An oxidation line up-and-down conveying device for aluminum profile machining
By introducing a buffer component into the conveyor system for the aluminum profile anodizing line, and using airbags to quickly stabilize the suspended components, the problem of swaying of the suspended components is solved, improving processing efficiency and safety, and enhancing the continuity and precision of production.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FOSHAN DAIMENG TECH CO LTD
- Filing Date
- 2025-09-08
- Publication Date
- 2026-07-07
AI Technical Summary
When the existing aluminum profile anodizing line conveyor uses a suspended conveying method, the suspended components are prone to tilting and swaying when the operation stops, which leads to a longer operation time and affects the processing efficiency and subsequent processing accuracy.
The system employs a buffer assembly, including an air supply component, an air storage chamber, a telescopic hose, an airbag, and a ventilation component. The airbag is rapidly inflated by the inertial force of the carriage sliding, and the elastic potential energy of the airbag is used to counteract the impact force of the motion inertia, thereby achieving rapid stabilization of the suspension components and reducing the static time.
It shortens the static stabilization time of the suspended components, improves processing efficiency and safety, avoids the impact of shaking on subsequent oxidation line treatment, and enhances the continuity and precision of the overall operation.
Smart Images

Figure CN224466912U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of aluminum profile upper and lower conveying technology, and in particular to an anodizing line conveying device for aluminum profile processing. Background Technology
[0002] Aluminum profile vertical arrangement refers to the arrangement of profiles in upper and lower layers during the processing, storage, or assembly of aluminum profiles. The upper and lower profiles are arranged vertically through specific support or positioning structures. In order to ensure production efficiency, processing quality, and operational safety, vertical conveying devices are used.
[0003] Existing technologies typically employ a suspension-assisted conveying method to meet the needs of aluminum profile anodizing line processing. However, during the suspension conveying process, due to the weight of the aluminum profile itself and its inertia, the suspension components are prone to tilting and swaying when the operation is stopped. This is not conducive to subsequent anodizing line processing and requires a period of stillness to ensure the stability of the suspension components. Overall, the operation time is relatively long, and the processing efficiency is generally low. Utility Model Content
[0004] In view of the problems existing in the current aluminum profile processing oxidation line conveying device, this utility model is proposed.
[0005] Therefore, the problem to be solved by this utility model is that the existing upper and lower row conveying devices generally adopt a suspension and conveying method to meet the processing requirements of aluminum profile oxidation lines. However, during the suspension conveying process, due to the weight of the aluminum profile itself and the inertia of motion, the suspension components are prone to tilting and shaking when the operation is stopped, which is not conducive to the subsequent oxidation line processing. It is necessary to let it stand for a period of time to ensure the stability of the suspension components. The overall operation time is long and the processing efficiency is generally low.
[0006] To solve the above-mentioned technical problems, this utility model provides the following technical solution: a conveying device for anodizing lines in aluminum profile processing, comprising,
[0007] The mounting assembly includes a gantry frame body, the surface of which is slidably connected to a carriage.
[0008] A buffer assembly is disposed on the surface of the gantry frame body, including an air supply component disposed on the top of the gantry frame body. Airbags are fixed on both sides of the gantry frame body, and an air storage chamber is fixed on the top of the gantry frame body. Second transmission pipes are fixed on both sides of the air storage chamber. A second one-way valve is fixed to one end of the second transmission pipe, and a venting component is disposed at one end of the second transmission pipe.
[0009] As a preferred embodiment of the aluminum profile processing oxidation line conveying device of the present invention, wherein: the bottom of the slide is fixed with an electric hoist body, and the suspension end of the electric hoist body is fixed with a material feeder.
[0010] As a preferred embodiment of the aluminum profile processing oxidation line conveying device of the present invention, the number of gas storage chambers is two, and one end of the second transmission pipe is connected to the inner cavity of the gas storage chamber.
[0011] As a preferred embodiment of the aluminum profile processing oxidation line conveying device of the present invention, wherein: a telescopic hose is fixed at one end of the gas storage chamber, and a mounting plate is fixed on one side of the slide.
