A building support assembly aid for high altitude construction

By using a building support assembly auxiliary device with position adjustment components, rope winding and unwinding components, and lubrication components in high-altitude construction, the problem of unstable support connection in high-altitude construction has been solved, construction safety and efficiency have been improved, the service life of wire ropes has been extended, and real-time monitoring of the construction process has been realized.

CN122380249APending Publication Date: 2026-07-14ZHEJIANG LVMEI CONSTR CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
ZHEJIANG LVMEI CONSTR CO LTD
Filing Date
2026-05-20
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

The assembly of existing high-altitude construction scaffolding is inconvenient to operate, not securely fixed, and has low construction safety and efficiency. In particular, it is difficult to ensure the stability of the scaffolding connection and the safety of construction personnel in small projects.

Method used

An auxiliary assembly device for building supports is adopted, which includes a position adjustment component, a rope winding and unwinding component, and a lubrication component. The horizontal and angle adjustments are achieved by motor drive, the vertical lifting and lowering of materials is ensured by steel wire rope and anti-detachment plate, and the automatic lubrication of steel wire rope is achieved by the lubrication component to reduce friction and wear.

Benefits of technology

It improves the safety and efficiency of high-altitude construction, ensures the stability of the support connection, extends the service life of the wire rope, and provides real-time monitoring and safety assurance for the construction process.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN122380249A_ABST
    Figure CN122380249A_ABST
Patent Text Reader

Abstract

The application relates to the technical field of building construction auxiliary equipment, in particular to a building support assembling auxiliary device and method for high-altitude construction, and the technical scheme points comprise a position adjusting assembly, the top of the position adjusting assembly is provided with a connecting plate, the top of the connecting plate is fixedly provided with a support arm, the top of the connecting plate is provided with a winding and unwinding rope assembly, and the surface of the support arm is provided with a lubricating assembly. The building support assembling auxiliary device for high-altitude construction is started by a first motor, horizontal position adjustment of the device is realized, a second motor is started, multi-angle adjustment of the device is realized, a third motor is started, vertical lifting and lowering of building supports and other materials are realized, the surface of a steel wire rope is contacted with a ball, the ball continuously transfers lubricating oil on an oil guide ring to the surface of the steel wire rope during operation, continuous automatic lubrication of the steel wire rope is realized, manual frequent oiling is not needed, friction and abrasion of the steel wire rope are effectively reduced, rust is reduced, and the service life of the steel wire rope is prolonged.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This invention relates to the technical field of auxiliary equipment for building construction, and specifically to an auxiliary device and method for assembling building supports for high-altitude construction. Background Technology

[0002] The demand for exterior wall construction on high-rise buildings is increasing, including tasks such as exterior wall cleaning, protective panel installation, and replacement of exterior wall protection. These operations typically require the erection of scaffolding on the building's exterior walls to provide a working platform. Currently, the transport and assembly of scaffolding for high-altitude construction mainly relies on large lifting equipment such as tower cranes. Tower cranes can lift scaffolding components to designated floors, where construction workers then assemble them on-site. However, tower crane construction itself is a large-scale, time-consuming, and costly undertaking, and it requires a significant amount of space. For smaller-scale projects with short timeframes, using tower cranes is clearly neither economical nor suitable.

[0003] In practical engineering, taking a 20-story building as an example, when construction is needed on the exterior wall of the 15th floor—for example, cleaning, installing protective panels, or replacing existing protective facilities—the construction workers typically use the following method: placing a support base inside the 15th floor and then assembling the support components from the inside out, i.e., assembling them section by section from the inside out. While this inside-out assembly method solves the transportation problem of support components to some extent and avoids reliance on tower cranes, it still has significant shortcomings in actual operation. Because construction workers can only operate from the indoor side, they have difficulty accessing the support fixing points on the outside of the building's exterior wall. This results in insufficient safety and stability in fixing and connecting the outer supports, making it difficult to guarantee assembly firmness. A single worker operating only from inside cannot effectively tighten and adjust the outer support nodes, which can easily cause the support connections to loosen or even fall off, posing a significant safety hazard.

