Automatic assembly machine for aluminum-plastic radiators
By designing the support frame and assembly table of the automatic aluminum-plastic radiator assembly machine, the problems of deformation and damage to the heat sink during the assembly process are solved, enabling precise multi-angle assembly and improving assembly efficiency and stability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI JIAHE AUTOMOBILE TECHNOLOGY CO LTD
- Filing Date
- 2025-07-28
- Publication Date
- 2026-06-26
AI Technical Summary
Traditional feeding structures can easily cause deformation and damage to the heat sink fins during the assembly of aluminum-plastic radiators, affecting the assembly effect.
The automatic assembly machine for aluminum-plastic radiators consists of components such as support frames, assembly tables, mounting frames, adjustment components, telescopic components, and suction cups. It uses positioning plates, suction cups, and brackets to fix and adjust the heat sinks, achieving precise assembly from multiple angles and directions.
It improves the automatic assembly effect and material feeding stability of aluminum-plastic heat sinks, avoids deformation and damage of heat sinks, and improves assembly efficiency.
Smart Images

Figure CN224406910U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of aluminum-plastic radiator assembly technology, and in particular to an automatic assembly machine for aluminum-plastic radiators. Background Technology
[0002] Aluminum-plastic radiators are a new type of composite radiator that uses high-polymer environmentally friendly materials as water pipes and aluminum alloy profiles as the surface heat dissipation material. Its core structure is usually made of copper pipes and aluminum profiles through precision processes. It has the characteristics of corrosion resistance and high temperature resistance, and is suitable for home, office and other scenarios.
[0003] Aluminum-plastic radiators are increasingly favored for their excellent characteristics of being lightweight, having fast heat dissipation, and having a beautiful appearance. The structure of this type of radiator is to assemble multiple heat dissipation fins in sequence to form a radiator with a large heat dissipation area. Each heat dissipation fin is a rectangular structure with water channels at both ends. Two heat dissipation fins can be assembled by the cooperation of two T-junctions and water channels. During the assembly process, the heat dissipation fins need to be fixed and moved to the mounting bracket for assembly.
[0004] Because the heat sink material of aluminum-plastic radiators is soft and thin, traditional feeding structures are prone to deformation and damage to the heat sink during the fixing process, affecting the assembly effect.
[0005] Therefore, it is necessary to provide an automatic assembly machine for aluminum-plastic radiators to solve the above-mentioned technical problems. Utility Model Content
[0006] This utility model provides an automatic assembly machine for aluminum-plastic radiators, which solves the problem that traditional feeding structures in the automatic assembly process of aluminum-plastic radiators are prone to causing deformation and damage to the heat sinks, thus affecting the assembly effect.
[0007] To solve the above-mentioned technical problems, the automatic assembly machine for aluminum-plastic radiators provided by this utility model includes: a support frame;
[0008] An assembly table is fixedly connected to the top of a support frame. A mounting frame is installed on the top of the assembly table. A mounting frame is installed on the top of the inner wall of the mounting frame. A first drive assembly is installed at one end of the mounting frame. An adjustment assembly is installed inside the mounting frame. A movable plate is installed at the bottom of the adjustment assembly. Second telescopic components are installed on the top of the movable plate near both the front and back sides. An adjustment frame with a limit strip is installed at the telescopic ends of the two second telescopic components. A second telescopic assembly is installed on the back of the adjustment frame. A movable frame is installed at the telescopic end of the second telescopic assembly. A second drive assembly is installed on the front of the movable frame. An adjustment plate is installed at the output end of the second drive assembly. A feeding rack is installed at the bottom of the front of the adjustment plate. Third telescopic components are installed at the bottom of the feeding rack via fixed plates at both the front and back sides. Brackets are installed at the telescopic ends of the two third telescopic components. A suction cup is installed at the bottom of the feeding rack. A vacuum device is installed on the top of the mounting frame. A flexible hose is installed at the inlet of the vacuum device.
[0009] Two first telescopic components are installed on the top of the assembly table near the other side, and each of the telescopic ends of the two first telescopic components is equipped with a positioning plate.
[0010] The adjustment component can move the movable plate left and right to adjust its position, and the second telescopic component can move the movable frame forward and backward to adjust its position. The top of the movable frame has an opening for the limit strip, which is used to hook the movable frame but does not affect its forward and backward movement. Pressure sensors are installed on the adjacent sides of the two brackets to determine whether they are in contact with the heat sink.
[0011] Preferably, an auxiliary frame is installed on one side of the adjustment frame, and an auxiliary device is installed at the bottom of the auxiliary frame near the other end.
