CN212391352U - Loaded coal rock mass CT triaxial experiment sample loading device - Google Patents

Abstract

The utility model discloses a loaded coal rock mass CT triaxial experiment dress appearance device, its characterized in that: the coal sample vacuum pump comprises a clamp assembly, a coal sample assembly serving as a clamp clamping object, a vacuum pump mechanism used for assembling the coal sample assembly and a jacking mechanism used for loading the coal sample assembly into the clamp assembly; the coal rock sample is sleeved with an elastic rubber sleeve, and the diameter of the rubber sleeve is smaller than that of the coal rock sample in a natural shrinkage state; the vacuum pump mechanism comprises a vacuum pump and a sample loading pipe with openings at the upper end and the lower end, an air suction port of the vacuum pump is connected with a vacuum pumping pipeline for pumping air through a connecting flange, and the tail end of the vacuum pumping pipeline is communicated with the side wall of the sample loading pipe along the radial direction of the sample loading pipe; meanwhile, the clamp assembly can be conveniently assembled or disassembled by matching the jacking mechanism with tools such as a depth gauge and the like, and the work of sample loading or disassembling can be conveniently and reliably completed.

Description

Loaded coal rock mass CT triaxial experiment sample loading device

Technical Field

The utility model relates to a geotechnical engineering field especially relates to a triaxial experiment loaded coal petrography sample loading device based on real-time dynamic scanning of industry micro-CT.

Background

CT scanning is a nondestructive test detection technology, is widely applied to experimental research on the microscopic damage mechanical characteristics of rocks in recent years, and is a very effective means for exploring the development and expansion rules of internal or surface fractures in the rock damage process.

From CT real-time dynamic scanning experiments under the condition of online loading of samples, stress-strain curves of the loaded sample in the whole destabilization damage process and CT scanning information of sample microscopically three-dimensional fracture structures at various stages under loading can be obtained, and experimental data are provided for the whole process of analyzing the destabilization of the loaded sample.

The sample loading of the test piece in the coal-loaded rock mass CT triaxial test is particularly critical, and the accuracy of the test result is directly influenced by the quality of the sample loading of the test piece.

In the prior art, due to the fact that manpower is excessively relied on, the coal rock sample is damaged, the sample cannot be guaranteed to be located at the axis position of the clamp assembly, the sample is bent due to improper sample loading, and the like, and the experiment result deviation is caused.

Therefore, the sample loading structure and the sample loading method which are efficient, accurate and low in labor intensity are urgently needed to be developed, the integrity of a sample is guaranteed, and the test piece is prevented from inclining and breaking.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a loaded coal rock mass CT triaxial experiment dress appearance device that can not damage coal petrography sample when easily assembling, coal petrography sample can bear the confined pressure again with can not invaded by confined pressure liquid.

In order to achieve the purpose, the loaded coal rock mass CT triaxial experiment sample loading device comprises a clamp holder assembly, a coal sample assembly serving as a clamping object of the clamp holder, a vacuum pump mechanism used for assembling the coal sample assembly and a jacking mechanism used for loading the coal sample assembly into the clamp holder assembly;

the coal sample assembly comprises a coal rock sample, an upper pressing block is arranged above the coal rock sample in a pressing mode, a lower pressing block is arranged below the coal rock sample in a pressing mode, the upper pressing block and the lower pressing block are identical in structure and size, and vent holes which are correspondingly communicated up and down are respectively formed in the upper pressing block and the lower pressing block;

the upper pressing block and the coal rock sample are coaxially arranged and have the same diameter; the coal rock sample is sleeved with an elastic rubber sleeve, the upper end and the lower end of the rubber sleeve are respectively sleeved on the lower part of the upper pressing block and the upper part of the lower pressing block, and the diameter of the rubber sleeve is smaller than that of the coal rock sample in a natural shrinkage state;

the vacuum pump mechanism comprises a vacuum pump and a sample containing pipe with openings at the upper end and the lower end, and the sample containing pipe is vertically arranged; the suction port of the vacuum pump is connected with a vacuum pumping pipeline for pumping air through a connecting flange, the tail end of the vacuum pumping pipeline is communicated with the side wall of the sample loading pipe along the radial direction of the sample loading pipe, the inner diameter of the sample loading pipe is larger than the diameter of the coal rock sample and is used for adsorbing the rubber sleeve, and the length of the sample loading pipe is longer than that of the coal rock sample.

The clamp holder assembly comprises a shell, the shell is provided with an inner cavity, a coal sample assembly is arranged at the vertical axis of the inner cavity, an upper opening pipe is integrally arranged at the top of the shell right above the coal sample assembly, a threaded flange and a liquid outlet pressing block are assembled in the upper opening pipe from top to bottom, the threaded flange is in threaded connection with the inner wall of the upper opening pipe, the liquid outlet pressing block is downwards pressed and connected with the coal sample assembly,

the axial line of the liquid outlet pressing block is provided with a vent hole which is communicated with the vent hole of the upper pressing block of the coal sample assembly downwards, the liquid outlet pressing block is integrally provided with a seepage air outlet pipe upwards, and the seepage air outlet pipe upwards extends out of an inner hole of the threaded flange;