[0004] Furthermore, in the high-altitude external environment, the safety of construction workers is difficult to guarantee, and the lack of effective auxiliary support and positioning means makes the entire assembly process inefficient and risky. Summary of the Invention

[0005] In order to solve the technical problems and shortcomings in the existing technology, the present invention provides an auxiliary device and method for assembling building supports for high-altitude construction, which improves construction safety and assembly efficiency, and solves the technical problems of inconvenient operation and unstable fixation in the assembly of high-altitude exterior wall supports for small projects.

[0006] To achieve the above and other related objectives, the present invention adopts the following technical solution:

[0007] An auxiliary device for assembling a building support frame for high-altitude construction includes a position adjustment component for lifting and driving, a connecting plate on the top of the position adjustment component, a support arm fixedly mounted on the top of the connecting plate, a rope winding and unwinding component on the top of the connecting plate, and a lubrication component for protecting the rope winding and unwinding component on the surface of the support arm.

[0008] The position adjustment assembly includes a mounting frame, on the side of which a first motor is fixedly mounted, and inside the mounting frame a threaded rod is rotatably mounted. The output shaft of the first motor and the threaded rod are connected for driving the rope winding and unwinding assembly to move left and right.

[0009] Preferably, a threaded sleeve is threaded onto the surface of the threaded rod, a sliding support is fixedly mounted on the top of the threaded sleeve, and a slide rail is fixedly mounted on the top of the mounting frame. The sliding support and the slide rail are slidably connected. When the first motor is started, the threaded rod is rotated, causing the threaded sleeve to drive the sliding support to move horizontally along the slide rail, thereby realizing the horizontal position adjustment of the device.

[0010] Preferably, a second motor is fixedly installed on the top of the sliding support, a first gear is connected to the output shaft of the second motor, a rotating column is rotatably installed inside the sliding support, a second gear is fixedly installed on the surface of the rotating column, a toothed belt meshes with the surface of the second gear, the first gear and the second gear are connected by a toothed belt drive, and a connecting plate is fixedly installed on the top of the rotating column. When the second motor is started, the rotating column can be driven to rotate under the action of the first gear, the toothed belt and the second gear, so as to realize the multi-angle adjustment of the device.

[0011] Preferably, the rope winding and unwinding assembly includes a third motor, which is fixedly mounted on the top of the connecting plate. A winch is connected to the output shaft of the third motor. A first anti-detachment plate is fixedly mounted on the top of the connecting plate. The first anti-detachment plate is correspondingly arranged with the winch to prevent the wire rope from falling off.

[0012] Preferably, the surface of the winch is wound with a steel wire rope, a fixed pulley is rotatably installed inside the support arm, and a second anti-detachment plate is fixedly installed on the top of the support arm. The second anti-detachment plate and the fixed pulley are correspondingly arranged to prevent the steel wire rope from falling off.

[0013] Preferably, a movable pulley is movably installed on the surface of the wire rope, and a lock is fixedly installed at the bottom of the movable pulley. One end of the wire rope is fixedly connected to the winch, and the other end of the wire rope is fixedly connected to the support arm. When the third motor is started, the winch rotates forward and backward. In conjunction with the fixed pulley, the movable pulley, and the wire rope, the vertical lifting and lowering of building supports and other materials is achieved through the lock.

[0014] Preferably, the lubrication assembly includes a mounting bracket, which is fixedly mounted on the surface of the support arm. An oil cylinder is fixedly mounted on the top of the mounting bracket, a lubrication seat is fixedly mounted inside the oil cylinder, and an oil guide ring is fixedly mounted inside the oil cylinder, with the oil guide ring located inside the lubrication seat.

