Battery aluminum barrel foaming cotton tooling
By using a lifting and rotating mechanism in conjunction with a telescopic mechanism, the foam inside the battery aluminum barrel is automatically attached, solving the problem of difficulty in positioning and attaching the foam tightly in manual operation, thus improving efficiency and accuracy.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 深圳市欧米加智能科技有限公司
- Filing Date
- 2025-06-20
- Publication Date
- 2026-06-19
AI Technical Summary
In existing technologies, there are problems with the foam being difficult to pick up, inaccurately positioned, and not sticking tightly during the process of attaching foam to the inside of the battery aluminum canister, resulting in low efficiency.
The lifting and rotating mechanisms, controlled by an electrical control box, combined with a telescopic mechanism and a positioning plate, automatically complete the foam attaching process, replacing manual operation.
It improves the precision and efficiency of foam bonding, reduces manual intervention, lowers labor intensity, and avoids foam creases.
Smart Images

Figure CN224374936U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of battery assembly, and in particular to a tooling for attaching foam to an aluminum battery barrel. Background Technology
[0002] Most batteries need to be assembled in a U-shaped aluminum can. The U-shaped aluminum can is molded in one piece. The important production step is to attach foam to the inside of the aluminum can to protect the battery. The current method of attaching foam to the aluminum can is usually done manually.
[0003] However, due to the small internal space of the aluminum bucket, it is inconvenient for manual operation. Specifically, the foam is relatively soft during the foaming process, making it difficult for manual handling and pressing, which can easily cause creases in the foam. In addition, there are also problems such as the foam not being able to be attached tightly and falling off easily, and the inconvenience of positioning the aluminum bucket, which leads to inaccurate placement. As a result, the efficiency of manually attaching foam to aluminum buckets is low. Utility Model Content
[0004] The purpose of this utility model is to provide a tooling for attaching foam to aluminum battery canisters, which solves the problems of inconvenience in handling foam, difficulty in positioning the aluminum canister, and poor foam adhesion during the manual application of foam to aluminum canisters.
[0005] To achieve this objective, the present invention adopts the following technical solution:
[0006] A tooling for attaching foam to an aluminum battery drum includes an electrical control box, a lifting mechanism, a rotating mechanism, a fixing component, two sets of telescopic mechanisms, and two sets of positioning plates.
[0007] A limit groove is provided on the top of the electrical control box;
[0008] The lifting mechanism, the rotating mechanism, and the two sets of telescopic mechanisms are all controlled by the electrical control box.
[0009] The lifting mechanism is installed on the top of the electrical control box, and the lifting mechanism is connected to the rotating mechanism to drive the rotating mechanism to perform lifting actions;
[0010] The fixing component is mounted on the rotating mechanism, and the rotating mechanism controls the rotation of the fixing component;
[0011] The telescopic mechanism is mounted on the fixed assembly, and the extended end of the telescopic mechanism is connected to one side of the positioning plate. The foam is attached to the other side of the positioning plate. The telescopic mechanism drives the positioning plate to move closer to the inner wall of the battery aluminum barrel. The positioning plate causes the foam to be squeezed and attached to the inner wall of the battery aluminum barrel.
[0012] Preferably, the fixing assembly includes a connecting plate and two support plates respectively installed on the top and bottom of the connecting plate, the two support plates being parallel to each other;
[0013] The connecting plate is connected to the rotating mechanism.
[0014] Preferably, each set of the telescopic mechanism is connected to a corresponding set of the positioning plates;
[0015] The telescopic mechanism is mounted on one of the support plates, and the other support plate has multiple first through holes. The extended end of the telescopic mechanism passes through the first through holes and connects to one side of the positioning plate.
[0016] Preferably, each set of the telescopic mechanisms has at least one telescopic cylinder;
[0017] The number of the first through holes is equal to the number of the telescopic cylinders, and their positions correspond one-to-one.
[0018] Preferably, each of the positioning plates includes a base plate and an adsorption plate that overlap each other, the base plate being disposed on the outside of the fixing assembly and connected to the telescopic mechanism;
[0019] Each of the positioning plates is also provided with an adsorption structure, and the electrical control box is provided with a vacuum button one and a vacuum button two, which are used to control the adsorption structures on the two positioning plates respectively.
[0020] Preferably, the adsorption structure includes an air extraction hole formed on one side of the base plate and a plurality of suction holes formed on the adsorption plate.
