CN114863779A

CN114863779A - Diversion tunnel overactive fault zone structure model

Info

Publication number: CN114863779A
Application number: CN202210355674.8A
Authority: CN
Inventors: 张延杰; 王明聪; 曹立; 李健; 吴亮; 胡开富; 杨东; 胡玉庆; 石春华; 白锐; 周琦
Original assignee: Yunnan Dianzhong Water Diversion Engineering Co ltd
Current assignee: Yunnan Dianzhong Water Diversion Engineering Co ltd
Priority date: 2022-04-06
Filing date: 2022-04-06
Publication date: 2022-08-05
Anticipated expiration: 2042-04-06
Also published as: CN114863779B

Abstract

The invention discloses a diversion tunnel overactive fault zone structure model which comprises a first active fault zone structure model and a second active fault zone structure model. According to the invention, through the matched use of the first active fault zone structure model, the second active fault zone structure model, the shell, the positioning component, the control component and the limiting component, a user can adjust the position of the second active fault zone structure model along the tracks of the first sliding groove and the second sliding groove according to possible phenomena of the first active fault zone structure model and the second active fault zone structure model and then position the extended water diversion pipe, so that the problems that most of the existing water diversion tunnel active fault zone structure models only enable the user to observe the appearance, but can not simulate the phenomena (such as the upper and lower dislocation of an active fault and the position stretch) which can occur when the water diversion tunnel passes the active fault zone are solved, and how to reasonably treat the water diversion pipe in the water diversion tunnel, so that the judgment of the user is influenced are solved.

Description

Diversion tunnel overactive fault zone structure model

Technical Field

The invention belongs to the technical field of models, and particularly relates to a diversion tunnel overactive fault zone structure model.

Background

Through subjective consciousness with the help of entity or virtual representation, constitute an object of expressing purpose of the objective explanation morphological structure (the object is not equal to the object, do not confine to entity and virtual, do not confine to plane and three-dimensional), the kind of model is many, including the model that is used for showing diversion tunnel survival fault zone structure, diversion tunnel survival fault zone structure model most can only let the user observe the outward appearance, and can not simulate the phenomenon that can take place when diversion tunnel survives fault zone (for example dislocation about the fault that lives, the position is pulled far away), and how rationally handle the leading water pipe in the diversion tunnel, thereby influence user's judgement, but this application has effectively filled the vacancy in this field, the problem that prior art exists is: most of diversion tunnel overactive fault zone structure models only allow users to observe appearances, but can not simulate phenomena (such as upper and lower dislocation of active faults and remote position) which can occur when diversion tunnels overactive fault zones, and how to reasonably process diversion pipes in diversion tunnels, thereby influencing the judgment of the users.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a diversion tunnel overactive fault zone structure model which has the advantages of demonstrating the probable phenomena (such as upper and lower dislocation of an active fault and remote position) of the diversion tunnel overactive fault zone in multiple directions and how to reasonably process a diversion pipe in a diversion tunnel, and solves the problems that most of the existing diversion tunnel overactive fault zone structure models only allow users to observe the appearance but cannot simulate the phenomena (such as upper and lower dislocation of an active fault and remote position) which can occur when the diversion tunnel overactive fault zone is generated, and how to reasonably process the diversion pipe in the diversion tunnel, so that the judgment of the users is influenced.

