JP7236187B1 - Simulating device and test method for dynamic hazards caused by deep rocky mountain splash - Google Patents

Abstract

Kind Code: A1 The present invention provides a deep rock mountain crash dynamic disaster simulating device capable of simulating a deep rock mountain crash state, obtaining more accurate data, and reducing the occurrence of dynamic disasters. A test method is disclosed. A simulation apparatus of this embodiment includes a front loader, a rear loader, a left loader, a right loader, an upper loader and a lower loader. The loader is positioned behind the rock simulating sample, the left loader 6 is positioned on the left side of the rock simulating sample 16, the right loader 10 is positioned on the right side of the rock simulating sample 16, and the upper loader 3 is above the rock simulating sample 16. , and the lower loader 11 is positioned below the rock simulation sample 16 . [Selection drawing] Fig. 1

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for simulating a crash of a rock mass, and more particularly to a device and test method for simulating a dynamic disaster caused by a deep rock mass crash.

After the deep rock body is subjected to dynamic mining disturbance, the stress inside the rock body is redistributed and the energy is released. end up When subjected to dynamic disturbance, the rock body will induce more dynamic disasters. Therefore, it is necessary to develop a simulator and a test method for conducting a test to induce a surrounding rock dynamic disaster by unloading a rock body.

The technical problem to be solved by the present invention is to simulate the deep rocky mountain crash state, acquire more accurate data, and reduce the occurrence of dynamic disasters. It is to provide a disaster simulator and test method.

To solve the above technical problems, the embodiments of the present invention adopt the following technical solutions.

In one aspect, an embodiment of the present invention includes a front loader, a rear loader, a left loader, a right loader, an upper loader and a lower loader, the front loader being positioned in front of the rock simulant and the rear loader being positioned above the rock simulant. The left loader is positioned on the left side of the rock simulant, the right loader is positioned on the right side of the rock simulant, the upper loader is positioned above the rock simulant, and the lower loader is positioned below the rock simulant. To provide a simulation device of deep rocky body splash dynamic disaster located in .

Preferably, the front loader includes a front hydraulic jack and a front support end, the front hydraulic jack is fixedly connected to the front support end, the front support end faces the rock simulation sample, and the rear loader comprises a rear hydraulic jack. a hydraulic jack and a rear support end, wherein the rear hydraulic jack is fixedly connected to the rear support end, the rear support end faces the rock simulation sample, the left loader comprises a left hydraulic jack and a left support end; The left hydraulic jack is fixedly connected to the left support end, the left support end faces the rock simulation sample, the right loader includes a right hydraulic jack and a right support end, the right hydraulic jack is the right support end. the right support end is toward the rock simulation sample, the lower loader includes a lower hydraulic jack, a lower support end and a bottom fixed end, the lower hydraulic jack is fixedly connected to the lower support end; The lower support end faces the rock simulant and the bottom fixed end is fixedly connected to the lower hydraulic jack.

Preferably, the front support end, the rear support end, the left support end, the right support end and the lower support end are each provided with an acoustic emission wiring hole.

Preferably, the lower support end of the lower loader is adapted to the bottom of the rock simulant.
Preferably, the upper loader includes a waveform transmitter, a connecting rod, a spring, an upper supporting end, an upper hydraulic jack and a pressure transmission ring, the waveform transmitter is fixedly connected to the tip of the connecting rod, and the bottom end of the connecting rod is the upper supporting end. The annular fixing base is fitted on the upper support end, the bottom surface of the upper support end faces the rock simulation sample, the spring is fitted on the connecting rod, and one end of the spring is in contact with the upper support end. , the other end of the spring is abutted on the pressure transmission ring, the upper hydraulic jack is fixedly connected to the pressure transmission ring, and the upper support end is provided with an acoustic emission wiring hole.

In another aspect, an embodiment of the present invention further provides a method for testing a deep rock mass splash dynamic hazard, the method including the following steps.

