Anti-shaking structure for extrusion of aluminum rod

The anti-vibration structure, which uses multi-directional roller limiting and drive mechanism adjustment, solves the vibration problem of aluminum rods during extrusion, improves processing stability, protects the rollers, and ensures the extrusion quality of aluminum rods.

CN224389631UActive Publication Date: 2026-06-23HENAN HUAYANG COPPER GRP

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HENAN HUAYANG COPPER GRP
Filing Date
2025-05-13
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

In the existing aluminum rod extrusion process, the aluminum rod is prone to vibration during extrusion due to the single limiting direction, which affects the processing effect.

Method used

A multi-directional roller limiting structure is adopted, and the position of the rollers is adjusted by the drive mechanism. Combined with the protection of the rollers by a ceramic coating, the stability of the aluminum rod is ensured during the extrusion process.

Benefits of technology

It effectively avoids vibration of the aluminum rod during the extrusion process, improves the processing effect, and protects the rollers from heat damage through a ceramic coating.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model provides a metal aluminum pole extrusion process anti shake structure, including the anti shake seat, the inside of anti shake seat is provided with the installation pipe, the inside slide of installation pipe is provided with a plurality of slide frame, the side of slide frame is close to the transverse center of installation pipe and is provided with a plurality of gyro wheel seat, the inside of gyro wheel seat all rotates and is provided with gyro wheel, still be provided with drive mechanism on the anti shake seat, and drive mechanism is used to drive the removal of gyro wheel. Through the metal aluminum pole extrusion process anti shake structure of the utility model, the aluminum pole of being extruded is positioned through the gyro wheel of multidirectional, and then can effectively avoid the aluminum pole to take place the shaking in the extrusion process, can effectively guarantee the processing effect of metal aluminum pole.
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Description

Technical Field

[0001] This utility model belongs to the field of metal aluminum rod processing technology, and specifically relates to an anti-vibration structure for the extrusion process of metal aluminum rods. Background Technology

[0002] The production and processing of aluminum rods involves a series of complex steps, from the selection of raw materials to the inspection of the final product. Due to its good electrical conductivity, light weight, and corrosion resistance, aluminum rods are widely used in many fields such as power transmission, construction, and transportation. By applying high pressure through an extruder, heated aluminum rods are extruded through a die of a specific shape to form aluminum rods with the required cross-sectional shape.

[0003] Existing anti-vibration structures for aluminum rod extrusion processes heat the cast aluminum rod to an appropriate temperature (generally 450℃ to 500℃) to facilitate subsequent extrusion operations. High pressure is applied through an extruder, causing the heated aluminum rod to be extruded through a die of a specific shape to form an aluminum rod with the desired cross-sectional shape. During the extrusion process, the extruded aluminum rod is supported by a support frame to prevent vibration. However, in actual use, due to the unidirectional limitation of the aluminum rod's direction, slight vibration still occurs during extrusion, which may affect the extrusion effect and the processing effect of the aluminum rod. Utility Model Content

[0004] In view of this, this utility model addresses the shortcomings of the prior art by providing an anti-vibration structure for the extrusion process of aluminum rods. By using multi-directional rollers to limit the extruded aluminum rod, it can effectively prevent the aluminum rod from vibrating during the extrusion process and effectively ensure the processing effect of the aluminum rod.

[0005] To solve the above-mentioned technical problems, the technical solution adopted by this utility model is: a vibration prevention structure for the extrusion process of aluminum rods, including a vibration prevention seat, an installation tube is provided inside the vibration prevention seat, multiple sliding frames are slidably arranged inside the installation tube, multiple roller seats are provided on the side of the sliding frames near the transverse center of the installation tube, and rollers are rotatably arranged inside the roller seats. A drive mechanism is also provided on the vibration prevention seat, which is used to drive the movement of the rollers; the outer arc surface of the rollers is provided with a ceramic coating.

[0006] As a further improvement of this utility model, the driving mechanism includes a driving seat symmetrically slidably disposed inside the anti-shake seat, and multiple connecting rods rotatably disposed on each driving seat. The side of each connecting rod away from the driving seat is rotatably connected to an adjacent sliding frame. A U-shaped seat is disposed at the bottom of the anti-shake seat. An adjusting screw is rotatably disposed between the U-shaped seat and the inner wall of the adjacent anti-shake seat. The adjusting screw is threadedly connected to the adjacent driving seat. A dual-axis motor is disposed inside the U-shaped seat. The output shaft of the dual-axis motor is fixed to the adjacent adjusting screw through a coupling.