[0015] Preferably, the oil guide ring is connected to an oil supply pipe on its side, and the lubrication seat has a circumferential array of movably installed balls inside. The lubricating oil is continuously diffused into the oil guide ring through the capillary effect of the oil supply pipe. The oil guide ring is in close contact with the circumferential array of balls inside the lubrication seat, and the balls then contact the surface of the wire rope. During operation, the balls continuously transfer the lubricating oil on the oil guide ring to the surface of the wire rope, thereby achieving continuous automatic lubrication of the wire rope.

[0016] On the other hand, a construction support assembly auxiliary method is also provided, which uses the above-mentioned construction support assembly auxiliary device for high-altitude construction.

[0017] Preferably, it includes the following steps:

[0018] S1. Determine the construction floor, install auxiliary devices on the floor above the construction floor or on the roof, fix the auxiliary devices near the exterior wall, and calculate the distance between the fixed position and the construction floor to use steel wire rope of the corresponding length.

[0019] S2. Workers wear protective gear and connect to the lock, or the lock is used to assist in connecting construction tools, or the lock is used to fix construction materials, including steel pipes and protective plates;

[0020] S3. Adjust the position of the lock by starting and controlling the first motor, the second motor and the third motor respectively;

[0021] S4. Based on the construction scope, add multiple auxiliary devices. Each lock of the multiple auxiliary devices is fixed with a camera. Each camera captures high-altitude construction footage and transmits it to a cloud server platform for recording via the network.

[0022] Compared with the prior art, the beneficial effects of the present invention are as follows: the auxiliary device for assembling building supports for high-altitude construction achieves horizontal position adjustment by starting the first motor, multi-angle adjustment by starting the second motor, and vertical lifting and lowering of building supports and other materials by starting the third motor. The ball bearings contact the surface of the wire rope, and during operation, the ball bearings continuously transfer the lubricating oil on the oil guide ring to the surface of the wire rope, achieving continuous automatic lubrication of the wire rope without the need for frequent manual oiling, effectively reducing friction and wear of the wire rope, reducing corrosion, and extending the service life of the wire rope. Attached Figure Description

[0023] Figure 1 This is a schematic diagram of the overall structure of the present invention;

[0024] Figure 2 This is a schematic diagram of the mounting bracket, the first motor, and the threaded rod structure of the present invention;

[0025] Figure 3 This is a schematic diagram of the third motor, winch, and first anti-detachment plate structure of the present invention;

[0026] Figure 4 This is a schematic diagram of the oil cylinder and lubrication seat structure of the present invention;

[0027] Figure 5 This is a schematic diagram of the oil guide ring, oil delivery pipe, and ball bearing structure of the present invention.

[0028] In the diagram: 1. Position adjustment assembly; 11. Mounting bracket; 12. First motor; 13. Threaded rod; 14. Threaded sleeve; 15. Sliding support; 16. Slide rail; 17. Second motor; 18. First gear; 19. Rotating column; 110. Second gear; 111. Toothed belt; 2. Connecting plate; 3. Support arm; 4. Rope winding and unwinding assembly; 41. Third motor; 42. Winch; 43. First anti-detachment plate; 44. Wire rope; 45. Fixed pulley; 46. Second anti-detachment plate; 47. Moving pulley; 48. Lock; 5. Lubrication assembly; 51. Mounting bracket; 52. Oil cylinder; 53. Lubrication seat; 54. Oil guide ring; 55. Oil supply pipe; 56. Ball bearing. Detailed Implementation

[0029] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0030] Example 1:

[0031] Please see Figure 1-5 The present invention provides a technical solution: an auxiliary device for assembling building supports for high-altitude construction, including a position adjustment component 1, a connecting plate 2 on the top of the position adjustment component 1, a support arm 3 fixedly installed on the top of the connecting plate 2, a rope winding and unwinding component 4 on the top of the connecting plate 2, and a lubrication component 5 on the surface of the support arm 3.