Attach the lower loader S10: First, fix the bottom fixed end to the concrete floor with a fixing nut, then attach the acoustic emission probe to the rock simulation sample through the acoustic emission wiring hole of the lower support end of the lower loader, and the acoustic emission The projection of the probe fits into the recess of the acoustic emission wiring hole and secures the bottom hydraulic jack to the bottom fixed end via the locking nut.

Loading the rock simulant S20: After the acoustic emission probe is attached to the rock simulant, the rock simulant is placed on the lower support end 11 of the lower loader, and the six wires connecting the acoustic emission probes are connected to the front loader, It is sent out through the acoustic emission wiring holes in the rear loader, left loader, right loader, upper loader and lower loader, connected to the external acoustic emission signal receiving end, and then a predetermined vertical pressure is applied to the rock simulation sample by the lower loader. In addition, during the upward movement of the lower loader, the rock simulant generates vertical pressure due to the interaction between the lower loader and the upper support end. After the applied lateral pressure load is stabilized, a horizontal axial pressure load is applied to the rock simulation sample by the front loader and the rear loader.

Adjust the pressure load S30: Lower loader, front loader, rear loader, left loader, right loader in different loading directions so that the pressure gauges of the lower loader, front loader, rear loader, left loader, and right loader reach predetermined values, respectively. Adjust the loader.

Test S40: By controlling the hydraulic unloading speed in the front loader, the rock simulation sample is unloaded. Including performing a documented unload test.

Preferably, the above S40 further includes adjusting the energy supply rate: reloading the upper support end by adjusting the stiffness of the spring and the loading speed of the upper hydraulic jack so that the upper hydraulic jack in turn loads the load. The signal transmitted to the rock simulation sample through the pressure transmission ring, the spring and the upper support end, and received by the acoustic emission signal receiving end, when the inside of the rock simulation sample is broken in the case of different stiffness and different loading speed By analyzing the generated acoustic emission rule, we analyze the effect of energy supply rate on rock dynamic hazards.

Preferably, the above S40 further includes a dynamic disturbance test: generating waves of different frequencies, different waveforms and different amplitudes by a waveform transmitter, the waves applying dynamic disturbance loads to the rock simulation sample through connecting rods; The received acoustic emission signal obtains the acoustic emission signal rule generated when the interior of the rock simulated sample breaks down to obtain the influence of the wave loading frequency, amplitude and waveform on the dynamic hazard.

Compared with the prior art, the embodiment of the present invention simulates the deep rock mountain crash condition, acquires more accurate data, and can reduce the occurrence of dynamic disasters. A disaster simulator and test method are provided. In the embodiment of the present invention, by installing a front loader, a rear loader, a left loader, a right loader, an upper loader, and a lower loader, a simulation of a deep rocky body crash dynamic disaster can be realized and related data can be obtained. . These loaders are provided with acoustic emission wiring holes, and after the acoustic emission probes are installed in different directions of the rock simulation sample, the connecting wires of the acoustic emission probes pass through the acoustic emission wiring holes of the loaders in different directions. After being sent out, it is connected to the acoustic emission signal receiving end to obtain the acoustic emission signal propagation rule data in each direction of the rock simulation sample. Based on the acoustic emission signal regulation data, the relevant data of deep rock mass splash dynamic disaster are obtained.

It is a front view of the simulator of the Example of this invention. It is a left view of the simulator of the Example of this invention. FIG. 4 is a diagram schematically showing positions of a rock simulation sample and a loader in the simulation device of the embodiment of the present invention;

The technical solution of the present invention will be described in detail below with reference to the drawings.

As shown in FIGS. 1 to 3, the deep rocky mountain spring dynamic disaster simulator of the embodiment of the present invention includes a front loader 14, a rear loader 15, a left loader 6, a right loader 10, and an upper loader 3. and lower loader 11 . The front loader is positioned on the front side of the rock simulant 16, the rear loader is positioned on the rear side of the rock simulant 16, the left loader is positioned on the left of the rock simulant 16, and the right loader is positioned on the right of the rock simulant 16. The upper loader is positioned above the rock simulating sample 16 and the lower loader is positioned below the rock simulating sample 16 .

