniature in anchoring body
2 times of FBG strain transducer string horizontal ranges, Δ ε=Δ λ/K (3)
In formula:Wavelength variable quantity (nm) centered on Δ λ;K is self-compensating miniature FBG strain transducer strain sensitivity coefficients;
The axle power value of the body of rod, anchoring body and second contact surface position that formula (2) is obtained brings formula (4) into, produces rod
The shear stress of body, anchoring body and second contact surface position,
τi=(Ni-Ni-1)/πDΔL (4)
In formula:NiFor by the axle power at a certain section i of geodesic structure, unit kN;Ni-1For by the next section i-1 of geodesic structure
Axle power, unit kN;Δ L is the distance between section i to next section i-1, unit mm;τiThe midpoint between two sections
Shear stress, be approximately considered average shearing stress, unit MPa.
2. nonmetallic anti-float anchor rod multiple solutions shear stress joint test method according to claim 1, it is characterised in that described
The agent structure of nonmetallic anti-float anchor rod multiple solutions shear stress joint test device includes anchor rod body, locking anchorage, stress and expanded
Dissipate pallet, the first punching billet, load sensor, the second punching billet, punching jack, the 3rd punching billet, wear
Heart reaction beam, self-control displacement tester, Optical Fiber Grating Displacement Meter, Magnetic gauge stand, datum line beam, I-steel pedestal beam, anchor pole support
Self-compensating miniature FBG strain transducers string in frame, the body of rod, self-compensating miniature FBG strain transducers string, second contact surface in anchoring body
Self-compensating miniature FBG strain transducers string, commodity mortar, fiber Bragg grating (FBG) demodulator, tied silk, hard steel wire and pea gravel concreten pad
Layer;Anchor rod body is solid glass fiber-reinforced polymer anchor pole;Lock the size of anchorage, stress spread pallet and anchor rod body
Supporting, locking anchorage installation by adhering locks anchorage and stress spread pallet passes through screw thread couple on stress spread pallet
Mode be closely connected to provide counter-force with anchor rod body;First is sequentially installed with from top to bottom below stress spread pallet to wear
Heart billet, load sensor, the second punching billet, punching jack and the 3rd punching billet, load sensor are external
Pressure display instrument, real-time display jack provide pulling capacity size;3rd punching billet is arranged on punching reaction beam, from
Displacement tester processed is welded by semicircle steel pipe and angle bar, and the anchor higher than anchoring body surface is symmetrically bonded in using structure glue
On club shaft, self-control displacement tester is vertical with anchoring body surface;The symmetrically placed two I-shaped bridle irons in anchor rod body both sides
Beam, I-steel pedestal beam are located on pea gravel concreten bed course, and the spacing of two I-steel pedestal beams is 25~30cm;Punching counter-force
Beam is placed on I-steel pedestal beam through anchor rod body, makes right angle setting light on displacement tester and anchoring body exposed face by oneself
Fine grating displacement meter, it is arranged on datum line beam on the Magnetic gauge stand of Optical Fiber Grating Displacement Meter, anchor pole bracket is by four a quarters
Band pin annulus iron is spliced with nut, is arranged on according to its pore size of the size Control of anchor rod body and uniformly anchor rod body
Bottom implantation soil body part;Self-compensating miniature FBG strain transducers string in the body of rod, self-compensating miniature FBG strains pass in anchoring body
Sensor string and second contact surface self-compensating miniature FBG strain transducer strings are made according to test requirements document, self-complementary wherein in the body of rod
Miniature FBG strain transducers string is repaid to be implanted into anchor rod body to be tested, self-compensating miniature FBG strain transducers string in the body of rod,
Self-compensating miniature FBG strain transducers string and second contact surface self-compensating miniature FBG strain transducer strings are taken in anchoring body
Close lower thin principle arrangement, three self-compensating miniature FBG strain transducers in each cross section are in identical depth;Commodity mortar
Pour into pre-drilled bolthole, its intensity determines according to the strength grade of test requirements document;Hard steel wire is fixed using tied silk
Self-compensating miniature FBG strain transducers string, second contact surface self-compensating miniature FBG strain transducers in anchor pole bracket, anchoring body
String is with tied silk lashing on hard steel wire;Fiber Bragg grating (FBG) demodulator respectively with self compensation in Optical Fiber Grating Displacement Meter, the body of rod
Self-compensating miniature FBG strain transducers string and second contact surface self-compensating miniature FBG in miniature FBG strain transducers string, anchoring body
Strain transducer string is connected.
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