A stable structure for climbing scaffolding on building exterior walls

By adjusting the length of the connecting rods with gears and fixing them with screws, and combining this with the support mechanism, a stable structure for the climbing scaffolding on the exterior wall of the building is achieved. This solves the problems of insufficient stability and inconvenient parts replacement in the existing technology, and improves the stability and replacement efficiency of the scaffolding.

CN224452215UActive Publication Date: 2026-07-03WUHAN CHUANGHONGYE MACHINERY EQUIPMENT CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
WUHAN CHUANGHONGYE MACHINERY EQUIPMENT CO LTD
Filing Date
2025-08-11
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

The existing building exterior wall climbing scaffolding has an unreliable stable structure, is cumbersome to install and operate, and is difficult to replace when parts are damaged. It is also prone to loosening and deformation, especially under high load conditions, which poses safety hazards.

Method used

The positional relationship between the first and second connecting rods is adjusted by gears, the length of the connecting rods is fixed by wire clamps and screws, the force balance is achieved by combining the support mechanism, the various mechanisms are modularly connected, the structural strength of the cross joint is improved, and the modular design of the stable structure is achieved by screw connection.

Benefits of technology

It improves the stability of the scaffolding, enhances the structural strength of the cross joints, facilitates the replacement and maintenance of parts, improves the efficiency of installation and dismantling, and avoids problems such as loosening and deformation of parts.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This utility model relates to the field of construction equipment technology and discloses a stabilizing structure for climbing scaffolding on building exterior walls. The structure includes a connecting mechanism, comprising a first connecting rod with a first cavity inside. A second cavity is formed at the upper end of the inner wall of the first cavity. A gear is rotatably connected to the inner wall of the second cavity, and a second connecting rod is slidably connected to the inner wall of the first cavity. Multiple locking teeth are fixedly connected to the center of the upper surface of the second connecting rod. A support mechanism is fixedly connected to the rear end of the connecting mechanism. In this utility model, the positional relationship between the first and second connecting rods is adjusted by the gear, and the support mechanism contacts the scaffolding, thereby achieving a balance between forces. This effectively stabilizes the scaffolding through the connecting mechanism, improves the structural strength of the cross-connection of the scaffolding, and achieves modular scaffolding stabilization, thus solving the problem of replacing deformed or damaged scaffolding parts.
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Description

Technical Field

[0001] This utility model relates to the field of building equipment technology, and in particular to a stable structure for climbing scaffolding on building exterior walls. Background Technology

[0002] Building exterior wall climbing scaffolding (also known as "attached lifting scaffolding" or "climbing scaffolding") is an important technical equipment in the construction of high-rise buildings. With the increasing scarcity of urban land and the rise of high-rise and super high-rise buildings, building exterior wall climbing scaffolding provides significant support for the development of high-rise buildings to meet the needs of this sector.

[0003] In existing stabilization structures for climbing scaffolding on building exterior walls, problems often arise such as unreliable scaffolding stabilization structures, overly cumbersome installation operations, and difficulty in replacing damaged parts. Especially in high-load climbing scaffolding structures, stabilization structures frequently experience loosening and deformation of parts, which can endanger life and safety.

[0004] Therefore, those skilled in the art have provided a stable structure for climbing scaffolding on building exterior walls to solve the problems mentioned in the background art. Utility Model Content

[0005] The purpose of this utility model is to address the shortcomings of existing technologies by proposing a stable structure for climbing scaffolding on building exterior walls. This structure adjusts the positional relationship between the first and second connecting rods using gears, fixes the length of the connecting rods using second clamps, and connects multiple connecting mechanisms to a support mechanism. The support mechanism contacts the scaffolding, thereby achieving a balance between forces. This effectively stabilizes the scaffolding through the connecting mechanisms, improves the structural strength of the cross joints, and connects the various mechanisms with screws, achieving a modular stable structure for the scaffolding and solving the problem of replacing deformed or damaged scaffolding parts.