In the above embodiment, by installing the front loader 14, the rear loader 15, the left loader 6, the right loader 10, the upper loader 3 and the lower loader 11, simulation of a deep rocky body spring dynamic disaster is realized. Relevant data are obtained. These loaders are provided with acoustic emission wiring holes 9, and after the acoustic emission probes are mounted in different directions of the rock simulation sample 16, the connecting wires of the acoustic emission probes are connected to the acoustic emission wiring holes 9 of the loaders in different directions. and then connected to the acoustic emission signal receiving end to obtain the acoustic emission signal propagation rule data in each direction of the rock simulation sample 16 . Based on the acoustic emission signal regulation data, the relevant data of deep rock mass splash dynamic disaster are obtained. The deep rock body is subjected to crustal stress, and the applied confining pressure is to simulate the crustal stress situation of the deep rock body.

Preferably, as shown in FIG. 1 , the front loader 14 includes a front hydraulic jack and a front support end, the front hydraulic jack fixedly connected to the front support end, the front support end receiving the rock simulant sample 16 . heading towards The rear loader 15 includes a rear hydraulic jack and a rear support end, the rear hydraulic jack is fixedly connected to the rear support end, and the rear support end faces the rock simulation sample 16 . The left loader 6 includes a left hydraulic jack 7 and a left support end 8 , the left hydraulic jack 7 is fixedly connected to the left support end 8 and the left support end 8 faces the rock simulation sample 16 . The right loader 10 includes a right hydraulic jack and a right support end, the right hydraulic jack is fixedly connected to the right support end and the right support end faces the rock simulation sample 16 . The lower loader 11 includes a lower hydraulic jack, a lower support end and a bottom fixed end 13 , the lower hydraulic jack is fixedly connected to the lower support end and the lower support end faces the rock simulation sample 16 . The bottom fixed end 13 is fixedly connected to the lower hydraulic jack.

Loaders in each direction apply the force by means of hydraulic jacks. The bottom fixed end 13 is placed on the lower loader 11 to stabilize the lower loader so that accurate data can be obtained in the test. Acoustic emission wiring holes 9 are provided at the front support end, the rear support end, the left support end, the right support end and the lower support end, respectively. Data obtained by the acoustic emission probe is output to the acoustic emission signal receiving end through the acoustic emission wiring hole 9 .

Lower loader 11 is connected to bottom fixed end 13 via fixing nut 12 . The bottom fixed end 13 is for fixing the lower loader 11 in a more stable position to avoid the lower loader 11 from shaking during operation and affecting the accuracy of data collection. A rock simulation sample 16 is placed on the lower support end of the lower loader 11 . The data transmission line of the acoustic emission probe located on the rock simulation sample 16 passes through the acoustic emission wiring hole 9 and is connected to the acoustic emission signal receiving end to acquire the acoustic emission signals generated in different directions during rock breaking. .

Acoustic emission wiring holes 9 are provided at the front support end, the rear support end, the left support end, the right support end, the upper support end and the lower support end, respectively. An acoustic emission probe is attached to the rock simulant sample 16 . The data transmission lines of the acoustic emission probe in different directions are respectively passed through the acoustic emission wiring holes 9 at the front support end, rear support end, left support end, right support end, upper support end and lower support end, and to the acoustic emission signal receiving end. Acoustic emission signal data generated during the fracture of rocks in different directions is acquired. The working process of the loader will be described by taking the front loader 14 as an example, but the working processes of the rear loader 15, the left loader 6 and the right loader 10 are the same except that the directions are different. The front loader 14 includes a front hydraulic jack and a front support end with pressure applied to the front support end by the front hydraulic jack. The front support end transmits pressure to the front side of the rock simulant 16, and the rock simulant 16 receives a load from the front. If desired, the amount of load applied by the front hydraulic jack can be adjusted.

Preferably, the lower support end of the lower loader 11 is fitted to the bottom of the rock simulant 16 . The top surface of the lower support end 11 is the same size as the bottom surface of the rock simulant 16, otherwise the left and right loaders often hit the bottom during loading, causing equipment wear.