The invention is realized in such a way that a diversion tunnel overactive fault zone structure model comprises a first active fault zone structure model and a second active fault zone structure model, wherein the second active fault zone structure model is positioned at the front side of the first active fault zone structure model, an ecological water storage tank is arranged at the rear side of the top of the first active fault zone structure model, a water diversion pipe is fixedly communicated with the front side of the ecological water storage tank, the front side of the water diversion pipe penetrates through the front side of the second active fault zone structure model, a fault groove is arranged at the front side of the top of the first active fault zone structure model, a pipe storage groove matched with the water diversion pipe is arranged inside the first active fault zone structure model, a support rod is fixedly connected with the bottom of the inner wall of the fault groove, a support block is sleeved at the top of the support rod, and a support hole matched with the support rod is arranged at the bottom of the support block, the front side of the supporting rod is provided with a matching groove, the top of the supporting block is fixedly connected with a first clamping block, the top of the first clamping block is fixedly connected with a shell, a positioning assembly is arranged in the shell, the top of the shell is provided with a control assembly, the left side of the first clamping block is provided with a second clamping block, the front side and the rear side of the right side of the second clamping block are fixedly connected with sliding rods, the left side of the second clamping block is provided with sliding holes matched with the sliding rods for use, the top of the second clamping block is fixedly connected with a matching block, the left side of the matching block is fixedly connected with a butt-joint block, the front side and the rear side of the butt-joint block are respectively provided with positioning grooves, the left side of the shell is provided with a butt-joint groove matched with the butt-joint block for use, the bottom of the first active fault zone structural model is fixedly connected with a first bottom plate, and the bottom of the second active fault zone structural model is provided with a second bottom plate, the front side of the first bottom plate is fixedly connected with a first sliding block, the rear side of the first bottom plate is provided with a first sliding groove matched with the first sliding block for use, the bottom of the second movable fault belt structure model is fixedly connected with a second sliding block, the top of the second bottom plate is provided with a second sliding groove matched with the second sliding block for use, and the front side of the supporting block is provided with a limiting assembly.

Preferably, the positioning assembly comprises a track rod and a track block, the front side and the rear side of the track rod are fixedly connected with the inner wall of the shell, the track block is sleeved on the surface of the track rod, one side of the track block, which is close to the butt-joint block, is fixedly connected with a positioning rod, one side of the positioning rod, which is close to the butt-joint block, penetrates into the butt-joint groove and is matched with the positioning groove for use, the top of the track block is fixedly connected with a connecting block, the left side of the connecting block is fixedly connected with a transmission rod, and the transmission rod is matched with the control assembly for use.

Preferably, the control assembly comprises a control block and a control rod, the bottom of the control block is fixedly connected with the top of the control rod, the bottom of the control rod penetrates through the inside of the shell and is fixedly connected with a linkage block, the bottom of the linkage block is fixedly connected with a spring, the front side and the rear side of the linkage block are fixedly connected with transmission blocks, and the transmission blocks are matched with the transmission rod for use.

Preferably, the limiting assembly comprises a threaded rod and a rotating block, the rear side of the rotating block is fixedly connected with the front side of the threaded rod, and the right side of the supporting block is provided with a threaded hole matched with the threaded rod for use.

Preferably, the number of the matching grooves is several, and the matching grooves are uniformly distributed on the front side of the supporting rod.

Preferably, the left side of the track block is provided with a track hole, and the track hole is matched with the track rod for use.

Preferably, the bottom of the linkage block is provided with a limiting hole, a limiting rod is inserted into the limiting hole, and the bottom of the limiting rod is fixedly connected with the inner wall of the shell.

Preferably, the front side of the transmission block is provided with a transmission groove, and the transmission groove is matched with the transmission rod for use.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, through the matched use of the first active fault band structure model, the second active fault band structure model, the shell, the positioning component, the control component and the limiting component, a user can adjust the position of the second active fault band structure model along the tracks of the first chute and the second chute according to the possible phenomena of the first active fault band structure model and the second active fault band structure model, and then positions the extended water diversion pipe, so that the problems that most of the existing water diversion tunnel active fault band structure models only can allow the user to observe the appearance, but can not simulate the phenomena (such as up-down dislocation of an active fault and remote position) which can occur when the water diversion tunnel passes the active fault band are solved, and how to reasonably process the water diversion pipe in the water diversion tunnel, so that the judgment of the user is influenced.

2. By arranging the positioning assembly, when the second fractured zone structural model and the first fractured zone structural model are simulated to be dislocated, the redundant water conduit can be taken out of the pipe storage groove, and then the water conduit is positioned through the matching of the positioning assembly, the first clamping block and the second clamping block.

3. The control assembly is arranged, so that the control assembly can be matched with the positioning assembly, the positioning rod is separated from the interior of the butt joint groove, the redundant water conduit can be taken out of the pipe storage groove, and then a proper position is selected for positioning.

4. According to the invention, by arranging the limiting component, the position of the supporting block can be adjusted according to the length of the water conduit taken out of the pipe storage groove, and then the supporting block is positioned, so that the heights of the supporting block, the first clamping block and the second clamping block are fixed.