a liquid outlet hole for enclosing the inner cavity of the pressure liquid flowing out of the shell is radially arranged in the side wall of the upper opening pipe at the liquid outlet pressing block, and the liquid outlet hole is outwards connected with a liquid outlet pipe; a gap is arranged between the middle lower part of the liquid outlet pressing block and the inner wall of the upper opening pipe, and the liquid outlet hole is communicated with the inner cavity of the shell through the gap; an annular sealing ring for preventing confining pressure liquid from seeping out of the upper opening pipe upwards is arranged between the top of the liquid outlet pressing block and the inner wall of the upper opening pipe;

a lower opening pipe is integrally arranged at the bottom of the shell right below the coal sample assembly, a liquid inlet plug is arranged in the lower opening pipe, and an annular sealing ring for preventing confining pressure liquid from seeping out of the lower opening pipe downwards is arranged between the bottom of the liquid inlet plug and the inner wall of the lower opening pipe; a gap communicated with the inner cavity is formed between the middle upper part of the liquid inlet plug and the inner wall of the lower opening pipe, a liquid inlet hole for confining pressure liquid to flow into the shell is formed in the side wall of the lower opening pipe at the gap along the radial direction, and the liquid inlet hole is connected with a liquid inlet pipe; the bottom of the outer wall of the lower opening pipe is provided with an external thread which is used for being in threaded connection with the jacking mechanism; and the axis of the liquid inlet plug is provided with a seepage air inlet which is correspondingly communicated with the vent hole of the lower pressing block.

The jacking mechanism comprises a hollow frame, a low-speed electric push rod is arranged in the frame, and an extension rod of the low-speed electric push rod faces to the right upper side; a mounting hole is formed in the top wall of the rack right above an extension bar of the low-speed electric push rod, and a lower opening pipe is in threaded connection with the mounting hole;

a top disc is arranged at the top end of an extension rod of the low-speed electric push rod, and a cushion block used for jacking the liquid inlet plug is arranged on the top disc.

In the clamp holder assembly, the top of the seepage air outlet pipe is provided with an external thread for disassembling the hydraulic block;

the lower end of the seepage air inlet hole is provided with an expanding part for ventilating and disassembling the liquid inlet plug, and the expanding part is provided with an internal thread for disassembling the liquid inlet plug or connecting the ventilating joint.

In the coal sample assembly, two annular ribs radially protrude from the lower part of the upper pressing block, and an upper annular groove is formed between the two annular ribs; two annular ribs radially protrude from the upper part of the lower pressing block, and a lower annular groove is formed between the two annular ribs; the upper portion of the rubber sleeve is sleeved on the upper annular groove, the lower portion of the rubber sleeve is sleeved on the lower annular groove, a rubber band used for compressing the rubber sleeve is sleeved on the rubber sleeve at the upper annular groove, and a rubber band used for compressing the rubber sleeve is sleeved on the rubber sleeve at the lower annular groove.

An upper positioning groove is arranged at the center of the bottom end of the liquid outlet pressing block, and an upper positioning lug matched with the upper positioning groove is upwards arranged at the center of the top end of the upper pressing block of the coal sample assembly;

the center of the upper end of the liquid inlet plug is provided with a lower positioning groove, and the center of the bottom end of the lower pressing block of the coal sample assembly is downwards provided with a lower positioning lug matched with the lower positioning groove.

The bottom surface of the upper pressing block and the top surface of the lower pressing block are both provided with a ventilation groove in a shape like a Chinese character 'mi' along the horizontal plane for uniform ventilation, the ventilation groove on the bottom surface of the upper pressing block is communicated with the ventilation hole in the upper pressing block, and the ventilation groove on the top surface of the lower pressing block is communicated with the ventilation hole in the lower pressing block.

The utility model discloses have following advantage:

the utility model can conveniently assemble the coal sample assembly through the vacuum pump mechanism, and the coal rock sample is not easy to damage; meanwhile, the clamp assembly can be conveniently assembled or disassembled by matching the jacking mechanism with tools such as a depth gauge and the like, and the work of sample loading or disassembling can be conveniently and reliably completed.

The elastic rubber sleeve covers the coal rock sample, so that the coal rock sample can be subjected to the confining pressure transmitted by the confining pressure liquid, and the confining pressure liquid is prevented from invading the coal rock sample. To do this, it is necessary to make the rubber sleeve firmly hold the coal rock sample and the upper and lower press blocks by the contractile force, so that the diameter of the rubber sleeve in the natural contraction state needs to be smaller than that of the coal rock sample. When the coal rock sample is loaded, the rubber sleeve is difficult to sleeve on the coal rock sample, and the rubber sleeve is forced to be sleeved upwards, so that the coal rock sample is easily damaged.

The utility model discloses a vacuum pump mechanism can utilize the negative pressure to make rubber sleeve adsorb at dress sample pipe inner wall conveniently, thereby need not manual or use mechanical force to prop big rubber sleeve pipe back cover to the coal petrography sample, the phenomenon that the coal petrography sample atress is damaged when just so having avoided manual or mechanical force to overlap rubber sleeve pipe at the coal petrography sample, make rubber sleeve pipe parcel tight coal petrography sample, it has the feasibility to realize that the coal petrography sample has not only born the confining pressure but also kept apart with the confining pressure liquid, and can convenient and fast ground dress appearance operation, high convenience is used.

The arrangement of the vent hole, the seepage air inlet hole and the seepage air outlet pipe is convenient for the seepage experiment. And the liquid outlet pipe and the liquid inlet pipe are arranged to apply confining pressure to the coal rock sample conveniently.