[0032] The position adjustment assembly 1 includes a mounting frame 11. A first motor 12 is fixedly mounted on the side of the mounting frame 11. A threaded rod 13 is rotatably mounted inside the mounting frame 11. The output shaft of the first motor 12 is connected to the threaded rod 13. A threaded sleeve 14 is threaded onto the surface of the threaded rod 13. A sliding support 15 is fixedly mounted on the top of the threaded sleeve 14. A slide rail 16 is fixedly mounted on the top of the mounting frame 11. The sliding support 15 and the slide rail 16 are slidably connected. When the first motor 12 is started, it drives the threaded rod 13 to rotate, causing the threaded sleeve 14 to drive the sliding support 15 to move horizontally along the slide rail 16, thereby realizing the horizontal position adjustment of the device. A second motor 17 is fixedly installed on the top of the support 15. A first gear 18 is connected to the output shaft of the second motor 17. A rotating column 19 is rotatably installed inside the sliding support 15. A second gear 110 is fixedly installed on the surface of the rotating column 19. A toothed belt 111 meshes with the surface of the second gear 110. The first gear 18 and the second gear 110 are connected by transmission through the toothed belt 111. A connecting plate 2 is fixedly installed on the top of the rotating column 19. When the second motor 17 is started, the rotating column 19 can be rotated under the action of the first gear 18, the toothed belt 111, and the second gear 110, so as to realize the multi-angle adjustment of the device.

[0033] The rope winding assembly 4 includes a third motor 41, which is fixedly mounted on the top of the connecting plate 2. A winch 42 is connected to the output shaft of the third motor 41. A first anti-detachment plate 43 is fixedly mounted on the top of the connecting plate 2, corresponding to the winch 42. The first anti-detachment plate 43 prevents the wire rope 44 from falling off. The surface of the winch 42 is wound with the wire rope 44. A fixed pulley 45 is rotatably mounted inside the support arm 3. A second anti-detachment plate 46 is fixedly mounted on the top of the support arm 3. The second anti-detachment plate 46 and the fixed pulley 45... A second anti-detachment plate 46 is provided corresponding to wheel 45 to prevent the wire rope 44 from falling off. A movable pulley 47 is movably installed on the surface of the wire rope 44. A lock 48 is fixedly installed at the bottom of the movable pulley 47. One end of the wire rope 44 is fixedly connected to the winch 42, and the other end of the wire rope 44 is fixedly connected to the support arm 3. The third motor 41 is started to drive the winch 42 to rotate forward and backward. With the help of the fixed pulley 45, the movable pulley 47 and the wire rope 44, the lock 48 is used to fix the building support and other materials, and the wire rope 44 is used for vertical lifting.

[0034] The lubrication assembly 5 includes a mounting bracket 51, which is fixedly mounted on the surface of the support arm 3. An oil cylinder 52 is fixedly mounted on the top of the mounting bracket 51. A lubrication seat 53 is fixedly mounted inside the oil cylinder 52, and an oil guide ring 54 is fixedly mounted inside the oil cylinder 52. The oil guide ring 54 is located inside the lubrication seat 53, and an oil delivery pipe 55 is connected to its side. A cotton thread is installed inside the oil delivery pipe 55 to guide the oil. Inside the lubrication seat 53, ball bearings 56 are movably mounted in a circumferential array. Lubricating oil continuously diffuses into the oil guide ring 54 through the capillary action of the oil delivery pipe 55. The oil guide ring 54 is in close contact with the circumferentially arrayed ball bearings 56 inside the lubrication seat 53. The ball bearings 56 then contact the surface of the wire rope 44. As the wire rope 44 passes through this area, the ball bearings 56 continuously transfer the lubricating oil from the oil guide ring 54 to the surface of the wire rope 44, achieving continuous automatic lubrication of the wire rope 44. The oil delivery pipe 55 can be connected to an external lubricating oil tank.