5. According to the invention, the matching grooves are arranged, so that the positions of the supporting blocks can be fixed by matching the threaded rods with the corresponding matching grooves after the positions of the supporting blocks are adjusted.

6. According to the invention, by arranging the track hole, the positions of the track block and the positioning rod can be limited by the matching between the track hole and the track rod, so that the operation of the track block and the positioning rod is more stable.

7. According to the invention, the position of the linkage block can be limited by arranging the limiting rod and the limiting hole, so that the position of the linkage block can not deviate when the linkage block moves.

8. According to the invention, the transmission groove is arranged, so that the surface of the transmission rod can be extruded by the inner wall of the transmission groove, and the transmission effect on the connecting block is achieved.

Drawings

FIG. 1 is a schematic diagram of a structure provided by an embodiment of the present invention;

FIG. 2 is a cross-sectional view providing a left side view of an embodiment of the present invention;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A in accordance with an embodiment of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 2 at B in accordance with an embodiment of the present invention;

fig. 5 is a perspective view illustrating a first latch and a second latch according to an embodiment of the present invention;

FIG. 6 is an enlarged view of a portion of FIG. 5 at C in accordance with an embodiment of the present invention;

fig. 7 is a top cross-sectional view of a first cartridge and a second cartridge in accordance with an embodiment of the present invention.

In the figure: 1. a first live fault zone structural model; 2. a second live fault zone structural model; 3. an ecological water storage tank; 4. a water conduit; 5. a fault groove; 6. a pipe storage groove; 7. a support bar; 8. a support block; 9. a support hole; 10. a mating groove; 11. a first clamping block; 12. a housing; 13. a positioning assembly; 1301. a track rod; 1302. a track block; 1303. positioning a rod; 1304. connecting blocks; 1305. a transmission rod; 14. a control component; 1401. a control block; 1402. a control lever; 1403. a linkage block; 1404. a spring; 1405. a transmission block; 15. a second fixture block; 16. a slide bar; 17. a slide hole; 18. a matching block; 19. a butt joint block; 20. positioning a groove; 21. a butt joint groove; 22. a first base plate; 23. a second base plate; 24. a first slider; 25. a first chute; 26. a second slider; 27. a second chute; 28. a limiting component; 2801. a threaded rod; 2802. rotating the block; 2803. a threaded hole; 29. a trace hole; 30. a limiting hole; 31. a limiting rod; 32. a transmission groove.

Detailed Description

In order to further understand the contents, features and effects of the present invention, the following embodiments are illustrated and described in detail with reference to the accompanying drawings.

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

As shown in fig. 1 to 7, an embodiment of the invention provides a diversion tunnel overactive fault zone structural model, which includes a first active fault zone structural model 1 and a second active fault zone structural model 2, the second active fault zone structural model 2 is located on the front side of the first active fault zone structural model 1, an ecological water storage tank 3 is arranged on the rear side of the top of the first active fault zone structural model 1, a water conduit 4 is fixedly communicated with the front side of the ecological water storage tank 3, the front side of the water conduit 4 penetrates through to the front side of the second active fault zone structural model 2, a fault groove 5 is arranged on the front side of the top of the first active fault zone structural model 1, a pipe storage groove 6 matched with the water conduit 4 is arranged inside the first active fault zone structural model 1, a support rod 7 is fixedly connected to the bottom of the inner wall of the fault groove 5, a support block 8 is sleeved on the top of the support rod 7, a support hole 9 matched with the support rod 7 is arranged at the bottom of the support block 8, the front side of the supporting rod 7 is provided with a matching groove 10, the top of the supporting block 8 is fixedly connected with a first fixture block 11, the top of the first fixture block 11 is fixedly connected with a shell 12, the inside of the shell 12 is provided with a positioning component 13, the top of the shell 12 is provided with a control component 14, the left side of the first fixture block 11 is provided with a second fixture block 15, the front side and the rear side of the right side of the second fixture block 15 are both fixedly connected with a sliding rod 16, the left side of the second fixture block 15 is provided with a sliding hole 17 matched with the sliding rod 16 for use, the top of the second fixture block 15 is fixedly connected with a matching block 18, the left side of the matching block 18 is fixedly connected with a butt-joint block 19, the front side and the rear side of the butt-joint block 19 are both provided with positioning grooves 20, the left side of the shell 12 is provided with a butt-joint groove 21 matched with the butt-joint block 19 for use, the bottom of the first active fault structure model 1 is fixedly connected with a first bottom plate 22, the bottom of the second active fault structure model 2 is provided with a second bottom plate 23, the front side of first bottom plate 22 is fixedly connected with first slider 24, and the rear side of first bottom plate 22 is opened and is equipped with the first spout 25 that uses with first slider 24 cooperation, and the bottom fixedly connected with second slider 26 of second active fault zone structure model 2, and the top of second bottom plate 23 is seted up and is used with second slider 26 cooperation second spout 27, and the front side of supporting shoe 8 is provided with spacing subassembly 28.