The structure of the holder assembly of the coal rock sample is convenient to assemble and can stably clamp the coal sample assembly. The arrangement of the vent hole, the seepage air inlet hole and the seepage air outlet pipe is convenient for the seepage experiment. And the liquid outlet pipe and the liquid inlet pipe are arranged to apply confining pressure to the coal rock sample conveniently.

The external screw thread is arranged at the top of the seepage air outlet pipe, so that the seepage air outlet pipe has the dual functions of air outlet during seepage experiments and disassembly of the hydraulic block, the nut and the seepage air outlet pipe are only needed to be connected during disassembly, the handle connected with the nut is pulled upwards, the top cover of the nut is pulled upwards by the annular plate, the liquid outlet pressing block can be conveniently pulled out, and the problem of inconvenient force application during disassembly of the hydraulic block is solved.

The arrangement of the upper annular groove, the lower annular groove and the rubber band can further prevent surrounding pressure liquid from entering a coal rock sample through the rubber sleeve.

The upper positioning groove is matched with the upper positioning lug, so that the coaxial line of an upper pressing block and a liquid outlet pressing block of the coal sample assembly can be ensured during sample loading, the coaxial line of the coal sample assembly and the clamp assembly is ensured, and the problem caused by non-coaxial line is avoided. When a seepage experiment is carried out, the ventilation groove shaped like a Chinese character 'mi' can enable fluid to uniformly pass through a coal rock sample.

Drawings

FIG. 1 is a schematic structural view of a loaded coal rock CT triaxial test sample loading device of the present invention during sample loading;

FIG. 2 is a schematic structural diagram of the loaded coal rock CT triaxial test sample loading device of the present invention during sample unloading;

FIG. 3 is a schematic diagram of the construction of the vacuum pump mechanism;

FIG. 4 is a schematic top view of a jacking mechanism;

FIG. 5 is a schematic view of the structure of the tie rod;

FIG. 6 is a schematic structural view of the bottom surface of the upper briquette and the top surface of the lower briquette;

FIG. 7 is a schematic view of the construction of the gripper assembly.

Detailed Description

As shown in fig. 1 to 7, the loaded coal rock mass CT triaxial experiment sample loading device of the present invention comprises a gripper assembly, a coal sample assembly as a gripping object of the gripper, a vacuum pump mechanism for assembling the coal sample assembly, and a jacking mechanism for loading the coal sample assembly into the gripper assembly;

the coal sample assembly comprises a coal rock sample 25, an upper pressing block 6 is arranged above the coal rock sample 25 in a pressing mode, a lower pressing block 16 is arranged below the coal rock sample 25 in a pressing mode, and the upper pressing block 6 and the lower pressing block 16 are identical in structure and size and are symmetrically arranged on the upper side and the lower side of the coal rock sample 25. The upper pressing block 6 and the lower pressing block 16 are respectively provided with vent holes 7 which are correspondingly communicated up and down;

the upper pressing block 6 and the coal rock sample 25 are coaxially arranged and have the same diameter; the coal rock sample 25 is sleeved with an elastic rubber sleeve 26, the upper end and the lower end of the rubber sleeve 26 are respectively sleeved on the lower part of the upper pressing block 6 and the upper part of the lower pressing block 16, and the diameter of the rubber sleeve 26 is smaller than that of the coal rock sample 25 in a natural contraction state;

the vacuum pump mechanism comprises a vacuum pump 31 and a sample containing pipe 32 with openings at the upper end and the lower end, and the sample containing pipe 32 is vertically arranged; the suction port of the vacuum pump 31 is connected with a vacuumizing pipeline 33 for pumping air through a connecting flange, the tail end of the vacuumizing pipeline 33 is communicated with the side wall of the sample loading pipe 32 along the radial direction of the sample loading pipe 32, the inner diameter of the sample loading pipe 32 is larger than the diameter of the coal rock sample 25 and is used for adsorbing the rubber sleeve 26, and the length of the sample loading pipe 32 is longer than that of the coal rock sample 25. The attachment flange is a conventional device, not shown.

And a sealing ring is arranged at the flange of the vacuum pump 31 mechanism to ensure the air tightness. Preferably, the coal rock sample 25 is cylindrical and has a size of 25mm × 50mm or 50mm × 100mm (diameter × height, numerical unit is mm).

Preferably, the inner diameter of the rubber sleeve 26 is 96% of the diameter of the coal rock sample 25 in a natural shrinkage state, namely, the specification is 24mm × 97mm or 48mm × 150 mm.

When the elastic rubber sleeve 26 covers the coal rock sample 25, the coal rock sample 25 can be subjected to the confining pressure transmitted by the confining pressure liquid, and the confining pressure liquid is prevented from invading the coal rock sample 25. To do this, it is necessary to make the rubber tube 26 firmly hold the coal sample 25 and the upper and lower press blocks 6 and 16 by a contractive force, so that the rubber tube 26 needs to have a diameter smaller than the coal sample 25 in a naturally contracted state. This causes a problem that it is difficult to fit the rubber sleeve 26 over the coal rock sample 25 during sample loading, and the coal rock sample 25 is easily damaged by forcibly fitting the rubber sleeve upward.

