A solid rod positioning device

By designing a rod-fixing and positioning device that includes horizontal rotation, vertical rotation, and lifting components, the problem of insufficient flexibility in existing devices is solved, enabling rapid and stable fixing of the rod and improving welding efficiency, thus ensuring the efficient operation of the production line.

CN224390326UActive Publication Date: 2026-06-23ANHUI JIABANG MACHINERY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ANHUI JIABANG MACHINERY CO LTD
Filing Date
2025-06-18
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing rod positioning devices suffer from insufficient design flexibility, fixed and simple positioning structures, and reliance on manual operation for adjustment, which is time-consuming, resulting in low welding efficiency and affecting production line cycle time.

Method used

A rod positioning device was designed, comprising a horizontal rotation component, a vertical rotation component, a clamping component, and a lifting component. The device achieves rapid clamping, horizontal rotation, vertical rotation, and height adjustment of the rod through motor drive, thereby improving the flexibility of the device and welding efficiency.

Benefits of technology

This technology enables rapid and stable fixing of the rods, improves welding efficiency, reduces non-production time, and ensures the efficient operation of the production line.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model belongs to the field of anchor bolt fastener processing technology, concretely relates to a fixed rod positioning device, including base, the inside installation of base has horizontal rotation subassembly and extends to the outside of the upper surface of base, the output of horizontal rotation subassembly is connected with the support board, the side surface of support board is connected with vertical rotation subassembly, the side surface of vertical rotation subassembly is connected with clamping assembly. The utility model through clamping assembly to the quick clamping of fixed rod, and through horizontal rotation subassembly drive support board rotation, when support board rotates through rotation subassembly and clamping assembly drive fixed rod horizontal rotation, at the same time, through rotation subassembly control clamping assembly carries out vertical rotation, thereby the convenient adjustment vertical angle of its clamping fixed rod adjustment, and lifting assembly passes through rotation subassembly and clamping assembly adjust the fixed rod height of its clamping, like this can be fixed rod stable fixed on the preset position of anchor bolt bottom plate upper surface and realize the welding between fixed rod and anchor bolt bottom plate conveniently.
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Description

Technical Field

[0001] This utility model belongs to the field of anchor bolt fastener processing technology, specifically relating to a rod positioning device. Background Technology

[0002] During the manufacturing process of anchor bolts, the anchor rods and base plate must be securely connected by welding to form a complete fastening unit. To ensure that the relative positional accuracy of the anchor rods and base plate after welding meets the design requirements, a dedicated anchor rod positioning device must be used during the welding process. This positioning device stably fixes the anchor rods in the preset position on the base plate, preventing displacement of the anchor rods due to welding heat deformation or external forces, thereby ensuring that the welded anchor bolts meet the accuracy standards of the engineering installation.

[0003] Existing rod positioning devices suffer from insufficient flexibility in their design. This is mainly manifested in the fact that the positioning structure of the device is fixed and singular, and the adjustment process relies on manual operation, which is time-consuming. This limitation means that frequent replacement or adjustment of the positioning device during the welding process will significantly increase non-production time, ultimately reducing the overall efficiency of rod welding, and may also affect the production line cycle time due to excessive positioning time.

[0004] Based on this, a rod positioning device is now provided, which can eliminate the drawbacks of existing devices. Utility Model Content

[0005] The purpose of this utility model is to provide a rod positioning device, which aims to solve the defects of existing rod positioning devices in terms of insufficient design flexibility. The main problem is that the positioning structure of the device is fixed and simple, and the adjustment process relies on manual operation, which takes a long time. This limitation leads to frequent replacement or adjustment of the positioning device during the welding process, which will significantly increase non-production time, ultimately reduce the overall efficiency of rod welding, and may affect the production line cycle due to excessive positioning time.

[0006] To achieve the above objectives, the present invention provides the following technical solution: a fixed rod positioning device, comprising a base, wherein a horizontal rotating component is installed inside the base and extends to the outside of the upper surface of the base, a support plate is connected to the output end of the horizontal rotating component, a vertical rotating component is connected to the side surface of the support plate, a clamping component is connected to the side surface of the vertical rotating component, and a lifting component connected to the support plate is connected to the bottom side surface of the vertical rotating component.

