CN203414442U - Sound emission and resistivity combined monitoring device for rupture process of rock sample - Google Patents

Abstract

The utility model discloses a sound emission and resistivity combined monitoring device for the rupture process of a rock sample. Electrodes at the front ends of acoustoelectric integrated test probes are connected with drill holes of the rock sample; a sound emission acquisition module and a resistivity acquisition module are both connected with a data processing system; the data processing system is connected with a real display system; the rock sample is placed between two load-bearing plates of a rigid servo pressing machine; a stress acquisition module and a strain acquisition module are both connected with the data processing system. Synchronous real-time acquisition of sound emission, resistivity and stress-strain data in the uniaxial compression test process of rock is realized, wherein the resistivity acquisition module realizes superhigh-frequency automatic acquisition of resistivity data, automatically increases the resistivity acquisition frequency after receiving a feedback regulation, ensures complete acquisition of the resistivity variation data in the rupture process of the rock sample, and thus can realize real-time dynamic capture of the rupture information of the rock sample.

Description

The acoustic emission of rock sample rupture process and resistivity monitoring device combining

Technical field

The utility model relates to the real-time monitoring device of combining of a kind of acoustic emission and resistivity, the particularly acoustic emission of rock sample rupture process and resistivity monitoring device combining.

Background technology

As everyone knows, rock is a kind of very complicated mechanics medium forming under long-term geologic condition, has elastoplasticity, heterogeneity and anisotropic feature, and wherein composing a large amount of initial fissures of depositing has impact very significantly to mechanical properties of rock especially.And traditional rock mechanics experiment, as uniaxial compression test, shear test, is merely able to obtain the parameters such as elastic modulus, Poisson ratio, compressive strength, shearing strength, this is far from being enough for the physico-mechanical properties of describing rock.Therefore, there is scholar to introduce the rupture process that resistivity and acoustic emission are carried out study of rocks.

As the basic physical parameters of rock, resistivity has reflected the quality of electric conduction of rock performance, and its situation of change can directly reflect the crack occurrence status of rock interior, thereby rock failure mechanism of rock state is monitored.But experimental study before has mostly been subject to the low restriction of instrument frequency acquisition, be difficult to capture the situation of change of rock burst moment resistivity, than total stress-strain curve, the imperfection of resistivity data seems more obvious.On the one hand, this may cause the loss of key message, to analysis of experiments, brings difficulty; On the other hand, incomplete data may be led conclusion (of pressure testing) to a blind alley, even can draw antipodal result sometimes.

When rock deforms or rupture, the strain energy of generation will discharge with elastic wave form, causes acoustic emission phenomenon.In acoustic emission signal, comprise bulk information parameter, reflected to a certain extent stress state and the energy release conditions of rock, closely bound up with rock stress destruction process.But experimental study before mostly rests in the description of acoustic emission result, lack the comparative analysis with other monitoring meanss, and the ability of existing acoustic emission opposing external environment noise a little less than, be easily subject to the interference of ambient noise, so just often cause monitoring result to have error.Meanwhile, in process of the test, pasting acoustic emission probe wastes time and energy, and makes test efficiency lower.

In sum, there are the following problems for existing rock failure process monitoring means: the mechanics parameter that 1. traditional Rock Under Uniaxial Compression compression test obtains is accurate not to the description of rock failure process, and existing monitoring means, as resistivity and acoustic emission monitor(ing) method, all there is limitation separately, thereby only adopt single monitoring means to be inaccurate to the discriminatory analysis of rock failure process; 2. existing resistivity monitoring method is mostly subject to the restriction that instrument sample frequency is low, can not complete documentation rock burst the change in resistance situation of moment, may cause the loss of key message, impact analysis result; 3. existing acoustic emission monitor(ing) method, the ability of opposing external environment noise a little less than, be easily subject to the interference of ambient noise, cause monitoring result to have error, meanwhile, in process of the test, the laying of acoustic emission probe is wasted time and energy, and makes test efficiency very low.For this reason, invent a kind of monitoring device combining, realize the Real-Time Monitoring of synchronizeing with resistivity to acoustic emission under uniaxial compression test condition, in rock sample rupture process, for the experimental study of rock failure process provides a feasible approach.