[0035] In use, starting the first motor 12 drives the threaded rod 13 to rotate, causing the threaded sleeve 14 to drive the sliding support 15 to move horizontally along the slide rail 16, thus adjusting the horizontal position of the device. Starting the second motor 17, under the action of the first gear 18, the toothed belt 111, and the second gear 110, drives the rotating column 19 to rotate, thus achieving multi-angle adjustment of the device. Starting the third motor 41 drives the winch 42 to rotate forward and backward, cooperating with the fixed pulley 45, the movable pulley 47, and the steel wire rope 44, and using the lock 48 to lift and lower materials such as building supports. The first anti-detachment plate 43 and the second anti-detachment plate 46 prevent the steel wire rope from being pulled out of the winch. Rope 44 detaches to ensure hoisting stability. Oil cylinder 52 delivers lubricating oil through oil pipe 55. The lubricating oil continuously diffuses through the capillary action of the cotton thread within the oil pipe 55 to the oil guide ring 54. The oil guide ring 54 makes close contact with the circumferentially arrayed ball bearings 56 inside the lubrication seat 53. The ball bearings 56 then contact the surface of the wire rope 44. During operation, the ball bearings 56 continuously transfer the lubricating oil from the oil guide ring 54 to the surface of the wire rope 44, achieving continuous automatic lubrication of the wire rope 44. This eliminates the need for frequent manual lubrication, effectively reducing friction and wear, minimizing corrosion, and extending the service life of the wire rope 44. The lubricating oil used is diluted wire rope oil or a solvent-based lubricant. The cotton thread material is selected for its good oil absorption and aging resistance, such as high-density cotton or blends.

[0036] Example 2:

[0037] A construction support assembly auxiliary method is provided, which adopts the construction support assembly auxiliary device for high-altitude construction in Embodiment 1.

[0038] This solution includes the following steps:

[0039] S1. Determine the construction floor. Erect auxiliary devices on the floor above or on the roof of the building. Fix the auxiliary devices near the exterior wall and calculate the distance between the fixing point and the construction floor to determine the appropriate length of steel wire rope. In practice, first determine the construction floor to be worked on based on the construction drawings or site survey. Then, select a sturdy load-bearing structure (such as a concrete beam, column, or precast lifting ring) on ​​the floor directly above (e.g., the floor above the current floor) or the roof platform of the building as the fixing point for the auxiliary devices. Securely install the auxiliary devices near the exterior wall using high-strength bolts, ensuring that its cantilever or support portion extends outwards to cover the construction area.

[0040] Next, use a laser rangefinder or measuring tape to accurately measure the vertical distance between the fixed point and the working surface of the construction floor. Based on this distance, select a steel wire rope of appropriate length, ensuring that the locking device at the end of the steel wire rope can reach the working position on the construction floor when fully lowered, while retaining a certain operational slack to avoid excessive tension on the steel wire rope, which could lead to excessive stress on the device or restrict operation. One end of the steel wire rope is fixed to the end of the support arm 3 of the auxiliary device, and connected to the locking device through a movable pulley and a fixed pulley to form a stable suspension system.

[0041] S2. Workers wear protective gear and connect the locking devices, or the locking devices assist in connecting construction tools, or the locking devices are used to secure construction materials, including steel pipes and protective plates. After the wire rope system is installed, safety preparations are carried out before work. Construction personnel must wear standard high-altitude work protective gear, such as full-body safety harnesses, and connect the harness hooks to the locking devices to form double protection (the wire rope system of the auxiliary device and the personal safety rope system). Simultaneously, the locking devices can also be used to connect construction tools (such as electric drills, wrenches, etc.) or secure construction materials (such as steel pipes, protective plates, glass curtain wall panels, etc.).

[0042] For tool attachment, a dedicated tool lanyard can be used to secure the tool to the lock, preventing it from falling. For material securing, the lock is designed with an adjustable clamping structure, which can be adjusted according to the shape and size of the material to ensure stability during lifting and preventing swaying or slippage. For example, steel pipes can be secured using the lock's U-shaped clamps, and guard plates can be connected to the lock using straps to ensure no displacement occurs during hoisting.