The utility model discloses a vacuum pump 31 mechanism can utilize the negative pressure to make rubber sleeve 26 adsorb at dress appearance pipe 32 inner wall conveniently, thereby need not manual or use mechanical force to prop big rubber sleeve 26 back cover to coal petrography sample 25, just so avoided manual or mechanical force with the rubber sleeve 26 cover the damaged phenomenon of coal petrography sample 25 atress when coal petrography sample 25, make rubber sleeve 26 parcel tight coal petrography sample 25, it has the feasibility to realize that coal petrography sample 25 both bears the confining pressure and has kept apart with the confining pressure liquid, and can convenient and fast ground dress appearance operation, it is very convenient to use.

The clamp holder assembly comprises a shell 1, the shell 1 is provided with an inner cavity 2, a coal sample assembly is arranged at the vertical axis of the inner cavity 2, an upper opening pipe 3 is integrally arranged at the top of the shell 1 right above the coal sample assembly, a threaded flange 4 and a liquid outlet pressing block 5 are assembled in the upper opening pipe 3 from top to bottom, the threaded flange 4 is in threaded connection with the inner wall of the upper opening pipe 3, the liquid outlet pressing block 5 is downwards pressed and connected with the coal sample assembly,

the axial line of the liquid outlet pressing block 5 is provided with a vent hole 7 which is used for being communicated with a vent hole 7 of an upper pressing block 6 of the coal sample assembly downwards, the liquid outlet pressing block 5 is integrally provided with a seepage outlet pipe 8 (the seepage outlet pipe 8 and the liquid outlet pressing block 5 are integrated) which is communicated with the vent hole 7 upwards, and the seepage outlet pipe 8 extends upwards out of an inner hole of the threaded flange 4;

a liquid outlet hole 9 for surrounding pressure liquid (the surrounding pressure liquid can be water or oil) to flow out of the inner cavity 2 of the shell 1 is radially arranged in the side wall of the upper opening pipe 3 at the liquid outlet pressing block 5, and the liquid outlet hole 9 is outwards connected with a liquid outlet pipe 10; a gap is arranged between the middle lower part of the liquid outlet pressing block 5 and the inner wall of the upper opening pipe 3, and the liquid outlet hole 9 is communicated with the inner cavity 2 of the shell 1 through the gap; an annular sealing ring 11 for preventing confining pressure liquid from seeping out of the upper opening pipe 3 upwards is arranged between the top of the liquid outlet pressing block 5 and the inner wall of the upper opening pipe 3;

a lower opening pipe 12 is integrally arranged at the bottom of the shell 1 right below the coal sample assembly, a liquid inlet plug 13 is arranged in the lower opening pipe 12, and a plurality of annular sealing rings 11 for preventing confining pressure liquid from leaking out of the lower opening pipe 12 downwards are arranged between the bottom of the liquid inlet plug 13 and the inner wall of the lower opening pipe 12; a gap communicated with the inner cavity 2 is formed between the middle upper part of the liquid inlet plug 13 and the inner wall of the lower opening pipe 12, a liquid inlet hole 14 for confining pressure liquid to flow into the shell 1 is radially arranged in the side wall of the lower opening pipe 12 at the gap, and the liquid inlet hole 14 is connected with a liquid inlet pipe 15; the bottom of the outer wall of the lower opening pipe 12 is provided with an external thread for being in threaded connection with a jacking mechanism (specifically, a mounting hole in the jacking mechanism); and a seepage air inlet 17 which is correspondingly communicated with the vent hole 7 of the lower pressing block 16 is arranged at the axis of the liquid inlet plug 13.

The housing 1 of the gripper assembly is preferably made of carbon fiber, and the scanning effect of the radiation on the sample is not influenced.

The arrangement of the vent hole 7, the seepage air inlet hole 17 and the seepage air outlet pipe 8 is convenient for seepage experiments. The liquid outlet pipe 10 and the liquid inlet pipe 15 are arranged to apply confining pressure on the coal rock sample 25 conveniently.

During the use, inject into the experimental gas of seepage flow into in the coal sample assembly through seepage flow inlet hole 17, make the experimental gas outflow of seepage flow through seepage flow outlet duct 8, through measuring the gas flow who injects the outflow, test coal petrography sample 25 seepage flow characteristic's experiment carries out. When confining pressure needs to be loaded, confining pressure liquid is injected into the shell 1 through the liquid inlet pipe 15, and meanwhile, a valve on a pipeline connected with the liquid outlet pipe 10 is closed, so that the confining pressure is applied to the coal rock sample 25 in the coal sample assembly.

The jacking mechanism comprises a hollow frame 34, a low-speed electric push rod 35 is arranged in the frame 34, and the low-speed electric push rod 35 is arranged on a base 40. The extension bar 36 of the low-speed electric push rod 35 faces to the right upper part; a mounting hole 37 is formed in the top wall of the frame 34 right above the extension bar 36 of the low-speed electric push rod 35, and the lower opening pipe 12 is in threaded connection with the mounting hole 37;

the top end of the extension rod 36 of the low-speed electric push rod 35 is provided with a top disc 38, and a cushion block 39 for jacking the liquid inlet plug 13 is arranged on the top disc 38. Wherein the mounting hole 37 is located at the very center of the top wall of the frame 34.

In the clamp holder assembly, the top of the seepage air outlet pipe 8 is provided with an external thread for disassembling the hydraulic block 5; the lower end of the seepage air inlet hole 17 is provided with an expanding part 18 for ventilating and disassembling the liquid inlet plug 13, and the expanding part 18 is provided with an internal thread for disassembling the liquid inlet plug 13 or connecting a ventilating joint for air inlet in a seepage experiment.