[0012] Preferably, the adjustment assembly includes an internal threaded bracket, an adjusting screw, and a slide bar, the adjusting screw and slide bar being used to install the internal threaded bracket inside the mounting frame;
[0013] The adjusting screw and the internal threaded bracket are threadedly connected, the slide rod and the internal threaded bracket are slidably connected, and the bottom of the internal threaded bracket is connected to the top of the movable plate.
[0014] Preferably, a control box with a door is installed on the top of the support frame, and an operation panel is installed on the front of the assembly table via a mounting base;
[0015] The control panel can control the operation of the equipment, and the door is equipped with a lock.
[0016] Preferably, the first telescopic assembly includes a support plate, a stabilizer bar, and a first telescopic component, wherein the support plate is used to mount the stabilizer bar and the first telescopic component on the top of the assembly table;
[0017] The telescopic end of the first telescopic component passes through the support plate, the stabilizer rod passes through the support plate, and one end of the stabilizer rod and the first telescopic component is connected to the positioning plate.
[0018] Preferably, the second drive assembly includes a protective housing, an angle sensor, and a drive component, wherein the protective housing is used to mount the drive component that provides rotational driving force.
[0019] Compared with related technologies, the automatic assembly machine for aluminum-plastic radiators provided by this utility model has the following advantages:
[0020] This utility model provides an automatic assembly machine for aluminum-plastic radiators. To improve the automatic assembly effect and feeding stability of aluminum-plastic radiators, two positioning plates are installed on one side of the assembly table via two first telescopic components. These plates can fix the frame of the aluminum-plastic radiator, facilitating the alignment and assembly of the heat sink fins. The adjustment component on the mounting frame can move the movable plate left and right, facilitating the movement of the fixed heat sink fins to the frame position for assembly. The second telescopic component can move the structure below the adjustment frame up and down, facilitating the installation of the heat sink fins. The second telescopic component drives the second drive component to adjust its position back and forth, allowing the heat sink fins to align with the frame. The second drive component drives the adjustment plate to adjust its angle, facilitating the adjustment of the heat sink position and assembly with the frame. The suction cups on the feeding rack, together with two brackets, can clamp and fix thinner heat sink fins. This design uses suction cups and brackets to fix and clamp the heat sink fins, and the multi-angle and direction adjustment structure can accurately deliver the heat sink fins to the frame for assembly, improving the assembly effect and efficiency. Attached Figure Description
[0021] Figure 1 A schematic diagram of a preferred embodiment of the automatic assembly machine for aluminum-plastic radiators provided by this utility model;
[0022] Figure 2 A structural schematic diagram of the assembly table is provided for this utility model;
[0023] Figure 3 Provided for this utility model Figure 2 An enlarged view of point A shown;
[0024] Figure 4 Provided for this utility model Figure 2 An enlarged view of point B shown;
[0025] Figure 5 A schematic diagram of the drive component is provided for this utility model.
[0026] The diagram is labeled as follows: 1. Support frame, 2. Mounting base, 3. Operation panel, 4. Assembly table, 5. Mounting frame, 6. First drive assembly, 7. Mounting frame, 8. Vacuum equipment, 9. Hoses, 10. Positioning plate, 11. First telescopic assembly, 111. Support plate, 112. Stabilizing rod, 113. First telescopic component, 12. Door, 13. Control box, 14. Movable plate, 15. Adjustment assembly, 151. Internal threaded frame, 152. Adjusting screw, 153. Slide rod, 16. Second telescopic component, 17. Second telescopic assembly, 18. Auxiliary frame, 19. Auxiliary equipment, 20. Second drive assembly, 201. Protective shell, 202. Angle sensor, 203. Drive component, 21. Movable frame, 22. Adjustment plate, 23. Limiting strip, 24. Adjustment frame, 25. Suction cup, 26. Loading rack, 27. Third telescopic component, 28. Fixing plate, 29. Bracket. Detailed Implementation
[0027] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0028] Please refer to the following: Figure 1 , Figure 2 , Figure 3 , Figure 4 and Figure 5 ,in, Figure 1 A schematic diagram of a preferred embodiment of the automatic assembly machine for aluminum-plastic radiators provided by this utility model; Figure 2 A structural schematic diagram of the assembly table is provided for this utility model; Figure 3 Provided for this utility model Figure 2 An enlarged view of point A shown;
[0029] Figure 4 Provided for this utility model Figure 2 An enlarged view of point B shown; Figure 5 This utility model provides a structural schematic diagram of the driving component. The automatic assembly machine for aluminum-plastic radiators includes: a support frame 1;
[0030] Assembly platform 4 is fixedly connected to the top of support frame 1. A mounting frame 5 is installed on the top of assembly platform 4. A mounting frame 7 is installed on the top of the inner wall of mounting frame 5. A first drive assembly 6 is installed at one end of mounting frame 7. An adjustment assembly 15 is installed inside mounting frame 7. A movable plate 14 is installed at the bottom of adjustment assembly 15. Second telescopic components 16 are installed on the top of movable plate 14 near both the front and back. An adjustment frame 24 with a limit strip 23 is installed at the telescopic ends of the two second telescopic components 16. A second telescopic assembly 17 is installed on the back of adjustment frame 24. The telescopic end of the second telescopic component 17 is equipped with a movable frame 21. The front of the movable frame 21 is equipped with a second drive component 20. The output end of the second drive component 20 is equipped with an adjustment plate 22. The front of the adjustment plate 22 is equipped with a feeding rack 26 at the bottom position. The bottom of the feeding rack 26 is equipped with a third telescopic component 27 at both the front and back positions via a fixing plate 28. The telescopic ends of the two third telescopic components 27 are equipped with brackets 29. The bottom of the feeding rack 26 is equipped with a suction cup 25. The top of the mounting frame 5 is equipped with a vacuum device 8. The inlet of the vacuum device 8 is equipped with a flexible hose 9.