[0012] As a preferred embodiment of the aluminum profile processing oxidation line conveying device of the present invention, wherein: the other end of the telescopic hose is fixed to one side of the mounting plate, and a first transmission pipe is fixed to one side of the gas storage chamber.
[0013] As a preferred embodiment of the aluminum profile processing oxidation line conveying device of the present invention, wherein: one end of the first transmission pipe is connected to the inner cavity of the gas storage chamber, and a first one-way valve is fixed on the surface of the first transmission pipe.
[0014] As a preferred embodiment of the aluminum profile processing oxidation line conveying device of the present invention, wherein: the other end of the first transmission pipe is connected to the inner cavity of the air bag, the other end of the second transmission pipe is connected to the inner cavity of the air bag, and includes a ball valve fixed to the surface of the second transmission pipe.
[0015] In a preferred embodiment of the aluminum profile processing oxidation line conveying device of the present invention, a valve stem is fixed on one side of the ball valve, and a compression spring is sleeved on the surface of the valve stem.
[0016] In a preferred embodiment of the aluminum profile processing oxidation line conveying device of the present invention, a lever is rotatably connected to the surface of the valve stem, and the lever is inclined.
[0017] In a preferred embodiment of the aluminum profile processing oxidation line conveying device of the present invention, one end of the compression spring is fixed to the surface of the ball valve, and the other end of the compression spring is fixed to the surface of the lever.
[0018] The beneficial effects of this utility model are as follows: By setting up the buffer component, the air supply component utilizes the stretching and compression of the telescopic hose during the sliding process of the slide to achieve directional inflation of the air storage chamber. The setting of the second transmission pipe and the second one-way valve ensures the stable maintenance of the air pressure inside the airbag. In the ventilation component, the tilting lever, under the action of the compression spring, realizes the automatic depressurization and reset of the airbag, shortens the static stabilization time of the suspension component, reduces the processing waiting links, and avoids the impact of shaking on the accuracy of subsequent oxidation line treatment. While improving the safety of operation, it effectively improves the overall processing efficiency. Attached Figure Description
[0019] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0020] Figure 1 This is a structural diagram of an oxidation line conveyor for aluminum profile processing.
[0021] Figure 2 This is a front sectional view of the anodizing line conveyor device used for aluminum profile processing.
[0022] Figure 3 This is a structural diagram of the buffer assembly of the anodizing line conveyor for aluminum profile processing.
[0023] Figure 4 For aluminum profile processing, an oxidation line conveyor device is used for vertical and horizontal conveying. Figure 3 Enlarged structural diagram of A in the middle.
[0024] In the diagram: 1. Mounting assembly; 11. Gantry frame body; 12. Slide carriage; 13. Electric hoist body; 14. Material discharge rack; 2. Buffer assembly; 21. Air supply component; 21-1. Air storage chamber; 21-2. Telescopic hose; 21-3. Mounting plate; 21-4. First transmission pipe; 21-5. First one-way valve; 22. Second transmission pipe; 22-1. Second one-way valve; 23. Air bag; 24. Ventilation component; 24-1. Ball valve; 24-2. Valve stem; 24-3. Compression spring; 24-4. Lever. Detailed Implementation
[0025] To make the above-mentioned objectives, features and advantages of this utility model more apparent and understandable, the specific embodiments of this utility model will be described in detail below with reference to the accompanying drawings.
[0026] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Those skilled in the art can make similar extensions without departing from the spirit of the present invention. Therefore, the present invention is not limited to the specific embodiments disclosed below.
[0027] Secondly, the term "an embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that excludes other embodiments.