[0043] S3. By activating and controlling the first, second, and third motors respectively, the position of the lock is adjusted. This is the core operation of the system. The auxiliary device is equipped with three independently controlled motors, each achieving motion control in different dimensions:

[0044] First motor (horizontal movement control): After startup, it drives the support arm 3 of the auxiliary device to move horizontally. For example, it can move left or right, allowing the wire rope and locks to be adjusted within the horizontal range of the construction floors to cover different work points.

[0045] Second motor (angle adjustment control): This motor controls the rotation angle of the support arm 3, thereby changing the suspension angle of the wire rope. For example, when it is necessary to move the lock to a specific position on the exterior wall (such as a corner or recess), the angle of the support arm 3 is adjusted so that the wire rope can be lowered at a certain swing angle.

[0046] The third motor (lifting distance control): This motor drives the winch 42 to control the length of the wire rope, thereby adjusting the vertical height of the lock. For example, when construction workers need to descend from the construction floor to the next floor for work, the third motor is activated to lower the wire rope, causing the lock to slowly descend to the target position.

[0047] In actual operation, the three motors can work simultaneously or in coordination. For example, when construction materials need to be hoisted from the ground to a specific location on the construction floor, the third motor first lifts the wire rope to raise the materials off the ground; then the first motor is activated to move the cantilever directly above the construction floor; next, the second motor adjusts the pulley angle to align the wire rope with the work point on the construction floor; finally, the third motor slowly lowers the wire rope to precisely place the materials in the designated location. The entire process can be precisely controlled via remote control or control panel to ensure smooth and accurate operation.

[0048] S4. Based on the construction area, multiple auxiliary devices will be added. Each lock of these auxiliary devices will be equipped with a camera. Each camera will capture high-altitude construction footage and transmit it to a cloud server platform for recording. To accommodate construction needs of large areas or complex structures, multiple auxiliary devices can be added at different locations depending on the size and shape of the construction area. For example, for a long, narrow building exterior wall, auxiliary devices can be installed at both ends and in the middle to ensure the entire construction area is covered. Each auxiliary device will have a miniature camera (such as a high-definition camera or panoramic camera) fixed to its lock. The camera will be waterproof, dustproof, and have night vision capabilities, enabling it to operate normally in various environments.

[0049] The camera system connects to the cloud server platform via wireless networks (such as Wi-Fi, 4G / 5G) or wired networks. During construction, the camera system captures real-time footage of high-altitude operations, including worker actions, material hoisting, and equipment operation, and transmits the video data to the cloud server for storage and recording. Management personnel can access the cloud server via computer or mobile device to view the construction footage in real time and monitor progress and safety. Simultaneously, the cloud server platform can analyze the video data, such as detecting whether workers are wearing safety gear or engaging in unauthorized operations, promptly identifying potential safety hazards and issuing warnings.

[0050] Furthermore, video recordings can serve as important evidence for construction quality acceptance and accident investigation. For example, in the event of a construction accident, video recordings can be reviewed to analyze the cause of the accident and identify the responsible party; during project acceptance, video recordings can be retrieved to verify whether the construction process meets the required specifications.

[0051] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0052] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and variations can be made to these embodiments without departing from the principles and spirit of the invention.

Claims

1. An auxiliary device for assembling building supports for high-altitude construction, characterized in that, include: A position adjustment assembly (1) is used to fix the top of the building or the upper floor of the construction floor. The position adjustment assembly (1) is provided with a connecting plate (2) on the top. A support arm (3) is fixedly installed on the top of the connecting plate (2). A rope winding and unwinding assembly (4) for lifting drive is provided on the top of the connecting plate (2). A lubrication assembly (5) for protecting the rope winding and unwinding assembly (4) is provided on the support arm (3). The position adjustment assembly (1) includes a mounting frame (11), on which a first motor (12) is fixedly mounted. A threaded rod (13) is rotatably mounted inside the mounting frame (11). The output shaft of the first motor (12) and the threaded rod (13) are connected for driving the rope winding and unwinding assembly (4) to move left and right.

