CN112057816B

CN112057816B - Engineering is with supplementary climbing equipment

Info

Publication number: CN112057816B
Application number: CN202010858791.7A
Authority: CN
Inventors: 李小平
Original assignee: Baoying Luxiao Economic Development Co ltd
Current assignee: BAOYING Luxiao Economic Development Co.,Ltd.
Priority date: 2020-08-24
Filing date: 2020-08-24
Publication date: 2021-08-03
Anticipated expiration: 2040-08-24
Also published as: CN112057816A

Abstract

The invention relates to the technical field of engineering safety auxiliary devices, in particular to an auxiliary climbing device for engineering. The device is convenient to complete automatic locking and positioning at a high position and convenient to install, position and detach through the design that an automatic locking component force positioning structure is matched with a component force pull belt, stable height positioning is completed through electric locking and mechanical locking, triangular pulling force is convenient to form by utilizing the determination of a carrying position, the positioning effect is convenient to stably improve under stress, the device is convenient to complete fastening connection between the belts at an extending connection position through the matching design of a multiple locking connection stress structure and a matching connection locking connection structure, fastening connection is completed through multiple different locking connection matching of structural members, the stress effect in the climbing process is improved, and stress falling and separation in the climbing process are avoided.

Description

Engineering is with supplementary climbing equipment

Technical Field

The invention relates to the technical field of engineering safety auxiliary devices, in particular to auxiliary climbing equipment for engineering.

Background

Along with the rapid development of society, safety more and more receives the attention in engineering operation, because often need carry out the climbing of take the altitude in some engineering operations, this kind grasps certain atress object and carries out the action of removing because lack stable stress point, lead to the safety problem appearing easily, in order to improve the security, often can use certain supplementary climbing equipment, however, the atress chucking structure of current device top often receives the design restriction at the climbing in-process, often be not convenient for reach electric and mechanical lock cooperation locking when quick installation, positioning stability is relatively poor, and lack stable locking structure between the connection in area and area, the separation drops when receiving great impact force that drops easily.

SUMMARY OF THE PATENT FOR INVENTION

The invention aims to provide auxiliary climbing equipment for engineering.

In order to achieve the purpose, the invention adopts the following technical scheme:

an auxiliary climbing device for engineering comprises a stress connecting buckle, wherein a matched elastic rope is sleeved at the bottom end of the stress connecting buckle, a multiple locking connection stress structure is sleeved at the bottom end of the matched elastic rope, the bottom end of the multiple locking connection stress structure is connected with a matched connection locking connection structure, two sides of the bottom end of the matched connection locking connection structure are connected with component force pull belts, and one end of each component force pull belt is connected with an automatic locking component force positioning structure;

the automatic locking component force positioning structure comprises a multifunctional carrying box, a handle, an electric control switch, a vacuum chuck, an electromagnet adsorption block, a matching carrying block, a first electric pushing cylinder, a piston locking rod, a displacement closed guide sheet, a supporting assembly table, a second electric pushing cylinder and a derivation closed clamping block, wherein one end of the multifunctional carrying box is connected with the handle, the electric control switch is installed at the top end of the handle, a controller, a time controller and a storage battery are installed inside the multifunctional carrying box, the electric control switch, the electromagnet adsorption block, the first electric pushing cylinder and the time controller are all electrically connected with the controller, the electric control switch, the electromagnet adsorption block, the first electric pushing cylinder, the second electric pushing cylinder, the time controller and the controller are all electrically connected with the storage battery, the second electric pushing cylinder is electrically connected with the time controller, and the upper end and the lower end of one end of the multifunctional carrying box are all fixedly connected with the electromagnet adsorption block, the multifunctional carrying box comprises a multifunctional carrying box body and is characterized in that the outer surface of one end of the multifunctional carrying box body is connected with a plurality of vacuum suckers, the top end of the multifunctional carrying box body is in welded connection with a loading block, the top end of the loading block is fixedly connected with a first electric pushing cylinder through screws, the output end of the first electric pushing cylinder is connected with a piston locking rod, a displacement closing guide sheet is welded at the bottom end of the piston locking rod, the two sides of the upper surface of the bottom end of the multifunctional carrying box body are in welded connection with a supporting assembly table, one end of the supporting assembly table is fixedly connected with a second electric pushing cylinder through screws, and the output end of the second electric pushing cylinder is in welded connection with a derivation closing clamping block.