[0007] The clamping assembly includes a clamping housing, a first bearing seat, a first rotating rod, a first gripper, a second bearing seat, a second rotating rod, and a second gripper. The clamping housing is connected to the end of the vertical rotating assembly. The first bearing seat is installed on the inner wall of the clamping housing. The first rotating rod is connected through the interior of the first bearing seat. A first gripper is connected to each end of the first rotating rod. The second bearing seat is installed on the inner wall of the clamping housing. The second rotating rod is connected through the interior of the second bearing seat. A second gripper is connected to each end of the second rotating rod. A driving part for driving is provided between the first rotating rod and the second rotating rod.

[0008] As a preferred embodiment of the rod positioning device of this utility model, the driving part includes a driven gear plate, a linkage gear plate, a first drive motor and a driving gear plate. The driven gear plate is connected to the surface of the first rotating rod, and the linkage gear plate that meshes with the driven gear plate is connected to the surface of the second rotating rod. The first drive motor is installed on the inner wall of the clamping housing, and the output end of the first drive motor is connected to the driving gear plate that meshes with the driven gear plate.

[0009] As a fixed rod positioning device of this utility model, preferably, the vertical rotation assembly includes a rotating housing, a first bearing ring and a third rotating rod. The rotating housing is disposed on the side surface of the support plate, and the first bearing ring is fitted and installed on the side surface of the rotating housing. The third rotating rod, which is connected to the clamping housing, is connected through the inside of the first bearing ring.

[0010] As a fixed rod positioning device of this utility model, preferably, the vertical rotation assembly further includes a first driven bevel gear connected to the end of the third rotating rod and located inside the rotating housing, and a second drive motor is installed inside the rotating housing, and the output end of the second drive motor is connected to a first driving bevel gear that meshes with the first driven bevel gear;

[0011] As a fixed rod positioning device of this utility model, preferably, the lifting assembly includes a telescopic rod installed on the surface of the support plate and whose movable end is connected to the rotating housing, a guide rail is connected to the side surface of the support plate near the rotating housing, and a guide sleeve matching the guide rail is connected to the side surface of the rotating housing.

[0012] As a preferred embodiment of the rod positioning device of this utility model, the horizontal rotation assembly includes a second bearing ring, a fourth rotating rod, a second driven bevel gear, a third drive motor, and a second driving bevel gear. The second bearing ring is fitted onto the upper surface of the base. The second bearing ring is connected through a fourth rotating rod that is connected to the bottom side of the support plate. The end of the fourth rotating rod is connected to the second driven bevel gear. The inner wall of the base is connected to the third drive motor. The output end of the third drive motor is connected to the second driving bevel gear that meshes with the second driven bevel gear.

[0013] Compared with the prior art, the beneficial effects of this utility model are:

[0014] This invention utilizes a clamping assembly to quickly clamp the fixed rod, and a horizontal rotating assembly to rotate the support plate. As the support plate rotates, the rotating and clamping assemblies cause the fixed rod to rotate horizontally. Simultaneously, the rotating assembly controls the vertical rotation of the clamping assembly, allowing for easy adjustment of the clamped fixed rod's vertical angle. Furthermore, a lifting assembly adjusts the height of the rotating assembly, which in turn adjusts the clamped fixed rod's height via the clamping assembly. This securely fixes the fixed rod to a preset position on the upper surface of the anchor bolt base plate, facilitating welding between the fixed rod and the anchor bolt base plate. This improves the welding efficiency of the anchor bolts and enhances the flexibility of the device. Attached Figure Description

[0015] The accompanying drawings are provided to further illustrate the present invention and form part of the specification. They are used together with the embodiments of the present invention to explain the present invention, but do not constitute a limitation thereof. In the drawings:

[0016] Figure 1 This is a schematic diagram of the overall structure provided for an embodiment of this application.

[0017] Figure 2 This is a schematic diagram of the connection structure between the clamping assembly, the vertical rotation assembly, and the lifting assembly provided in the embodiments of this application.

[0018] Figure 3 This is a cross-sectional view of the clamping component connection structure provided in an embodiment of this application.

[0019] Figure 4 This is a schematic cross-sectional view of the vertical rotation assembly provided in an embodiment of this application.

[0020] Figure 5 This is a cross-sectional view of the horizontal rotation component connection structure provided in an embodiment of this application.

