CN113275654A - Fault making device and method for underground engineering similar model test - Google Patents

Abstract

The invention relates to the technical field of geological simulation experiments, in particular to a fault making device and a fault making method for an underground engineering similar model test. The invention can be used for manufacturing faults on the geological simulation model, can realize the fault manufacturing in any direction and any size, and can ensure that the faults are straight and are densely filled.

Description

Fault making device and method for underground engineering similar model test

Technical Field

The invention relates to the technical field of geological simulation experiments, in particular to a fault making device and method for an underground engineering similar model test.

Background

The fault is a structure with obvious relative displacement of the crust broken by stress and the rock masses on two sides of the broken surface, is widely existed in the stratum and obviously influences the geomechanical activities, including coal mining, non-coal mining and the like. To study the effect of faults on geomechanical activity, it is often necessary to develop similar model tests. The similar model test is to simulate stratum and geological structure with similar material, set stress or displacement boundary condition, simulate geomechanical activity process and observe the response characteristic of the model in laboratory environment based on similar principle. In similar model testing, faults are typically made during the model building process, there are two methods: the first method is that aiming at each laying layer, a model is cut at the position of a designed fault and filled with fault zone materials, and the fault zone materials are manufactured layer by layer until the fault with the designed length is finished; the second is to install one or two baffles in the model to orient the fault and fill the fault band material. The first method has poor fault directionality, and the manufactured fault is difficult to straighten, so that the test effect is influenced; in the second method, the clapboard can seriously influence the compaction of the model, reduce the laying quality of the model and delay the laying progress of the model. Aiming at the difficult problem that the fault is difficult to accurately and efficiently manufacture in the geomechanical model test, the patent provides a novel fault manufacturing device and a novel fault manufacturing method for the similar model test.

Disclosure of Invention

The invention provides a fault making device for an underground engineering similar model test, which can be used for making a fault on a geological simulation model, can realize fault making in any direction and any size, and can ensure that the fault is straight and is densely filled.

The invention provides a fault making device for an underground engineering similar model test, which comprises a guide rail, a joint cutting device, a filling device, a first lifting structure and a second lifting structure, wherein the joint cutting device and the filling device are respectively and movably arranged on the guide rail and can slide along the length direction of the guide rail, and the joint cutting device and the filling device are respectively connected with the first lifting structure and the second lifting structure to realize lifting.

According to the fault making device for the underground engineering similar model test, the joint cutting device comprises a movable disc saw for cutting the model, the movable disc saw is connected with the first lifting structure to lift, and foreign objects are cut by rotation.

According to the fault making device for the underground engineering similar model test, provided by the invention, the first lifting structure comprises a first sliding block and a lifting rod connected with the movable disc saw, the first sliding block is movably arranged on the guide rail and can slide along the length direction of the guide rail, and the movable disc saw is movably connected on the first sliding block in a lifting manner through the lifting rod and can slide on the guide rail along with the first sliding block.

According to the fault making device for the underground engineering similar model test, the movable disc saw is detachably connected to the lifting rod.

According to the fault making device for the underground engineering similar model test, the filling device comprises a hopper for filling the model, and the hopper is movably connected to the second lifting structure to lift.

According to the fault making device for the underground engineering similar model test, provided by the invention, the second lifting structure comprises a second sliding block and a lifting groove formed on the hopper, the second sliding block is movably arranged on the guide rail and can slide along the length direction of the guide rail, and the hopper is movably matched on the second sliding block in a lifting way through the lifting groove and can slide on the guide rail along with the second sliding block.

According to the fault making device for the underground engineering similar model test, the hopper comprises a hinged shaft, a fixed hopper piece and a movable hopper piece movably hinged to the fixed hopper piece through the hinged shaft, the upper parts of the fixed hopper piece and the movable hopper piece are bent and then mutually enclosed to form a storage cavity, the lower parts of the fixed hopper piece and the movable hopper piece are linearly extended and then mutually overlapped to form a normally closed flat clamping nozzle, and the flat clamping nozzle can be driven to open by controlling the movable hopper piece to rotate around the hinged shaft.