Preferably, the multiple locking connection stress structure comprises an integrated built-in block, an extending rope ring, an electricity storage control module, a limiting guide block, a matching sliding groove, a motor, an output gear, a driven gear, a toggle gear, a matching displacement rack clamping column, an extending connection plate, a micro electric piston cylinder and a closing locking push block, one side of the top end of the integrated built-in block is welded with the extending rope ring, the electricity storage control module is fixed on the other side of the top end of the integrated built-in block through a screw, the electricity storage control module comprises a rechargeable lithium battery, two control buttons and a remote controller, the motor, the micro electric piston cylinder and the control buttons are electrically connected with the remote controller, the motor, the micro electric piston cylinder and the remote controller are connected with the rechargeable lithium battery, and two sides of the inside of the integrated built-in block are welded with the limiting guide block, the improved structure of the lock comprises a limiting guide block, a matching sliding groove, a matching displacement rack clamping column, a motor, an output gear, a driven gear, a toggle gear, a matching displacement rack clamping column, a screw and a micro electric piston cylinder, wherein the matching sliding groove is formed in one side of the limiting guide block, the inside of the matching sliding groove is connected with the matching displacement rack clamping column in a sliding mode, the inside of an integrated built-in block is fixedly connected with the motor, the output end of the motor is connected with the output gear in a rotating mode, the two sides of the output gear are connected with the driven gear through gear teeth meshing, one side of the driven gear is connected with the toggle gear through meshing, the toggle gear is connected with the matching displacement rack clamping column in a meshing mode, the bottom end of the matching displacement rack clamping column is connected with the extending distribution plate in a welding mode, one side of the extending distribution plate is connected with the micro electric piston cylinder through screws, and the output end of the micro electric piston cylinder is connected with the closed locking push block in a welding mode.

Preferably, the cooperation is connected and is locked connection structure and is joined in marriage lock lug, bayonet lock groove, supplementary latch segment and rope end locating piece including cooperation lock seat, T type, the inboard and the T type on cooperation lock seat top are joined in marriage lock lug welded connection, bayonet lock groove is seted up in the inside of cooperation lock seat, the lower surface both sides of cooperation lock seat all with supplementary latch segment and rope end locating piece fixed connection, bayonet lock groove is clearance fit with cooperation displacement rack joint post.

Preferably, a guide sliding groove is formed in one side of the support assembly table, matching sliding blocks are welded to two sides of the displacement closed guide piece, and the matching sliding blocks are in clearance fit with the guide sliding groove.

Preferably, the model of the controller is SC200, the model of the time controller is LT-233D, and the model of the remote controller is KL 4-GPRS-RFVC.

Preferably, a semicircular clamping groove is formed in the derivation closed clamping block, and the diameter of the semicircular clamping groove is the same as that of the piston locking rod.

Preferably, the external force step-up lockhole has been seted up to the inside of spacing guide block, just the external force step-up lockhole has also been seted up to the inside of cooperation lock seat, the inside grafting of external force step-up lockhole has the grafting locating pin, multiple locking connection atress structure runs through the external force step-up lockhole of spacing guide block and cooperation lock seat department with the cooperation through the grafting locating pin with the cooperation connection locking connection structure outside and is connected.

Preferably, a square inserting locking hole is formed in the auxiliary locking block, and the square inserting locking hole is in clearance fit with the closed locking push block.

Preferably, the interior of the toggle gear and the driven gear is respectively inserted with a rotating mandrel, two ends of the rotating mandrel are respectively sleeved with a roller bearing, and the toggle gear and the driven gear are respectively rotatably connected with the inner side of the integrated built-in block through the roller bearings.

Preferably, the outside of the integral built-in block is provided with a T-shaped limiting and clamping chute, and the T-shaped limiting and clamping chute is in clearance fit with the T-shaped locking lug.