[0007] As a further improvement of this utility model, a return spring is provided between the roller seat and the mounting tube.

[0008] As a further improvement of this utility model, a worktable is provided on the lower surface of the sliding door, multiple sliding doors are slidably arranged on the front side of the worktable, multiple support legs are provided on the lower surface of the worktable, a control board is provided on the front side of the worktable, and a dual-axis motor is electrically connected to the control board.

[0009] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0010] Firstly, during the extrusion process, the extruded aluminum rod is conveyed between rollers, and the extruded aluminum rod is limited by the multi-directional rollers, which can effectively prevent the aluminum rod from shaking during the extrusion process.

[0011] Secondly, the drive seat drives the sliding frame to slide between itself and the mounting tube via a connecting rod, thereby causing the sliding frame to move the roller closer to or further away from the lateral center of the mounting tube, thus adjusting the distance between the roller and the lateral center of the mounting tube.

[0012] Third, the control board regulates the operation of the dual-axis motor, causing the output shaft of the dual-axis motor to drive the adjusting screw connected to it to rotate. Then, by adjusting the thread relationship between the adjusting screw and the drive seat, the drive seats on both sides are driven to move towards each other or away from each other, thereby quickly and stably driving the roller to move.

[0013] Fourth, the ceramic coating on the outside of the roller can effectively prevent the hot aluminum rod from damaging the roller. Attached Figure Description

[0014] The present invention will now be described in further detail with reference to the accompanying drawings and specific embodiments.

[0015] Figure 1 This is a schematic diagram of the structure of this utility model;

[0016] Figure 2 This is a schematic diagram of the internal cross-sectional structure of this utility model;

[0017] Figure 3This is an enlarged structural diagram of point A in this utility model;

[0018] Figure 4 This is a schematic diagram of the planar structure of this utility model.

[0019] In the diagram: 101, workbench; 102, sliding door; 103, support leg; 104, anti-shake seat; 105, mounting tube; 201, sliding frame; 202, roller seat; 203, roller; 204, ceramic coating; 205, return spring; 206, drive seat; 207, connecting rod; 208, U-shaped seat; 209, dual-axis motor; 210, adjusting screw; 301, control panel. Detailed Implementation

[0020] To better understand this utility model, the following embodiments further illustrate its content, but the scope of protection of this utility model is not limited to the embodiments described below. Numerous specific details are set forth in the following description to provide a more thorough understanding of this utility model. However, it will be apparent to those skilled in the art that this utility model can be practiced without one or more of these details.

[0021] like Figure 2 , 3 As shown, the device includes a stabilizing base 104, an installation tube 105 inside the stabilizing base 104, and multiple sliding frames 201 slidably arranged inside the installation tube 105. Multiple roller seats 202 are arranged on one side of each sliding frame 201 near the lateral center of the installation tube 105. Rollers 203 are rotatably arranged inside each roller seat 202. A driving mechanism is also provided on the stabilizing base 104, which is used to drive the movement of the rollers 203.

[0022] like Figure 3 , 4 As shown, the drive mechanism includes a drive seat 206 symmetrically slidably disposed inside the anti-shake seat 104. Multiple connecting rods 207 are rotatably disposed on the drive seat 206. The side of the connecting rods 207 away from the drive seat 206 is rotatably connected to the adjacent sliding frame 201. A U-shaped seat 208 is disposed at the bottom of the anti-shake seat 104. An adjusting screw 210 is rotatably disposed between the U-shaped seat 208 and the inner wall of the adjacent anti-shake seat 104. The adjusting screw 210 is threadedly connected to the adjacent drive seat 206. A dual-axis motor 209 is disposed inside the U-shaped seat 208. The output shaft of the dual-axis motor 209 is fixed to the adjacent adjusting screw 210 by a coupling.

[0023] like Figure 2 , 3 As shown, a return spring 205 is provided between the roller seat 202 and the mounting tube 105.