8 tops of seepage flow outlet duct are equipped with the external screw thread, and the dual function of dismantling hydraulic block 5 when making seepage flow outlet duct 8 have the seepage flow experiment give vent to anger and dismantle, only need use nut and 8 threaded connection of seepage flow outlet duct during the dismantlement, upwards stimulate the handle that is connected with the nut again, and the annular plate upwards stimulates the top cap of nut this moment, can conveniently extract hydraulic block 5, solves the problem of the inconvenient application of force when dismantling hydraulic block 5.

In the coal sample assembly, two annular ribs radially protrude from the lower part of the upper pressing block 6, and an upper annular groove 27 is formed between the two annular ribs; two annular ribs radially protrude from the upper part of the lower pressing block 16, and a lower annular groove 28 is formed between the two annular ribs; the upper portion of the rubber sleeve 26 is sleeved on the upper annular groove 27, the lower portion of the rubber sleeve 26 is sleeved on the lower annular groove 28, a rubber band used for pressing the rubber sleeve 26 is sleeved on the rubber sleeve 26 at the position of the upper annular groove 27, and a rubber band used for pressing the rubber sleeve 26 is sleeved on the rubber sleeve 26 at the position of the lower annular groove 28. The elastic band is a conventional device, not shown.

The arrangement of the upper annular groove 27, the lower annular groove 28 and the rubber band can further prevent surrounding pressure liquid from entering the coal rock sample 25 through the rubber sleeve 26.

An upper positioning groove 19 is arranged at the center of the bottom end of the liquid outlet pressing block 5, and an upper positioning lug 20 matched with the upper positioning groove 19 is upwards arranged at the center of the top end of the upper pressing block 6 of the coal sample assembly;

the center of the upper end of the liquid inlet plug 13 is provided with a lower positioning groove 23, and the center of the bottom end of the lower pressing block 16 of the coal sample assembly is downwards provided with a lower positioning convex block 24 matched with the lower positioning groove 23.

The upper positioning groove 19 is matched with the upper positioning lug 20, so that the coaxial line of the upper pressing block 6 and the liquid outlet pressing block 5 of the coal sample assembly can be ensured during sample loading, the coaxial line of the coal sample assembly and the clamp assembly is ensured, and the problem caused by the non-coaxial line is avoided.

The bottom surface of the upper pressing block 6 and the top surface of the lower pressing block 16 are both provided with a ventilation groove 29 which is shaped like a Chinese character 'mi' and used for uniform ventilation along the horizontal plane, the ventilation groove 29 on the bottom surface of the upper pressing block 6 is communicated with the ventilation hole 7 in the upper pressing block 6, and the ventilation groove 29 on the top surface of the lower pressing block 16 is communicated with the ventilation hole 7 in the lower pressing block 16. In the seepage test, the ventilation grooves 29 in a shape like a Chinese character mi allow the fluid to uniformly pass through the coal rock sample 25.

The utility model also discloses a dress appearance method that uses above-mentioned loaded coal rock mass CT triaxial experiment dress appearance device to go on carries out according to following step:

the first step is a preparation step;

the second step is to make a coal sample assembly;

and the third step is to install the clamp assembly to finish sample loading.

The first step, the preparation step, is specifically: manufacturing a coal rock sample 25, debugging a vacuum pump 31 and a low-speed electric push rod 35 to ensure that the coal rock sample is in a usable state;

the second step, namely the coal sample manufacturing assembly, comprises the following specific steps:

the first sub-step is to load the loading tube 32;

the rubber sleeve 26 is plugged into a sample containing pipe 32 of a vacuum pump 31 mechanism, and the upper end and the lower end of the rubber sleeve 26 respectively extend out of the upper end and the lower end of the sample containing pipe 32;

the second substep is to turn over and wrap up;

the upper end and the lower end of the rubber sleeve 26 are respectively folded outwards (the term "outside" refers to the outside of the sample tube 32) and then pulled back, so that the two ends of the rubber sleeve 26 are covered outside the two ends of the sample tube 32;

the third substep is to expand the rubber sleeve 26;

the vacuum pump 31 is opened, and the negative pressure is transmitted to the gap between the rubber sleeve 26 and the inner wall of the sample loading pipe 32 along the vacuum-pumping pipeline 33, so that the rubber sleeve 26 is expanded and adsorbed on the inner wall of the sample loading pipe 32 under the action of the negative pressure;

the fourth substep is to load the coal rock sample 25;

turning off the vacuum pump 31, loading the coal rock sample 25 into the rubber sleeve 26 in the sample loading pipe 32 from the opening at any end of the rubber sleeve 26, then loading the bottom of the upper pressing block 6 into the rubber sleeve 26, and loading the top of the lower pressing block 16 into the rubber sleeve 26; the upper end part of the rubber sleeve 26 is turned over from the outer wall of the upper end of the sample containing pipe 32 and covers the bottom of the pressing block 6; turning down the lower end part of the rubber sleeve 26 from the outer wall of the lower end of the sample loading pipe 32 and coating the top of the lower pressing block 16 to form a coal sample assembly; at the moment, the negative pressure between the rubber sleeve 26 and the inner wall of the sample containing tube 32 is relieved;

the fifth substep is to take out the coal sample assembly;

and taking the whole coal sample assembly out of the sample loading pipe 32 to finish the manufacture of the coal sample assembly.