[0006] To achieve the above objectives, the present invention provides the following technical solution:

[0007] A stabilizing structure for climbing scaffolding on building exterior walls includes a clamp mechanism. The clamp mechanism includes a first clamp, with first screws fastened to both sides of the outer wall of the first clamp. A first slot is formed at the lower part of the outer wall of the first clamp, and a first rotating rod is rotatably connected to the inner wall of the first slot. A connecting mechanism is threaded to the rear end of the clamp mechanism. The connecting mechanism includes a first connecting rod, with a first cavity inside the first connecting rod. A second cavity is formed at the upper end of the inner wall of the first cavity, and a gear is rotatably connected to the inner wall of the second cavity. A third slot is formed on both sides of the outer wall of one end of the first connecting rod, and a third connecting rod is slidably connected to the inner wall of the third slot. A second clamp is fixedly connected to the outer wall of the third connecting rod at the end away from the third slot. The second connecting rod is slidably connected to the inner wall of the first cavity, and multiple locking teeth are fixedly connected to the center of the upper surface of the second connecting rod.

[0008] The rear end of the connecting mechanism is fixedly connected to a support mechanism, which includes a connecting block. The lower part of the outer wall of the connecting block is provided with a fourth slot. The inner wall of the fourth slot is rotatably connected to a third rotating rod. The center of the lower surface of the connecting block is fixedly connected to a first support rod. The inner wall of the first support rod is threadedly connected to a threaded rod. The lower end of the outer wall of the threaded rod is threadedly connected to a second support rod. The lower surface of the second support rod is fixedly connected to a fourth rotating rod. The lower end of the outer wall of the fourth rotating rod is hingedly connected to a third wire clamp. The upper surface of the third wire clamp is provided with a sixth slot.

[0009] Through the above technical solution, the first cavity is slidably connected to the second connecting rod, and a second clamp is slidably connected to the outer wall of one end of the first connecting rod, thereby adjusting and fixing the length between the first connecting rod and the first cavity. The outer wall of the threaded rod is threadedly connected to the first support rod and the second support rod, thereby enabling the support mechanism to support the scaffold. This allows the connecting mechanism and the support mechanism to mutually restrain each other, thus achieving a balance between forces. The connecting mechanism effectively stabilizes the scaffold, improves the structural strength of the cross joint of the scaffold, and connects the various mechanisms with screws, achieving a modular and stable scaffold structure, thereby solving the problem of replacing deformed or damaged scaffold parts.

[0010] Furthermore, a first hole is provided at the center of both sides of the outer wall of the first clamp, the first screw is engaged inside the first hole, and a first nut is threaded onto the outer wall of the first screw;

[0011] Through the above technical solution, the first wire clamp cooperates with the scaffold, and by rotating the first nut, the first screw and the first nut respectively come into contact with the outer wall of the first wire clamp, thereby achieving the clamping and fixing of the scaffold by the first wire clamp.

[0012] Furthermore, the first connecting rod is snapped into the outer wall of one side of the first rotating rod, a rotating block is fixedly connected to the upper end of the outer wall of the first connecting rod, a second rotating rod is rotatably connected to the inner wall of the rotating block, knobs are rotatably connected to the outer walls on both sides of the second rotating rod, the gear is fixedly connected to the center of the outer wall of the second rotating rod, and the snapping teeth mesh with the gear;

[0013] Through the above technical solution, the engagement of the locking teeth and the gear enables the gear to drive the second connecting rod, which then slides against the inner wall of the first cavity. This allows for adjustment of the length between the first and second connecting rods, enabling the connection mechanism to be adjusted according to actual conditions and improving the adjustability of the stable structure in the face of real-world situations.

[0014] Furthermore, a third hole is provided at both the upper and lower ends of the outer wall of the second clamp, and a second screw is snapped into the inner wall of the third hole, and a second nut is threaded into the outer wall of the second screw;

[0015] Through the above technical solution, the second wire clamp is attached to the outer wall of the second connecting rod, and the second screw and the second nut are rotated to make them respectively attach to the second wire clamp, thereby achieving the clamping and fixing of the second connecting rod by the second wire clamp, thus fixing the length of the connecting mechanism.

[0016] Furthermore, a second slot is provided at the center of the outer wall of the first rotating rod away from the first clamp, and a second hole is provided at both the upper and lower ends of the outer wall of the first rotating rod. A third screw is snapped into the inner wall of the second hole, and a fourth hole is snapped into the outer wall of the third screw away from the second hole. A third nut is threaded into the outer wall of the third screw near the fourth hole. A first locking block is fixedly connected at the center of the outer wall of the front end of the first connecting rod, and the first locking block engages with the second slot.