[0021] In the diagram: 1. Base; 2. Support plate; 3. Clamping assembly; 301. Clamping housing; 302. First bearing seat; 303. First rotating rod; 304. Driven gear plate; 305. First gripper; 306. Second bearing seat; 307. Second rotating rod; 308. Linkage gear plate; 309. Second gripper; 310. First drive motor; 311. Drive gear plate; 4. Vertical rotation assembly; 401. Rotating housing; 402. First bearing ring; 403. Third rotating rod; 404. First driven bevel gear; 405. Second drive motor; 406. First drive bevel gear; 5. Lifting assembly; 501. Telescopic rod; 502. Guide rail; 503. Guide sleeve; 6. Horizontal rotation assembly; 601. Second bearing ring; 602. Fourth rotating rod; 603. Second driven bevel gear; 604. Third drive motor; 605. Second drive bevel gear. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] Please see Figure 1-5 The present invention provides the following technical solution: a fixed rod positioning device, including a base 1, a horizontal rotating component 6 installed inside the base 1 and extending to the outside of the upper surface of the base 1, a support plate 2 connected to the output end of the horizontal rotating component 6, a vertical rotating component 4 connected to the side surface of the support plate 2, a clamping component 3 connected to the side surface of the vertical rotating component 4, and a lifting component 5 connected to the support plate 2 connected to the bottom side surface of the vertical rotating component 4.

[0024] The clamping assembly 3 includes a clamping housing 301, a first bearing seat 302, a first rotating rod 303, a first gripper 305, a second bearing seat 306, a second rotating rod 307, and a second gripper 309. The clamping housing 301 is connected to the end of the vertical rotating assembly 4. The first bearing seat 302 is installed on the inner wall of the clamping housing 301. The first rotating rod 303 is connected through the interior of the first bearing seat 302. A first gripper 305 is connected to each end of the first rotating rod 303. The second bearing seat 306 is installed on the inner wall of the clamping housing 301. The second rotating rod 307 is connected through the interior of the second bearing seat 306. A second gripper 309 is connected to each end of the second rotating rod 307.

[0025] Preferably, the drive unit includes a driven gear 304, a linkage gear 308, a first drive motor 310, and a drive gear 311. The driven gear 304 is connected to the surface of the first rotating rod 303, and the linkage gear 308, which meshes with the driven gear 304, is connected to the surface of the second rotating rod 307. The first drive motor 310 is installed on the inner wall of the clamping housing 301, and the output end of the first drive motor 310 is connected to the drive gear 311, which meshes with the driven gear 304.

[0026] In practical use, when the first drive motor 310 runs, it can drive the active gear disk 311 to rotate. When the active gear disk 311 rotates, it drives the driven gear disk 304 to rotate through the meshing structure. When the driven gear disk 304 rotates, it can drive the driven gear disk 304 to rotate. When the driven gear disk 304 rotates, it can drive the first rotating rod 303. When the first rotating rod 303 rotates, it can drive the first gripper 305. At the same time, when the driven gear disk 304 rotates, it can drive the linkage gear disk 308 to rotate in the opposite direction through the meshing structure. When the linkage gear disk 308 rotates in the opposite direction, it can drive the second rotating rod 307 to rotate in the opposite direction. When the second rotating rod 307 rotates in the opposite direction, it can drive the second gripper 309 to rotate in the opposite direction. In this way, the first gripper 305 and the second gripper 309 can rotate in opposite directions, so that the gripping and releasing of the fixed rod can be achieved through the first gripper 305 and the second gripper 309.

[0027] Preferably, the vertical rotation assembly 4 includes a rotating housing 401, a first bearing ring 402 and a third rotating rod 403. The rotating housing 401 is disposed on the side surface of the support plate 2. The first bearing ring 402 is fitted onto the side surface of the rotating housing 401. The third rotating rod 403, which is connected to the clamping housing 301, is connected through the interior of the first bearing ring 402.

[0028] Preferably, the vertical rotation assembly 4 further includes a first driven bevel gear 404 connected to the end of the third rotating rod 403 and located inside the rotating housing 401. A second drive motor 405 is installed inside the rotating housing 401, and the output end of the second drive motor 405 is connected to a first driving bevel gear 406 that meshes with the first driven bevel gear 404.