The utility model discloses broken through the conventional connection structure that the axial links to each other between pipeline and the pipeline, make evacuation pipeline 33 communicate with each other with dress appearance pipe 32 along dress appearance pipe 32's radial direction, through the negative pressure, expand rubber sleeve 26 and adsorb and adorn the coal sample and go up briquetting 6 and briquetting 16 down behind dress appearance pipe 32 inner wall, think about ingeniously, the operation of packing into the great coal petrography sample 25 of diameter in the less rubber sleeve 26 of diameter has been simplified greatly, and the process of packing into can not harm coal petrography sample 25, make coal petrography sample 25 can receive the confined pressure that the confined pressure liquid transmitted, prevent again that the confined pressure liquid from invading coal petrography sample 25.

Turning down the upper end part of the rubber sleeve 26 from the outer wall of the upper end of the sample containing tube 32 and coating the bottom of the upper pressing block 6, coating the rubber sleeve 26 in the upper annular groove 27 at the lower part of the upper pressing block 6, and then using a rubber band, wherein the diameter of the rubber band is smaller than that of the upper pressing block 6 when the rubber band is naturally contracted; the rubber band is used for pressing the rubber sleeve 26 into the upper annular groove 27;

turning down the lower end part of the rubber sleeve 26 from the outer wall of the lower end of the sample containing pipe 32 and coating the top of the lower pressing block 16, coating the rubber sleeve 26 in a lower annular groove 28 at the upper part of the lower pressing block 16, and then using a rubber band, wherein the diameter of the rubber band is smaller than that of the lower pressing block 16 when the rubber band is naturally contracted; causing the rubber band to compress the rubber cannula 26 within the lower annular groove 28.

By using rubber bands to press the rubber bushing 26 into the upper and lower annular grooves 27, 28, it has a dual function: on one hand, the sealing performance between the rubber sleeve 26 and the upper pressing block 6 and the lower pressing block 16 can be further improved, and the surrounding pressure liquid is prevented from invading the coal rock sample 25 during the experiment; on the other hand, the rubber sleeve 26 can be prevented from slipping relative to the coal rock sample 25.

The first substep is to connect the coal sample assembly with the liquid inlet plug 13; pressing a lower positioning bump 24 of a lower pressing block 16 of the coal sample assembly into a lower positioning groove 23 at the upper end of the liquid inlet plug 13 to ensure that the coal sample assembly and the liquid inlet plug 13 are coaxial;

the second substep is to mount the coal sample assembly and body 1 of the clamp assembly on the jack-up mechanism;

operating the low-speed electric push rod 35, lowering the extension rod 36 of the low-speed electric push rod 35 to the lowest position, and placing a cushion block 39 for jacking the liquid inlet plug 13 on a top disc 38 at the top end of the extension rod 36; the liquid inlet plug 13 connected with the coal sample assembly penetrates through the mounting hole 37 from top to bottom, the bottom end of the liquid inlet plug 13 is placed on the cushion block 39, and the middle upper part of the coal sample assembly is higher than the mounting hole 37; sleeving a shell 1 of the clamp assembly on the coal sample assembly above the mounting hole 37 from top to bottom, and screwing a lower opening pipe 12 integrally arranged with the shell 1 into the mounting hole 37 and connecting the lower opening pipe with the mounting hole 37 in a threaded manner;

the third substep is to lift up the coal sample assembly and feed liquor choke plug 13;

the total thickness of the hydraulic block 5 and the threaded flange 4 is measured to be Xmm (namely X millimeter) by a graduated scale, then a depth scale is arranged at the top of the upper open pipe 3 of the gripper assembly, the scale frame of the depth scale is arranged at the top end of the upper open pipe 3, and the scale body of the depth scale falls downwards to the top end of the upper pressing block 6; the annular sealing ring 11 is sleeved at the bottom of the liquid inlet plug 13, the low-speed electric push rod 35 is controlled, the extension rod 36 of the low-speed electric push rod is enabled to be lifted upwards slowly at a constant speed, when the scale of the depth scale is Xmm, the low-speed electric push rod 35 is controlled to stop moving immediately, the liquid outlet press block 5 and the threaded flange 4 can be ensured to be arranged in the upper open pipe 3 right, at the moment, the liquid inlet plug 13 is lifted upwards into the lower open pipe 12, the annular sealing ring 11 forms sealing between the liquid inlet plug 13 and the inner wall of the lower open pipe 12, and confining pressure liquid is prevented from leaking out of the lower open pipe 12 downwards;

the fourth substep is to assemble the gripper assembly;

the pull rod is used and comprises a handle 61, the handle 61 is connected with a vertical rod 62 downwards, a screw cap 63 is sleeved on the vertical rod 62, and the screw cap 63 is provided with a top cover and is opened at the lower end; an annular plate 65 for supporting the top cover of the nut 63 is fixedly connected to the vertical rod 62 below the top cover of the nut 63, and a guide needle 66 for guiding when the clamp assembly is assembled is connected downwards to the vertical rod 62;

the top of the liquid outlet pressing block 5 is sleeved with an annular sealing ring 11, a guide needle 66 of a pull rod is inserted into a vent hole 7 of the liquid outlet pressing block 5 and then is aligned with and inserted into the vent hole 7 of the upper pressing block 6, so that the liquid outlet pressing block 5 is pressed into the upper open pipe 3 by guiding, the liquid outlet pressing block 5 and the coal sample assembly are ensured to be coaxial, the eccentric force is prevented, and meanwhile, the upper positioning bump 20 of the upper pressing block 6 is ensured to just enter the upper positioning groove 19 at the bottom end of the liquid outlet pressing block 5; and (5) upwards pulling out the pull rod, screwing the threaded flange 4 into the upper open pipe 3, and assembling the clamp assembly to finish sample assembling.