Preferably, as shown in FIGS. 1 and 2, the upper loader 3 includes a waveform transmitter 1, a connecting rod 2, a spring 4, an upper support end 5, an annular fixed base 17, an upper hydraulic jack 18 and a pressure transmission ring. 19 included. The waveform transmitter 1 is fixedly connected to the tip of the connecting rod 2, the bottom end of the connecting rod 2 is fixedly connected to the upper supporting end 5, the annular fixing base 17 is fitted on the upper supporting end 5, and the bottom surface of the upper supporting end 5 is Heading towards the rock simulant 16 . The spring 4 is fitted on the connecting rod 2 , one end of the spring 4 is in contact with the pressure transmission ring 19 , the other end of the spring 4 is in contact with the upper support end 5 , and the pressure transmission ring 19 is attached to the upper hydraulic jack 18 . The annular fixing base 17 is fitted onto the lower support end 5 and the upper support end 5 is provided with an acoustic emission wiring hole 9 . The annular fixing base 17 has a fixing function. The annular fixed base 17 is fixedly connected to an external fixture. The position of the annular fixed base 17 does not change during the operation of the upper loader. The upper support end 5 can only move downwards and cannot move upwards under the action of the annular fixing base 17, so that during the upward movement of the lower loader, the rock simulation sample 16 will move to the lower loader. and under the action of the upper support edge, a certain normal stress is reached. The waveform transmitter 1 is located at the tip of the connecting rod 2. The waveform transmitter 1 transmits waves with different frequencies, amplitudes and waveforms. obtain the acoustic emission law tested on the rock simulant sample 16 of the acoustic emission probe, and further analyze the effects of wave loading frequency, amplitude and waveform on dynamic hazards. The upper hydraulic jack 19 applies a downward load to the spring 4 through the pressure transmission ring 18 , the spring 4 transmits the load to the upper support end 5 , and the upper support end 5 applies the downward load to the rock simulation sample 16 . By changing the magnitude of the load on the spring 4 by the upper hydraulic jack 19 and the loading speed, the acoustic emission law generated in the rock simulation sample 16 by the acoustic emission probe is obtained, and the rock motion by different energy supply speeds is obtained. Analyze impact on natural disasters.

The upper loader 3 is for providing a vertical pressure load. By varying the stiffness of the spring 4 and providing different energy supply velocities under the action of the upper loader 3, the energy supply velocities of the rock body with different stiffness can be simulated, and the dynamic hazards caused by the landslide due to the energy supply velocities can be simulated. can be used to analyze the impact on The pressure transmission ring 18 is of hollow construction. The connecting rod 2 and pressure transmission ring 18 are coaxial. The upper part of connecting rod 2 is located in the hollow cavity of pressure transmission ring 18 . A connecting rod 2 connects the waveform transmitter 1 and the upper support end 5 . In this case, the connecting rod 2 also serves to stabilize the loading direction of the upper hydraulic jack 18 so that the upper hydraulic jack 18 loads vertically against the spring 4 . Also, the waveform transmitter 1 is connected to the connecting rod 2 , and the waveform transmitter 1 excites waves of different shapes, amplitudes and frequencies, which in turn pass through the connecting rod 2 and the upper support end 5 to the rock simulation sample 16 . It is possible to transmit and provide a dynamic disturbance load to the rock simulation sample 16, and analyze the impact of the dynamic disturbance on the mountain crash dynamic disaster.

The test method of deep rock mountain splash dynamic disaster by the above simulator includes the following steps:

Step S10 for attaching the lower loader: First, the bottom fixing end 13 is fixed to the concrete floor with the fixing nut 12, and then the acoustic emission probe is passed through the acoustic emission wiring hole 9 in the lower support end of the lower loader 11 to the rock simulation sample. 16, the projection of the acoustic emission probe is delivered through the caustic emission wiring hole 9. The protrusion attached to the rock simulation sample of the acoustic emission probe fits into the recess of the acoustic emission wiring hole 9 , and the lower hydraulic jack is fixed to the bottom fixed end 13 via the fixing nut 12 .

