CN114290102A - Self-adaptive supporting device for milling thin-wall part - Google Patents

Abstract

The invention belongs to the technical field of thin-wall part support, and particularly discloses a self-adaptive support device for milling thin-wall parts, which comprises a device whole body, a control panel and a movable block, wherein the control panel is arranged at the top of the left side right in front of the device whole body, a filter drawer is embedded in the middle of the left side right in front of the device whole body, a movable baffle is movably arranged at the middle part of the top of the device whole body, the movable block is movably arranged at the right side of the top of the device whole body, a sliding chute is embedded in the middle of the top of the right side of the device whole body, a self-adaptive support mechanism can effectively expand and support inner holes of parts when a user uses the device whole body to process parts with different diameters of the inner holes, so that the parts can be more stably processed by a milling device under the expansion support of eight expansion support blocks, further, the applicability of the entire device is higher.

Description

Self-adaptive supporting device for milling thin-wall part

Technical Field

The invention belongs to the technical field of thin-wall part support, and particularly relates to a self-adaptive support device for milling of a thin-wall part.

Background

Along with the more and more outstanding environmental problems, the requirements for energy conservation and emission reduction are also improved, the lightweight design of mechanical parts is more and more popular with people, and particularly in the field of aerospace, the use of a large number of large-scale integral thin-wall parts enables the product quality to be lighter, the mechanical efficiency to be higher and the reliability to be better.

At present, current thin wall part strutting arrangement can not be according to the hole diameter variation of processing part and change the support aperture of self, thereby make can not support the processing to the part of different hole diameter sizes, current thin wall part strutting arrangement supports the thin wall part simultaneously, thin wall part strutting arrangement that can have can not carry out accurate control to supporting dynamics size, thereby make and probably lead to the thin wall part to warp because of supporting dynamics is too big when supporting the thin wall part, and current thin wall part strutting arrangement is provided with the baffle that carries out the water conservancy diversion to the piece that processing produced, can this guide plate is inconvenient to shrink, thereby lead to the user can influence the user and process the processing part cover in strutting arrangement's periphery when using thin wall part strutting arrangement.

Therefore, how to design an adaptive support device for milling thin-walled parts becomes a problem to be solved at present.

Disclosure of Invention

The invention aims to: in order to solve the problem that the milling processing of thin-wall parts is affected by the fact that parts with different inner diameters cannot be supported, the supporting force is not accurately mastered, and the guide plate is inconvenient to shrink, the machined parts are placed on the periphery of a supporting device for machining.

The technical scheme adopted by the invention is as follows: a self-adaptive supporting device for milling of thin-wall parts comprises a device whole body, a control panel and a movable block, wherein the control panel is arranged at the top of the left side right in front of the device whole body;

a first motor is arranged on the left side inside the whole device, a transmission hinge is arranged at the right end of the first motor in a linkage manner, a rotating disc is movably arranged on the left inner side of the top of the whole device, a limiting guide rail groove is embedded in the right side of the rotating disc, an expansion supporting block is embedded in the limiting guide rail groove, an expansion conical block is movably arranged at the left end of the movable block, a pressure sensor is arranged at the top of the expansion conical block, a second motor is arranged at the right end of the whole device, a transmission threaded rod is arranged at the left end of the second motor in a linkage manner, a hydraulic telescopic rod is arranged at the top of the lifting device, and a conveying pump is arranged inside the water storage barrel;

a filter screen is arranged at the bottom of the inner side of the filter drawer;

a rolling device is movably arranged in the middle of the inside of the whole device, shielding leather cloth is rolled on the periphery of the middle of the rolling device, and a steering shaft is movably arranged at the bottom of the middle of the shielding leather cloth;

the movable baffle plate is characterized in that protruding columns are fixedly arranged on two sides of the rear end of the movable baffle plate, rolling shafts are arranged on the outer periphery of the protruding columns in an embedded mode, a protruding connecting block is fixedly arranged in the middle of the front of the movable baffle plate, a penetrating shaft penetrates through the right side of the protruding connecting block, and a conveying water pipe is tightly communicated with the bottom of the movable baffle plate.