[0028] Example 1
[0029] Reference Figure 1 and Figure 2 This is the first embodiment of the present invention. This embodiment provides an anodizing line conveying device for aluminum profile processing. The anodizing line conveying device for aluminum profile processing includes an installation component 1 and a buffer component 2. The air supply component 21 uses the stretching and compression of the telescopic hose 21-2 during the sliding of the slide 12 to achieve directional inflation of the air storage chamber 21-1. When the slide 12 stops moving, the setting of the second transmission pipe 22 and the second one-way valve 22-1 ensures the stable maintenance of the air pressure in the airbag 23. The tilting lever 24-4 in the ventilation component 24 achieves automatic depressurization and reset of the airbag 23 under the action of the compression spring 24-3, which shortens the static stabilization time of the suspended component, reduces the processing waiting link, and avoids the impact of shaking on the accuracy of subsequent anodizing line processing. While improving the safety of operation, it effectively improves the overall processing efficiency.
[0030] Specifically, the installation component 1 includes a gantry frame body 11, and a slide 12 is slidably connected to the surface of the gantry frame body 11.
[0031] The gantry frame body 11 serves as a fixed support frame to bear the overall weight. The slide 12 slides horizontally along the gantry frame to provide a path for the transfer of aluminum profiles. The electric hoist body 13 is fixed to the bottom of the slide and is driven to lift and lower the suspension end through the lifting mechanism, thereby driving the material rack 14 and aluminum profiles to complete the vertical adjustment of the upper and lower row positions and realize the stable transfer of profiles. The working principle of this part is all existing technology, which can be clearly understood by those skilled in the art, and will not be described in detail here.
[0032] Specifically, the buffer assembly 2 is disposed on the surface of the gantry frame body 11, including an air supply component 21 disposed on the top of the gantry frame body 11. Airbags 23 are fixed on both sides of the gantry frame body 11. An air storage chamber 21-1 is fixed on the top of the gantry frame body 11. A second transmission pipe 22 is fixed on both sides of the air storage chamber 21-1. A second one-way valve 22-1 is fixed at one end of the second transmission pipe 22. A venting component 24 is disposed at one end of the second transmission pipe 22.
[0033] The gantry frame 11 serves as the running track and load-bearing skeleton of the slide 12, providing stable horizontal sliding guidance for the slide 12, supporting the weight of the entire suspension system, and providing an installation carrier for the airbag 23 and air storage chamber 21-1 of the buffer assembly 2, ensuring the stability and operation of the overall structure of the device.
[0034] Example 2
[0035] Reference Figures 2-4 This is the second embodiment of the present invention, which is based on the previous embodiment.
[0036] Specifically, the bottom of the slide 12 is fixed with an electric hoist body 13, and the suspension end of the electric hoist body 13 is fixed with a material discharge plate 14. The steel wire rope at the suspension end of the electric hoist body 13 is mostly made of multi-strand high-strength steel wire rope with oil coating to prevent rust. The multi-strand structure improves the overall load-bearing strength and fatigue resistance, ensuring the safety and durability of the suspension operation. The oil coating also forms a physical barrier to reduce the direct contact between the steel wire rope and air, moisture and dust, slowing down the corrosion rate and extending the service life.
[0037] There are two gas storage chambers 21-1, and one end of the second transmission pipe 22 is connected to the inner cavity of the gas storage chamber 21-1.
[0038] The slide 12 serves as both a moving component that carries the electric hoist body 13 and the material rack 14 and a key component for triggering the buffer assembly 2. By sliding on the gantry frame body 11, the aluminum profile is horizontally conveyed, and the telescopic hose 21-2 deforms to provide power for inflating the airbag 23.
[0039] The electric hoist body 13 serves as the power source for suspension and lifting. The material rack 14 is connected to the suspension end to control the vertical lifting of the aluminum profile, meet the height adjustment requirements of the upper and lower racks, provide stable power output for the picking, placing and conveying of aluminum profiles in the oxidation line processing, and ensure the controllability of the operation.
[0040] By setting up the material rack 14, as the direct load-bearing component of the aluminum profile, the aluminum profile can be stably placed, avoiding profile displacement or falling during the conveying process, ensuring the structural stability of the aluminum profile in the suspended state, and providing a regular profile position for subsequent anodizing line processing.
[0041] One end of the air storage chamber 21-1 is fixed with a telescopic hose 21-2, and one side of the slide 12 is fixed with a mounting plate 21-3.