The invention has at least the following beneficial effects:

1. according to the invention, through the design that the automatic locking component force positioning structure is matched with the component force pull belt, the device is convenient for completing high-position automatic locking positioning and is convenient for installation, positioning and disassembly, stable height positioning is completed through electric locking and mechanical locking, and meanwhile, the triangular tension is conveniently formed by utilizing the determination of the carrying position, so that the positioning effect is more conveniently improved due to stable stress;

2. according to the invention, through the matching design of the multiple locking connection stress structure and the matching connection locking connection structure, the device is convenient for completing the fastening connection between the belts at the extending connection part, the fastening connection is completed by utilizing the multiple different locking connection matching of the structural members, the stress effect in the climbing process is further improved, and the stress falling and separation in the climbing process are avoided.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the patent of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the patent 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 schematic structural view of the present invention as a whole;

FIG. 2 is a front view of the present invention in its entirety;

FIG. 3 is a schematic illustration of the connection of the strap connection structure of the present invention;

FIG. 4 is a schematic view of a portion of a multiple locking force receiving structure according to the present invention;

FIG. 5 is an enlarged partial view of a derivative closure of the present invention;

FIG. 6 is a schematic view of a partial structure of the mating connection locking connection structure of the present invention;

FIG. 7 is a partial schematic structural view of the self-locking force-distributing positioning structure of the present invention;

fig. 8 is a locking schematic diagram of the automatic locking force component positioning structure of the invention.

In the figure: 1. a stress connecting buckle; 2. an elastic rope is matched and connected; 3. a block is arranged in the body; 4. extending over the cord loop; 5. an electrical storage control module; 6. a limiting guide block; 7. a sliding groove is matched; 8. a motor; 9. an output gear; 10. a driven gear; 11. shifting a gear; 12. the column is clamped and connected by matching with the displacement rack; 13. an extension adapter plate; 14. a miniature electric piston cylinder; 15. closing the locking push block; 16. multiple locking connection stress structure; 17. matching with the lock seat; 18. a T-shaped locking lug; 19. a plug-in type locking groove; 20. an auxiliary locking block; 21. a rope end positioning block; 22. the locking connection structure is connected in a matching way; 23. the lock hole is tightened by external force; 24. inserting a positioning pin; 25. a component force pull belt; 26. a multifunctional carrying box; 27. a grip; 28. an electric control switch; 29. a vacuum chuck; 30. an electromagnet adsorption block; 31. assembling a carrying block; 32. a first electric push cylinder; 33. A piston locking rod; 34. a displacement closing guide vane; 35. a support assembly table; 36. a second electric push cylinder; 37. deducing a closed clamping block; 38. automatic locking component force positioning structure.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly apparent, the present invention is further described in 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 present invention and are not intended to limit the present invention.

Referring to fig. 1-8, an auxiliary climbing device for engineering comprises a stressed connecting buckle 1, wherein the bottom end of the stressed connecting buckle 1 is sleeved with a matching elastic rope 2, the bottom end of the matching elastic rope 2 is sleeved with a multiple locking connection stressed structure 16, the bottom end of the multiple locking connection stressed structure 16 is connected with a matching connection locking connection structure 22, two sides of the bottom end of the matching connection locking connection structure 22 are connected with component force drawstrings 25, and one end of each component force drawstring 25 is connected with an automatic locking component force positioning structure 38;