[0029] In practical use, when the second drive motor 405 is running, it can drive the first active bevel gear 406 to rotate. When the first active bevel gear 406 rotates, it can drive the first driven bevel gear 404 to rotate through the meshing structure. When the first driven bevel gear 404 rotates, it can drive the third rotating rod 403 to rotate inside the first bearing ring 402. When the third rotating rod 403 rotates, it can drive the clamping assembly 3 to rotate. Thus, the rotation of the clamping assembly 3 can drive the fixed rod it clamps to rotate, thereby realizing the angle adjustment of the fixed rod.

[0030] Preferably, the lifting assembly 5 includes a telescopic rod 501 mounted on the surface of the support plate 2 and connected at its movable end to the rotating housing 401. A guide rail 502 is connected to the side surface of the support plate 2 near the rotating housing 401, and a guide sleeve 503 matching the guide rail 502 is connected to the side surface of the rotating housing 401.

[0031] In practical use, when the telescopic rod 501 extends, it can drive the rotating housing 401 to move longitudinally. When the rotating housing 401 moves longitudinally, it can drive the guide sleeve 503 to slide on the surface of the guide rail 502. This allows the height of the rotating housing 401 to be adjusted, thereby adjusting the height of the clamping assembly 3.

[0032] Preferably, the horizontal rotation assembly 6 includes a second bearing ring 601, a fourth rotating rod 602, a second driven bevel gear 603, a third drive motor 604, and a second driving bevel gear 605. The second bearing ring 601 is fitted onto the upper surface of the base 1. The second bearing ring 601 is connected through the fourth rotating rod 602, which is connected to the bottom side of the support plate 2. The end of the fourth rotating rod 602 is connected to the second driven bevel gear 603. The inner wall of the base 1 is connected to the third drive motor 604. The output end of the third drive motor 604 is connected to the second driving bevel gear 605, which meshes with the second driven bevel gear 603.

[0033] In practical use, when the third drive motor 604 is running, it can drive the second active bevel gear 605 to rotate. When the second active bevel gear 605 rotates, it can drive the second driven bevel gear 603 to rotate through the meshing structure. When the second driven bevel gear 603 rotates, it can drive the fourth rotating rod 602 to rotate inside the second bearing ring 601. When the fourth rotating rod 602 rotates, it can drive the support plate 2 to rotate. When the support plate 2 rotates, it can drive the vertical rotating assembly 4 to rotate. When the vertical rotating assembly 4 rotates, it can drive the clamping assembly 3 to rotate. In this way, the clamping assembly 3 can drive the fixed rod to rotate.

[0034] The working principle of this utility model in specific use is as follows: When using this positioning device, the vertical rotating component 4 is first driven to move downward by the telescopic rod 501. When the vertical rotating component 4 moves downward, it can drive the clamping component 3 to move downward. When the first clamping jaw 305 and the second clamping jaw 309 of the clamping component 3 move to both sides of the fixed rod, the first drive motor 310 can be activated. When the first drive motor 310 runs, it can drive the active gear disk 311 to rotate. When the active gear disk 311 rotates, it can drive the driven gear disk 304 to rotate. When the driven gear disk 304 rotates, it can drive the first clamping jaw 305 to rotate towards the rotating second clamping jaw 309 through the first rotating rod 303. At the same time, when the driven gear disk 304 rotates, it drives the linkage gear disk 308 to rotate in the opposite direction. When the linkage gear disk 308 rotates in the opposite direction, it can drive the second clamping jaw 309 to rotate towards the first clamping jaw 305. In this way, the fixed rod can be clamped by the first clamping jaw 305 and the second clamping jaw 309.

[0035] Next, the telescopic rod 501 extends and drives the vertical rotating component 4 to move upward. The upward movement of the vertical rotating component 4 can drive the fixed rod to move upward through the clamping component 3. Then, the third drive motor 604 can be operated. When the third drive motor 604 is running, it can drive the second active bevel gear 605 to rotate. When the second active bevel gear 605 rotates, it can drive the second driven bevel gear 603 to rotate. When the second driven bevel gear 603 rotates, it can drive the support plate 2 to rotate through the fourth rotating rod 602. When the support plate 2 rotates, it drives the fixed rod to rotate to the upper surface of the welding table surface through the clamping housing 301 and the clamping component 3.