According to the fault making device for the underground engineering similar model test, provided by the invention, the upper part of the hinged shaft is provided with the pressure spring of which two ends are respectively and elastically abutted against the fixed bucket piece and the movable bucket piece, and the movable bucket piece is pushed by the elastic acting force of the pressure spring so as to enable the flat clamping nozzle to maintain a normally closed state.

The fault making device for the underground engineering similar model test further comprises a fixed support, and the fixed support is fixedly supported at the bottom of the guide rail.

Based on the scheme, the invention also provides a fault making method for the underground engineering similar model test, which comprises the fault making device for the underground engineering similar model test and comprises the following steps:

s1, manufacturing a simulation model for simulating the geological fault;

s2, making fault marking lines in advance according to the design on the simulation model;

s3, erecting and fixing the fault making device at a proper position on the simulation model according to the direction of the fault marking line;

s4, moving the movable disc saw of the joint cutting device to the end part of the fault marking line, adjusting the falling depth of the movable disc saw through the first lifting structure, starting the movable disc saw, and controlling the movable disc saw to cut a joint on the simulation model along the fault marking line by utilizing the guide rail guide until the simulation model is cut through to form a fault joint cut;

s5, filling the hopper of the filling device with filling material and moving the hopper 202 along the guide rail to the end of the fault cutting;

s6, controlling the hopper to descend through the second lifting structure so that the flat clamping nozzle at the bottom of the hopper is inserted into the depth of the fault incision;

s7, operating the movable bucket piece of the hopper to rotate around the hinge shaft to drive the flat clamping mouth to open, opening the fault joint seam by using the opened flat clamping mouth, and simultaneously enabling the filling material in the hopper to fall into the fault joint seam downwards through the opened flat clamping mouth;

s8, adjusting the position and height of the hopper through a guide rail and a second lifting structure until the filling material is filled in the fault joint cutting;

and S9, removing the fault making device.

When the fault making device and the fault making method for the underground engineering similar model test are used, the fault making device can be placed on a simulation model according to fault making in any direction, a guide rail is parallel to a preset fault trajectory line on the simulation model, a joint cutting device and a filling device on the guide rail respectively downwards correspond to the preset fault trajectory line on the simulation model, and the joint cutting device is movably arranged on the guide rail and can slide along the length direction of the guide rail, so that the joint cutting device can be controlled to move linearly along the guide rail to cut a straight joint on the simulation model along the preset fault trajectory line, and the cut fault trajectory can be ensured to be straight; meanwhile, the joint cutting device can be lifted by being connected to the first lifting structure, so that the joint cutting device can be controlled to ascend and descend through the first lifting structure, the cutting depth can be adjusted, fault production of different sizes can be responded, the joint cutting device can be ensured to cut through a simulation model, and fault production of any size can be realized. In addition, the filling device is movably arranged on the guide rail and can slide along the length direction of the guide rail, so that after the cutting slit is cut on the simulation model, the filling device on the guide rail can be controlled to move along the track of the cutting slit, and the filling material in the filling device can fall into the cutting slit downwards to fill the cutting slit; simultaneously because filling device can realize going up and down through connecting in second elevation structure, consequently can ensure that filling material fills up the inside of joint-cutting completely through controlling filling device's lift, make to fill more closely knit, finally let the fault effect of producing better. Therefore, the invention can realize the fault manufacture in any direction and any size, and can ensure that the fault is straight and is densely filled.