Utility model content

The purpose of this utility model is for overcoming above-mentioned the deficiencies in the prior art, a kind of acoustic emission and resistivity monitoring device combining of rock sample rupture process are provided, can carry out the surveying work of acoustic emission and resistivity simultaneously, convenient and swift, be specially adapted to the combined monitoring under the small space condition of small size rock sample surface, solved because rock sample space surface is narrow and small the difficult problem that acoustic emission probe and arrangement of electrodes are limited.

For achieving the above object, the utility model adopts following technical proposals:

The acoustic emission of rupture process and a resistivity monitoring device combining, comprising: acoustic emission-resistivity combined measurement system, stress-strain measuring system, data handling system and real-time display system;

The acoustic emission acquisition module of described acoustic emission-resistivity combined measurement system and resistivity acquisition module are connected with some acoustic-electric integration testings probes, acoustic emission acquisition module and resistivity acquisition module by the data upload collecting to data handling system; Acoustic-electric integration testing probe is arranged on acoustic-electric integration testing probe clamping device, and resistivity acquisition module can also receive the feedback regulation from data handling system, and acoustic emission acquisition module and resistivity acquisition module are powered by supply module;

The stress acquisition module of described stress-strain measuring system is connected with bearing plate on rigidity servo-pressing machine, and strain acquirement module is connected with lower bearing plate; The data that described stress acquisition module and strain acquirement module collect are all uploaded to data handling system;

Data handling system will show by real-time display system after data processing.

Described acoustic-electric integration testing probe clamping device is provided with several acoustic-electric integration testing probes, the acoustic-electric integration testing probe electrode of front end and the boring of rock sample are connected, the rear end of described acoustic-electric integration testing probe is connected to acoustic emission acquisition module and resistivity acquisition module by cable, described acoustic emission acquisition module is all connected with data handling system with resistivity acquisition module, described data handling system is connected with real-time display system, described rock sample is placed in the middle of two bearing plates of rigidity servo-pressing machine, wherein going up bearing plate is connected with stress acquisition module, lower bearing plate is connected with strain acquirement module, described stress acquisition module is all connected with data handling system with strain acquirement module, described acoustic emission acquisition module, resistivity acquisition module is powered by supply module.

Described acoustic-electric integration testing probe is by electrode, electrode sleeve pipe, piezoelectric element, piezoelectric element sleeve pipe, housing, low noise cable, wire, prime amplifier and cable form, described housing is cylindrical, described housing is arranged on the outermost layer of acoustic-electric integration testing probe, housing upper end open centre is electrode, described electrode sleeve is contained in electrode sleeve pipe, described electrode sleeve pipe periphery is piezoelectric element, described piezoelectric element periphery is piezoelectric element sleeve pipe, piezoelectric element sleeve pipe periphery is housing, described piezoelectric element is connected with the prime amplifier of housing inner bottom part by low noise cable, described electrode is connected with prime amplifier by the wire through electrode sleeve bottom interstitial hole, the signal of electrode is derived by wire, the signal that signal after described prime amplifier is processed prime amplifier by the cable through housing bottom interstitial hole and wire pass over is derived, send follow-up harvester to.

Described acoustic-electric integration testing probe is specially adapted to the combined monitoring under the small space condition of small size rock sample surface.

Described housing is that metal is made, and can increase probe intensity on the one hand, and high-frequency signal plays shielding action to external world on the other hand.

Described piezoelectric element Front-end Design becomes circular-arc, contacts better with right cylinder Standard rock sample surface, facilitates acoustic emission coupling, and described piezoelectric element is made into hollow right cylinder, and electrode stretches out the hole in the middle of piezoelectric element.

Described electrode sleeve pipe is made by insulating material, is used for preventing that the electric current in electrode from causing interference to piezoelectric element.

Described piezoelectric element sleeve pipe is the hollow cylinder of being made by acoustic absorbant.

Described piezoelectric element sleeve pipe and electrode sleeve pipe all play the effect that absorbs outside noise, prevent that the signal that piezoelectric element is produced from causing interference.

Described acoustic-electric integration testing probe clamping device is comprised of probe clip, slide bar, rotating mechanism, main strut, hinge and base, described main strut is welded on base, base plays a supportive role, main strut is divided into again two sections, between two sections, by hinge, be connected, on described main strut, by rotating mechanism, fix a slide bar, one end of described slide bar is provided with probe clip, and described probe clip is used for clamping probe.