[0036] Then the second drive motor 405 can be operated. When the second drive motor 405 is running, it can drive the first active bevel gear 406 to rotate. When the first active bevel gear 406 rotates, it can drive the first driven bevel gear 404 to rotate. When the first driven bevel gear 404 rotates, it can drive the third rotating rod 403 to rotate. When the third rotating rod 403 rotates, it can drive the fixed rod to rotate through the clamping assembly 3. After the clamping assembly 3 drives the fixed rod to rotate 90°, the telescopic rod 501 retracts and drives the vertical rotating assembly 4 to move downward. The downward movement of the vertical rotating assembly 4 can drive the fixed rod to move downward through the clamping assembly 3. In this way, the fixed rod can be stably fixed to the preset position on the upper surface of the anchor bolt base plate. Then, welding is performed by the welding device, thereby realizing the processing of the anchor bolt.

[0037] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.

Claims

1. A rod positioning device, comprising a base (1), characterized in that, The base (1) is equipped with a horizontal rotating component (6) which extends to the outside of the upper surface of the base (1). The output end of the horizontal rotating component (6) is connected to a support plate (2). The side surface of the support plate (2) is connected to a vertical rotating component (4). The side surface of the vertical rotating component (4) is connected to a clamping component (3). The bottom side surface of the vertical rotating component (4) is connected to a lifting component (5) connected to the support plate (2). The clamping assembly (3) includes a clamping housing (301), a first bearing seat (302), a first rotating rod (303), a first gripper (305), a second bearing seat (306), a second rotating rod (307), and a second gripper (309). The clamping housing (301) is connected to the end of the vertical rotating assembly (4). The first bearing seat (302) is installed on the inner wall of the clamping housing (301). The first rotating rod (303) is connected through the inside of the first bearing seat (302). A first gripper (305) is connected to each end of the first rotating rod (303). The second bearing seat (306) is installed on the inner wall of the clamping housing (301). The second rotating rod (307) is connected through the inside of the second bearing seat (306). A second gripper (309) is connected to each end of the second rotating rod (307). A driving part for driving is provided between the first rotating rod (303) and the second rotating rod (307).

2. The rod positioning device according to claim 1, characterized in that: The drive unit includes a driven gear disk (304), a linkage gear disk (308), a first drive motor (310), and a drive gear disk (311). The driven gear disk (304) is connected to the surface of the first rotating rod (303), and the linkage gear disk (308) that meshes with the driven gear disk (304) is connected to the surface of the second rotating rod (307). The first drive motor (310) is installed on the inner wall of the clamping housing (301), and the output end of the first drive motor (310) is connected to the drive gear disk (311) that meshes with the driven gear disk (304).

3. The rod positioning device according to claim 2, characterized in that: The vertical rotation assembly (4) includes a rotating housing (401), a first bearing ring (402), and a third rotating rod (403). The rotating housing (401) is located on the side surface of the support plate (2). The first bearing ring (402) is fitted onto the side surface of the rotating housing (401). The third rotating rod (403), which is connected to the clamping housing (301), is connected through the interior of the first bearing ring (402).

4. The rod positioning device according to claim 3, characterized in that: The vertical rotation assembly (4) further includes a first driven bevel gear (404) connected to the end of the third rotating rod (403) inside the rotating housing (401). A second drive motor (405) is installed inside the rotating housing (401). The output end of the second drive motor (405) is connected to a first driving bevel gear (406) that meshes with the first driven bevel gear (404).

5. A rod positioning device according to claim 1, characterized in that: The lifting assembly (5) includes a telescopic rod (501) mounted on the surface of the support plate (2) and connected at its movable end to the rotating housing (401). A guide rail (502) is connected to the side surface of the support plate (2) near the rotating housing (401), and a guide sleeve (503) matching the guide rail (502) is connected to the side surface of the rotating housing (401).

6. A rod positioning device according to claim 1, characterized in that: The horizontal rotating assembly (6) includes a second bearing ring (601), a fourth rotating rod (602), a second driven bevel gear (603), a third drive motor (604), and a second driving bevel gear (605). The second bearing ring (601) is fitted onto the upper surface of the base (1). The second bearing ring (601) is connected through a fourth rotating rod (602) that is connected to the bottom side of the support plate (2). The end of the fourth rotating rod (602) is connected to the second driven bevel gear (603). The inner wall of the base (1) is connected to the third drive motor (604). The output end of the third drive motor (604) is connected to the second driving bevel gear (605) that meshes with the second driven bevel gear (603).