Preferably, the inner side of the limiting guide rail groove is provided with a contact spring group.

Preferably, the right inner side of the expansion supporting block is movably provided with a movable roller.

Preferably, a conductive slip ring is movably arranged in the middle of the left side of the movable block.

Preferably, the bottom end of the movable block is movably provided with a supporting roller.

Preferably, baffles are fixedly arranged on two sides of the bottom end of the filtering drawer.

Preferably, the left side of the shielding leather cloth is tightly attached with a scraper.

Preferably, the first motor is matched with the transmission hinge, the rotating disk, the limiting guide rail groove and the expansion supporting block to form the self-adaptive supporting mechanism.

Preferably, the movable block is matched with the sliding groove, the expansion taper block, the pressure sensor, the second motor and the transmission threaded rod for use to form an expansion sensing mechanism.

Preferably, the protruding column is matched with the rolling shaft, the protruding connecting block, the penetrating shaft, the conveying water pipe, the lifting device and the hydraulic telescopic rod for use together to form the enclosing and blocking mechanism.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, the self-adaptive support mechanism is arranged, so that when a user uses the device to integrally process parts with different inner hole diameters, the user can effectively expand and support the inner hole of the part through the self-adaptive support mechanism arranged at the top part of the left side of the device, so that the part can be more stably processed through the milling device under the expansion support of the eight expansion support blocks, and the applicability of the device is higher.

2. According to the expansion induction mechanism, when a user uses the self-adaptive supporting mechanism to support and process the part, the self-adaptive supporting mechanism can cooperate with the pressure sensor electrically connected with the second motor to simultaneously expand and support the part, and the pressure sensor can effectively prevent the expansion supporting block from expanding and damaging the part due to excessive expansion, so that the part can be stably expanded and supported while the part is prevented from being excessively expanded and damaged due to the damage of the processed part.

3. According to the invention, the enclosure mechanism is arranged, so that when a user uses the whole device to process parts, the whole device can effectively block and recycle metal scraps generated by processing through the unfolded movable baffle, and after the use is finished or in the earlier stage of use, the movable baffle can be in a flat state, so that the user does not influence the additional sheathing of the movable baffle on the periphery of the expansion supporting block, and the user can more conveniently use the whole device to mill the parts.

Drawings

FIG. 1 is a schematic view of the overall structure of the apparatus of the present invention;

FIG. 2 is a schematic view of the overall front cross-sectional structure of the apparatus of the present invention;

FIG. 3 is an enlarged schematic view of the structure at A of the present invention;

FIG. 4 is an enlarged view of the structure at B of the present invention;

fig. 5 is a schematic view of the structure of the movable baffle plate of the invention.

The labels in the figure are: 1. the whole device; 2. a control panel; 3. a filter drawer; 4. a movable baffle; 401. a projecting post; 402. a roller; 403. a protruding connecting block; 404. penetrating the shaft; 405. a water delivery pipe; 5. a movable block; 6. a chute; 7. a water storage barrel; 8. a lifting device; 9. a first motor; 10. a drive hinge; 11. rotating the disc; 12. a limiting guide rail groove; 13. against the spring set; 14. expanding the supporting block; 15. a movable roller; 16. a conductive slip ring; 17. expanding the conical block; 18. a pressure sensor; 19. a second motor; 20. a transmission threaded rod; 21. supporting the rollers; 22. a hydraulic telescopic rod; 23. a delivery pump; 24. a filter screen; 25. a baffle plate; 26. shielding leather cloth; 27. a steering shaft; 28. a squeegee; 29. and a rolling device.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1-5, the present invention provides a technical solution: a self-adaptive supporting device for milling thin-wall parts comprises a device whole 1, an operation panel 2 and a movable block 5, wherein the operation panel 2 is arranged at the top of the left side right in front of the device whole 1, a filtering drawer 3 is embedded in the middle of the left side right in front of the device whole 1, a movable baffle 4 is movably arranged at the middle part of the top of the device whole 1, the movable block 5 is movably arranged at the right side of the top of the device whole 1, a sliding groove 6 is embedded in the middle of the top of the right side of the device whole 1, a water storage bucket 7 is arranged at the bottom of the left side of the device whole 1, and lifting devices 8 are movably arranged at two ends of the movable baffle 4;