the automatic locking component force positioning structure 38 comprises a multifunctional carrying box 26, a handle 27, an electric control switch 28, a vacuum chuck 29, an electromagnet adsorption block 30, a loading assembly block 31, a first electric pushing cylinder 32, a piston locking rod 33, a displacement closing guide sheet 34, a supporting assembly table 35, a second electric pushing cylinder 36 and a closing pushing and clamping block 37, wherein one end of the multifunctional carrying box 26 is connected with the handle 27, the electric control switch 28 is installed at the top end of the handle 27, a controller, a time controller and a storage battery are installed inside the multifunctional carrying box 26, the controller is SC200, the time controller is LT-233D, the electric control switch 28, the electromagnet adsorption block 30, the first electric pushing cylinder 32 and the time controller are electrically connected with the controller, and the electric control switch 28, the electromagnet block 30, the first electric pushing cylinder 32, the second electric pushing cylinder 36, the time controller, The controller is electrically connected with the storage battery, the second electric pushing cylinder 36 is electrically connected with the time controller, the upper end and the lower end of one end of the multifunctional carrying box 26 are fixedly connected with the electromagnet adsorption block 30, the outer surface of one end of the multifunctional carrying box 26 is connected with the plurality of vacuum suckers 29, the top end of the multifunctional carrying box 26 is welded with the assembling carrying block 31, the top end of the assembling carrying block 31 is fixedly connected with the first electric pushing cylinder 32 through screws, the output end of the first electric pushing cylinder 32 is connected with the piston locking rod 33, the bottom end of the piston locking rod 33 is welded with the displacement closing guide piece 34, the two sides of the upper surface of the bottom end of the multifunctional carrying box 26 are welded with the supporting assembly platform 35, one end of the supporting assembly platform 35 is fixedly connected with the second electric pushing cylinder 36 through screws, the output end of the second electric pushing cylinder 36 is welded with the derivation closing clamping block 37, the automatic high-position positioning locking connection is convenient to form, and after the two automatic locking component force positioning structures 38 are separated and positioned by matching the component force pull belt 25, a triangular shape is formed, the component force pull belt is stressed and unfolded, and the stretching stress is stabilized.

The scheme has the following working processes:

the stressed connecting buckle 1 is buckled and clamped with a safety belt at the waist of a climber, the matched elastic rope 2 and the component pull belt 25 are connected through a multi-locking connection stressed structure 16 and a matching connection locking connection structure 22, a T-shaped matching locking lug 18 is connected with a T-shaped limiting clamping chute at the position of an integrated built-in block 3 in a matching way, an inserting positioning pin 24 penetrates through an external force fastening lock hole 23 to enable the matching connection locking connection structure 22 and the outer side of the multi-locking connection stressed structure 16 to complete connection and locking, a control button at the position of an electricity storage control module 5 is pressed in the connection process, so that a motor 8 is controlled to rotate, the output gear 9, a driven gear 10 and a toggle gear 11 are utilized to conduct rotation, torque is pushed through meshing conduction between the toggle gear 11 and a matching displacement rack clamping column 12, and the gear teeth of the toggle gear 11 are used to push the matching displacement rack clamping column 12 to follow a matching sliding groove 7 for displacement, in the closing process, the rack clamping column 12 passes through the plug-in type locking groove 19 to be leveled with the auxiliary locking block 20 through derivation and matching displacement, the miniature electric piston cylinder 14 is controlled to finish derivation by pressing another control button, the closing locking push block 15 is pushed to perform parallel displacement so as to achieve the purpose of penetrating through a square insertion locking hole in the auxiliary locking block 20, the limited locking after closing is finished, the fastening connection is finished by utilizing multiple different locking matching of structural parts, the stress effect in the climbing process is improved, and the matched elastic rope 2 and the component force pull belt 25 in the climbing process are prevented from being forced to fall off and separated;

through holding the automatic locking component force positioning structure 38 by two hands, the automatic locking component force positioning structure 38 is used for contacting the ladder frame to complete positioning in each climbing process, the multifunctional carrying box 26 is pushed to contact the ladder frame in the positioning process, after the preliminary positioning is completed by the suction force of the vacuum chuck 29, the electric control switch 28 is pressed, the electric control switch 28 is connected with the controller, the electromagnet adsorption block 30 is controlled to generate magnetic adsorption after being electrified, the first electric pushing cylinder 32 is controlled to push the piston locking rod 33 to extend, the displacement closing guide sheet 34 is pushed to displace, the clamping on the outer side of the ladder frame is completed by matching with the support assembly table 35 in a sliding manner, in the pushing process of the piston locking rod 33, the controller synchronously transmits a command to the time controller, and after one second, the second electric pushing cylinder 36 is controlled to complete pushing of the pushing closing clamping block 37, so that the pushing closing clamping block 37 is matched with punching, the clamping limit of the piston locking rod 33 is completed, the piston locking rod 33 is prevented from sliding and falling out in an overtravel process in a stress process, when the piston locking rod is opened, the electric control switch 28 is pressed again to complete contact positioning, climbing is continuously promoted, distance adjustment is carried out between the two automatic locking component force positioning structures 38 in the process of climbing positioning each time, a triangle is formed between the two automatic locking component force positioning structures 38 and the component force pull belt 25 and the matched connecting and locking connecting structure 22, better stretching stability is maintained by utilizing the stability of the triangle, the device is convenient to complete high-position automatic locking positioning, mounting, positioning and dismounting are convenient, stable high positioning is completed by utilizing the determination of a carrying position, and the positioning effect is improved more conveniently and stably under stress.