Described rotating mechanism comprises the first screw, the first fixture, the first knob, locking sliding block and stiff end, wherein, one end of the first screw and the welding of the end face of stiff end, other one end and first knob of the first screw screw, on the first screw, be also provided with locking sliding block and the first fixture, described locking sliding block is near stiff end, described the first fixture is near the first knob, described stiff end is solid cylinder, the curvature portion of described stiff end is provided with circular hole, the diameter of circular hole is consistent with the diameter of slide bar, described locking sliding block is enclosed within on stiff end, locking sliding block curvature portion is provided with two symmetrical semi arches, the diameter of semi arch is consistent with the diameter of the circular hole of stiff end, the first fixture fixing by the first screw and the first knob screw realize.

Described probe clip comprises the second screw, the second fixture, the second knob, slide bar and the welding of the second screw, and the fixing of the second fixture realized by screwing between the second screw and the second knob.

Described hinge comprises nut and the 3rd knob, the welding of nut and the 3rd screw, the connection of main strut two sections by the 3rd screw and the 3rd knob coordinate realize.

During actual use, by constantly rotating and adjust hinge, rotating mechanism and probe clip, realize acoustic-electric integration testing probe multi-angle, multi-faceted freely installing, greatly improved test efficiency.

Described acoustic emission acquisition module is responsible for gathering the acoustic emission signal in rock sample rupture process, is transferred to after treatment acoustic emission processing module again.

Described resistivity acquisition module is responsible for the resistivity signal of rock sample in acquisition test process, then transfers data to resistivity processing module.The ultrahigh frequency that described resistivity acquisition module has been realized resistivity data gathers automatically, and highest frequency can reach 250KHz.Simultaneously, described resistivity acquisition module can also be accepted the feedback regulation from acoustic emission processing module, according to acoustic emission before rock burst, count the rule of sharp increase, automatically improve resistivity frequency acquisition, guarantee intactly to collect the change in resistance data in rock sample rupture process.

The function of described supply module is whole acoustic emission-resistivity combined measurement system power supply.

Described stress acquisition module is connected with rigidity servo-pressing machine, is responsible for pressing machine institute's applied pressure and corresponding time thereof in acquisition test process, and by these real-time data transmissions to stress processing module.

Described strain acquirement module is connected with rigidity servo-pressing machine, downward displacement and the corresponding time thereof of bearing plate on pressing machine in responsible acquisition test process, and these real-time data transmissions are arrived to strained handling module.

Described stress processing module can be accepted the data from stress acquisition module, obtains the suffered stress of rock sample after calculation process, data is got off with the form real time record of form afterwards again.

Described strained handling module can be accepted the data from strain acquirement module, obtains rock sample institute strained after calculation process, data is got off with the form real time record of form afterwards again.

Described acoustic emission processing module can be integrated the data analysis from acoustic emission acquisition module, selects Ring-down count, energy number and corresponding time thereof, and is recorded as table.

Described resistivity processing module can be accepted the data from resistivity acquisition module, obtains the rock sample resistivity in each moment, and data are got off with the form real time record of form after calculation process.

Described real-time display system is depicted as relation curve while being mainly responsible for fructufy from data handling system, as curves of stress-strain relationship, stress-time curve, strain-time curve, acoustic emission Ring-down count-time curve, acoustic emission Ring-down count-curves of stress-strain relationship, acoustic emission energy number-time curve, acoustic emission energy number-curves of stress-strain relationship, resistivity-time curve, resistivity-curves of stress-strain relationship etc.And any four kinds of curves split screen in same screen wherein dynamically can be shown, thereby can observe more intuitively acoustic emission, resistivity with the relation between stress-strain.

The beneficial effects of the utility model are:

(1) acoustic emission the utility model proposes and resistivity associating real-time monitoring device has been realized the Real-time Collection of synchronizeing of acoustic emission in Rock Under Uniaxial Compression compression test process, resistivity, stress-strain data first, thereby can carry out real-time motion capture to the rock sample information of breaking;

(2) acoustic emission the utility model proposes is combined resistivity acquisition module in real-time monitoring device and has been realized the ultrahigh frequency of resistivity data and automatically gather with resistivity, highest frequency can reach 250KHz, the rock sample moment change in resistance situation of breaking that collects that can be complete;

(3) the resistivity acquisition module that the acoustic emission the utility model proposes is combined with resistivity in real-time monitoring device can also be accepted the feedback regulation from acoustic emission processing module, according to acoustic emission before rock burst, count the rule of sharp increase, automatically improve resistivity frequency acquisition, guarantee intactly to collect the change in resistance data in rock sample rupture process;