[0031] Two first telescopic components 11 are installed on the top of the assembly table 4 near the other side, and each of the telescopic ends of the two first telescopic components 11 is equipped with a positioning plate 10.
[0032] The adjustment component 15 can drive the movable plate 14 to adjust its position left and right. The second telescopic component 17 can drive the movable frame 21 to adjust its position back and forth. The top of the movable frame 21 has an opening for the limit strip 23, which is used to hang the movable frame 21 without affecting its back and forth movement. Pressure sensors are installed on the adjacent sides of the two brackets 29 to determine whether they are in contact with the heat sink. The other end of the hose 9 is connected to the suction cup 25. The positioning plate 10 is used to fix the frame of the aluminum-plastic heat sink. The vacuum device 8 is used to provide suction for the suction cup 25.
[0033] An auxiliary frame 18 is installed on one side of the adjustment frame 24, and an auxiliary device 19 is installed at the bottom of the auxiliary frame 18 near the other end.
[0034] Auxiliary equipment 19 is a camera that assists in alignment and monitoring the assembly.
[0035] The adjustment assembly 15 includes an internal threaded bracket 151, an adjusting screw 152, and a slide bar 153. The adjusting screw 152 and slide bar 153 are used to install the internal threaded bracket 151 inside the mounting frame 7.
[0036] The adjusting screw 152 and the internal threaded bracket 151 are threadedly connected, the slide rod 153 and the internal threaded bracket 151 are slidably connected, and the bottom of the internal threaded bracket 151 is connected to the top of the movable plate 14.
[0037] A control box 13 with a door 12 is installed on the top of the support frame 1, and an operation panel 3 is installed on the front of the assembly table 4 via the mounting base 2.
[0038] The control panel 3 can control the operation of the equipment. The door 12 is equipped with a lock. The control box 13 contains a power switch and a controller for controlling the operation of the equipment.
[0039] The first telescopic assembly 11 includes a support plate 111, a stabilizer bar 112, and a first telescopic component 113. The support plate 111 is used to mount the stabilizer bar 112 and the first telescopic component 113 on the top of the assembly platform 4.
[0040] The telescopic end of the first telescopic component 113 passes through the support plate 111, and the stabilizer 112 passes through the support plate 111. One end of the stabilizer 112 and the first telescopic component 113 are connected to the positioning plate 10.
[0041] The second drive assembly 20 includes a protective housing 201, an angle sensor 202, and a drive component 203. The protective housing 201 is used to mount the drive component 203, which provides rotational driving force.
[0042] The angle sensor 202, together with the drive component 203 controller, can precisely control the rotation angle and speed.
[0043] The working principle of the automatic assembly machine for aluminum-plastic radiators provided by this utility model is as follows:
[0044] Two positioning plates 10 are installed on the upper part of the assembly table 4 near one side via two first telescopic components 11, which can fix the frame of the aluminum-plastic heat sink, facilitating the alignment and assembly of the heat sink fins. The adjustment component 15 on the mounting bracket 5 can move the movable plate 14 left and right, facilitating the movement of the fixed heat sink fins to the frame position for assembly. The second telescopic component 16 can move the structure below the adjustment bracket 24 up and down, facilitating the installation of the heat sink fins. The second telescopic component 17 drives the second drive component 20 to adjust its position back and forth, allowing the heat sink fins to align with the frame. The second drive component 20 drives the adjustment plate 22 to adjust its angle, facilitating the adjustment of the heat sink position and assembly with the frame. The suction cup 25 on the loading rack 26, together with two brackets 29, can clamp and fix thinner heat sink fins. First, the frame of the aluminum-plastic heat sink is fixed by the positioning plate 10. Then, the heat sink is placed on the top of the assembly table 4. After that, the second telescopic component 16 is activated to drive the adjustment frame 24 to move downward. At the same time, the second telescopic component 17 moves the loading rack 26 to the corresponding position. The second telescopic component 16 makes the suction cup 25 contact the heat sink. After that, the vacuum device 8 provides suction force, and the heat sink can be sucked by the suction cup 25. At the same time, the two third telescopic components 27 drive the two brackets 29 to contact the front and back of the heat sink to prevent the heat sink from falling off due to the failure of the suction cup 25. After the fixation is completed, the second drive component 20 drives the loading rack 26 to adjust the angle so that the heat sink faces the frame. Then, the heat sink can be moved into the frame for assembly by the adjustment component 15 and the second telescopic component 17.