[0017] Through the above technical solution, by rotating the third nut, the third screw and the third nut are respectively attached to the outer wall of the first connecting rod and the first rotating rod, thereby realizing the fixed connection of the wire clamp mechanism. By engaging the first locking block with the second locking slot, the wire clamp mechanism and the connecting mechanism are limited, thereby ensuring the stability of the structure of the wire clamp mechanism and the connecting mechanism.

[0018] Furthermore, a fifth slot is provided at the center of the outer wall of one side of the third rotating rod, and a sixth hole is provided at both the upper and lower ends of the outer wall of one side of the third rotating rod. A fourth screw is snapped into the inner wall of the sixth hole, and a fifth hole is snapped into the outer wall of the end of the fourth screw away from the sixth hole. A fourth nut is threaded into the outer wall of the end of the fourth screw near the fifth hole. A second locking block is fixedly connected at the center of the outer wall of the rear end of the second connecting rod, and the second locking block engages with the fifth slot.

[0019] Through the above technical solution, by rotating the fourth nut, the fourth screw and the fourth nut are respectively attached to the outer walls of the second connecting rod and the third rotating rod, thereby achieving a fixed connection between the connecting mechanism and the supporting mechanism. By engaging the second locking block with the fifth locking slot, the connecting mechanism and the supporting mechanism are limited, thereby ensuring the stability of the structure of the supporting mechanism and the connecting mechanism.

[0020] Furthermore, a sixth slot is provided on the upper surface of the third clamp, and the sixth slot is rotatably connected to the fourth rotating rod;

[0021] Through the above technical solution, the sixth slot is rotatably connected to the fourth rotating rod. By cooperating with the scaffold, the angle between the support mechanism and the scaffold can be adjusted, so that the support mechanism can remain perpendicular to the scaffold, thereby enabling the support mechanism to stably support the scaffold and ensure the overall stability of the device.

[0022] Furthermore, the outer walls around the support mechanism are provided with connecting mechanisms, and the ends of the connecting mechanisms away from the support mechanism are provided with wire clamp mechanisms;

[0023] The above technical solution, through the independently set mechanisms, ensures the independent operation of each unit of the device, thereby facilitating the replacement of damaged parts by operators and improving the portability of the device assembly and disassembly.

[0024] This utility model has the following beneficial effects:

[0025] 1. This utility model proposes a stable structure for climbing scaffolding on building exterior walls. By adjusting the angle of the rotating rod, adjusting the positional relationship between the first and second connecting rods through gears, and fixing the length of the connecting rods through the second clamp, the length of the connecting mechanism can be adjusted according to the actual situation. This allows multiple connecting mechanisms to be connected to the support mechanism, and the support mechanism to contact the scaffolding and provide support. This achieves a balance between forces with the connecting mechanisms, effectively improving the stability of the structure, increasing the structural strength of the cross connection of the scaffolding, and achieving stable support during the use of the scaffolding.

[0026] 2. This utility model proposes a stable structure for climbing scaffolding on building exterior walls. Each mechanism is connected by threads, and locking blocks limit the movement of the mechanisms, ensuring stability between them and preventing misalignment of parts that could lead to structural instability. This modular structure allows users to replace only damaged modules without replacing the entire structure, thus solving problems such as deformation and loosening of parts under high pressure and load. It also facilitates parts replacement and stability testing, thereby improving the efficiency of installation and dismantling. Attached Figure Description

[0027] Figure 1 This is an axonometric drawing of a stable structure for a climbing scaffold on the exterior wall of a building, as proposed in this utility model.

[0028] Figure 2 for Figure 1 Enlarged view of point A;

[0029] Figure 3 This is a schematic diagram of the wire clamp mechanism for a stable structure of a building exterior wall climbing scaffolding proposed in this utility model.

[0030] Figure 4 This is a structural schematic diagram of the connection mechanism for a stable structure used in climbing scaffolding for building exterior walls, as proposed in this utility model.

[0031] Figure 5 This is a cross-sectional view of the connection mechanism of a stable structure for a climbing scaffold on the exterior wall of a building, as proposed in this utility model.

[0032] Figure 6 This is a structural diagram of a support mechanism for a stable structure used in climbing scaffolding for building exterior walls, as proposed in this utility model.