(4) the utility model proposes a kind of acoustic-electric integration testing probe, can carry out the surveying work of acoustic emission and resistivity simultaneously, convenient and swift, be specially adapted to the combined monitoring under the small space condition of small size rock sample surface, solved because rock sample space surface is narrow and small the difficult problem that acoustic emission probe and arrangement of electrodes are limited;

(5) the utility model has also proposed a kind of improved acoustic-electric integration testing probe clamping device, can freely adjust angle, the position of probe, the installation of convenient probe, thus greatly improved test efficiency.

Accompanying drawing explanation

Fig. 1 is that in the utility model embodiment 1, the complete layout of real-time monitoring device is combined in acoustic emission with resistivity;

Fig. 2 is the workflow diagram between each module of the utility model;

Fig. 3 is the procedure chart of the utility model acoustic emission processing module to the feedback regulation of resistivity acquisition module;

Fig. 4 is acoustic-electric integration testing probe diagrammatic cross-section;

Fig. 5 is the 3 d effect graph of acoustic-electric integration testing probe clamping device;

Fig. 6 is the 3 d effect graph of hinge in acoustic-electric integration testing probe clamping device;

Fig. 7 is the 3 d effect graph of rotating mechanism in acoustic-electric integration testing probe clamping device;

Fig. 8 is the 3 d effect graph of probe clip in acoustic-electric integration testing probe clamping device;

Wherein, 1. rigidity servo-pressing machine, 2. rock sample, 3. go up bearing plate, 4. descend bearing plate, 5. scribble the plastic sheeting of insullac, 6. boring, 7. the first acoustic-electric integration testing is popped one's head in, 8. the second acoustic-electric integration testing is popped one's head in, 9. the 3rd acoustic-electric integration testing is popped one's head in, 10. fourth sound electricity integration testing is popped one's head in, 11. acoustic emission acquisition modules, 12. resistivity acquisition modules, 13. supply modules, 14. acoustic-electric integration testing probe clamping devices, 15. stress acquisition modules, 16. strain acquirement modules, 17. data handling systems, 18. real-time display systems, 19. electrodes, 20. piezoelectric elements, 21. piezoelectric element sleeve pipes, 22. electrode sleeve pipes, 23. low noise cables, 24. housings, 25. wires, 26. prime amplifiers, 27. cables, 28. probe clips, 29. rotating mechanisms, 30. slide bars, 31. main struts, 32. hinges, 33. bases, 34. stiff ends, 35. locking sliding blocks, 36. first fixtures, 37. first knobs, 38. first screws, 39. the 3rd knobs, 40. nuts, 41. second fixtures, 42. second knobs, 43. second screws.

Embodiment

Below in conjunction with accompanying drawing and embodiment, the utility model is described in further detail.

Described in embodiment 1 use embodiment 2, described in acoustic-electric integration testing probe and embodiment 3, the using method of real-time monitoring device is combined in the acoustic emission of acoustic-electric integration testing probe clamping device 14 with resistivity.

Embodiment 1

As shown in Fig. 1-Fig. 7, on rigidity servo-pressing machine 1, be placed with rock sample 2, rock sample 2 is conventional right cylinder standard specimen, it is of a size of Ф 50mm * 100mm, meets the requirement of < < GB/T50266-99 Standard for test methods of engineering rock masses > >.Between rock sample 2 and upper bearing plate 3, lower bearing plate 4, pasting the plastic sheeting 5 that one deck scribbles insullac, be used for preventing in resistivity measurement process that electric current is directly by 1 conduction of rigidity servo-pressing machine.