[0021] An air groove is provided on the side of the base plate near the adsorption plate, and both the air extraction hole and the suction hole are connected to the air groove.
[0022] The base plate and the adsorption plate are sealed together.
[0023] The air extraction port is connected to an external air extraction device via an air pipe;
[0024] The adsorption plate has multiple protruding limiting structures on the side away from the telescopic mechanism.
[0025] Preferably, the electrical control box is also equipped with a rotary button, a pressing button, and an emergency stop reset button;
[0026] The rotary button controls the start of the rotary mechanism;
[0027] The pressing button controls the activation of the two sets of telescopic mechanisms;
[0028] The emergency stop reset button is used to pause and reset the entire battery aluminum barrel foam-attached fixture.
[0029] Preferably, the end of the limiting groove away from the lifting mechanism is open, and locking components are provided on both sides;
[0030] The top of the electrical control box also has two fixing slots, which are located on both sides of the opening of the limiting slot.
[0031] The positioning assembly includes a positioning block and a rotating rod rotatably connected within the fixed groove; the positioning block is located outside the fixed groove and is connected to the rotating rod.
[0032] A second through hole is provided on the side wall of the fixed groove, the rotating rod is movably installed in the second through hole, and a damping pad is provided between the rotating rod and the second through hole;
[0033] When the positioning block rotates, the resulting circumference radius is greater than the minimum distance from the second through hole to the opening of the limiting groove.
[0034] Preferably, the rotating mechanism is a rotary cylinder, which has a rotary worktable, and the fixing component is mounted on the rotary worktable.
[0035] Preferably, the lifting mechanism is a slide cylinder, which has a slide, and the rotating mechanism is mounted on the slide.
[0036] Compared with the prior art, the present invention has the following beneficial effects:
[0037] In this invention, during the foam application process, the operator uses a lifting and rotating mechanism in conjunction to flip two sets of telescopic mechanisms mounted on a fixed component, facilitating the attachment of the foam to the positioning plates on the two sets of telescopic mechanisms. The battery aluminum cylinder is fitted outside the two sets of telescopic mechanisms and placed within a limiting groove. The limiting groove is used to position the battery aluminum cylinder. The two sets of telescopic mechanisms press the positioning plate with the foam against the inner wall of the battery aluminum cylinder, replacing manual pressing of the foam and preventing creases in the foam. Attached Figure Description
[0038] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art 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.
[0039] The structures, proportions, sizes, etc., shown in the accompanying drawings of this specification are only for the purpose of assisting those skilled in the art in understanding and reading the content disclosed in the specification, and are not intended to limit the implementation conditions of this utility model. Therefore, they have no substantial technical significance. Any modifications to the structure, changes in the proportions, or adjustments to the size, without affecting the effects and purposes that this utility model can produce, should still fall within the scope of the technical content disclosed in this utility model.
[0040] Figure 1 A schematic diagram of the overall structure of a tooling for attaching foam to an aluminum battery drum;
[0041] Figure 2 A schematic diagram of the electrical control box, lifting mechanism and rotating mechanism in a tooling for attaching foam to an aluminum battery drum;
[0042] Figure 3 A side view of a tooling for attaching foam to an aluminum battery drum;
[0043] Figure 4 A front view of a tooling for attaching foam to an aluminum battery drum;
[0044] Figure 5 A schematic diagram of the positioning plate in a tooling for attaching foam to an aluminum battery barrel;
[0045] Figure 6 for Figure 5 Schematic diagram of the midsole plate;
[0046] Figure 7 for Figure 2 A schematic diagram of the cross-section of the fixed groove.
[0047] Illustrations: 1. Electrical control box; 2. Limiting groove; 3. Lifting mechanism; 4. Rotating mechanism; 5. Fixing component; 6. Telescopic mechanism; 7. Positioning plate; 101. Vacuum button one; 102. Vacuum button two; 103. Rotating button; 104. Pressing button; 105. Emergency stop reset button; 106. Fixing groove; 107. Rotating rod; 108. Positioning block; 301. Slide table; 401. Rotating worktable; 501. Connecting plate; 502. Support plate; 503. First through hole; 701. Base plate; 702. Adsorption plate; 703. Air groove; 1061. Second through hole; 1071. Damping pad; 7021. Limiting structure; 7031. Air extraction hole; 7032. Suction hole. Detailed Implementation
[0048] To make the utility model's objectives, features, and advantages more apparent and understandable, the technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the embodiments described below are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present utility model.