Step S20 of applying a load to the rock simulation sample: After attaching the acoustic emission probe to the rock simulation sample 16, the rock simulation sample 16 is placed on the lower support end 11 of the lower loader 11, and the six wires connecting the acoustic emission probe are connected. through the acoustic emission wiring holes 9 in the front loader 14, rear loader 15, left loader 6, right loader 10, upper loader 3 and lower loader 11 respectively, connect to the external acoustic emission signal receiving end, and then lower A predetermined vertical pressure is applied to the rock simulation sample 16 by the loader 11 . Due to the interaction between the upper support end 5 and the annular fixing base 17, the rock imitation sample 16 can only move downward, and cannot move upward. During the upward movement of the lower loader 11 , the rock imitation sample 16 generates vertical pressure through interaction between the lower loader 11 and the upper support end 5 . After the vertical pressure load is stabilized, a lateral pressure load is applied to the rock simulation sample 16 by the left loader 6 and right loader 10, and after the applied lateral pressure load is stabilized, the rock simulation sample 16 is horizontally loaded by the front loader 14 and the rear loader 15. Apply axial pressure load.

Step S30 for adjusting the pressure load: The front loader 14 and the rear loader 15 are loaded in different loading directions so that the pressure gauges of the front loader 14, rear loader 15, left loader 6, right loader 10, and lower loader 11 reach predetermined values, respectively. , left loader 6, right loader 10 and lower loader 11 are adjusted.

Test step S40: By controlling the hydraulic unloading speed in the front loader 14, the rock simulant sample 16 is unloaded. Including performing an unload test for receiving and obtaining an acoustic emission signal.

Preferably, the above S40 further includes adjusting the energy supply speed: reloading the upper support end 5 and adjusting the upper hydraulic jack 18 loading speed by adjusting the stiffness of the spring 4 and the loading speed of the upper hydraulic jack 18; transmits the load to the rock simulation sample 16 in turn through the pressure transmission ring 19, the spring 4 and the upper support end 5, and the signal received at the acoustic emission signal receiving end determines the rock simulation with different stiffness and different load speed. By analyzing the internal fracture rule of sample 16, we analyze the influence of energy supply rate on rock dynamic disasters. A way to adjust the stiffness of the spring 4 is to employ springs of different stiffness during loading. A method of adjusting the load speed of the spring loader 3 is to control the load speed by controlling the hydraulic load speed inside the upper hydraulic jack 18 .

Preferably, the above S40 further includes a dynamic disturbance test: waves with different frequencies, different waveforms and different amplitudes are generated by the waveform transmitter 1, and the waves are applied to the rock simulation sample 16 via the connecting rod 2 to apply dynamic disturbance loads. to analyze the effects of wave loading frequency, amplitude and waveform on dynamic hazards. The received acoustic emission signal obtains the acoustic emission signal rule generated when the interior of the rock simulation sample 16 breaks down to obtain the effect of the wave loading frequency, amplitude and waveform on the dynamic hazard.

The simulation device of the above embodiment can load the rock simulation sample 16 with pressure loads having different lateral pressure coefficients. Thus, loading the rock simulation sample 16 with pressure loads with different lateral pressure coefficients is realized. The simulation device of this embodiment can also realize unloading to the rock simulation sample, application of disturbance load, and control of the energy transfer rate inside the rock body. The simulator of this example tests the acoustic emission rule due to the fracture inside the rock body with the acoustic emission probe.

The simulation device and test method of this embodiment simulate the rigidity change and deformation speed of the rock body by adjusting the rigidity change of the spring located in the upper part and the loading speed of the upper hydraulic jack, and transfer to the rock simulation sample 16 below. We will change the energy supply rate of , and analyze the effect of the energy transfer rate on the mountain spring.

