Workshop steel component processing auxiliary frame

By designing the flipping components and clamping structure of the auxiliary frame for processing steel components in the factory, the problems of laborious and easily damaged steel beam welding and flipping were solved, realizing convenient and efficient flipping of steel beam welding and ensuring welding speed and clamping stability.

CN224463883UActive Publication Date: 2026-07-07ANHUI YONGGU STEEL STRUCTURE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ANHUI YONGGU STEEL STRUCTURE CO LTD
Filing Date
2025-07-09
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Flipping steel beams during welding is laborious and can easily damage already welded sections; existing auxiliary frames cannot effectively solve this problem.

Method used

An auxiliary frame for processing steel components in a factory building was designed, which includes a flipping component, a rotating frame, a fixed frame, a cylinder, a motor, and clamping plates. The flipping component enables the automatic flipping of steel beams, and the clamping plates and reinforcing plates improve the clamping stability.

Benefits of technology

This technology facilitates the flipping of steel beams during welding, improves welding efficiency, avoids clamping deformation, and ensures welding speed and quality.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a factory building steel member processing auxiliary frame, it includes turnover subassembly, the top rotation of turnover subassembly is connected with rotating frame, the inner chamber fixed connection of rotating frame has two symmetries fixed frame, the inner chamber of rotating frame is provided with the sliding frame, the inner chamber of rotating frame is provided with two rows of symmetrical air cylinders, two rows the air cylinder with one of fixed frame fixed connection. The utility model discloses through placing two sections of steel beam between two pairs of symmetrical mounting frames, starting fixed frame makes two pairs of symmetrical mounting frames to the clamping of steel beam, starts the motor, makes the two -way screw rod with the sliding plate screw thread movement, makes two pairs of symmetrical clamping plate to the front and back of steel beam clamping, starts turnover subassembly, makes rotating frame drive steel beam and overturns, can reach the steel beam of overturning structure to steel beam and overturn, avoid factory building steel beam welding and overturning when too much effort, has guaranteed that the user to the speed of factory building steel beam welding.
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Description

Technical Field

[0001] This utility model belongs to the field of steel component processing technology for factory buildings, and in particular relates to an auxiliary frame for processing steel components for factory buildings. Background Technology

[0002] Steel components are the core components of steel structure factory buildings. They are diverse in type and function. The main functions of steel components include: load-bearing components, supports and connectors, and enclosure and auxiliary components. Among them, load-bearing components are steel beams and steel columns. Steel beams need to be welded during processing. Commonly used welding methods include manual arc welding (SMAW), carbon dioxide gas shielded welding (CO2 welding), and submerged arc welding (SAW). During the welding of steel beams, auxiliary frames are mostly used to fix the position of the steel beams to ensure the alignment and verticality of the axis during welding and to avoid deformation caused by self-weight or welding stress.

[0003] In the welding and processing of steel beams in factory buildings, auxiliary frames are mostly used to limit their movement. After welding one side of the steel beam, the user needs to flip it over for welding. Flipping the steel beam is quite troublesome, and the welded parts may be damaged during the flipping process. Therefore, an auxiliary frame for processing steel components in factory buildings is needed. The steel beam can be flipped over through a flipping structure, avoiding excessive effort when flipping the steel beam during welding and ensuring the speed of welding steel beams for the user. Utility Model Content

[0004] The purpose of this utility model is to provide an auxiliary frame for processing steel components in factory buildings, which can flip steel beams through a flipping structure, avoiding excessive effort when flipping steel beams for welding in factory buildings, and ensuring the speed of welding steel beams for factory buildings by users, thereby solving the above-mentioned technical problems.

[0005] The technical solution of this utility model to solve the above-mentioned technical problems is as follows: A steel component processing auxiliary frame for factory buildings includes a flipping assembly. A rotating frame is rotatably connected to the top of the flipping assembly. Two symmetrical fixed frames are fixedly connected to the inner cavity of the rotating frame. A slide is provided in the inner cavity of the rotating frame. Two rows of symmetrical cylinders are provided in the inner cavity of the rotating frame. The two rows of cylinders are fixedly connected to one of the fixed frames. The output end of the cylinder is fixedly connected to the top of the slide. A mounting frame is fixedly connected to one side of the fixed frame opposite to the slide. Four pairs of symmetrical sliding grooves are opened on the opposite side of the two mounting frames. Four symmetrical clamps are provided on the opposite side of the two mounting frames. Four symmetrical sliding plates are provided in the inner cavity of the mounting frame. One side of the sliding plate passes through the sliding groove and is fixedly connected to the clamp. Two symmetrical bidirectional threaded rods are rotatably connected to the inner cavity of the mounting frame. The bidirectional threaded rods pass through the two symmetrical sliding plates and are threadedly connected to the sliding plates. Two symmetrical motors are fixedly installed on the front of the mounting frame by bolts. The output shaft of the motor passes through the mounting frame and is fixedly connected to the bidirectional threaded rod.

[0006] Preferably, the inner cavity of the mounting bracket is fixedly connected to two symmetrical support plates, which are arranged longitudinally.