[0049] In the description of this utility model, it should be understood that the terms "upper," "lower," "top," "bottom," "inner," and "outer," etc., indicating the orientation or positional relationship are based on the orientation or positional relationship 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 element 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. It should be noted that when a component is considered to be "connected" to another component, it can be directly connected to the other component or there may be a component centrally located at the same time.
[0050] The technical solution of this utility model will be further described below with reference to the accompanying drawings and specific embodiments.
[0051] like Figures 1-4 As shown, this utility model embodiment provides a battery aluminum barrel foam attaching fixture, including an electrical control box 1, a lifting mechanism 3, a rotating mechanism 4, a fixing component 5, two sets of telescopic mechanisms 6 and two sets of positioning plates 7;
[0052] A limiting groove 2 is provided on the top of the electrical control box 1;
[0053] The lifting mechanism 3, the rotating mechanism 4, and the two sets of telescopic mechanisms 6 are all controlled by the electrical control box 1;
[0054] The lifting mechanism 3 is installed on the top of the electrical control box 1, and the lifting mechanism 3 is connected to the rotating mechanism 4, driving the rotating mechanism 4 to perform lifting actions;
[0055] The fixing component 5 is mounted on the rotating mechanism 4, and the rotating mechanism 4 controls the rotation of the fixing component 5;
[0056] The telescopic mechanism 6 is mounted on the fixed component 5, and the extended end of the telescopic mechanism 6 is connected to one side of the positioning plate 7. The foam is attached to the other side of the positioning plate 7. The telescopic mechanism 6 drives the positioning plate 7 to move closer to the inner wall of the battery aluminum barrel. The positioning plate 7 drives the foam to be squeezed and attached to the inner wall of the battery aluminum barrel.
[0057] In this embodiment, the operator uses the lifting mechanism 3 and the rotating mechanism 4 to flip the two sets of telescopic mechanisms 6 mounted on the fixed component 5, facilitating the attachment of the foam to the positioning plates 7 on the two sets of telescopic mechanisms 6. The battery aluminum cylinder is fitted outside the two sets of telescopic mechanisms 6 and placed in the limiting groove 2. The limiting groove 2 is used to position the battery aluminum cylinder. The two sets of telescopic mechanisms 6 press the positioning plates 7 with foam against the inner wall of the battery aluminum cylinder, replacing manual pressing of the foam and avoiding creases in the foam.
[0058] like Figure 3 and Figure 4As shown, the fixing assembly 5 further includes a connecting plate 501 and two support plates 502 respectively installed on the top and bottom of the connecting plate 501, with the two support plates 502 parallel to each other. It should be noted that the two support plates 502 are parallel to each other, and in the reset state, the support plates 502 are parallel to the bottom of the limiting groove 2, the purpose of which is to enable the telescopic mechanism 6 to push the positioning plate 7 to press parallel against the inner wall of the battery aluminum can. The connecting plate 501, as a core component, is directly connected to the rotating mechanism 4, allowing the entire fixing assembly to rotate together with the rotating mechanism.
[0059] The connecting plate 501 is connected to the rotating mechanism 4. Each telescopic mechanism 6 is mounted on a support plate 502, and the other support plate 502 has multiple first through holes 503. The extended end of the telescopic mechanism 6 passes through these first through holes 503 and connects to one side of the positioning plate 7. This design ensures that the telescopic mechanism 6 can stably push the positioning plate for precise position adjustment.
[0060] In this embodiment, when performing the foam attachment task, the rotating mechanism 4 is first controlled by the electrical control box 1 to rotate the fixing component 5 and all components mounted on it to an appropriate angle. Then, the telescopic mechanism 6 extends or retracts according to instructions, driving the positioning plate 7 to move closer to or away from the inner wall of the battery aluminum barrel, completing the foam attachment work. This high degree of automation reduces the need for manual intervention, simplifies the operation process, improves work efficiency, and reduces labor intensity.
[0061] Furthermore, each set of the telescopic mechanism 6 is connected to a corresponding set of the positioning plates 7;
[0062] The telescopic mechanism 6 is mounted on one of the support plates 502, and the other support plate 502 has a plurality of first through holes 503. The extended end of the telescopic mechanism 6 passes through the first through holes 503 and is connected to one side of the positioning plate 7.