Referring to fig. 3, the positioning assembly 13 includes a track rod 1301 and a track block 1302, the front side and the rear side of the track rod 1301 are fixedly connected to the inner wall of the housing 12, the track block 1302 is sleeved on the surface of the track rod 1301, a positioning rod 1303 is fixedly connected to one side of the track block 1302 close to the butt-joint block 19, one side of the positioning rod 1303 close to the butt-joint block 19 penetrates through the butt-joint groove 21 and is used in cooperation with the positioning groove 20, a connecting block 1304 is fixedly connected to the top of the track block 1302, a transmission rod 1305 is fixedly connected to the left side of the connecting block 1304, and the transmission rod 1305 is used in cooperation with the control assembly 14.

Adopt above-mentioned scheme: through setting up locating component 13, can take out unnecessary leading water pipe 4 from depositing tub groove 6 when simulation second active fault zone structure model 2 takes place the dislocation with first active fault zone structure model 1, later through locating component 13 and the cooperation between first fixture block 11 and the second fixture block 15, fix a position leading water pipe 4.

Referring to fig. 3 and 6, the control assembly 14 includes a control block 1401 and a control rod 1402, the bottom of the control block 1401 is fixedly connected to the top of the control rod 1402, the bottom of the control rod 1402 penetrates into the housing 12, and is fixedly connected with a linkage block 1403, the bottom of the linkage block 1403 is fixedly connected with a spring 1404, the front side and the rear side of the linkage block 1403 are both fixedly connected with a transmission block 1405, and the transmission block 1405 is used in cooperation with a transmission rod 1305.

Adopt above-mentioned scheme: by providing the control unit 14, the control unit 14 and the positioning unit 13 can be engaged with each other, and the positioning rod 1303 is separated from the inside of the abutting groove 21, so that the excess water guide pipe 4 can be taken out from the pipe storage groove 6, and then an appropriate position is selected for positioning.

Referring to fig. 4 and 5, the limiting assembly 28 includes a threaded rod 2801 and a rotating block 2802, a rear side of the rotating block 2802 is fixedly connected to a front side of the threaded rod 2801, and a threaded hole 2803 used in cooperation with the threaded rod 2801 is formed in a right side of the supporting block 8.

Adopt above-mentioned scheme: through setting up spacing subassembly 28, can adjust the supporting shoe 8 position according to the length that the penstock 4 took out from depositing tub 6, later fixing a position supporting shoe 8 to the height of fixed supporting shoe 8 and first fixture block 11 and second fixture block 15.

Referring to fig. 4 and 5, the number of the fitting grooves 10 is several and is uniformly distributed on the front side of the support bar 7.

Adopt above-mentioned scheme: by providing the fitting groove 10, the position of the support block 8 can be fixed by fitting the threaded rod 2801 and the corresponding fitting groove 10 after the position of the support block 8 is adjusted.

Referring to fig. 3, a track hole 29 is formed on the left side of the track block 1302, and the track hole 29 is used in cooperation with the track bar 1301.

Adopt above-mentioned scheme: by providing the track hole 29, the positions of the track block 1302 and the positioning rod 1303 can be restricted by the engagement between the track hole 29 and the track rod 1301, so that the operation is more stable.

Referring to fig. 3, a limiting hole 30 is formed at the bottom of the linkage block 1403, a limiting rod 31 is inserted into the limiting hole 30, and the bottom of the limiting rod 31 is fixedly connected with the inner wall of the housing 12.