After the sample is loaded, the holder assembly can be unscrewed from the rack 34, and the holder assembly is mounted on the CT machine for CT triaxial experiment.

The CT triaxial experiment specifically comprises the steps of installing the clamper assembly on a loading cylinder of a CT machine, further installing the clamper assembly on a triaxial rotary table in the CT machine, connecting a pipeline, and carrying out loading and scanning. The loading and scanning has three substeps: a first substep of positioning the scanned image: the position of an X axis and the position of a Y axis are adjusted by utilizing a position operating rod of the CT machine to enable a sample to be in a proper position, the position of a Z axis is adjusted to enable the sample to have the optimal resolution, and an image formed by the transmission of the coal rock sample 25 rotating for 360 degrees can be kept to occupy the center of a screen of the detector; a second substep, sample prepressing: exerting pre-jacking force on the coal rock sample 25 according to CT triaxial experiment operation specifications, wherein the pre-jacking force can ensure that the sample does not shake in the scanning process, so that the unclear scanned image is avoided; third substep, experimental scan: loading is carried out according to the experimental scheme and the operation specification, and scanning is carried out by utilizing CT equipment in the loading process.

And (5) after the CT triaxial experiment is completed, disassembling the sample.

The sample disassembly includes four substeps:

the first substep, after the experiment is finished, unscrewing and detaching the pipeline connected to the gripper assembly, and then detaching the gripper assembly with the coal rock sample 25 from the loading cylinder;

in the second sub-step, a handle 67 (shown in fig. 2) is used, the top end of the handle 67 is provided with an external thread matched with the internal thread of the expanding portion 18 of the seepage air inlet hole 17, the bottom end of the handle 67 is provided with a connecting disc 68, and the connecting disc 68 is used for being connected with the top disc 38 of the extension rod 36 of the low-speed electric push rod 35 through a bolt 69. The top end of the handle 67 is screwed into the diameter-expanding part 18 of the seepage air inlet 17, the connecting disc 68 is connected with the top disc 38 of the extension bar 36 of the low-speed electric push rod 35 through a bolt, then the low-speed electric push rod 35 is operated to enable the extension bar 36 to withdraw downwards, and the liquid inlet plug 13 is pulled out of the lower opening pipe 12 of the coal sample assembly.

The liquid inlet plug 13 cannot be damaged in the whole pulling-out process, the liquid inlet plug 13 is protected, and the liquid inlet plug 13 can be conveniently and laborsavingly taken out.

A third substep, using a pull rod, wherein the pull rod comprises a handle 61, the handle 61 is downwards connected with a vertical rod 62, a screw cap 63 is sleeved on the vertical rod 62, and the screw cap 63 is provided with a top cover and is opened at the lower end; an annular plate 65 for supporting the top cover of the nut 63 is fixedly connected to the vertical rod 62 below the top cover of the nut 63, and a guide needle 66 for guiding when the clamp assembly is assembled is connected downwards to the vertical rod 62;

the threaded flange 4 is unscrewed and detached by a flange wrench, the screw cap 63 of the pull rod is screwed on the external thread at the top of the seepage air outlet pipe 8, the liquid outlet pressing block 5 can be conveniently pulled out by pulling the handle 61 upwards, and the problem of inconvenient force application when the hydraulic block 5 is detached is solved.

And the fourth substep is to take out the coal sample assembly to finish the sample disassembly.

The above embodiments are only used for illustrating but not limiting the technical solutions of the present invention, and although the present invention is described in detail with reference to the above embodiments, those of ordinary skill in the art should understand that: the present invention may be modified or substituted with equivalents without departing from the spirit and scope of the invention, which should be construed as being limited only by the claims.

Claims (7)

1. Loading coal rock mass CT triaxial experiment dress appearance device, its characterized in that: the coal sample vacuum pump comprises a clamp assembly, a coal sample assembly serving as a clamp clamping object, a vacuum pump mechanism used for assembling the coal sample assembly and a jacking mechanism used for loading the coal sample assembly into the clamp assembly;

the coal sample assembly comprises a coal rock sample, an upper pressing block is arranged above the coal rock sample in a pressing mode, a lower pressing block is arranged below the coal rock sample in a pressing mode, the upper pressing block and the lower pressing block are identical in structure and size, and vent holes which are correspondingly communicated up and down are respectively formed in the upper pressing block and the lower pressing block;

the upper pressing block and the coal rock sample are coaxially arranged and have the same diameter; the coal rock sample is sleeved with an elastic rubber sleeve, the upper end and the lower end of the rubber sleeve are respectively sleeved on the lower part of the upper pressing block and the upper part of the lower pressing block, and the diameter of the rubber sleeve is smaller than that of the coal rock sample in a natural shrinkage state;

the vacuum pump mechanism comprises a vacuum pump and a sample containing pipe with openings at the upper end and the lower end, and the sample containing pipe is vertically arranged; the suction port of the vacuum pump is connected with a vacuum pumping pipeline for pumping air through a connecting flange, the tail end of the vacuum pumping pipeline is communicated with the side wall of the sample loading pipe along the radial direction of the sample loading pipe, the inner diameter of the sample loading pipe is larger than the diameter of the coal rock sample and is used for adsorbing the rubber sleeve, and the length of the sample loading pipe is longer than that of the coal rock sample.