a first motor 9 is arranged on the left side inside the device body 1, a transmission hinge 10 is arranged at the right end of the first motor 9 in a linkage manner, a rotating disk 11 is movably arranged on the left inner side of the top of the device body 1, a limiting guide rail groove 12 is embedded in the right side of the rotating disk 11, an expansion supporting block 14 is embedded in the inner side of the limiting guide rail groove 12, an expansion conical block 17 is movably arranged at the left end of the movable block 5, a pressure sensor 18 is arranged at the top of the expansion conical block 17, a second motor 19 is arranged at the top of the right end of the device body 1, a transmission threaded rod 20 is arranged at the left end of the second motor 19 in a linkage manner, a hydraulic telescopic rod 22 is arranged at the top of the lifting device 8, and a conveying pump 23 is arranged inside the water storage barrel 7;

a filter screen 24 is arranged at the bottom of the inner side of the filter drawer 3;

a rolling device 29 is movably arranged in the middle of the inside of the device whole body 1, shielding leather cloth 26 is rolled on the periphery of the middle of the rolling device 29, and a steering shaft 27 is movably arranged at the bottom of the middle of the shielding leather cloth 26;

the rear end of the movable baffle 4 is fixedly provided with protruding columns 401 on two sides, the outer periphery of the protruding columns 401 is provided with rolling shafts 402 in an embedded mode, the middle of the front of the movable baffle 4 is fixedly provided with protruding connecting blocks 403, the right sides of the protruding connecting blocks 403 are provided with penetrating shafts 404 in a penetrating mode, and the bottom of the movable baffle 4 is provided with a conveying water pipe 405 in a tightly communicated mode.

Preferably, the inside of the limit rail groove 12 is provided with the collision spring group 13, because the limit rail groove 12 and the expansion supporting block 14 are provided with eight, the collision spring group 13 is also provided with eight groups, which are respectively arranged at the inside of each limit rail groove 12, and the collision spring group 13 is all through surrounding the supporting point with the periphery, and the inside is the collision point, so when the eight expansion supporting blocks 14 are not used, the eight expansion supporting blocks 14 can be curled into a circular ring with the minimum diameter due to the support of the collision spring group 13, thereby enabling a user to more conveniently place the processing part sleeve at the periphery of the curled expansion supporting block 14.

Preferably, the movable roller 15 is movably disposed on the right inner side of the expanded supporting block 14, after a user sleeves a machined part on the periphery of the expanded supporting block 14, the expanded supporting block 14 needs to be embedded into the expanded conical block 17 arranged on the right end to achieve the purpose of expansion, and when the expanded conical block 17 is inserted into the right side of a cylinder formed by curling the eight expanded supporting blocks 14, the eight expanded pile supporting blocks 14 can be expanded by using the expanded conical block 17 as a supporting point through the movable roller 15 disposed on the right inner side, and the expanded supporting block 14 can be better expanded by using the expanded conical block 17 as the supporting point through the arrangement.

Preferably, the conductive slip ring 16 is movably disposed in the middle of the left side of the movable block 5, and because the rotating disc 11, the expansion support block 14 and the coupled expansion cone block 17 need to rotate in situ when processing the parts, the conductive slip ring 16 is disposed so that the pressure sensor 18 disposed on the top of the expansion cone block 17 can be better electrically connected to the second motor 19 through the conductive slip ring 16.

Preferably, the bottom activity of movable block 5 is provided with supporting roller 21, the bottom of movable block 5 runs through and is provided with drive threaded rod 20, and the downthehole thread groove that is provided with the peripheral adaptation of drive threaded rod 20 that runs through drive threaded rod 20, and movable block 5 can't be rotatory simultaneously along with drive threaded rod 20 because receive the restriction of spout 6 again, so movable block 5 will turn left or turn right translation when drive threaded rod 20 is rotatory, and the accessible supporting roller 21 more smoothly moves in the inboard of spout 6 when movable block 5 removes.