Adopt above-mentioned scheme: by providing the stopper rod 31 and the stopper hole 30, the position of the link block 1403 can be restricted so that the position does not deviate when the link block moves.

Referring to fig. 3, a driving groove 32 is formed in the front side of the driving block 1405, and the driving groove 32 is used in cooperation with the driving rod 1305.

Adopt above-mentioned scheme: by providing the transmission groove 32, the inner wall of the transmission groove 32 can be pressed against the surface of the transmission rod 1305, thereby transmitting the connection block 1304.

The working principle of the invention is as follows:

when the device is used, a user can adjust the position of the second active fault belt structure model 2 along the tracks of the first sliding groove 25 and the second sliding groove 27 according to possible phenomena of the first active fault belt structure model 1 and the second active fault belt structure model 2, then push the control block 1401 downwards, the control block 1401 drives the control rod 1402 to move downwards, the control rod 1402 drives the linkage block 1403 to move downwards, the linkage block 1403 drives the transmission block 1405 to move downwards, the surface of the transmission rod 1305 is squeezed by the inner wall of the transmission groove 32, the connection block 1304 is driven to move towards one side far away from the butt-joint block 19, the connection block 1304 drives the track block 1302 to move towards one side far away from the butt-joint block 19, the track block drives the positioning rod 1303 to leave the butt-joint groove 21, then the second fixture block 15 is separated from the first fixture block 11 along the track of the sliding rod 16, and then the extended water conduit 4 is placed between the second fixture block 1302 and the first fixture block 11, then the clamping block is reset, the clamping block enters the clamping groove, the control block 1401 is loosened, the elastic force generated by the spring 1404 pushes the linkage block 1403 to move upwards, the linkage block 1403 drives the transmission block 1405 to move upwards, the surface of the transmission rod 1305 is extruded through the inner wall of the transmission groove 32, the connection block 1304 is driven to move towards one side close to the butting block 19, the connection block 1304 drives the track block 1302 to move towards one side close to the butting block 19, the track block 1302 drives the positioning rod 1303 to move into the positioning groove 20, so that the position of the second clamping block 15 is limited, the position of the water guide pipe 4 is limited, the height of the supporting block 8 can be adjusted at the same time, the rotating block 2802 is rotated to enable the threaded rod 2801 to leave the matching groove 10, then the heights of the supporting block 8, the first clamping block 11 and the second clamping block 15 are adjusted along the track of the supporting rod 7, and finally the threaded rod 2801 is rotated anticlockwise to enable the threaded rod 2801 to enter the corresponding matching groove 10, effectively fills the gap in the field.

In summary, the following steps: the diversion tunnel over-active fault zone structure model is characterized in that a first active fault zone structure model 1, a second active fault zone structure model 2, a shell 12, a positioning component 13, a control component 14 and a limiting component 28 are arranged to be matched for use, a user can adjust the position of the second active fault zone structure model 2 along the tracks of a first sliding groove 25 and a second sliding groove 27 according to the phenomena possibly occurring to the first active fault zone structure model 1 and the second active fault zone structure model 2 and then position an extended diversion pipe 4, and the problem that most of the existing diversion tunnel over-active fault zone structure models only enable the user to observe the appearance is solved, and the phenomena (such as the upper and lower dislocation of the active fault and the remote position) which can occur when the diversion tunnel passes through the active fault zone can not be simulated, and the problem of how to reasonably treat the diversion pipe in the diversion tunnel so as to influence the judgment of a user.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a diversion tunnel overactive fault zone structure model, includes first active fault zone structure model (1) and second active fault zone structure model (2), its characterized in that: the second active fault zone structural model (2) is positioned on the front side of the first active fault zone structural model (1), an ecological water storage tank (3) is arranged on the rear side of the top of the first active fault zone structural model (1), a water guide pipe (4) is fixedly communicated with the front side of the ecological water storage tank (3), the front side of the water guide pipe (4) penetrates through the front side of the second active fault zone structural model (2), a fault groove (5) is arranged on the front side of the top of the first active fault zone structural model (1), a pipe storage groove (6) matched with the water guide pipe (4) is arranged inside the first active fault zone structural model (1), a support rod (7) is fixedly connected to the bottom of the inner wall of the fault groove (5), a support block (8) is sleeved on the top of the support rod (7), and a support hole (9) matched with the support rod (7) is formed in the bottom of the support block (8), a matching groove (10) is formed in the front side of the supporting rod (7), a first clamping block (11) is fixedly connected to the top of the supporting block (8), a shell (12) is fixedly connected to the top of the first clamping block (11), a positioning assembly (13) is arranged inside the shell (12), a control assembly (14) is arranged on the top of the shell (12), a second clamping block (15) is arranged on the left side of the first clamping block (11), a sliding rod (16) is fixedly connected to the front side and the rear side of the right side of the second clamping block (15), a sliding hole (17) matched with the sliding rod (16) for use is formed in the left side of the second clamping block (15), a matching block (18) is fixedly connected to the top of the second clamping block (15), a butt-joint block (19) is fixedly connected to the left side of the matching block (18), and positioning grooves (20) are formed in the front side and the rear side of the butt-joint block (19), the butt joint structure of the high-power-density flexible printed circuit board is characterized in that a butt joint groove (21) matched with a butt joint block (19) for use is formed in the left side of the shell (12), a first bottom plate (22) is fixedly connected to the bottom of the first active fault zone structure model (1), a second bottom plate (23) is arranged at the bottom of the second active fault zone structure model (2), a first sliding block (24) is fixedly connected to the front side of the first bottom plate (22), a first sliding groove (25) matched with the first sliding block (24) for use is formed in the rear side of the first bottom plate (22), a second sliding groove (27) matched with the second sliding block (26) for use is formed in the top of the second bottom plate (23), and a limiting assembly (28) is arranged on the front side of the supporting block (8).