[0033] Legend:

[0034] 1. Wire clamp mechanism; 101. First wire clamp; 102. First hole; 103. First screw; 104. First nut; 105. First slot; 106. First rotating rod; 107. Second slot; 108. Second hole;

[0035] 2. Connecting mechanism; 201. First connecting rod; 202. First cavity; 203. Second connecting rod; 204. Rotating block; 205. Second rotating rod; 206. Knob; 207. Third slot; 208. Third connecting rod; 209. Second wire clamp; 2010. Third hole; 2011. Second screw; 2012. Second nut; 2013. Clamping tooth; 2014. Second cavity; 2015. Gear; 2016. Fourth hole; 2017. Third screw; 2018. Third nut; 2019. Fifth hole; 2020. Fourth screw; 2021. Fourth nut; 2022. First clamping block; 2023. Second clamping block;

[0036] 3. Support mechanism; 301. Connecting block; 302. Fourth slot; 303. Third rotating rod; 304. Fifth slot; 305. Sixth hole; 306. First support rod; 307. Threaded rod; 308. Second support rod; 309. Fourth rotating rod; 3010. Sixth slot; 3011. Third clamp. Detailed Implementation

[0037] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of specific embodiments. Obviously, the described specific embodiments are only a part of the specific embodiments of the present invention, and not all of them. Based on the specific embodiments of the present invention, all other specific embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0038] One specific embodiment of this utility model is provided:

[0039] Reference Figure 1 , Figure 4 and Figure 6 A stable structure for climbing scaffolding on building exterior walls includes a wire clamp mechanism 1. The wire clamp mechanism 1 includes a first wire clamp 101. First screws 103 are snapped onto both sides of the outer wall of the first wire clamp 101. A first slot 105 is formed at the lower part of the outer wall of the first wire clamp 101. A first rotating rod 106 is rotatably connected to the inner wall of the first slot 105. A connecting mechanism 2 is threadedly connected to the rear end of the wire clamp mechanism 1. The connecting mechanism 2 includes a first connecting rod 201. A first cavity 202 is formed inside the first connecting rod 201. A second cavity 2014 is provided at the upper end of the wall. A gear 2015 is rotatably connected to the inner wall of the second cavity 2014. A third slot 207 is provided on both sides of the outer wall of one end of the first connecting rod 201. A third connecting rod 208 is slidably connected to the inner wall of the third slot 207. A second wire clamp 209 is fixedly connected to the outer wall of the end of the third connecting rod 208 away from the third slot 207. A second connecting rod 203 is slidably connected to the inner wall of the first cavity 202. Multiple teeth 2013 are fixedly connected to the center of the upper surface of the second connecting rod 203.

[0040] The rear end of the connecting mechanism 2 is fixedly connected to the support mechanism 3. The support mechanism 3 includes a connecting block 301. The lower part of the outer wall of the connecting block 301 is provided with a fourth slot 302. The inner wall of the fourth slot 302 is rotatably connected to a third rotating rod 303. The center of the lower surface of the connecting block 301 is fixedly connected to a first support rod 306. The inner wall of the first support rod 306 is threadedly connected to a threaded rod 307. The lower end of the outer wall of the threaded rod 307 is threadedly connected to a second support rod 308. The lower surface of the second support rod 308 is fixedly connected to a fourth rotating rod 309. The lower end of the outer wall of the fourth rotating rod 309 is hingedly connected to a third wire clamp 3011. The upper surface of the third wire clamp 3011 is provided with a sixth slot 3010.

[0041] The first cavity 202 is slidably connected to the second connecting rod 203, and the second clamp 209 is slidably connected to the outer wall of one end of the first connecting rod 201, thereby adjusting and fixing the length between the first connecting rod 201 and the first cavity 202. The outer wall of the threaded rod 307 is threadedly connected to the first support rod 306 and the second support rod 308, thereby enabling the support mechanism 3 to support the scaffold. This allows the connecting mechanism 2 and the support mechanism 3 to mutually restrain each other, thereby achieving a balance between forces. The connecting mechanism 2 effectively stabilizes the scaffold, improves the structural strength of the cross joint of the scaffold, and connects the various mechanisms with screws, achieving modular scaffold stability and solving the problem of replacing deformed or damaged scaffold parts.