Drawings

In order to more clearly illustrate the technical solutions of the present invention or the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a perspective view of the overall construction of the present invention;

FIG. 2 is a perspective view of the overall construction of the present invention;

FIG. 3 is a perspective view of the overall construction of an embodiment of the present invention;

FIG. 4 is a perspective view of the overall construction of an embodiment of the present invention;

FIG. 5 is a perspective view of the overall construction of an embodiment of the present invention;

FIG. 6 is a perspective view of the overall construction of an embodiment of the present invention;

FIG. 7 is a perspective view of the overall construction of an embodiment of the present invention;

FIG. 8 is a perspective view of the overall construction of an embodiment of the present invention;

FIG. 9 is a perspective view of the overall construction of an embodiment of the present invention;

FIG. 10 is a perspective view of the overall construction of an embodiment of the present invention;

FIG. 11 is a perspective view of the overall construction of an embodiment of the present invention;

FIG. 12 is a perspective view of the overall construction of an embodiment of the present invention;

fig. 13 is a perspective view of the overall structure of an embodiment of the present invention.

1-a guide rail, 2-a fixed bracket, 3-a movable disc saw, 4-a first slide block, 5-a lifting rod, 6-a first control handle, 7-a second slide block, 8-a lifting groove, 9-a second control handle, 10-a hinged shaft, 11-a fixed bucket piece, 12-a movable bucket piece, 13-a storage cavity, 14-a flat clamping nozzle, 15-a pressure spring, 100-a lancing device, 101-a first lifting structure, 200-a filling device, 201-a second lifting structure and 202-a hopper.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The fault making device for the underground engineering similar model test is described below with reference to fig. 1 and 2, and includes a guide rail 1, a lancing device 100, a filling device 200, a first lifting structure 101 and a second lifting structure 201, the lancing device 100 and the filling device 200 are respectively movably mounted on the guide rail 1 and can linearly slide along the length direction of the guide rail 1, and the lancing device 100 and the filling device 200 are respectively lifted by being connected to the first lifting structure 101 and the second lifting structure 201. That is, the guide rail 1 may guide the slitting device 100 and the filling device 200 to move linearly, and the first and second lifting structures 101 and 201 may guide the slitting device 100 and the filling device 200 to ascend and descend, respectively.

When the device is used, a fault making device can be placed on a simulation model according to fault making in any direction, the guide rail 1 is parallel to a preset fault trajectory line on the simulation model, and the lancing device 100 and the filling device 200 on the guide rail 1 respectively correspond to the preset fault trajectory line on the simulation model downwards; meanwhile, the lancing device 100 can be lifted by being connected to the first lifting structure 101, so that the first lifting structure 101 can control the lancing device 100 to ascend and descend, the cutting depth can be adjusted, the lancing device 100 can deal with the fault production of different sizes, the lancing device 100 can be ensured to cut through a simulation model, and the fault production of any size can be realized. In addition, because the filling device 200 is movably mounted on the guide rail 1 and can slide along the length direction of the guide rail 1, after a cut is cut on the simulation model, the filling device 200 on the guide rail 1 can be controlled to move along the track of the cut, so that the filling material in the filling device 200 can fall down into the cut to fill the cut; meanwhile, the filling device 200 can be lifted through being connected to the second lifting structure 201, so that the filling material can be ensured to be completely filled in the cutting seams by controlling the lifting of the filling device 200, the filling is more compact, and the manufactured fault effect is better. Therefore, the invention can realize the fault manufacture in any direction and any size, and can ensure that the fault is straight and is densely filled.

Specifically, as shown in fig. 3, the cutting and sewing device 100 includes a movable disk saw 3 for cutting a model, the movable disk saw 3 is connected to a first lifting structure 101 to lift and cut foreign objects by rotation, the movable disk saw 3 is in a circular disk shape, and is more stable during rotation cutting, and the cutting and sewing which is beneficial to cutting is smoother, when cutting is needed, as long as the movable disk saw 3 is started to rotate, and the movable disk saw 3 is controlled to move linearly along a guide rail 1, so that a straight cutting and sewing can be cut on the simulation model efficiently and quickly, and meanwhile, the movable disk saw 3 can be controlled to lift and fall by the first lifting structure 101, so that the actions of lifting and falling the saw can be realized, the cutting depth can be adjusted, fault manufacturing of different sizes can be handled, and the movable disk saw 3 can be ensured to cut through the simulation model, and fault manufacturing of any size can be realized.