[0045] Compared with related technologies, the automatic assembly machine for aluminum-plastic radiators provided by this utility model has the following advantages:
[0046] To improve the automatic assembly effect and feeding stability of aluminum-plastic radiators, two positioning plates 10 are installed on one side of the assembly table 4 via two first telescopic components 11. These plates can fix the frame of the aluminum-plastic radiator, facilitating the alignment and assembly of the heat sink fins. The adjustment component 15 on the mounting frame 5 can move the movable plate 14 left and right, facilitating the movement of the fixed heat sink fins to the frame position for assembly. The second telescopic component 16 can move the structure below the adjustment frame 24 up and down, facilitating the installation of the heat sink fins. The second telescopic component 17 drives the second drive component 20 to adjust its position back and forth, allowing the heat sink fins to align with the frame. The second drive component 20 drives the adjustment plate 22 to adjust its angle, facilitating the adjustment of the heat sink position and assembly with the frame. The suction cup 25 on the feeding rack 26, together with two brackets 29, can clamp and fix thinner heat sink fins. This design allows the heat sink fins to be fixed and clamped by the suction cup 25 and brackets 29. At the same time, the multi-angle and direction adjustment structure can accurately deliver the heat sink fins to the frame for assembly, improving the assembly effect and efficiency.
[0047] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the content of this utility model specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.
Claims
1. An automatic assembly machine for aluminum-plastic radiators, characterized in that, include: Support frame; An assembly table is fixedly connected to the top of a support frame. A mounting frame is installed on the top of the assembly table. A mounting frame is installed on the top of the inner wall of the mounting frame. A first drive assembly is installed at one end of the mounting frame. An adjustment assembly is installed inside the mounting frame. A movable plate is installed at the bottom of the adjustment assembly. Second telescopic components are installed on the top of the movable plate near both the front and back sides. An adjustment frame with a limit strip is installed at the telescopic ends of the two second telescopic components. A second telescopic assembly is installed on the back of the adjustment frame. A movable frame is installed at the telescopic end of the second telescopic assembly. A second drive assembly is installed on the front of the movable frame. An adjustment plate is installed at the output end of the second drive assembly. A feeding rack is installed at the bottom of the front of the adjustment plate. Third telescopic components are installed at the bottom of the feeding rack via fixed plates at both the front and back sides. Brackets are installed at the telescopic ends of the two third telescopic components. A suction cup is installed at the bottom of the feeding rack. A vacuum device is installed on the top of the mounting frame. A flexible hose is installed at the inlet of the vacuum device. Two first telescopic components are installed on the top of the assembly table near the other side, and each of the telescopic ends of the two first telescopic components is equipped with a positioning plate.
2. The automatic assembly machine for aluminum-plastic radiators according to claim 1, characterized in that, An auxiliary frame is installed on one side of the adjustment frame, and an auxiliary device is installed at the bottom of the auxiliary frame near the other end.
3. The automatic assembly machine for aluminum-plastic radiators according to claim 1, characterized in that, The adjustment assembly includes an internal threaded bracket, an adjusting screw, and a slide bar, the adjusting screw and slide bar being used to install the internal threaded bracket inside the mounting frame.
4. The automatic assembly machine for aluminum-plastic radiators according to claim 1, characterized in that, A control box with a door is installed on the top of the support frame, and an operation panel is installed on the front of the assembly table via a mounting base.
5. The automatic assembly machine for aluminum-plastic radiators according to claim 1, characterized in that, The first telescopic assembly includes a support plate, a stabilizer bar, and a first telescopic component. The support plate is used to mount the stabilizer bar and the first telescopic component on the top of the assembly table.
6. The automatic assembly machine for aluminum-plastic radiators according to claim 1, characterized in that, The second drive assembly includes a protective housing, an angle sensor, and a drive component, wherein the protective housing is used to mount the drive component that provides rotational driving force.