2. The diversion tunnel overactive fault zone structural model as claimed in claim 1, wherein: the positioning assembly (13) comprises a track rod (1301) and a track block (1302), the front side and the rear side of the track rod (1301) are fixedly connected with the inner wall of the shell (12), the track block (1302) is sleeved on the surface of the track rod (1301), one side, close to the butt joint block (19), of the track block (1302) is fixedly connected with a positioning rod (1303), one side, close to the butt joint block (19), of the positioning rod (1303) penetrates through the inside of the butt joint groove (21) and is matched with the positioning groove (20) for use, the top of the track block (1302) is fixedly connected with a connecting block (1304), the left side of the connecting block (1304) is fixedly connected with a transmission rod (1305), and the transmission rod (1305) is matched with the control assembly (14) for use.

3. The diversion tunnel overactive fault zone structural model as claimed in claim 2, wherein: the control assembly (14) comprises a control block (1401) and a control rod (1402), the bottom of the control block (1401) is fixedly connected with the top of the control rod (1402), the bottom of the control rod (1402) penetrates into the casing (12), a linkage block (1403) is fixedly connected with the bottom of the linkage block (1403), a spring (1404) is fixedly connected with the bottom of the linkage block (1403), transmission blocks (1405) are fixedly connected with the front side and the rear side of the linkage block (1403), and the transmission blocks (1405) are matched with the transmission rod (1305) for use.

4. The diversion tunnel overactive fault zone structural model as claimed in claim 1, wherein: the limiting assembly (28) comprises a threaded rod (2801) and a rotating block (2802), the rear side of the rotating block (2802) is fixedly connected with the front side of the threaded rod (2801), and a threaded hole (2803) matched with the threaded rod (2801) for use is formed in the right side of the supporting block (8).

5. The diversion tunnel overactive fault zone structural model as claimed in claim 1, wherein: the number of the matching grooves (10) is a plurality, and the matching grooves are uniformly distributed on the front side of the supporting rod (7).

6. The diversion tunnel overactive fault zone structural model as claimed in claim 2, wherein: the left side of the track block (1302) is provided with a track hole (29), and the track hole (29) is matched with the track rod (1301) for use.

7. The diversion tunnel overactive fault zone structural model as claimed in claim 3, wherein: spacing hole (30) have been seted up to the bottom of linkage piece (1403), the inside grafting of spacing hole (30) has gag lever post (31), the bottom of gag lever post (31) and the inner wall fixed connection of casing (12).

8. The diversion tunnel overactive fault zone structural model as claimed in claim 3, wherein: the front side of transmission piece (1405) is opened and is equipped with transmission groove (32), transmission groove (32) and transfer line (1305) cooperation use.