[0042] Reference Figure 3 , Figure 4 and Figure 5The first clamp 101 has a first hole 102 at the center of both sides of its outer wall. A first screw 103 is engaged inside the first hole 102. A first nut 104 is threaded onto the outer wall of the first screw 103. A second groove 107 is formed at the center of the outer wall of the first rotating rod 106 on the side away from the first clamp 101. A second hole 108 is formed at both the upper and lower ends of the outer wall of the first rotating rod 106. A third screw 2017 is engaged on the inner wall of the second hole 108. A fourth hole 2016 is engaged on the outer wall of the third screw 2017 at the end away from the second hole 108. The third screw 2017 is close to the fourth hole. A third nut 2018 is threaded onto the outer wall of one end of hole 2016. A first locking block 2022 is fixedly connected to the center of the outer wall of the front end of the first connecting rod 201. The first locking block 2022 engages with the second locking groove 107. A fifth locking groove 304 is provided at the center of the outer wall of one side of the third rotating rod 303. A sixth hole 305 is provided at both the upper and lower ends of the outer wall of one side of the third rotating rod 303. A fourth screw 2020 is snapped onto the inner wall of the sixth hole 305. A fifth hole 2019 is snapped onto the outer wall of the end of the fourth screw 2020 away from the sixth hole 305. The end of the fourth screw 2020 closest to the fifth hole 2019 is... A fourth nut 2021 is threaded onto the outer wall of the second connecting rod 203. A second locking block 2023 is fixedly connected to the center of the outer wall of the rear end of the second connecting rod 203. The second locking block 2023 engages with the fifth locking groove 304. The first wire clamp 101 engages with the scaffolding. By rotating the first nut 104, the first screw 103 and the first nut 104 respectively come into contact with the outer wall of the first wire clamp 101, thereby clamping and fixing the scaffolding. By rotating the third nut 2018, the third screw 2017 and the third nut 2018 respectively come into contact with the outer walls of the first connecting rod 201 and the first rotating rod 106, thereby fixing the wire clamp. Mechanism 1 is fixedly connected to the support mechanism 3 by engaging the first locking block 2022 with the second locking slot 107, thereby limiting the position of the wire clamp mechanism 1 and the connecting mechanism 2 and ensuring the stability of the structure of the wire clamp mechanism 1 and the connecting mechanism 2. By rotating the fourth nut 2021, the fourth screw 2020 and the fourth nut 2021 are respectively attached to the outer wall of the second connecting rod 203 and the third rotating rod 303, thereby achieving a fixed connection between the connecting mechanism 2 and the support mechanism 3. The second locking block 2023 engages with the fifth locking slot 304, thereby limiting the position of the connecting mechanism 2 and the support mechanism 3 and ensuring the stability of the structure of the connecting mechanism 2 and the support mechanism 3.

[0043] Reference Figure 2 , Figure 5 and Figure 6The first connecting rod 201 is snapped into the outer wall of one side of the first rotating rod 106. A rotating block 204 is fixedly connected to the upper end of the outer wall of the first connecting rod 201. A second rotating rod 205 is rotatably connected to the inner wall of the rotating block 204. Knobs 206 are rotatably connected to the outer walls on both sides of the second rotating rod 205. A gear 2015 is fixedly connected to the center of the outer wall of the second rotating rod 205. A locking tooth 2013 meshes with the gear 2015. A third hole 2010 is provided at both the upper and lower ends of the outer wall of the second wire clamp 209. The inner wall of the 010 is connected to a second screw 2011, and the outer wall of the second screw 2011 is threaded with a second nut 2012. The upper surface of the third wire clamp 3011 has a sixth slot 3010, which is rotatably connected to the fourth rotating rod 309. The outer walls of the support mechanism 3 are all provided with connecting mechanisms 2, and the ends of the connecting mechanisms 2 away from the support mechanism 3 are all provided with wire clamp mechanisms 1. Through the meshing of the teeth 2013 and the gear 2015, the gear 2015 drives the second connecting rod 203, so that the second The connecting rod 203 is slidably connected to the inner wall of the first cavity 202, thereby adjusting the length between the first connecting rod 201 and the second connecting rod 203. This allows the connecting mechanism 2 to be adjusted according to actual conditions, improving the adjustability of the stable structure in actual situations. The second clamp 209 is attached to the outer wall of the second connecting rod 203. By rotating the second nut 2012, the second screw 2011 and the second nut 2012 are respectively attached to the second clamp 209, thereby clamping and fixing the second connecting rod 203, thus fixing the length of the connecting mechanism 2. The sixth slot 3010 is rotatably connected to the fourth rotating rod 309. By cooperating with the scaffold, the angle between the support mechanism 3 and the scaffold is adjusted, so that the support mechanism 3 can remain perpendicular to the scaffold, thereby enabling the support mechanism 3 to stably support the scaffold and ensuring the overall stability of the device. Through the independently set mechanisms, the independent action of each unit of the device is ensured, thereby facilitating the replacement of damaged parts by operators and improving the portability of the device assembly and disassembly.