Preferably, the fixed baffle 25 that is provided with in bottom both sides of filtering drawer 3, because filtering drawer 3 sets up through the embedding, so filtering drawer 3 and the whole 1 inner wall junction of device can have the gap, and set up baffle 25 in the bottom both sides of filtering drawer 3 and can effectually place the cooling water of recycling and have the leakage in gap through filtering drawer 3 and the whole 1 inner wall junction of device to make the cooling water of retrieving through filtering drawer 3 can be better flow back to in the water storage bucket 7 through baffle 25.

Preferably, the left side that shelters from leather clothing 26 is closely laminated and is provided with scraper 28, when sheltering from leather clothing 26 and being in laxity state, shelter from leather clothing 26 and can be in the periphery of rolling up device 29 (the middle part of rolling up device 29 is provided with clockwork spring) of winding up under the drive of rolling up device 29 elasticity, so can drive when sheltering from leather clothing 26 and be in laxity state and roll up device 29 and roll up sheltering from leather clothing 26, and when sheltering from leather clothing 26 and retracting the middle periphery of winding up device 29, scraper 28 can effectually will drop and strike off at the metal residue piece that shelters from the top of leather clothing 26, the metal piece after scraping off can circulate to the top of filtering drawer 3 because of the setting on scraper 28 inclined plane.

Preferably, the first motor 9 cooperates with the transmission hinge 10, the rotating disk 11, the limiting guide rail groove 12 and the expanding support block 14 to form a self-adaptive support mechanism, when a user uses the device as a whole 1 to process parts, the user can manually sleeve the parts to be processed on the periphery of a cylinder formed by the eight expanding support blocks 14, then the user can control the expanding induction mechanism by using the control panel 2 to push the expanding conical block 17 to move towards the left end, when the expanding conical block 17 moves towards the left end and is inserted into the middle of the cylinder formed by the eight expanding support blocks 14, the eight expanding support blocks 14 can be expanded outwards through the movable roller 15 due to the continuous insertion of the expanding conical block 17 (the left end of the expanding support block 14 can compress the abutting spring group 13 along the limiting guide rail groove 12), and can be tightly attached to the inner wall of the processed parts sleeved on the periphery of the expanding support block 14, then, the user can operate the first motor 9 through the operation panel 2, and when the first motor 9 operates, the rotation disc 11 is driven to rotate through the transmission hinge 10, when the rotating disk 11 rotates, the expanding supporting block 14 and the processing parts sleeved on the periphery of the expanding supporting block 14 are driven to rotate simultaneously, therefore, the milling device can better process the other parts, and through the arrangement, when a user uses the whole device 1 to process parts with different inner hole diameters, the user can effectively expand and support the inner hole of the part through the self-adaptive supporting mechanism arranged at the top part of the left side of the device whole body 1, therefore, the parts can be processed more stably through the milling device under the expansion support of the eight expansion support blocks 14, and the applicability of the whole device 1 is higher.

Preferably, the movable block 5 cooperates with the sliding slot 6, the expansion cone block 17, the pressure sensor 18, the second motor 19 and the transmission threaded rod 20 to form an expansion sensing mechanism, the second motor 19 is electrically connected with the pressure sensor 18 through a lead and a conductive slip ring 16, when the control panel 2 controls the second motor 19 to drive the transmission threaded rod 20 to rotate clockwise to push the movable block 5 to move along the transmission threaded rod 20 and the sliding slot 6 to translate towards the left end to push the expansion cone block 17 to expand the eight expansion supporting blocks 14, the pressure sensor 18 arranged at the top of the expansion cone block 17 can effectively sense the supporting force of the expanded expansion supporting blocks 14, when the pressure value of the pressure sensor 18 rises (when the expansion supporting blocks 14 expand, only the processed parts are supported, and when the expansion supporting blocks 14 are tightly attached to the inner walls of the processed parts, the extrusion force will slowly rise, and when the extrusion force rises, the pressure sensor 18 will control the second motor 19 to stop operating), the pressure sensor 18 will control the second motor 19 to stop operating through the conducting wire and the conducting slip ring 16, so that the movable block 5 stays at the current position, the expansion cone block 17 does not move towards the left end to push the eight expansion supporting blocks 14 to continue to expand and support the other parts, so that the part can be stably sleeved on the periphery of the expanded eight expansion supporting blocks 14 and is not deformed by the expansion pressure, and the self-adaptive supporting mechanism can cooperate with the pressure sensor 18 electrically connected with the second motor 19 to simultaneously expand and support the part when a user uses the self-adaptive supporting mechanism to support the part, and the pressure sensor 18 can effectively prevent the expansion supporting blocks 14 from expanding and damaging the part due to over expansion, therefore, the part expansion support can be stabilized, and the damage to the machined part caused by over expansion of the part can be prevented.