2. The loaded coal rock mass CT triaxial experiment loading device of claim 1, characterized in that: the clamp holder assembly comprises a shell, the shell is provided with an inner cavity, a coal sample assembly is arranged at the vertical axis of the inner cavity, an upper opening pipe is integrally arranged at the top of the shell right above the coal sample assembly, a threaded flange and a liquid outlet pressing block are assembled in the upper opening pipe from top to bottom, the threaded flange is in threaded connection with the inner wall of the upper opening pipe, the liquid outlet pressing block is downwards pressed and connected with the coal sample assembly,

the axial line of the liquid outlet pressing block is provided with a vent hole which is communicated with the vent hole of the upper pressing block of the coal sample assembly downwards, the liquid outlet pressing block is integrally provided with a seepage air outlet pipe upwards, and the seepage air outlet pipe upwards extends out of an inner hole of the threaded flange;

a liquid outlet hole for enclosing the inner cavity of the pressure liquid flowing out of the shell is radially arranged in the side wall of the upper opening pipe at the liquid outlet pressing block, and the liquid outlet hole is outwards connected with a liquid outlet pipe; a gap is arranged between the middle lower part of the liquid outlet pressing block and the inner wall of the upper opening pipe, and the liquid outlet hole is communicated with the inner cavity of the shell through the gap; an annular sealing ring for preventing confining pressure liquid from seeping out of the upper opening pipe upwards is arranged between the top of the liquid outlet pressing block and the inner wall of the upper opening pipe;

a lower opening pipe is integrally arranged at the bottom of the shell right below the coal sample assembly, a liquid inlet plug is arranged in the lower opening pipe, and an annular sealing ring for preventing confining pressure liquid from seeping out of the lower opening pipe downwards is arranged between the bottom of the liquid inlet plug and the inner wall of the lower opening pipe; a gap communicated with the inner cavity is formed between the middle upper part of the liquid inlet plug and the inner wall of the lower opening pipe, a liquid inlet hole for confining pressure liquid to flow into the shell is formed in the side wall of the lower opening pipe at the gap along the radial direction, and the liquid inlet hole is connected with a liquid inlet pipe; the bottom of the outer wall of the lower opening pipe is provided with an external thread which is used for being in threaded connection with the jacking mechanism; and the axis of the liquid inlet plug is provided with a seepage air inlet which is correspondingly communicated with the vent hole of the lower pressing block.

3. The loaded coal rock mass CT triaxial experiment loading device of claim 2, characterized in that: the jacking mechanism comprises a hollow frame, a low-speed electric push rod is arranged in the frame, and an extension rod of the low-speed electric push rod faces to the right upper side; a mounting hole is formed in the top wall of the rack right above an extension bar of the low-speed electric push rod, and a lower opening pipe is in threaded connection with the mounting hole;

a top disc is arranged at the top end of an extension rod of the low-speed electric push rod, and a cushion block used for jacking the liquid inlet plug is arranged on the top disc.

4. The loaded coal rock mass CT triaxial experiment loading device of claim 3, characterized in that: in the clamp holder assembly, the top of the seepage air outlet pipe is provided with an external thread for disassembling the hydraulic block;

the lower end of the seepage air inlet hole is provided with an expanding part for ventilating and disassembling the liquid inlet plug, and the expanding part is provided with an internal thread for disassembling the liquid inlet plug or connecting the ventilating joint.

5. The loaded coal rock mass CT triaxial experiment loading device of any one of claims 1 to 4, which is characterized in that: in the coal sample assembly, two annular ribs radially protrude from the lower part of the upper pressing block, and an upper annular groove is formed between the two annular ribs; two annular ribs radially protrude from the upper part of the lower pressing block, and a lower annular groove is formed between the two annular ribs; the upper portion of the rubber sleeve is sleeved on the upper annular groove, the lower portion of the rubber sleeve is sleeved on the lower annular groove, a rubber band used for compressing the rubber sleeve is sleeved on the rubber sleeve at the upper annular groove, and a rubber band used for compressing the rubber sleeve is sleeved on the rubber sleeve at the lower annular groove.

6. The loaded coal rock mass CT triaxial experiment loading device of claim 5, characterized in that: an upper positioning groove is arranged at the center of the bottom end of the liquid outlet pressing block, and an upper positioning lug matched with the upper positioning groove is upwards arranged at the center of the top end of the upper pressing block of the coal sample assembly;

the center of the upper end of the liquid inlet plug is provided with a lower positioning groove, and the center of the bottom end of the lower pressing block of the coal sample assembly is downwards provided with a lower positioning lug matched with the lower positioning groove.

7. The loaded coal rock mass CT triaxial experiment loading device of claim 6, characterized in that: the bottom surface of the upper pressing block and the top surface of the lower pressing block are both provided with a ventilation groove in a shape like a Chinese character 'mi' along the horizontal plane for uniform ventilation, the ventilation groove on the bottom surface of the upper pressing block is communicated with the ventilation hole in the upper pressing block, and the ventilation groove on the top surface of the lower pressing block is communicated with the ventilation hole in the lower pressing block.

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