Specifically, as shown in fig. 4 to 5, the first lifting structure 101 includes a first slider 4 and a lifting rod 5 connected to the movable disk saw 3, the first slider 4 is movably mounted on the guide rail 1 and can slide along the length direction of the guide rail 1, and the movable disk saw 3 is movably connected to the first slider 4 through the lifting rod 5 in a liftable manner and can slide on the guide rail 1 along with the first slider 4. That is, the movable disk saw 3 can move not only in the up-and-down motion on the first slider 4 along with the up-and-down rod 5, but also in the linear motion on the guide rail 1 along with the first slider 4, so that the movable disk saw 3 can be controlled to move from multiple directions.

Optionally, the movable disc saw 3 is detachably connected to the lifting rod 5, so that the movable disc saw 3 can be detached, the movable disc saws 3 with different diameters can be replaced conveniently according to actual conditions, the movable disc saw 3 can be ensured to cut through the simulation model, and fault manufacturing of any size is realized.

Optionally, the first slider 4 is fixedly connected with the first control handle 6, so that the first slider 4 and the movable disk saw 3 can be controlled to move by the first control handle 6 when the movable disk saw is used, and the operation is more convenient.

Specifically, as shown in fig. 6, the filling device 200 comprises a hopper 202 for filling the model, and the hopper 202 is lifted and lowered by being movably connected to a second lifting structure 201. In this embodiment, the top of hopper 202 is formed with the pan feeding mouth, when needing to fill the kerf, fill into filler material in advance toward hopper 202 through the pan feeding mouth, in this embodiment, filler material is no cementing material or weak cementing material, and control hopper 202 along 1 rectilinear movement of guide rail, alright pour into filler material into in the kerf on the simulation model in order to be complete, simultaneously can control hopper 202 through second elevation structure 201 and go up and down, consequently can be through the lift of controlling hopper 202, ensure that filler material fills up the inside of kerf completely, it is closely knit to make the packing, finally let the fault effect of producing better.

Specifically, as shown in fig. 7 to 8, the second lifting structure 201 includes a second slider 7 and a lifting groove 8 formed on the back of the hopper 202, the second slider 7 is movably mounted on the guide rail 1 and can slide along the length direction of the guide rail 1, and the hopper 202 is movably coupled to the second slider 7 through the lifting groove 8 in a liftable manner and can slide on the guide rail 1 along with the second slider 7. That is, the hopper 202 can move not only in the up-and-down motion on the second slider 7 along with the up-and-down slot 8, but also in the linear motion on the guide rail 1 along with the second slider 7, thereby realizing the control of the movement of the hopper 202 from a plurality of directions.