Preferably, the protruding column 401 cooperates with the roller 402, the protruding connection block 403, the through shaft 404, the water delivery pipe 405, the lifting device 8 and the telescopic hydraulic rod 22 to form a barrier mechanism, after the user stably sleeves the part on the periphery of the expanding support block 14 by using the adaptive support mechanism and the expansion sensing mechanism, the user can operate the liquid pump inside the lifting device 8 by using the control panel 2, and push the hydraulic oil inside the telescopic hydraulic rod 22 when the liquid pump operates, so as to push the telescopic hydraulic rod 22 to extend upward, and when the telescopic hydraulic rod 22 extends upward, the telescopic hydraulic rod 22 pushes the front end of the movable baffle plate 4 to move to the top through the protruding connection block 403 (the top of the telescopic hydraulic rod 22 is movably connected with the protruding connection block 403 through the through shaft 404), and when the front end of the movable baffle plate 4 moves to the top, the rear end of the movable baffle 4 can move through the protruding column 401 and the roller 402 at the periphery of the protruding column 401 to match with the movable baffle 4 (the periphery of the protruding column 401 and the roller 402 is preset with a longer limit chute, so that the front end of the movable baffle 4 can be matched with the movable baffle 4 to perform inclined plane unfolding along the limit chute when moving to the top), thereby forming an inclined plane, the movable baffle 4 forming the inclined plane can effectively block metal scraps generated by processing, so that the metal scraps can be circulated to the inside of the device whole body 1 through the movable baffle 4 forming the inclined plane, after the device whole body 1 completes additional processing, a user can control the hydraulic telescopic rod 22 to retract to the bottom through the control panel 2, so that the movable baffle 4 is restored to the state in the figure I, and the user can use the device whole body 1 to process parts through the arrangement, the effectual metal piece that produces the processing of the whole 1 accessible of device after expansion blocks to retrieve, and when using the completion after or using earlier stage, adjustable fender 4 can be the tiling state and will not influence the user and will overlap in the periphery of expansion supporting shoe 14 in addition to make the whole 1 of utilization device that the user can be more convenient mill the processing to the part.

The working principle is as follows: firstly, a user needs to manually sleeve parts to be processed on the periphery of eight expanded supporting blocks 14 which are curled and contracted into a cylinder, then the second motor 19 is controlled by the control panel 2 to operate, so that the movable block 5 and the expansion conical block 17 are pushed to move towards the left end, the second motor 19 is inserted into the central position of the eight expanded supporting blocks 14 when the expansion conical block 17 moves towards the left end, then the eight expanded supporting blocks 14 are expanded, the pressure sensor 18 arranged at the top of the expansion conical block 17 can control the second motor 19 to stop operating after the pressure value changes (when the expansion conical block 17 pushes the eight expanded supporting blocks 14 to expand and support the processed parts, the inner walls of the processed parts are attached after the expansion supporting blocks 14 are expanded to a certain position, and the pressure value of the pressure sensor 18 changes at the moment), then the user controls the enclosure mechanism to expand by the control panel 2, the self-adaptive support device for the milling of the thin-wall parts has the advantages that metal scraps generated by machining are blocked and recovered, and the working principle of the self-adaptive support device for the milling of the thin-wall parts is the working principle.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The utility model provides a self-adaptation strutting arrangement for thin wall part milling process, includes that the device is whole (1), controls panel (2) and movable block (5), its characterized in that: a control panel (2) is arranged at the top of the left side right in front of the device body (1), a filter drawer (3) is embedded in the middle of the left side right in front of the device body (1), a movable baffle (4) is movably arranged at the middle part of the top of the device body (1), a movable block (5) is movably arranged at the right side of the top of the device body (1), a sliding groove (6) is embedded in the middle of the top of the right side of the device body (1), a water storage barrel (7) is arranged at the bottom of the left side of the device body (1), and lifting devices (8) are movably arranged at two ends of the movable baffle (4);