The resistivity measurement of rock sample 2 adopts four-electrode method, thereby need on the same straight line of rock sample 2 one side, arrange in advance four borings 6, adjacent boring 6 spacing are followed successively by 15mm, 50mm, 15mm from top to bottom, each 6 diameter 3mm that hole, the about 8mm of hole depth, 6 impacts on test specimen mechanical property reduce to hole as far as possible.During test, need to will near four borings 6, clean out, then utilize acoustic-electric integration testing probe clamping device 14 to realize the installation location of first acoustic-electric integration testing probe the 7, second acoustic-electric integration testing probe the 8, the 3rd acoustic-electric integration testing probe 9, fourth sound electricity integration testing probe 10.The example that is installed as with the first acoustic-electric integration testing probe 7 describes: first the first acoustic-electric integration testing probe 7 is placed on the second fixture 41, tighten the second knob 42 by its clamping, just constantly adjust afterwards probe clip 28, rotating mechanism 29 and hinge 32, the first acoustic-electric integration testing probe 7 is fixing in place, electrode 19 can be put in boring 6 just, can make again front end cambered surface and the surperficial close contact of rock sample 2 of the first acoustic-electric integration testing probe 7 simultaneously.Stake resistance when reducing resistivity measurement, is all filled with couplant in four borings 6, simultaneously, in order to guarantee the first acoustic-electric integration testing probe 7, the second acoustic-electric integration testing probe 8, the 3rd acoustic-electric integration testing probe 9, close contact between fourth sound electricity integration testing probe 10 and rock sample 2, obtain desirable acoustic emission test result, need to be at the first acoustic-electric integration testing probe 7, the second acoustic-electric integration testing probe 8, the 3rd acoustic-electric integration testing probe 9, fourth sound electricity integration testing is popped one's head in and is smeared low-intensity silica gel as couplant between 10 front end cambered surfaces and rock sample 2, can not impact the mechanical property of rock sample 2 like this, and also easily that acoustic-electric integration testing probe is separated with rock sample 2 after off-test.Finally acoustic emission acquisition module 11, resistivity acquisition module 12 are connected with supply module 13 respectively, form complete acoustic emission-resistivity combined measurement system, and acoustic emission acquisition module 11 is all connected with data handling system 17 with resistivity acquisition module 12, realize data transmission between the two.

Stress-strain measuring system is comprised of stress acquisition module 15 and strain acquirement module 16, both be connected with rigidity servo-pressing machine 1, wherein the upper bearing plate 3 of rigidity servo-pressing machine 1 is connected with stress acquisition module 15, the lower bearing plate 4 of rigidity servo-pressing machine 1 is connected with strain acquirement module 16, and realizes the communication between stress acquisition module 15 and strain acquirement module 16 and data handling system 17 by data line.Finally connection data disposal system 17 and real-time display system 18 again, acoustic emission is combined and has substantially been completed being just connected between each module of real-time monitoring device with resistivity like this.

After each module has connected, also need to check line each other, guarantee errorless after, switch on power and open modules.In data handling system 17, input successively the diameter D(mm of rock sample 2), height h(mm), the distance L (mm) between the second acoustic-electric integration testing probe the 8, the 3rd acoustic-electric integration testing probe 9, basic parameter as rock sample 2 is preserved, and facilitates follow-up data processing.

Then respectively acoustic emission and resistivity combined measurement system and stress-strain measuring system are debugged: under normal circumstances, resistivity-the time curve showing in real-time display system 18 should approach straight line, if do not have reading or reading too high, should check whether wire 25 disconnects or short circuit, the first acoustic-electric integration testing probe 7, the second acoustic-electric integration testing probe 8, the 3rd acoustic-electric integration testing probe 9, between the electrode 19 of fourth sound electricity integration testing probe 10 and rock sample 2, whether contact well, scribble the plastic sheeting 5 of insullac whether complete etc., acoustic emission Ring-down count-the time curve and the acoustic emission energy number-time curve that in real-time display system 18, show, all should show as the straight line that numerical value is very little, and while beaing rock sample 2, numerical value can raise suddenly, if find that acoustic emission Ring-down count and energy number are all unstable, should check whether between first acoustic-electric integration testing probe the 7, second acoustic-electric integration testing probe the 8, the 3rd acoustic-electric integration testing probe 9, fourth sound electricity integration testing probe 10 and rock sample 2, whether contact tight, silica gel has played coupling etc., the whether normal of stress-strain measuring system can judge according to the curves of stress-strain relationship showing in real-time display system 18, in control, bearing plate 3 is slowly mobile downwards, before contacting with rock sample 2, curves of stress-strain relationship should be that numerical value is 0 straight line, and when both contact, stress value can rise suddenly.

Through checking, after guaranteeing that each module is working properly, in control, bearing plate 3 slowly declines, just contact with the upper surface of rock sample 2, test formally starts, and starts the collection of acoustic emission and resistivity data, until finally break when rigidity servo-pressing machine 1 starts rock sample 2 to exert pressure.

