A deburring mechanism for aluminum profiles
By combining the drive component and the fine-tuning component, the automatic removal of burrs on aluminum profiles is achieved, solving the problem that traditional methods are difficult to use for deburring complex aluminum profiles, and improving processing efficiency and product quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN LANJI IND TECH CO LTD
- Filing Date
- 2025-08-06
- Publication Date
- 2026-07-03
AI Technical Summary
Traditional roll forming methods for aluminum profiles cannot effectively remove burrs from the product surface, making it difficult to meet the automated deburring requirements of complex aluminum profiles.
By employing a combination of drive components, fine-tuning components, cutting tools, and fixtures, the drive components drive the cutting tools closer to the fixtures, and the fine-tuning components drive them to make fine adjustments within the processing area, thereby achieving automatic removal of burrs from aluminum profiles.
It improves the efficiency and yield of deburring aluminum profiles, reduces manual intervention, and ensures the stability and precision of processing.
Smart Images

Figure CN224444761U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of automated processing equipment, and in particular to a deburring mechanism for aluminum profiles. Background Technology
[0002] Industrial aluminum profiles are key structural components in mechanical structures. With the rapid development of the automation industry, the demand for these products is increasing day by day, and the structure of aluminum profiles is becoming more complex. The traditional method of rolling and pressing aluminum strips cannot guarantee the integrity of the product surface and the burr state of the torn surface, making it difficult to meet the needs of automated tearing of specific aluminum strips of new aluminum profiles. Utility Model Content
[0003] The purpose of this invention is to address the technical problems existing in the background art by proposing a deburring mechanism for aluminum profiles.
[0004] To achieve the above technical objectives, the technical solution adopted by this utility model is as follows:
[0005] A deburring mechanism for aluminum profiles includes a drive assembly, a fine-tuning assembly, a cutting tool, and a fixture. The fine-tuning assembly is mounted on the drive assembly and is driven to be connected to the drive assembly. The cutting tool is driven to be connected to the fine-tuning assembly. The fixture is used to fix the aluminum profile. Under the drive of the drive assembly, the cutting tool approaches the fixture and is placed in the processing area of the aluminum profile. Under the drive of the fine-tuning assembly, the cutting tool is fine-tuned within the processing area.
[0006] Preferably, the drive assembly includes an X-axis drive module, a mounting bracket, a first Y-axis drive module, and a Z-axis drive module. The mounting bracket is mounted on the X-axis drive module and is driven to and connected to the X-axis drive module. Under the drive of the X-axis drive module, the mounting bracket moves closer to or further away from the fixture. The first Y-axis drive module is mounted on the mounting bracket. The Z-axis drive module is mounted on the first Y-axis drive module and is driven to and connected to the first Y-axis drive module. The fine-tuning component is mounted on the Z-axis drive module and is driven to and connected to the Z-axis drive module.
[0007] Preferably, the X-axis drive module includes a drive component, a gear, a rack, and a slide rail. The mounting bracket is slidably mounted on the slide rail, and the drive component is mounted on the mounting bracket. The drive shaft of the drive component is fixedly connected to the gear. The rack is arranged in the same direction as the slide rail and is placed on one side of the slide rail. The gear and rack mesh and transmit power. Under the drive of the drive component, the gear transmits power along the length direction of the rack and drives the mounting bracket to slide along the length direction of the slide rail to move closer to or away from the fixture.
[0008] Preferably, both the first Y-axis drive module and the Z-axis drive module include linear motors.
[0009] Preferably, the fine-tuning component includes a second Y-axis drive module and a fixing block. The second Y-axis drive module is mounted on the Z-axis drive module, and the fixing block is fixed on the second Y-axis drive module. The tool is fixedly connected to the fixing block.
[0010] Preferably, the fine-tuning component further includes a limiting block and an elastic element. The limiting block is mounted on the Z-axis drive module and placed at the end of the second Y-axis drive module. One end of the elastic element is connected to the fixed block, and the other end of the elastic element is connected to the limiting block.
[0011] Compared with the prior art, the utility model has the following beneficial technical effects: it includes a drive component, a fine-tuning component, a cutting tool, and a fixture. The fine-tuning component is mounted on the drive component and driven by the drive component; the cutting tool is driven by the fine-tuning component; the fixture is used to fix the aluminum profile; wherein, driven by the drive component, the cutting tool approaches the fixture and is placed in the processing area of the aluminum profile, and driven by the fine-tuning component, the cutting tool is fine-tuned in the processing area, thereby realizing the automatic removal of burrs on the aluminum profile, reducing manual intervention, and improving the burr removal efficiency and yield of the aluminum profile. Attached Figure Description
[0012] Figure 1 This is a schematic diagram of the structure of an embodiment of the present utility model. Figure 1 ;
[0013] Figure 2 This is a schematic diagram of the structure of an embodiment of the present utility model. Figure 2 ;
[0014] Figure 3 This is an exploded view of an embodiment of the present invention.