According to the working process, the following steps are known:

Referring to fig. 4, further, the multiple locking connection stress structure 16 includes an integrated internal block 3, an extending rope ring 4, an electricity storage control module 5, a limit guide block 6, a matching sliding groove 7, a motor 8, an output gear 9, a driven gear 10, a toggle gear 11, a matching displacement rack clamping column 12, an extending matching plate 13, a micro electric piston cylinder 14 and a closed locking push block 15, one side of the top end of the integrated internal block 3 is connected with the extending rope ring 4 in a welding manner, the electricity storage control module 5 is fixed on the other side of the top end of the integrated internal block 3 through a screw, the electricity storage control module 5 internally includes a rechargeable lithium battery, two control buttons and a remote controller, the model of the remote controller is KL4-GPRS-RFVC, the motor 8, the micro electric piston cylinder 14 and the control buttons are all electrically connected with the remote controller, and the motor 8, the micro electric piston cylinder 14 and the remote controller are all connected with the rechargeable lithium battery, the two sides of the inside of the integrated built-in block 3 are welded with the limit guide block 6, the matching sliding groove 7 is arranged on one side of the limit guide block 6, the inside of the matching sliding groove 7 is connected with the matching displacement rack clamping column 12 in a sliding manner, the inside of the integrated built-in block 3 is also fixedly connected with the motor 8, the output end of the motor 8 is connected with the output gear 9 in a rotating manner, the two sides of the output gear 9 are connected with the driven gear 10 through gear tooth meshing, one side of the driven gear 10 is connected with the toggle gear 11 through meshing, the toggle gear 11 is connected with the matching displacement rack clamping column 12 through meshing, the bottom end of the matching displacement rack clamping column 12 is connected with the extension connecting plate 13 in a welding manner, one side of the extension connecting plate 13 is connected with the miniature electric piston cylinder 14 through screws, the output end of the miniature electric piston cylinder 14 is connected with the closed locking push block 15 in a welding manner, and the electric poking and electric splicing is formed through electric control, forming electric locking;

referring to fig. 3-6, further, the matching connection locking connection structure 22 includes a matching lock base 17, a T-shaped matching lock protrusion 18, a plug-in lock groove 19, an auxiliary lock block 20 and a rope end positioning block 21, the inner side of the top end of the matching lock base 17 is welded to the T-shaped matching lock protrusion 18, the plug-in lock groove 19 is disposed inside the matching lock base 17, both sides of the lower surface of the matching lock base 17 are fixedly connected to the auxiliary lock block 20 and the rope end positioning block 21, the plug-in lock groove 19 is in clearance fit with the matching displacement rack fastening column 12, an external force fastening lock hole 23 is disposed inside the limiting guide block 6, an external force fastening lock hole 23 is also disposed inside the matching lock base 17, a plug-in positioning pin 24 is inserted inside the external force fastening hole 23, the multiple locking connection force receiving structure 16 and the matching connection locking connection structure 22 are connected to the external force fastening lock hole 23 at the matching lock base 17 through the plug-in the limiting guide block 6 via the plug-in positioning pin 24, the sliding insertion and closing can be conveniently completed by matching with the automatic locking component force positioning structure 38, and the connection is fastened again through external force to form mechanical stress limiting, so that the connection strength between the matched elastic rope 2 and the component force pull belt 25 is further improved;