In process of the test, the specific works flow process of associating real-time monitoring device as shown in Figure 2.

1 applied pressure F(KN of rigidity servo-pressing machine in stress acquisition module 15 acquisition test processes) and corresponding time t(s), and by these real-time data transmissions to the stress processing module in data handling system 17.Then stress processing module is according to the diameter D(mm of the rock sample 2 of inputting in advance), according to formula

$\mathrm{\&sigma;}=\frac{F}{\frac{1}{4}\mathrm{\&pi;}{\mathrm{<figure-callout\; id="2"\; label="D"\; filenames="HDA00002540512900011.png"\; state="\{\{state\}\}">D</figure-callout>}}^2}\&times;1000$

Calculate the suffered stress σ of rock sample 2 (MPa), then diameter, pressure, stress and corresponding time thereof are got off with the form real time record of form.

The upper downward displacement y(mm of bearing plate 3 in strain acquirement module 16 acquisition test processes) and corresponding time t(s), and by these real-time data transmissions to the strained handling module in data handling system 17.Then strained handling module is according to the height h(mm of the rock sample 2 of inputting in advance), according to formula

$\mathrm{\&epsiv;}=\frac{y}{h}$

Calculate the suffered strain stress of rock sample 2, then length, displacement, strain and corresponding time thereof are got off with the form real time record of form.

The acoustic emission signal that acoustic emission acquisition module 11 is popped one's head in 10 acquisition test processes by first acoustic-electric integration testing probe the 7, second acoustic-electric integration testing probe the 8, the 3rd acoustic-electric integration testing probe 9, fourth sound electricity integration testing is transferred to the acoustic emission processing module in data handling system 17 after amplification is processed again.Then acoustic emission processing module is integrated data analysis, selects Ring-down count, energy number and corresponding time thereof, is recorded as table.

Potential difference (PD) Δ U(V in resistivity acquisition module 12 acquisition test processes between the second acoustic-electric integration testing probe the 8 and the 3rd acoustic-electric integration testing probe 9), the supply current I(A of flow through the first acoustic-electric integration testing probe 7 and fourth sound electricity integration testing probe 10), and transfer data to the resistivity processing module in data handling system 17.Especially, when acoustic emission number becomes suddenly large, resistivity acquisition module 12 regulates automatically, automatically improves resistivity frequency acquisition, and its feedback regulation process as shown in Figure 3.Resistivity processing module receives after data, can be according to the diameter D(mm of the rock sample 2 of prior input) and the second acoustic-electric integration testing probe the 8, the 3rd acoustic-electric integration testing probe 9 between distance L (mm), according to formula

$\mathrm{\&rho;}=\frac{\mathrm{\&Delta;U}}{I}\&CenterDot;\frac{\mathrm{\&pi;}{\mathrm{<figure-callout\; id="2"\; label="D"\; filenames="HDA00002540512900011.png"\; state="\{\{state\}\}">D</figure-callout>}}^2}{4L}$

Calculate rock sample 2 each electricalresistivityρ (Ω m) constantly, then diameter, probe spacing, voltage, electric current, resistivity and corresponding time thereof are got off with the form real time record of form.

Data handling system 17 is integrated the Data classification after processing, real-time display system 18 more based on this real-time rendering go out relation curve (as curves of stress-strain relationship, stress-time curve, strain-time curve, acoustic emission Ring-down count-time curve, acoustic emission Ring-down count-curves of stress-strain relationship, acoustic emission energy number-time curve, acoustic emission energy number-curves of stress-strain relationship, resistivity-time curve, resistivity-curves of stress-strain relationship etc.), and split screen dynamically shows in same screen.

2 one kinds of acoustic-electric integration testing probes of embodiment

As shown in Figure 4, a kind of acoustic-electric integration testing probe outermost layer is the housing 24 that metal is made, and can increase probe intensity on the one hand, and high-frequency signal plays shielding action to external world on the other hand, avoids acoustic emission signal to be interfered.The collection of acoustic emission signal realizes by piezoelectric element 20, and piezoelectric element 20 Front-end Design become circular-arc, can contact better with right cylinder Standard rock sample 2 surfaces, facilitate acoustic emission coupling, in addition, piezoelectric element 20 is made into hollow right cylinder, and electrode 19 stretches out from middle hole.The part that electrode 19 stretches out housing 24 is about 8mm, just can put in boring 6, and the cambered surface of piezoelectric element 20 front ends is contacted just with rock sample 2 surfaces during test.Electrode 19 is sleeved in electrode sleeve pipe 22, and electrode sleeve pipe 22 is made by insulating material, can be used for preventing that the electric current in electrode 19 from causing interference to piezoelectric element 20.Between piezoelectric element 20 and housing 24, be piezoelectric element sleeve pipe 21, it is the hollow cylinder of being made by acoustic absorbant.Piezoelectric element sleeve pipe 21 and electrode sleeve pipe 22 can absorb outside noise, prevent that the signal that piezoelectric element 20 is produced from causing interference.