Specifically, as shown in fig. 9 to 10, the hopper 202 includes an articulated shaft 10, a fixed bucket piece 11 and a movable bucket piece 12, the movable bucket piece 12 is movably articulated on the fixed bucket piece 11 through the articulated shaft 10, so that the movable bucket piece 12 can deflect around the articulated shaft 10 on the fixed bucket piece 11, in addition, the upper portions of the fixed bucket piece 11 and the movable bucket piece 12 are bent and then mutually enclosed to form a storage cavity 13, the lower portions of the fixed bucket piece 11 and the movable bucket piece 12 are linearly extended and then mutually overlapped to form a normally closed flat clamping nozzle 14, and when in use, the flat clamping nozzle 14 can be driven to open by controlling the movable bucket piece 12 to rotate around the articulated shaft 10. It should be noted that, in this embodiment, the hinge shaft 10 is located inside the material storage chamber 13 and above the flat clamping nozzle 14, so that the upper end of the movable bucket 12 and the flat clamping nozzle 14 are respectively located at the upper side and the lower side of the hinge shaft 10, and thus, as long as the upper end of the movable bucket 12 is pushed and pressed to deflect toward the inside of the material storage chamber 13, the flat plate at the lower end of the movable bucket 12 can be driven to deflect outward, and further the flat clamping nozzle 14 is driven to open, and after the flat clamping nozzle 14 opens, the filling material inside the material storage chamber 13 can fall into the slit downward, so as to implement the operation of filling the fault. In addition, because the lower parts of the fixed bucket piece 11 and the movable bucket piece 12 are overlapped with each other after extending linearly to form a normally closed flat clamping mouth 14, therefore, when the kerf of the simulation model is filled, the hopper 202 can be controlled to descend through the lifting groove 8 of the second lifting structure 201, so that the flat clamping mouth 14 is inserted into the deep part of the kerf in advance, the movable bucket 12 is then manipulated to rotate about the hinge axis 10 to drive the flat jaws 14 to open, properly spread the slits of the phantom with the flat jaws 14 open, meanwhile, the filling material in the storage cavity 13 can fall into the cutting seam through the opened flat clamping nozzle 14 to fill the cutting seam, during the continuous blanking and filling process, the flat clamping nozzle 14 is guided to move transversely and move up and down through the second lifting structure 201 and the guide rail 1 at the same time until the filling material completely fills the whole inside of the cutting seam, so that the dense filling can be ensured.

Further, as shown in fig. 11 to 12, a compression spring 15 is disposed above the hinge shaft 10, two ends of the compression spring 15 elastically abut against the fixed bucket piece 11 and the movable bucket piece 12, respectively, and the movable bucket piece 12 is pushed by the elastic force of the compression spring 15, so that the flat nozzle 14 maintains a normally closed state. That is to say, the elastic force of the pressure spring 15 is utilized to expand the upper end of the movable bucket piece 12 outwards, so that the flat plate at the lower end of the movable bucket piece 12 is drawn close inwards, thereby the flat clamping nozzle 14 can be maintained in a clamped normally closed state, therefore, it can be ensured that the filling material in the storage cavity 13 cannot drop downwards at ordinary times, when filling is required, the upper end of the movable bucket piece 12 is pushed to deflect and compress the internal pressure spring 15, then the flat clamping nozzle 14 at the bottom can be driven to open and perform blanking and filling, after filling is completed and the external force does not deflect the movable bucket piece 12 any more, the reset force of the pressure spring 15 can push the movable bucket piece 12 to reset and deflect, the flat clamping nozzle 14 is driven to reset and clamp again, and the movable bucket piece is restored to a normally closed state, and therefore, the hopper 202 can be opened and closed conveniently.

Optionally, the second slider 7 is fixedly connected with the second control handle 9, so that when the device is used, the second slider 7 and the hopper 202 can be controlled to move by the second control handle 9, and the operation is more convenient.

Further, as shown in fig. 13, the fault diagnosis device further comprises a fixing support 2, and the fixing support 2 is fixedly supported at the bottom of the guide rail 1, so that the guide rail 1 can be stably supported, and the fault diagnosis device can be conveniently fixed on the simulation model, which is beneficial to positioning.

Based on the above specific schemes, the present embodiment further provides a fault making method for the similar model test of the underground engineering, as shown in fig. 1 to 13, including the fault making apparatus for the similar model test of the underground engineering, and including the following steps:

s1, manufacturing a simulation model for simulating the geological fault;

s2, making fault marking lines in advance according to the design on the simulation model;

s3, erecting and fixing the fault making device at a proper position on the simulation model according to the direction of the fault marking line;

s4, moving the movable disc saw 3 of the joint cutting device 100 to the end part of the fault marking line, adjusting the saw falling depth of the movable disc saw 3 through the first lifting structure 101, starting the movable disc saw 3, and controlling the movable disc saw 3 to cut a joint on the simulation model along the fault marking line by utilizing the guide rail 1 to form a fault joint;