[0044] Working principle: First, engage the third wire clamp 3011 with the near-end scaffolding, adjust the angle of the fourth rotating rod 309 to make the support mechanism 3 perpendicular to the third wire clamp 3011, then rotate the threaded rod 307 and fix the first support rod 306 to prevent it from rotating, until the lengths of the first support rod 306 and the second support rod 308 are suitable for the structural stability of the scaffolding. Next, adjust the wire clamp mechanism 1 on the near-end scaffolding sequentially to make the inner wall of the first wire clamp 101 fit against the near-end scaffolding. Then, rotate the first nut 104 to clamp the first wire clamp 101 onto the near-end scaffolding. Next, the first locking block 2022 is fitted onto the inner wall of the second slot 107. Then, it is sequentially threaded onto the inner wall of the second hole 108 on the upper and lower surfaces of the first connecting rod 201 and the third screw 2017. Then, the third nut 2018 is rotated until it is in contact with the surface of the first rotating rod 106, thus fixing the wire clamp mechanism 1 and the connecting mechanism 2. Then, the second locking block 2023 is fitted onto the inner wall of the fifth slot 304. Then, it is sequentially threaded onto the inner wall of the sixth hole 305 on the upper and lower surfaces of the third rotating rod 303 and the fourth screw 2020. Then, it is rotated... The fourth nut 2021 is adjusted until it is in contact with the surface of the third rotating rod 303, thus fixing the connecting mechanism 2 and the support mechanism 3. Then, the lengths of the first connecting rod 201 and the second connecting rod 203 are adjusted via the gear 2015 until the length of the connecting mechanism 2 is suitable for the stability of the structure. Then, the third connecting rod 208 is slid so that the inner wall of the third wire clamp 3011 is in contact with the second connecting rod 203. Next, the second screw 2011 is rotated so that the third wire clamp 3011 clamps the second connecting rod 203, thereby adjusting the lengths of the first connecting rod 201 and the second connecting rod 203. The degree is fixed, so that the support mechanism 3 and the two connecting mechanisms 2 on the near end of the scaffold can play a supporting role. Then, the above operation is repeated to adjust the two clamping mechanisms 1 on the far end of the scaffold in turn, so that they clamp the far end of the scaffold and fix the clamping mechanism 1 to the connecting mechanism 2. The connecting mechanism 2 is fixedly connected to the support mechanism 3. Then, the connecting mechanism 2 connected to it is adjusted to play a reinforcing role. The far end of the scaffold is reinforced by the two connecting mechanisms 2, and the two connecting mechanisms 2 and the support mechanism 3 support the near end of the scaffold, realizing the balance between forces, thereby improving the structural strength of the cross connection of the scaffold.

[0045] The following points should be noted in this article:

[0046] 1. The accompanying drawings of the embodiments disclosed herein only relate to the structures involved in the embodiments disclosed herein; other structures can be referred to in general design.

[0047] 2. Where there is no conflict, the embodiments of this disclosure and the features thereof can be combined with each other to obtain new embodiments.

[0048] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "connected" and "linked" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium. The specific meaning of the above terms in this utility model shall be understood by those skilled in the art based on the specific circumstances. In addition, unless otherwise stated, "multiple" means two or more; the terms "upper," "lower," "left," "right," "inner," "outer," "front end," "rear end," "head," "tail," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing this utility model and simplifying the description. They do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and should not be construed as a limitation on this utility model; the terms "first," "second," "third," etc., are used for descriptive purposes only and should not be construed as indicating or implying relative importance.