In process of the test, electrode 19 gathers the resistivity signal that rock sample 2 breaks and produces, and passes to wire 25; Meanwhile, piezoelectric element 20 picks up the elastic wave on rock sample 2 surfaces, and converts mechanical energy to electric signal, is transferred to prime amplifier 26 amplifies processing by low noise cable 23.Finally, the electric signal that the responsible signal that prime amplifier 26 was processed of cable 27 and wire 25 transmit is derived respectively, sends follow-up harvester to.

3 one kinds of acoustic-electric integration testing probe clamping devices of embodiment

As shown in Figure 5, a kind of acoustic-electric integration testing probe clamping device 14 is comprised of probe clip 28, rotating mechanism 29, slide bar 30, main strut 31, hinge 32 and base 33.Base 33 supports whole device, and is connected with main strut 31.In actual use, a plurality of rotating mechanisms 29 can be installed on main strut 31 as required, and subsidiary slide bar 30 and probe clip 28, realize a plurality of probes and clamp simultaneously.

Main strut 31 is divided into again two sections, and hypomere and base 33 are integrally welded, between two sections, by hinge 32, are connected.The structure of hinge 32 as shown in Figure 6, has thin phase wedging between main strut 31 two sections, between thin, utilize screw to run through, and the two ends of screw are respectively nut 40 and the 3rd knob 39.Unscrew like this 3rd knob 39, main strut 31 epimeres just can be take screw as axle, rotate before and after hypomeres relative to main strut 31, adjust to behind suitable position, then tighten the 3rd knob 39 and just the relative position of main strut 31 two sections can be fixed up.

Between main strut 31 epimeres and slide bar 30, by rotating mechanism 29, be connected, as shown in Figure 7, rotating mechanism 29 is comprised of locking sliding block 35, the first fixture 36, the first knob 37, the first screw 38, wherein the first fixture 36 is sheet metals of " R " font, lower end two thin slices are connected by the first screw 38, one end of the first screw 38 is connected with the first knob 37, and the other end is welded on stiff end 34.Stiff end 34 is shaped as right cylinder, has a circular hole on cylindrical curved surface, and large I is held slide bar 30 and freely passed through.At stiff end 34 and 36 of the first fixtures, also has a locking sliding block 35, locking sliding block 35 is shell structures, right-hand member leaves circular hole and passes for the first screw 38, the concordant opening of left end, at left port place, be designed with the semi-circular arc identical with slide bar 30 diameters, locking sliding block 35 can be nested on stiff end 34 just simultaneously.During use, unscrew the first knob 37, by the first fixture 36, be nested on main strut 31, at this moment rotating mechanism 29 can be moved up and down along main strut 31, and can freely rotate around main strut 31, meanwhile, the circular hole forming between locking sliding block 35 and stiff end 34 can move around for slide bar 30, and can make slide bar 30 take the first screw 38 to rotate freely as axle.

Slide bar 30 one end are provided with probe clip 28, and as shown in Figure 8, one end of the second screw 43 is welded on slide bar 30 concrete structure, and through two thin slices of the second fixture 41 bottoms, the other end is connected with the second knob 42.In the annulus hole on the second fixture 41 tops, be placed with rubber spacer, can be used for clamping acoustic-electric integration testing probe, by adjusting the degree of tightness of the second knob 42, acoustic-electric integration testing probe can be along with the second fixture 41 freely rotates around the second screw 43 like this.

Although above-mentioned, by reference to the accompanying drawings embodiment of the present utility model is described; but the not restriction to the utility model protection domain; one of ordinary skill in the art should be understood that; on the basis of the technical solution of the utility model, those skilled in the art do not need to pay various modifications that creative work can make or distortion still in protection domain of the present utility model.