2. The auxiliary device for assembling building supports for high-altitude construction according to claim 1, characterized in that: The threaded rod (13) is threaded with a threaded sleeve (14), and a sliding support (15) is fixedly installed on the top of the threaded sleeve (14). A slide rail (16) is fixedly installed on the top of the mounting bracket (11). The sliding support (15) and the slide rail (16) are slidably connected.

3. The auxiliary device for assembling building supports for high-altitude construction according to claim 2, characterized in that: A second motor (17) is fixedly installed on the top of the sliding support (15). A first gear (18) is connected to the output shaft of the second motor (17). A rotating column (19) is rotatably installed inside the sliding support (15). A second gear (110) is fixedly installed on the surface of the rotating column (19). A toothed belt (111) meshes with the surface of the second gear (110). The first gear (18) and the second gear (110) are connected by a toothed belt (111). The connecting plate (2) is fixedly installed on the top of the rotating column (19).

4. The auxiliary device for assembling building supports for high-altitude construction according to claim 3, characterized in that: The rope winding and unwinding assembly (4) includes a third motor (41), which is fixedly installed on the top of the connecting plate (2). A winch (42) is connected to the output shaft of the third motor (41). A first anti-detachment plate (43) is fixedly installed on the top of the connecting plate (2). The first anti-detachment plate (43) and the winch (42) are arranged correspondingly.

5. The auxiliary device for assembling building supports for high-altitude construction according to claim 4, characterized in that: The surface of the winch (42) is wound with a steel wire rope (44), and a fixed pulley (45) is rotatably installed inside the support arm (3). A second anti-detachment plate (46) is fixedly installed on the top of the support arm (3), and the second anti-detachment plate (46) and the fixed pulley (45) are arranged correspondingly.

6. The auxiliary device for assembling building supports for high-altitude construction according to claim 5, characterized in that: A movable pulley (47) is movably mounted on the surface of the wire rope (44), and a lock (48) is fixedly mounted on the bottom of the movable pulley (47). One end of the wire rope (44) is fixedly connected to the winch (42), and the other end of the wire rope (44) is fixedly connected to the support arm (3).

7. The auxiliary device for assembling building supports for high-altitude construction according to claim 6, characterized in that: The lubrication assembly (5) includes a mounting bracket (51), which is fixedly mounted on the surface of the support arm (3). An oil cylinder (52) is fixedly mounted on the top of the mounting bracket (51). A lubrication seat (53) is fixedly mounted inside the oil cylinder (52). An oil guide ring (54) is fixedly mounted inside the oil cylinder (52). The oil guide ring (54) is located inside the lubrication seat (53).

8. The auxiliary device for assembling building supports for high-altitude construction according to claim 7, characterized in that: The oil guide ring (54) is connected to an oil supply pipe (55) on its side, and the lubrication seat (53) is equipped with ball bearings (56) arranged in a circumferential array inside.

9. A construction support assembly auxiliary method, characterized in that, The auxiliary device for assembling building supports for high-altitude construction as described in any one of claims 1-8 is adopted.

10. A construction support assembly auxiliary method according to claim 9, characterized in that, The process involves the following steps: S1. Determine the construction floor, install auxiliary devices on the floor above the construction floor or on the roof, fix the auxiliary devices near the exterior wall, and calculate the distance between the fixed position and the construction floor to use steel wire rope of the corresponding length. S2. Workers wear protective gear and connect to the lock, or the lock is used to assist in connecting construction tools, or the lock is used to fix construction materials, including steel pipes and protective plates; S3. Adjust the position of the lock by starting and controlling the first motor, the second motor and the third motor respectively; S4. Based on the construction scope, add multiple auxiliary devices. Each lock of the multiple auxiliary devices is fixed with a camera. Each camera captures high-altitude construction footage and transmits it to a cloud server platform for recording via the network.