a first motor (9) is arranged on the left side in the device body (1), a transmission hinge (10) is arranged at the right end of the first motor (9) in a linkage manner, the left inner side of the top of the device whole body (1) is movably provided with a rotating disk (11), a limiting guide rail groove (12) is embedded in the right side of the rotating disk (11), an expansion supporting block (14) is embedded in the inner side of the limiting guide rail groove (12), an expansion taper block (17) is movably arranged at the left end of the movable block (5), a pressure sensor (18) is arranged at the top of the expansion taper block (17), the top of the right end of the device whole body (1) is provided with a second motor (19), a transmission threaded rod (20) is arranged at the left end of the second motor (19) in a linkage manner, a hydraulic telescopic rod (22) is arranged at the top of the lifting device (8), and a conveying pump (23) is arranged in the water storage barrel (7);

a filter screen (24) is arranged at the bottom of the inner side of the filter drawer (3);

a rolling device (29) is movably arranged in the middle of the inside of the device whole body (1), shielding leather cloth (26) is rolled on the periphery of the middle of the rolling device (29), and a steering shaft (27) is movably arranged at the bottom of the middle of the shielding leather cloth (26);

the fixed salient post (401) that is provided with in rear end both sides of adjustable fender (4), the outside periphery nestification of salient post (401) is provided with roller bearing (402), the fixed salient connecting block (403) that is provided with in the middle of adjustable fender (4) dead ahead, the right side of salient connecting block (403) is run through and is provided with through axle (404), the tight intercommunication in bottom of adjustable fender (4) is provided with delivery pipe (405).

2. The adaptive support device for milling of thin-walled parts according to claim 1, wherein: and the inner side of the limiting guide rail groove (12) is provided with a contact spring group (13).

3. The adaptive support device for milling of thin-walled parts according to claim 1, wherein: the right inner side of the expansion supporting block (14) is movably provided with a movable roller (15).

4. The adaptive support device for milling of thin-walled parts according to claim 1, wherein: and a conductive slip ring (16) is movably arranged in the middle of the left side of the movable block (5).

5. The adaptive support device for milling of thin-walled parts according to claim 1, wherein: the bottom end of the movable block (5) is movably provided with a supporting roller (21).

6. The adaptive support device for milling of thin-walled parts according to claim 1, wherein: and baffles (25) are fixedly arranged on two sides of the bottom end of the filtering drawer (3).

7. The adaptive support device for milling of thin-walled parts according to claim 1, wherein: the left side of the shielding leather cloth (26) is tightly attached with a scraper (28).

8. The adaptive support device for milling of thin-walled parts according to claim 1, wherein: the first motor (9) is matched with the transmission hinge (10), the rotating disk (11), the limiting guide rail groove (12) and the expansion supporting block (14) to form a self-adaptive supporting mechanism.

9. The adaptive support device for milling of thin-walled parts according to claim 1, wherein: the movable block (5) is matched with the sliding groove (6), the expansion taper block (17), the pressure sensor (18), the second motor (19) and the transmission threaded rod (20) to form an expansion sensing mechanism.

10. The adaptive support device for milling of thin-walled parts according to claim 1, wherein: the protruding column (401) is matched with the rolling shaft (402), the protruding connecting block (403), the penetrating shaft (404), the conveying water pipe (405), the lifting device (8) and the hydraulic telescopic rod (22) to be used together to form the enclosing and blocking mechanism.

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