[0049] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing specific embodiments, those skilled in the art can still modify the technical solutions described in the foregoing specific embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A stabilizing structure for a building exterior wall climbing scaffold comprising a wire clamp mechanism, characterized by: The wire clamp mechanism includes a first wire clamp, with first screws fastened to both sides of the outer wall of the first wire clamp. A first slot is formed at the lower part of the outer wall of the first wire clamp, and a first rotating rod is rotatably connected to the inner wall of the first slot. A connecting mechanism is threaded to the rear end of the wire clamp mechanism. The connecting mechanism includes a first connecting rod, with a first cavity formed inside the first connecting rod. A second cavity is formed at the upper end of the inner wall of the first cavity, and a gear is rotatably connected to the inner wall of the second cavity. A third slot is formed on both sides of the outer wall of one end of the first connecting rod, and a third connecting rod is slidably connected to the inner wall of the third slot. A second wire clamp is fixedly connected to the outer wall of the third connecting rod at the end away from the third slot. The second connecting rod is slidably connected to the inner wall of the first cavity, and multiple locking teeth are fixedly connected to the center of the upper surface of the second connecting rod. The rear end of the connecting mechanism is fixedly connected to a support mechanism, which includes a connecting block. The lower part of the outer wall of the connecting block is provided with a fourth slot. The inner wall of the fourth slot is rotatably connected to a third rotating rod. A threaded rod is fixedly connected to the center of the lower surface of the connecting block. The inner wall of the threaded rod is threadedly connected to a second support rod. The lower surface of the second support rod is fixedly connected to a fourth rotating rod. The lower end of the outer wall of the fourth rotating rod is hinged to a third wire clamp. The upper surface of the third wire clamp is provided with a sixth slot.

2. The stabilizing structure for a building outer wall climbing scaffold according to claim 1, characterized in that: The first clamp has a first hole at the center of both sides of its outer wall. The first screw is engaged inside the first hole and the outer wall of the first screw is threaded with a first nut.

3. The stabilizing structure for a building outer wall climbing scaffold according to claim 1, characterized in that: The first connecting rod is snapped into the outer wall of one side of the first rotating rod. A rotating block is fixedly connected to the upper end of the outer wall of the first connecting rod. A second rotating rod is rotatably connected to the inner wall of the rotating block. Knobs are rotatably connected to the outer walls on both sides of the second rotating rod. The gear is fixedly connected to the center of the outer wall of the second rotating rod. The snapping teeth mesh with the gear.

4. The stabilizing structure for a building outer wall climbing scaffold according to claim 1, characterized in that: The upper and lower ends of the outer wall of the second clamp are provided with third holes. The inner wall of the third hole is connected to a second screw, and the outer wall of the second screw is threaded with a second nut.

5. A stable structure for climbing scaffolding on building exterior walls according to claim 1, characterized in that: A second slot is provided at the center of the outer wall of the first rotating rod away from the first clamp. A second hole is provided at both the upper and lower ends of the outer wall of the first rotating rod. A third screw is snapped into the inner wall of the second hole. A fourth hole is snapped into the outer wall of the third screw away from the second hole. A third nut is threaded into the outer wall of the third screw near the fourth hole. A first locking block is fixedly connected at the center of the outer wall of the front end of the first connecting rod. The first locking block engages with the second slot.

6. The stabilizing structure for a building outer wall climbing scaffold according to claim 1, characterized in that: A fifth slot is provided at the center of one side of the outer wall of the third rotating rod. A sixth hole is provided at both the upper and lower ends of one side of the outer wall of the third rotating rod. A fourth screw is snapped into the inner wall of the sixth hole. A fifth hole is snapped into the outer wall of the end of the fourth screw away from the sixth hole. A fourth nut is threaded into the outer wall of the end of the fourth screw near the fifth hole. A second locking block is fixedly connected at the center of the outer wall of the rear end of the second connecting rod. The second locking block engages with the fifth slot.

7. The stabilizing structure for a building outer wall climbing scaffold according to claim 1, characterized in that: The upper surface of the third clamp is provided with a sixth slot, which is rotatably connected to the fourth rotating rod.

8. The stabilizing structure for a building outer wall climbing scaffold according to claim 1, characterized in that: The outer walls around the support mechanism are provided with connecting mechanisms, and the ends of the connecting mechanisms away from the support mechanism are provided with wire clamp mechanisms.