[0042] The other end of the telescopic hose 21-2 is fixed to one side of the mounting plate 21-3, and the first transmission pipe 21-4 is fixed to one side of the air storage chamber 21-1.
[0043] One end of the first transmission pipe 21-4 is connected to the inner cavity of the gas storage chamber 21-1, and a first one-way valve 21-5 is fixed on the surface of the first transmission pipe 21-4.
[0044] The gas storage chamber 21-1 serves as a gas storage unit, pre-storing compressed gas. When the telescopic hose 21-2 is squeezed or stretched, the gas can be released to provide sufficient gas supply for the inflation of the airbag 23, ensuring that the airbag 23 can expand and play a buffering role, avoiding buffering delays caused by insufficient gas supply. The telescopic hose 21-2 is a force transmission component connecting the gas storage chamber 21-1 and the mounting plate 21-3. It can generate compression or stretching deformation with the inertial movement of the slide 12, converting the mechanical inertial force of the slide 12 into gas pressure, driving the gas in the gas storage chamber to be transported to the airbag 23.
[0045] By setting the mounting plate 21-3, the force transmission structure fixed to one side of the slide 12 directly transmits the inertial force of the slide 12 to the telescopic hose 21-2, ensuring the synchronization of the movement of the slide 12 and the deformation of the hose, and ensuring that the buffer component 2 is triggered in time. It is a key node for the transmission of inertial force. By setting the first transmission pipe 21-4, a gas return channel for the airbag 23 is formed, allowing the gas in the airbag 23 to return to the air storage chamber 21-1 after the buffering is completed, realizing gas recycling and avoiding gas waste. At the same time, it works with the first one-way valve 21-5 to ensure orderly return and prevent reverse airflow from interfering with the buffering process.
[0046] The second transmission pipe 22 serves as the main channel for transporting gas from the gas storage chamber 21-1 to the airbag 23, providing an efficient gas transmission path. This ensures that the gas in the gas storage chamber 21-1 can enter the airbag 23 under the inertial action of the slide 12, providing a channel guarantee for the rapid expansion of the airbag 23. Through the airbag 23, the expansion of the airbag generates supporting force, and the elastic deformation of the gas absorbs the inertial impact force of the slide 12, suppressing the swaying of the suspension components and avoiding damage to the device or profile caused by the impact. It also adapts to the buffering requirements of different sway amplitudes.
[0047] The other end of the first transmission tube 21-4 is connected to the inner cavity of the airbag 23, and the other end of the second transmission tube 22 is connected to the inner cavity of the airbag 23, including a ball valve 24-1 fixed to the surface of the second transmission tube 22.
[0048] A valve stem 24-2 is fixed to one side of the ball valve 24-1, and a compression spring 24-3 is sleeved on the surface of the valve stem 24-2.
[0049] A lever 24-4 is rotatably connected to the surface of the valve stem 24-2, and the lever 24-4 is inclined.
[0050] One end of the compression spring 24-3 is fixed to the surface of the ball valve 24-1, and the other end of the compression spring 24-3 is fixed to the surface of the lever 24-4.
[0051] The ball valve 24-1 is a key component that controls the opening and closing of the air bladder 23's deflation channel. By adjusting the degree of opening and closing, the gas emission rate is controlled, ensuring the controllability of pressure release during the buffering process and avoiding excessive or insufficient deflation. The lever 24-4 is directly in contact with the slide 12. The greater the amplitude of the shaking, the stronger the contact force on the lever 24-4, which in turn drives the valve stem 24-2 and the ball valve 24-1 to adjust the deflation rate.