1 waveform transmitter 2 connecting rod 3 upper loader 4 spring 5 upper support end 6 left loader 7 left hydraulic jack 8 left support end 9 acoustic emission wiring hole 10 right loader 11 lower loader 12 fixing nut 13 bottom fixed end 14 front loader 15 Rear loader 16 Simulated rock sample 17 Annular fixing base 18 Upper hydraulic jack 19 Pressure transmission ring

Claims (2)

A test method for deep rock mass splash dynamic hazards, comprising the steps of:
Install the lower loader S10: First, fix the bottom fixed end (13) to the concrete floor with the fixing nut (12), then pass through the acoustic emission wiring hole (9) at the lower support end of the lower loader (11). The acoustic emission probe is attached to the rock simulation sample (16), the convex part of the acoustic emission probe is fitted to the concave part of the acoustic emission wiring hole (9), and the lower hydraulic jack is attached to the bottom fixed end through the fixing nut (12). fixing to (13);
Loading the rock simulation sample S20: After attaching the acoustic emission probe to the rock simulation sample (16), the rock simulation sample (16) is placed on the lower support end 11 of the lower loader (11), and the acoustic emission probe is connected. The six wires connect the acoustic emission wiring holes (9) in the front loader (14), rear loader (15), left loader (6), right loader (10), upper loader (3) and lower loader (11) respectively. through and connected to the external acoustic emission signal receiving end, then apply a predetermined vertical pressure to the rock simulation sample (16) by the lower loader (11), during the upward movement of the lower loader (11) , the rock simulation sample (16) generates vertical pressure through the interaction between the lower loader (11) and the upper support end (5), and after the vertical pressure load is stabilized, the left loader (6) and the right loader (10) applying a lateral pressure load to the rock simulating sample (16) by applying a lateral pressure load to the rock simulating sample (16), and after the applied lateral pressure load is stabilized, applying a horizontal axial pressure load to the rock simulating sample (16) by the front loader (14) and the rear loader (15);
Adjust pressure load S30: Different loads are adjusted so that the pressure gauges of the lower loader (11), front loader (14), rear loader (15), left loader (6), and right loader (10) reach predetermined values. adjusting the direction of the lower loader (11), the front loader (14), the rear loader (15), the left loader (6), the right loader (10);
Test S40: By controlling the hydraulic unloading speed in the front loader (14), the rock simulation sample (16) is unloaded, and in the process of unloading, the rock simulation sample ( 16) performing an unload test that records the acoustic emission signal due to the breakdown;
Adjusting the energy supply rate: By adjusting the stiffness of the spring (4) and the loading speed of the upper hydraulic jack (18), the upper support end (5) is reloaded and the upper hydraulic jack (18) is , the load is transmitted to the rock simulation sample (16) through the pressure transmission ring (19), the spring (4) and the upper support end (5) in order, and the signal received at the acoustic emission signal receiving end causes different stiffness and analyzing the effect of energy supply rate on rock dynamic hazards by analyzing the acoustic emission law generated when the interior of the rock simulant (16) fails for different loading rates; and Disturbance test: waves of different frequencies, different waveforms and different amplitudes are generated by the waveform transmitter (1), the waves apply dynamic disturbance loads to the rock simulation sample (16) through the connecting rod (2), and are received. Acquisition of the acoustic emission signal rule generated when the interior of the rock simulant (16) is broken by the acoustic emission signal obtained from the wave loading frequency, amplitude and waveform to obtain the impact on the dynamic hazard. ,
A method comprising: Said upper loader (3) includes waveform transmitter (1), connecting rod (2), spring (4), upper support end (5), upper hydraulic jack (18) and pressure transmission ring (19), and waveform transmission The container (1) is fixedly connected to the tip of the connecting rod (2), the bottom end of the connecting rod (2) is fixedly connected to the upper supporting end (5), and the annular fixing base (17) is externally connected to the upper supporting end (5). The bottom surface of the upper support end (5) faces the rock simulation sample (16), the spring (4) is fitted onto the connecting rod (2), and one end of the spring (4) is connected to the upper support end (5). , the other end of the spring (4) abuts on the pressure transmission ring (19), the upper hydraulic jack (18) is fixedly connected to the pressure transmission ring (19), and the upper support end (5) 2. The testing method of deep rock body splash dynamic hazard according to claim 1, characterized in that there is provided an acoustic emission wiring hole (9).

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