[0015] Icon labels:
[0016] 100 Drive assembly, 101 X-axis drive module, 1011 Drive component, 1012 Gear, 1013 Rack, 1014 Slide rail, 102 Mounting bracket, 103 First Y-axis drive module, 104 Z-axis drive module;
[0017] 200 Fine-tuning component, 201 Second Y-axis drive module, 202 Fixed block, 203 Limiting block, 204 Elastic component;
[0018] 300 cutting tools;
[0019] 400 fixtures. Detailed Implementation
[0020] It should be noted that, unless otherwise specified, the embodiments and features described in these embodiments can be combined with each other.
[0021] In the description of this utility model, it should be understood that the terms "center," "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," and "outer," etc., indicating orientation or positional relationships, are based on the orientation or positional relationships shown in the accompanying drawings and are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or assembly referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model. Furthermore, the terms "first," "second," etc., are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of indicated technical features. Thus, features defined with "first," "second," etc., may explicitly or implicitly include one or more features. In the description of this utility model, unless otherwise stated, "a plurality of" means two or more.
[0022] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to a fixed connection, a link, or a specific 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; and they can refer to the connection within two groups. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.
[0023] The specific embodiments of this utility model will be described in detail below with reference to the accompanying drawings.
[0024] like Figures 1-3 As shown, this utility model proposes an aluminum profile deburring mechanism, including a drive assembly 100, a fine-tuning assembly 200, a cutting tool 300, and a fixture 400. The fine-tuning assembly 200 is mounted on the drive assembly 100 and is drivenly connected to the drive assembly 100; the cutting tool 300 is drivenly connected to the fine-tuning assembly 200; the fixture 400 is used to fix the aluminum profile; wherein, driven by the drive assembly 100, the cutting tool 300 approaches the fixture 400 and is placed in the processing area of the aluminum profile, and driven by the fine-tuning assembly 200, the cutting tool 300 is finely adjusted within the processing area.
[0025] In this embodiment, the specific implementation method is as follows: the aluminum profile to be processed is placed and fixed on the fixture 400, and the cutting tool 300 corresponding to the aluminum profile is driven and connected to the fine-tuning component 200. The drive component 100 and the fine-tuning component 200 are activated to drive the cutting tool 300 close to the fixture 400 and process the aluminum profile. Specifically, burrs or scrap aluminum strips on the aluminum profile are removed. The positions of these burrs or scrap aluminum strips are difficult to completely remove when driven by the drive component 100. Therefore, the position of the cutting tool 300 is fine-tuned in conjunction with the fine-tuning component 200 to remove the burrs or scrap aluminum strips cleanly. It should be noted that the drive component 100 performs a tool setting operation before processing to determine the spatial position of the cutting tool 300 and the aluminum profile to ensure normal operation of the processing.
[0026] In one embodiment of this application, the drive assembly 100 includes an X-axis drive module 101, a mounting bracket 102, a first Y-axis drive module 103, and a Z-axis drive module 104. The mounting bracket 102 is mounted on the X-axis drive module 101 and is drivenly connected to the X-axis drive module 101. Under the drive of the X-axis drive module 101, the mounting bracket 102 moves closer to or further away from the fixture 400. The first Y-axis drive module 103 is mounted on the mounting bracket 102. The Z-axis drive module 104 is mounted on the first Y-axis drive module 103 and is drivenly connected to the first Y-axis drive module 103. The fine-tuning assembly 200 is mounted on the Z-axis drive module 104 and is drivenly connected to the Z-axis drive module 104.
[0027] It should be noted that the X-axis drive module 101, the first Y-axis drive module 103, and the Z-axis drive module 104 work together to drive the tool 300 to move freely in three-dimensional space. It is important to note that the fixture 400 is positioned directly in front of the drive assembly 100, as shown in the attached diagram. Figure 1 As shown, the X-axis drive module 101 can therefore serve as the feed drive source for the tool 300.
[0028] In one embodiment of this application, the X-axis drive module 101 includes a drive component 1011, a gear 1012, a rack 1013, and a slide rail 1014. The mounting bracket 102 is slidably mounted on the slide rail 1014. The drive component 1011 is mounted on the mounting bracket 102. The drive shaft of the drive component 1011 is fixedly connected to the gear 1012. The rack 1013 is arranged in the same direction as the slide rail 1014 and is placed on one side of the slide rail 1014. The gear 1012 and the rack 1013 mesh and transmit power.
[0029] It should be noted that the driving component 1011 is specifically a drive motor, which is inverted on the mounting bracket 102. The output end of the driving component 1011 extends out of the mounting bracket 102 and is fixedly connected to the gear 1012. It should be noted that there are two slide rails 1014. The mounting bracket 102 is entirely mounted on the slide rail 1014 and slides on the slide rail 1014, so that the mounting bracket 102 is in a raised state. Therefore, there is a certain space between the mounting bracket 102 and the bottom surface of the slide rail 1014. The gear 1012 is located in this space and meshes with the rack 1013 for transmission. Under the drive of the driving component 1011, the gear 1012 transmits along the length direction of the rack 1013 and drives the mounting bracket 102 to slide along the length direction of the slide rail 1014 to move closer to or away from the fixture 400.