[0007] Preferably, the top of the clamping plate is fixedly connected to two symmetrical reinforcing plates, which are triangular in shape.

[0008] Preferably, the flipping assembly has two longitudinal support legs threaded to both sides, and a pad is fixedly connected to the bottom of the support legs.

[0009] Preferably, the top of the skateboard fits into the top of the inner cavity of the mounting frame, the clamp is L-shaped, and the bottom of the clamp fits into the top of the mounting frame.

[0010] The beneficial effects of this utility model are:

[0011] 1. This utility model places two steel beams between two pairs of symmetrical mounting frames, activates the fixing frame to clamp the steel beams, starts the motor to move the bidirectional threaded rod and the sliding plate thread, so that the two pairs of symmetrical clamping plates clamp the front and back of the steel beams, and activates the flipping component to rotate the steel beams. This allows the steel beams to be flipped through the flipping structure, avoiding excessive effort when flipping the steel beams during welding in the factory and ensuring the speed of welding steel beams for the user.

[0012] 2. By setting up a reinforcing plate, this utility model supports the clamping plate when it clamps the steel beam, preventing deformation of the clamping plate under stress and ensuring the firmness of the clamping plate. Attached Figure Description

[0013] in:

[0014] Figure 1 This is a front view schematic diagram of one embodiment of the present utility model;

[0015] Figure 2 This is a perspective view of one embodiment of the present utility model;

[0016] Figure 3 This is a three-dimensional schematic diagram of a limiting structure according to an embodiment of the present invention;

[0017] Figure 4 This is a three-dimensional disassembled schematic diagram of a limiting structure according to an embodiment of the present invention.

[0018] The attached diagram lists the components represented by each number as follows:

[0019] 1. Flipping assembly, 2. Rotating frame, 3. Fixing frame, 4. Slide, 5. Cylinder, 6. Mounting frame, 7. Slide groove, 8. Clamping plate, 9. Slide plate, 10. Two-way threaded rod, 11. Motor, 12. Support plate, 13. Reinforcing plate, 14. Support leg. Detailed Implementation

[0020] In the following description, embodiments of the auxiliary frame for processing steel components in a factory building according to the present invention will be described with reference to the accompanying drawings. Example 1

[0021] Figure 1-4 This invention illustrates an embodiment of an auxiliary frame for processing steel components in a factory. It includes a tilting assembly 1, a rotating frame 2 rotatably connected to the top of the tilting assembly 1, two symmetrical fixed frames 3 fixedly connected to the inner cavity of the rotating frame 2, a slide 4 provided within the inner cavity of the rotating frame 2, and two rows of symmetrical cylinders 5 arranged within the inner cavity of the rotating frame 2. The two rows of cylinders 5 are fixedly connected to one of the fixed frames 3, and the output end of the cylinder 5 is fixedly connected to the top of the slide 4. Mounting frames 6 are fixedly connected to the opposite side of one of the fixed frames 3 and the slide 4. Two symmetrical support plates 12 are fixedly connected to the inner cavity of the mounting frames 6, and the support plates 12 are arranged longitudinally. Four pairs of symmetrical sliding grooves 7 are provided on the opposite side of each of the two mounting frames 6, and four symmetrical clamps are provided on the opposite side of each of the two mounting frames 6. The top of the clamping plate 8 is fixedly connected to two symmetrical reinforcing plates 13. The reinforcing plates 13 are triangular. When the clamping plate 8 clamps the steel beam, the reinforcing plates 13 will support the clamping plate 8 and prevent the clamping plate 8 from deforming under the force when clamping the steel beam, thus ensuring the firmness of the clamping plate 8. The inner cavity of the mounting frame 6 is provided with four symmetrical sliding plates 9. One side of the sliding plate 9 passes through the sliding groove 7 and is fixedly connected to the clamping plate 8. The inner cavity of the mounting frame 6 is rotatably connected to two symmetrical bidirectional threaded rods 10. The bidirectional threaded rods 10 pass through the two symmetrical sliding plates 9 and are threadedly connected to the sliding plates 9. The front of the mounting frame 6 is fixedly installed with two symmetrical motors 11 by bolts. The output shaft of the motor 11 passes through the mounting frame 6 and is fixedly connected to the bidirectional threaded rods 10. Example 2