referring to fig. 7, further, a guide sliding groove is formed in one side of the support assembly table 35, adapter sliding blocks are welded on two sides of the displacement closing guide piece 34, the adapter sliding blocks are in clearance fit with the guide sliding groove, a semicircular clamping groove is formed in the derivation closing clamping block 37, the diameter of the semicircular clamping groove is the same as that of the piston locking rod 33, clamping limiting and clamping guiding are facilitated to be formed, and therefore the automatic locking component force positioning structure 38 is prevented from being disengaged due to stress in the locking and positioning process;

referring to fig. 4-6, further, a square inserting locking hole is formed inside the auxiliary locking block 20, the square inserting locking hole is in clearance fit with the closed locking push block 15, a T-shaped limiting and clamping chute is formed outside the integrated inner block 3, and the T-shaped limiting and clamping chute is in clearance fit with the T-shaped locking protrusion block 18, so as to assist in forming the closed locking of the multiple locking connection stress structure 16 and the matched connection locking connection structure 22;

referring to fig. 4, further, a rotating mandrel is inserted into the toggle gear 11 and the driven gear 10, roller bearings are sleeved at two ends of the rotating mandrel, and the toggle gear 11 and the driven gear 10 are rotatably connected with the inner side of the integrated built-in block 3 through the roller bearings, so that electric power pushing and locking of the multiple locking connection stress structure 16 can be completed through derivation and conduction.

The foregoing shows and describes the general principles of the present patent, its essential features, and its advantages. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are only for the purpose of illustrating the principles of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims. The scope of the invention patent claims is defined by the appended claims and their equivalents.

Claims

1. The auxiliary climbing equipment for engineering comprises a stress connecting buckle (1) and is characterized in that a matching elastic rope (2) is sleeved at the bottom end of the stress connecting buckle (1), a multiple-locking connection stress structure (16) is sleeved at the bottom end of the matching elastic rope (2), the bottom end of the multiple-locking connection stress structure (16) is connected with a matching connection locking connection structure (22), two sides of the bottom end of the matching connection locking connection structure (22) are connected with component force pull belts (25), and one end of each component force pull belt (25) is connected with an automatic locking component force positioning structure (38);

automatic locking component force location structure (38) including multi-functional box (26), handle (27), electric control switch (28), vacuum chuck (29), electro-magnet adsorb piece (30), join in marriage dress and carry piece (31), first electronic promotion jar (32), piston locking rod (33), displacement closure guide vane (34), support assembly stand (35), second electronic promotion jar (36) and derive closed clamp piece (37), the one end and handle (27) of multi-functional box (26) of carrying on, electric control switch (28) are installed in the top of handle (27), the internally mounted of multi-functional box (26) has controller, time controller and battery, electric control switch (28), electro-magnet adsorb piece (30), first electronic promotion jar (32) and time controller all are connected with the controller electricity, electric control switch (28) and electric control switch (28), The electromagnet adsorption block (30), the first electric pushing cylinder (32), the second electric pushing cylinder (36), the time controller and the controller are all electrically connected with the storage battery, the second electric pushing cylinder (36) is electrically connected with the time controller, the upper end and the lower end of one end of the multifunctional carrying box (26) are fixedly connected with the electromagnet adsorption block (30), the outer surface of one end of the multifunctional carrying box (26) is connected with a plurality of vacuum suckers (29), the top end of the multifunctional carrying box (26) is welded with the assembling carrying block (31), the top end of the assembling carrying block (31) is fixedly connected with the first electric pushing cylinder (32) through screws, the output end of the first electric pushing cylinder (32) is connected with the piston locking rod (33), the bottom end of the piston locking rod (33) is welded with a displacement closing guide sheet (34), and two sides of the upper surface of the bottom end of the multifunctional carrying box (26) are welded with the supporting assembly table (35), one end of the support assembly table (35) is fixedly connected with a second electric pushing cylinder (36) through a screw, and the output end of the second electric pushing cylinder (36) is welded with a pushing and closing clamping block (37); the multiple locking connection stress structure (16) comprises an integrated built-in block (3), an extending rope ring (4), an electric storage control module (5), a limiting guide block (6), a matching sliding groove (7), a motor (8), an output gear (9), a driven gear (10), a toggle gear (11), a matching displacement rack clamping column (12), an extending distribution plate (13), a micro electric piston cylinder (14) and a closed locking push block (15), wherein one side of the top end of the integrated built-in block (3) is connected with the extending rope ring (4) in a welding mode, the other side of the top end of the integrated built-in block (3) is fixedly provided with an electric storage control module (5) through a screw, the electric storage control module (5) internally comprises a rechargeable lithium battery, two control buttons and a remote controller, and the motor (8), the micro electric piston cylinder (14) and the control buttons are all electrically connected with the remote controller, the motor (8), the miniature electric piston cylinder (14) and the remote controller are all connected with a rechargeable lithium battery, two sides of the inside of the integrally-installed block (3) are connected with the limiting guide block (6) in a welding mode, the matching sliding groove (7) is arranged on one side of the limiting guide block (6), the inside of the matching sliding groove (7) is connected with the matching displacement rack clamping column (12) in a sliding mode, the inside of the integrally-installed block (3) is further fixedly connected with the motor (8), the output end of the motor (8) is connected with the output gear (9) in a rotating mode, two sides of the output gear (9) are connected with the driven gear (10) through gear tooth meshing, one side of the driven gear (10) is connected with the toggle gear (11) through meshing, the toggle gear (11) is connected with the matching displacement rack clamping column (12) in a meshing mode, the bottom end of the matching displacement rack clamping column (12) is connected with the extending distribution plate (13) in a welding mode, one side of the extension joint plate (13) is connected with a miniature electric piston cylinder (14) through a screw, and the output end of the miniature electric piston cylinder (14) is welded with a closed locking push block (15); locking connection structure (22) is connected in the cooperation and locks lug (18), bayonet lock groove (19), supplementary latch segment (20) and rope end locating piece (21) are joined in marriage including cooperation lock seat (17), T type, the inboard and the T type on cooperation lock seat (17) top join in marriage lock lug (18) welded connection, the inside of cooperation lock seat (17) is seted up in bayonet lock groove (19), the lower surface both sides of cooperation lock seat (17) all with supplementary latch segment (20) and rope end locating piece (21) fixed connection, bayonet lock groove (19) are clearance fit with cooperation displacement rack joint post (12).