[0030] In one embodiment of this application, both the first Y-axis drive module 103 and the Z-axis drive module 104 include linear motors.
[0031] In one embodiment of this application, the fine-tuning component 200 includes a second Y-axis drive module 201 and a fixing block 202. The second Y-axis drive module 201 is mounted on the Z-axis drive module 104, and the fixing block 202 is fixed on the second Y-axis drive module 201. The tool 300 is fixedly connected to the fixing block 202.
[0032] In one embodiment of this application, the fine-tuning component 200 further includes a limiting block 203 and an elastic element 204. The limiting block 203 is mounted on the Z-axis drive module 104 and placed at the end of the second Y-axis drive module 201. One end of the elastic element 204 is connected to the fixing block 202, and the other end of the elastic element 204 is connected to the limiting block 203.
[0033] It should be noted that the driving method of the second Y-axis drive module 201 is the same as that of the first Y-axis drive module 103. The only difference between the second Y-axis drive module 201 and the second Y-axis drive module 201 is that the driving distance is shorter and the driving precision is higher, which ensures the fine-tuning effect. The elastic element 204 includes, but is not limited to, a helical spring structure. The elastic element 204 is used to alleviate the vibration generated by the tool 300 during processing, so as to avoid damage to the fine-tuning component 200 and ensure the stability of processing.
[0034] It should be noted that the above descriptions are one or more embodiments provided in conjunction with specific content, and do not imply that the specific implementation of this utility model is limited to these descriptions. Any methods or structures that are similar to or identical to those of this utility model, or any technical deductions or substitutions made based on the concept of this utility model, should be considered within the scope of protection of this utility model.
Claims
1. An aluminum profile deburring mechanism characterized by, include: Drive component (100); A fine-tuning component (200) is mounted on the drive component (100) and is drivenly connected to the drive component (100); The cutting tool (300) is driven to connect with the fine-tuning component (200); A fixture (400) is used to fix the aluminum profile; Under the drive of the drive assembly (100), the cutting tool (300) approaches the fixture (400) and is placed in the processing area of the aluminum profile. Under the drive of the fine-tuning assembly (200), the cutting tool (300) is fine-tuned in the processing area.
2. The aluminum profile deburring mechanism according to claim 1, characterized in that, The drive component (100) includes: X-axis drive module (101); The mounting bracket (102) is mounted on the X-axis drive module (101) and drivenly connected to the X-axis drive module (101), wherein, driven by the X-axis drive module (101), the mounting bracket (102) moves closer to or further away from the fixture (400). The first Y-axis drive module (103) is mounted on the mounting bracket (102); The Z-axis drive module (104) is installed on the first Y-axis drive module (103) and is drivenly connected to the first Y-axis drive module (103); The fine-tuning component (200) is mounted on the Z-axis drive module (104) and is drivenly connected to the Z-axis drive module (104).
3. The aluminum profile deburring mechanism according to claim 2, characterized in that, The X-axis drive module (101) includes a drive component (1011), a gear (1012), a rack (1013), and a slide rail (1014). The mounting bracket (102) is slidably mounted on the slide rail (1014). The drive component (1011) is mounted on the mounting bracket (102). The drive shaft of the drive component (1011) is fixedly connected to the gear (1012). The rack (1013) is arranged in the same direction as the slide rail (1014) and is placed on one side of the slide rail (1014). The gear (1012) meshes with the rack (1013) for transmission. Under the drive of the drive component (1011), the gear (1012) is driven along the length direction of the rack (1013) and drives the mounting bracket (102) to slide along the length direction of the slide rail (1014) to move closer to or away from the fixture (400).
4. The aluminum profile deburring mechanism according to claim 2, characterized in that, Both the first Y-axis drive module (103) and the Z-axis drive module (104) include linear motors.
5. The aluminum profile deburring mechanism according to claim 2, wherein, The fine-tuning component (200) includes a second Y-axis drive module (201) and a fixing block (202). The second Y-axis drive module (201) is mounted on the Z-axis drive module (104), and the fixing block (202) is fixed on the second Y-axis drive module (201). The tool (300) is fixedly connected to the fixing block (202).
6. The aluminum profile deburring mechanism according to claim 5, characterized in that, The fine adjustment assembly (200) further comprises a limiting block (203) and an elastic member (204), the limiting block (203) is installed on the Z-axis driving module (104) and is arranged at the end of the second Y-axis driving module (201), one end of the elastic member (204) is connected with the fixed block (202), and the other end of the elastic member (204) is connected with the limiting block (203).