Claims (5)

1. the acoustic emission of rock sample rupture process and a resistivity monitoring device combining, is characterized in that, comprising: acoustic emission-resistivity combined measurement system, stress-strain measuring system, data handling system and real-time display system;

The acoustic emission acquisition module of described acoustic emission-resistivity combined measurement system is connected with some acoustic-electric integration testing probes with resistivity acquisition module, the acoustic-electric integration testing probe various information for testing the rock sample that is clamped in rigidity servo-pressing machine, acoustic emission acquisition module and resistivity acquisition module by the data upload collecting to data handling system; Acoustic-electric integration testing probe is arranged on acoustic-electric integration testing probe clamping device, and resistivity acquisition module can also receive the feedback regulation from data handling system, and acoustic emission acquisition module and resistivity acquisition module are powered by supply module;

The stress acquisition module of described stress-strain measuring system is connected with bearing plate on rigidity servo-pressing machine, and strain acquirement module is connected with lower bearing plate; The data that described stress acquisition module and strain acquirement module collect are all uploaded to data handling system;

Data handling system will show by real-time display system after data processing.

2. the acoustic emission of a kind of rock sample rupture process as claimed in claim 1 and resistivity monitoring device combining, it is characterized in that, described acoustic-electric integration testing probe is by electrode, electrode sleeve pipe, piezoelectric element, piezoelectric element sleeve pipe, housing, low noise cable, wire, prime amplifier and cable form, described housing is cylindrical, described housing is arranged on the outermost layer of acoustic-electric integration testing probe, housing upper end open centre is electrode, described electrode sleeve is contained in electrode sleeve pipe, described electrode sleeve pipe periphery is piezoelectric element, described piezoelectric element periphery is piezoelectric element sleeve pipe, piezoelectric element sleeve pipe periphery is housing, described piezoelectric element is connected with the prime amplifier of housing inner bottom part by low noise cable, described electrode is connected with prime amplifier by the wire through electrode sleeve bottom interstitial hole, the signal of electrode is derived by wire, the signal that signal after described prime amplifier is processed prime amplifier by the cable through housing bottom interstitial hole and wire pass over is derived, send follow-up harvester to.

3. the acoustic emission of a kind of rock sample rupture process as claimed in claim 2 and resistivity monitoring device combining, it is characterized in that, described piezoelectric element front end becomes circular-arc, contact better with right cylinder Standard rock sample surface, described piezoelectric element is made into hollow right cylinder, and electrode stretches out the hole in the middle of piezoelectric element; Described electrode sleeve pipe is made by insulating material; Described piezoelectric element sleeve pipe is the hollow cylinder of being made by acoustic absorbant.

4. the acoustic emission of a kind of rock sample rupture process as claimed in claim 1 and resistivity monitoring device combining, it is characterized in that, described acoustic-electric integration testing probe clamping device is comprised of probe clip, slide bar, rotating mechanism, main strut, hinge and base, described main strut is welded on base, base plays a supportive role, main strut is divided into again two sections, between two sections, by hinge, be connected, on described main strut, by rotating mechanism, fix a slide bar, one end of described slide bar is provided with probe clip, and described probe clip is used for clamping probe.

5. the acoustic emission of a kind of rock sample rupture process as claimed in claim 4 and resistivity monitoring device combining, is characterized in that, described rotating mechanism comprises the first screw, the first fixture, the first knob, locking sliding block and stiff end, wherein, one end of the first screw and the welding of the end face of stiff end, other one end and first knob of the first screw screw, on the first screw, be also provided with locking sliding block and the first fixture, described locking sliding block is near stiff end, described the first fixture is near the first knob, described stiff end is solid cylinder, the curvature portion of described stiff end is provided with circular hole, the diameter of circular hole is consistent with the diameter of slide bar, described locking sliding block is enclosed within on stiff end, locking sliding block curvature portion is provided with two symmetrical semi arches, the diameter of semi arch is consistent with the diameter of the circular hole of stiff end, the first fixture fixing by the first screw and the first knob screw realize, described probe clip comprises the second screw, the second fixture, the second knob, slide bar and the welding of the second screw, and the fixing of the second fixture realized by screwing between the second screw and the second knob, described hinge comprises nut and the 3rd knob, the welding of nut and the 3rd screw, the connection of main strut two sections by the 3rd screw and the 3rd knob coordinate realize.

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