[0024] like Figure 1 , 2 As shown, a workbench 101 is provided on the lower surface of the sliding door 102, and multiple sliding doors 102 are slidably provided on the front side of the workbench 101. Multiple support legs 103 are provided on the lower surface of the workbench 101, and a control board 301 is provided on the front side of the workbench 101. A dual-axis motor 209 is electrically connected to the control board 301.

[0025] In use, the control board 301 controls the operation of the dual-axis motor 209, causing the output shaft of the dual-axis motor 209 to drive the adjusting screw 210 connected to it to rotate. Then, by adjusting the thread relationship between the adjusting screw 210 and the drive seat 206, the two drive seats 206 on both sides move towards each other or away from each other. During the movement of the drive seats 206: the drive seats 206 and the connecting rod 207 rotate, and the connecting rod 207 and the sliding frame 201 rotate, causing the drive seats 206 to drive the sliding frame 201 to slide between the mounting tube 105 through the connecting rod 207. This causes the sliding frame 201 to drive the roller 203 to move closer to or away from the lateral center of the mounting tube 105, thereby adjusting the distance between the roller 203 and the lateral center of the mounting tube 105.

[0026] During the extrusion molding process, the extruded aluminum rod is conveyed between rollers 203. The multi-directional rollers 203 limit the extruded aluminum rod, thereby effectively preventing the aluminum rod from shaking during the extrusion process.

[0027] According to another embodiment of the present invention, such as Figure 2 , 3 As shown, the outer arc surface of the roller 203 is provided with a ceramic coating 204. During the processing of the aluminum rod, the ceramic coating 204 on the outside of the roller 203 can effectively prevent the hot aluminum rod from damaging the roller 203.

[0028] Finally, it should be noted that the above embodiments are only used to illustrate the technical solution of this utility model and are not intended to limit it. Any other modifications or equivalent substitutions made by those skilled in the art to the technical solution of this utility model, as long as they do not depart from the spirit and scope of the technical solution of this utility model, should be covered within the scope of the claims of this utility model.

Claims

1. A vibration-damping structure for the extrusion process of aluminum rods, comprising a vibration-damping seat (104), characterized in that: The anti-shake base (104) is provided with an installation tube (105) inside. Multiple sliding frames (201) are slidably arranged inside the installation tube (105). Multiple roller seats (202) are provided on the side of the sliding frame (201) near the horizontal center of the installation tube (105). Rollers (203) are rotatably arranged inside the roller seats (202). The anti-shake base (104) is also provided with a drive mechanism, which is used to drive the movement of the rollers (203).

2. The anti-vibration structure for the extrusion process of aluminum rods as described in claim 1, characterized in that: The driving mechanism includes a driving seat (206) symmetrically slidably disposed inside the anti-shake seat (104). Multiple connecting rods (207) are rotatably disposed on the driving seat (206). The side of the connecting rod (207) away from the driving seat (206) is rotatably connected to the adjacent sliding frame (201).

3. The anti-vibration structure for the extrusion process of aluminum rods as described in claim 2, characterized in that: The bottom of the anti-shake seat (104) is provided with a U-shaped seat (208). An adjusting screw (210) is rotatably provided between the U-shaped seat (208) and the inner wall of the adjacent anti-shake seat (104). The adjusting screw (210) is threadedly connected to the adjacent drive seat (206).

4. The anti-vibration structure for the extrusion process of aluminum rods as described in claim 3, characterized in that: The U-shaped seat (208) is equipped with a dual-axis motor (209), and the output shaft of the dual-axis motor (209) is fixed to the adjacent adjusting screw (210) by a coupling.

5. The anti-vibration structure for the extrusion process of aluminum rods as described in claim 1, characterized in that: A return spring (205) is provided between the roller seat (202) and the mounting tube (105).

6. The anti-vibration structure for the extrusion process of aluminum rods as described in claim 4, characterized in that: A control board (301) is provided on the front side of the workbench (101), and a dual-axis motor (209) is electrically connected to the control board (301). Multiple sliding doors (102) are slidably provided on the front side of the workbench (101), and multiple support legs (103) are provided on the lower surface of the workbench (101).

7. The anti-vibration structure for the extrusion process of aluminum rods as described in claim 1, characterized in that: The outer arc surface of each roller (203) is provided with a ceramic coating (204).