[0052] When in use, when the slide 12 stops moving and the suspended aluminum profile stops moving, its inertial force will push the mounting plate 21-3 to squeeze or stretch the telescopic hose 21-2. At this time, the gas in the gas storage chamber 21-1 is quickly transported to the air bag 23 through the second transmission pipe 22 and the second one-way valve 22-1, causing the air bag 23 to inflate rapidly. The inflated air bag 23 can form a buffer support for the slide 12, using the elastic potential energy of the gas to counteract the impact force generated by the inertia of the movement, suppressing the tilting and swaying of the suspension components. There is no need to wait for a long time for stability to recover, which greatly shortens the overall time of a single operation and improves the continuity and efficiency of the oxidation line processing. The cooperation of the first transmission pipe 21-4 and the first one-way valve 21-5 realizes the gas return channel of the air bag 23.
[0053] When the tilt lever 24-4 of the venting component 24 is touched by the material discharge 14 with different forces, it will compress or release the compression spring 24-3 through the valve stem 24-2, thereby adjusting the opening and closing degree of the ball valve 24-1. This allows the air release speed of the airbag 23 to be adaptively adjusted according to the shaking amplitude. It can quickly relieve pressure and buffer during large shaking, and maintain stable support during slight shaking. It is suitable for different counterweight aluminum profiles and buffering requirements under different movement speeds, enhancing the versatility and reliability of the device.
[0054] 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. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solution of this utility model without departing from the spirit and scope of the technical solution of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.
Claims
1. A conveying device for anodizing lines in aluminum profile processing, characterized in that: include, The mounting assembly (1) includes a gantry frame body (11), on which a carriage (12) is slidably connected; and, A buffer assembly (2) is disposed on the surface of the gantry frame body (11), including an air supply component (21) disposed on the top of the gantry frame body (11). Airbags (23) are fixed on both sides of the gantry frame body (11). An air storage chamber (21-1) is fixed on the top of the gantry frame body (11). A second transmission pipe (22) is fixed on both sides of the air storage chamber (21-1). A second one-way valve (22-1) is fixed at one end of the second transmission pipe (22). A venting component (24) is disposed at one end of the second transmission pipe (22).
2. The aluminum profile processing anodizing line conveying device as described in claim 1, characterized in that: The bottom of the slide (12) is fixed with an electric hoist body (13), and the suspension end of the electric hoist body (13) is fixed with a material feeder (14).
3. The aluminum profile processing anodizing line conveying device as described in claim 2, characterized in that: There are two gas storage chambers (21-1), and one end of the second transmission pipe (22) is connected to the inner cavity of the gas storage chamber (21-1).
4. The aluminum profile processing anodizing line conveying device as described in claim 3, characterized in that: One end of the gas storage chamber (21-1) is fixed with a telescopic hose (21-2), and one side of the slide (12) is fixed with a mounting plate (21-3).
5. The aluminum profile processing anodizing line conveying device as described in claim 4, characterized in that: The other end of the telescopic hose (21-2) is fixed to one side of the mounting plate (21-3), and the first transmission pipe (21-4) is fixed to one side of the air storage chamber (21-1).
6. The aluminum profile processing anodizing line conveying device as described in claim 5, characterized in that: One end of the first transmission pipe (21-4) is connected to the inner cavity of the gas storage chamber (21-1), and a first one-way valve (21-5) is fixed on the surface of the first transmission pipe (21-4).
7. The aluminum profile processing anodizing line conveying device as described in claim 6, characterized in that: The other end of the first transmission tube (21-4) is connected to the inner cavity of the airbag (23), and the other end of the second transmission tube (22) is connected to the inner cavity of the airbag (23), including a ball valve (24-1) fixed to the surface of the second transmission tube (22).
8. The aluminum profile processing anodizing line conveying device as described in claim 7, characterized in that: A valve stem (24-2) is fixed to one side of the ball valve (24-1), and a compression spring (24-3) is sleeved on the surface of the valve stem (24-2).
9. The aluminum profile processing anodizing line conveying device as described in claim 8, characterized in that: The valve stem (24-2) is rotatably connected to a lever (24-4), which is inclined.
10. The aluminum profile processing anodizing line conveying device as described in claim 9, characterized in that: One end of the compression spring (24-3) is fixed to the surface of the ball valve (24-1), and the other end of the compression spring (24-3) is fixed to the surface of the lever (24-4).