2. The auxiliary climbing equipment for engineering as claimed in claim 1, wherein a guide chute is formed in one side of the support assembly table (35), mating sliding blocks are welded to two sides of the displacement closing guide vane (34), and the mating sliding blocks are in clearance fit with the guide chute.

3. The auxiliary climbing device for engineering as claimed in claim 2, wherein the model of the controller is SC200, the model of the time controller is LT-233D, and the model of the remote controller is KL 4-GPRS-RFVC.

4. The auxiliary climbing equipment for engineering as claimed in claim 1, wherein a semicircular clamping groove is formed in the inside of the pushing-closing clamping block (37), and the diameter of the semicircular clamping groove is the same as that of the piston locking rod (33).

5. The auxiliary climbing equipment for engineering as claimed in claim 3, wherein an external force tightening lock hole (23) is formed in the limiting guide block (6), an external force tightening lock hole (23) is also formed in the matching lock seat (17), an insertion positioning pin (24) is inserted into the external force tightening lock hole (23), and the multiple locking connection stress structure (16) and the matching connection locking connection structure (22) are connected through the external force tightening lock hole (23) at the limiting guide block (6) and the matching lock seat (17) through the insertion positioning pin (24).

6. The auxiliary climbing equipment for engineering as claimed in claim 1, wherein a square insertion locking hole is formed in the auxiliary locking block (20), and the square insertion locking hole is in clearance fit with the closed locking push block (15).

7. The auxiliary climbing equipment for engineering as claimed in claim 2, wherein a rotating mandrel is inserted into the toggle gear (11) and the driven gear (10), roller bearings are sleeved at two ends of the rotating mandrel, and the toggle gear (11) and the driven gear (10) are rotatably connected with the inner side of the integrated built-in block (3) through the roller bearings.

8. The auxiliary climbing equipment for engineering as claimed in claim 1, wherein the outside of the integral built-in block (3) is provided with a T-shaped limiting and clamping chute, and the T-shaped limiting and clamping chute is in clearance fit with the T-shaped locking convex block (18).