s5, filling the hopper 202 of the filling device 200 with a filling material and moving the hopper 202 along the guide rail 1 to the end of the fault-cutting;

s6, controlling the hopper 202 to descend through the second lifting structure 201 so that the flat mouth 14 at the bottom of the hopper 202 is inserted into the depth of the fault incision;

s7, operating the movable bucket piece 12 of the bucket 202 to rotate around the hinge shaft 10 to drive the flat jaws 14 to open, and using the open flat jaws 14 to open the fault cuts, and simultaneously, the filling material in the bucket 202 falls down into the fault cuts through the open flat jaws 14;

s8, adjusting the position and height of the hopper 202 through the guide rail 1 and the second lifting structure 201 until the filling material is filled in the fault cutting seam;

and S9, removing the fault making device.

In step S1, after the simulation model is laid, the model may be demolded after curing to form, but it is not necessary to wait for complete curing, otherwise the strength of the model is too high, which may increase the difficulty of cutting and filling.

In step S2, by making fault marking lines for simulating fault positions on the simulation model in advance, on one hand, it is convenient to pre-position the fault making device according to the track direction of the fault marking lines in step S3, make the guide rail 1 parallel to the fault track line and to pre-downwards correspond the movable disc saw 3 and the flat clamping mouth 14 to the fault marking lines for pre-positioning; on the other hand, the movable disc saw 3 can accurately cut a pre-designed fault kerf along the fault marking line.

In step S4, the guide rail 1 guides the movable disk saw 3 to move linearly on the phantom so as to ensure that the cut cross-sectional cut is straight, and the first elevation structure 101 adjusts the cutting depth, which is the drop depth of the movable disk saw 3, so as to ensure that the movable disk saw 3 can cut through the phantom to form the cross-sectional cut. Therefore, after the cutting depth of the movable disc saw 3 can be adjusted, the fault making of different sizes can be dealt with, the movable disc saw 3 can be ensured to cut through the simulation model, and the fault making of any size is realized.

The hopper 202 is moved to the end of the fault-cut in advance in step S5 in preparation for subsequent filling of the fault-cut.

In steps S6 to S8, the hopper 202 is controlled to descend by the second lifting structure 201, so that the flat nozzles 14 are inserted into the deep parts of the fault cuts in advance, then the movable bucket 12 is controlled to rotate around the hinge shaft 10 to drive the flat nozzles 14 to open, the fault cuts of the simulation model are properly opened by the open flat nozzles 14, the internal space of the fault cuts is properly enlarged, meanwhile, the filling material in the storage cavity 13 can fall into the cuts through the open flat nozzles 14, so as to fill the cuts, and then the flat nozzles 14 are guided to move transversely and lift by the second lifting structure 201 and the guide rail 1 until the filling material completely fills the whole cuts, so that the dense filling of the fault cuts can be ensured.

In conclusion, the fault making method for the underground engineering similar model test can realize fault making in any direction and any size, and can ensure that the fault is straight and is densely filled.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. The fault making device for the underground engineering similar model test is characterized by comprising a guide rail (1), a joint cutting device (100), a filling device (200), a first lifting structure (101) and a second lifting structure (201), wherein the joint cutting device (100) and the filling device (200) are movably arranged on the guide rail (1) respectively and can slide along the length direction of the guide rail (1), and the joint cutting device (100) and the filling device (200) are respectively lifted through being connected to the first lifting structure (101) and the second lifting structure (201).

2. The fault making device for underground engineering similar model test according to claim 1, characterized in that the cutting and cutting device (100) comprises a movable disk saw (3) for cutting model, the movable disk saw (3) is connected with the first lifting structure (101) to realize lifting and cutting foreign objects by rotation.