[0022] Figure 1-4This invention illustrates an embodiment of an auxiliary frame for processing steel components in a factory. It includes a tilting assembly 1, with two longitudinal support legs 14 threaded to both sides of the tilting assembly 1. A pad is fixedly connected to the bottom of each support leg 14. A rotating frame 2 is rotatably connected to the top of the tilting assembly 1. Two symmetrical fixed frames 3 are fixedly connected to the inner cavity of the rotating frame 2. A slide 4 is provided within the inner cavity of the rotating frame 2. Two rows of symmetrical cylinders 5 are provided within the inner cavity of the rotating frame 2. The two rows of cylinders 5 are fixedly connected to one of the fixed frames 3. The output end of the cylinder 5 is fixedly connected to the top of the slide 4. Mounting brackets 6 are fixedly connected to the side of one of the fixed frames 3 opposite to the slide 4. Both mounting brackets 6 have openings on their opposite sides. The mounting bracket has four pairs of symmetrical grooves 7. Each of the two mounting brackets 6 has four symmetrical clamps 8 on one side. The inner cavity of the mounting bracket 6 has four symmetrical sliding plates 9. The top of the sliding plate 9 fits against the top of the inner cavity of the mounting bracket 6. The clamps 8 are L-shaped and the bottom of the clamps 8 fits against the top of the mounting bracket 6. One side of the sliding plate 9 passes through the groove 7 and is fixedly connected to the clamp 8. The inner cavity of the mounting bracket 6 is rotatably connected to two symmetrical bidirectional threaded rods 10. The bidirectional threaded rods 10 pass through the two symmetrical sliding plates 9 and are threadedly connected to the sliding plates 9. The front of the mounting bracket 6 is fixedly mounted with two symmetrical motors 11 by bolts. The output shaft of the motor 11 passes through the mounting bracket 6 and is fixedly connected to the bidirectional threaded rods 10.

[0023] Working principle: When using this utility model, the user places two steel beams between two pairs of symmetrical mounting brackets 6, activates the fixing bracket 3, and causes the cylinder 5 to push the slide 4 downward, so that the two pairs of symmetrical mounting brackets 6 clamp the steel beams. The motor 11 is activated, causing the bidirectional threaded rod 10 to move threadedly with the slide plate 9. Through the limiting of the slide groove 7, the two pairs of symmetrical clamping plates 8 clamp the front and back of the steel beams. The flipping component 1 is activated, so that the rotating frame 2 drives the steel beams to flip through the fixing bracket 3, slide 4 and mounting bracket 6, avoiding excessive effort when flipping the steel beams for welding in the factory, and ensuring the speed of welding the steel beams for the factory. Through the setting of the reinforcing plate 13, when the clamping plate 8 clamps the steel beams, the reinforcing plate 13 will support the clamping plate 8, preventing the clamping plate 8 from deforming under force when clamping the steel beams, and ensuring the firmness of the clamping plate 8.

[0024] In summary, this auxiliary frame for processing steel components in the factory achieves the following: By placing two steel beams between two pairs of symmetrical mounting frames 6, activating the fixing frame 3, the two pairs of symmetrical mounting frames 6 clamp the steel beams; activating the motor 11, the bidirectional threaded rod 10 and the sliding plate 9 move threadedly, causing the two pairs of symmetrical clamping plates 8 to clamp the front and back of the steel beams; and activating the flipping component 1, the rotating frame 2 drives the steel beams to flip. This allows the steel beams to be flipped through the flipping structure, avoiding excessive effort when flipping the steel beams during welding and ensuring the speed of welding the steel beams for the factory.

Claims

1. An auxiliary frame for processing steel components in a factory, characterized in that, The device includes a flipping assembly (1), the top of which is rotatably connected to a rotating frame (2). Two symmetrical fixed frames (3) are fixedly connected to the inner cavity of the rotating frame (2). A slide (4) is provided within the inner cavity of the rotating frame (2). Two rows of symmetrical cylinders (5) are provided within the inner cavity of the rotating frame (2). The two rows of cylinders (5) are fixedly connected to one of the fixed frames (3). The output end of the cylinder (5) is fixedly connected to the top of the slide (4). Mounting brackets (6) are fixedly connected to the side of one of the fixed frames (3) opposite to the slide (4). Four pairs of symmetrical grooves are provided on the opposite side of each of the two mounting brackets (6). 7) Each of the two mounting brackets (6) has four symmetrical clamps (8) on one side. The inner cavity of the mounting bracket (6) has four symmetrical sliding plates (9). One side of the sliding plate (9) passes through the slide groove (7) and is fixedly connected to the clamp (8). The inner cavity of the mounting bracket (6) is rotatably connected to two symmetrical bidirectional threaded rods (10). The bidirectional threaded rods (10) pass through the two symmetrical sliding plates (9) and are threadedly connected to the sliding plates (9). The front of the mounting bracket (6) is fixedly mounted with two symmetrical motors (11) by bolts. The output shaft of the motor (11) passes through the mounting bracket (6) and is fixedly connected to the bidirectional threaded rods (10).

2. The auxiliary frame for processing steel components in a factory building according to claim 1, characterized in that, The inner cavity of the mounting bracket (6) is fixedly connected to two symmetrical support plates (12), which are arranged longitudinally.

3. The auxiliary frame for processing steel components in a factory building according to claim 2, characterized in that, The top of the clamp (8) is fixedly connected to two symmetrical reinforcing plates (13), which are triangular.

4. The auxiliary frame for processing steel components in a factory building according to claim 3, characterized in that, The flipping assembly (1) has two longitudinal support legs (14) threadedly connected to both sides, and a pad is fixedly connected to the bottom of the support legs (14).

5. The auxiliary frame for processing steel components in a factory building according to claim 4, characterized in that, The top of the slide plate (9) is in contact with the top of the inner cavity of the mounting bracket (6), the clamp (8) is L-shaped, and the bottom of the clamp (8) is in contact with the top of the mounting bracket (6).