3. The fault making device for the underground engineering similar model test is characterized in that the first lifting structure (101) comprises a first slide block (4) and a lifting rod (5) connected with the movable disc saw (3), the first slide block (4) is movably arranged on the guide rail (1) and can slide along the length direction of the guide rail (1), and the movable disc saw (3) is movably connected to the first slide block (4) through the lifting rod (5) in a lifting mode and can slide on the guide rail (1) along with the first slide block (4).

4. The fault making device for underground works simulation model test according to claim 3, characterized in that the movable disc saw (3) is detachably connected to the lifting rod (5).

5. The fault making device for underground engineering similar model test according to claim 1, characterized in that the filling device (200) comprises a hopper (202) for filling the model, the hopper (202) is lifted by being movably connected to the second lifting structure (201).

6. The fault making device for the underground engineering similar model test is characterized in that the second lifting structure (201) comprises a second sliding block (7) and a lifting groove (8) formed in the hopper (202), the second sliding block (7) is movably arranged on the guide rail (1) and can slide along the length direction of the guide rail (1), and the hopper (202) is movably matched on the second sliding block (7) in a lifting mode through the lifting groove (8) and can slide on the guide rail (1) along with the second sliding block (7).

7. The fault making device for the underground engineering similar model test is characterized in that the hopper (202) comprises a hinged shaft (10), a fixed hopper piece (11) and a movable hopper piece (12) movably hinged on the fixed hopper piece (11) through the hinged shaft (10), the upper parts of the fixed hopper piece (11) and the movable hopper piece (12) are bent and then mutually enclosed to form a storage cavity (13), the lower parts of the fixed hopper piece (11) and the movable hopper piece (12) are mutually overlapped after linearly extending to form a normally closed flat clamping nozzle (14), and the flat clamping nozzle (14) can be driven to open by controlling the movable hopper piece (12) to rotate around the hinged shaft (10).

8. The fault making device for the underground engineering similar model test according to claim 7, characterized in that a compression spring (15) with two ends respectively elastically abutted against the fixed bucket piece (11) and the movable bucket piece (12) is arranged above the hinged shaft (10), and the movable bucket piece (12) is pushed by the elastic force of the compression spring (15) to maintain the normally closed state of the flat clamping nozzle (14).

9. The fault making device for underground engineering similar model test according to claim 1, characterized by further comprising a fixed bracket (2), wherein the fixed bracket (2) is fixedly supported at the bottom of the guide rail (1).

10. A fault making method for an underground engineering similar model test is characterized by comprising the fault making device for the underground engineering similar model test as claimed in claims 1-9, and comprising the following steps:

s1, manufacturing a simulation model for simulating the geological fault;

s2, making fault marking lines in advance according to the design on the simulation model;

s3, erecting and fixing the fault making device at a proper position on the simulation model according to the direction of the fault marking line;

s4, moving the movable disc saw (3) of the joint cutting device (100) to the end part of the fault marking line, adjusting the saw falling depth of the movable disc saw (3) through the first lifting structure (101), starting the movable disc saw (3), and guiding and controlling the movable disc saw (3) to cut a joint on the simulation model along the fault marking line by using the guide rail (1) until the simulation model is cut through to form a fault joint cut;

s5, filling the filling material into the hopper (202) of the filling device (200) and moving the hopper (202) to the end part of the fault cutting along the guide rail (1);

s6, controlling the hopper (202) to descend through the second lifting structure (201) so that the flat clamping nozzle (14) at the bottom of the hopper (202) is inserted into the depth of the fault incision;

s7, operating the movable bucket piece (12) of the bucket (202) to rotate around the hinge shaft (10) to drive the flat clamping nozzle (14) to open, utilizing the opened flat clamping nozzle (14) to open the fault cutting seam, and simultaneously enabling the filling material in the bucket (202) to fall into the fault cutting seam downwards through the opened flat clamping nozzle (14);

s8, adjusting the position and height of the hopper (202) through the guide rail (1) and the second lifting structure (201) until the filling material is filled in the fault cutting seam;

and S9, removing the fault making device.

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