[0063] In this embodiment, each set of telescopic mechanisms 6 corresponds to a set of positioning plates 7. Specifically, the telescopic mechanism 6 is fixed to a support plate 502, while another support plate 502 has multiple first through holes 503. The extended end of the telescopic mechanism 6 passes through these first through holes 503 and connects to one side of the positioning plate 7. This design ensures that the telescopic mechanism can effectively drive the positioning plate to move.
[0064] Furthermore, each of the telescopic mechanisms 6 has at least one telescopic cylinder; it should be noted that the telescopic mechanism 6 here is not limited to a telescopic cylinder, but can also be an electric push rod or a pneumatic push rod. In short, any structure or device that can be used to push and retract the positioning plate 7 is acceptable.
[0065] The number of the first through holes 503 is equal to the number of the telescopic cylinders, and their positions correspond one-to-one.
[0066] In this embodiment, the first through hole 503 corresponds one-to-one with the position of the telescopic cylinder, ensuring the accuracy of the telescopic mechanism 6's telescopic action, avoiding any possible positional deviation, and improving the precision of foam attachment.
[0067] like Figure 5 and Figure 6 As shown, each of the positioning plates 7 further includes a base plate 701 and an adsorption plate 702 that overlap each other. It should be noted that the base plate 701 and the adsorption plate 702 can be an integrally formed structure or they can be fixed to each other by bolts. The base plate 701 is disposed on the outside of the fixing component 5 and is connected to the telescopic mechanism 6;
[0068] Each of the positioning plates 7 is also provided with an adsorption structure. The electrical control box 1 is provided with a vacuum button 101 and a vacuum button 102, which are used to control the adsorption structures on the two positioning plates 7 respectively.
[0069] In this embodiment, the adsorption structure design enables stable adsorption of the foam material, preventing displacement or falling during handling or attachment. The independent vacuum button 101 and vacuum button 102 allow for separate control of the adsorption state on each positioning plate 7, increasing operational flexibility and allowing adjustment of the working state of each positioning plate according to actual conditions to adapt to different production needs.
[0070] Furthermore, the adsorption structure includes an air extraction hole 7031 formed on one side of the base plate 701 and a plurality of suction holes 7032 formed on the adsorption plate 702.
[0071] An air groove 703 is provided on the side of the base plate 701 near the adsorption plate 702, and the air extraction hole 7031 and the suction hole 7032 are both connected to the air groove 703.
[0072] The base plate 701 and the adsorption plate 702 are sealed together. It should be noted that the sealed connection here can be that the base plate 701 and the adsorption plate 702 are structurally integrated, or that a rubber pad or other object can be provided at the edge position between the base plate 701 and the adsorption plate 702 to seal the gap between the base plate 701 and the adsorption plate 702.
[0073] The air extraction port 7031 is connected to an external air extraction device via an air pipe.
[0074] The adsorption plate 702 has multiple protruding limiting structures 7021 on the side away from the telescopic mechanism 6.
[0075] In this embodiment, when foam needs to be adsorbed, the operator controls the adsorption structure on the two positioning plates 7 to start via vacuum button 101 or vacuum button 102 on the control box 1. An external air extraction device draws air through the air extraction port 7031, allowing the adsorption plate 702 to firmly adsorb the foam. After the foam adsorption is complete, the telescopic mechanism 6 pushes the positioning plate 7 closer to the inner wall of the battery aluminum tank according to a preset command. During this process, the suction holes 7032 on the adsorption plate 702 continuously provide suction, keeping the foam in a fixed position until it is accurately attached to the inner wall of the aluminum tank. Simultaneously, multiple raised limiting structures 7021 are provided on the side of the adsorption plate away from the telescopic mechanism 6, helping to ensure the foam is correctly attached without wrinkles.
[0076] like Figure 1 As shown, the electrical control box 1 is further provided with a rotary button 103, a pressing button 104 and an emergency stop reset button 105;
[0077] The rotary button 103 controls the rotary mechanism 4 to start;
[0078] The pressing button 104 controls the activation of the two sets of telescopic mechanisms 6;
[0079] The emergency stop reset button 105 is used to pause and reset the entire battery aluminum barrel foam-attached fixture.
[0080] In this embodiment, the operator first attaches the front foam to a positioning plate 7, presses the vacuum 1 button to adsorb the foam, presses the rotation button 103, and the lifting mechanism 3 rises. Then, the rotation mechanism 4 flips the other positioning plate 7 to the top, and the lifting mechanism 3 resets. The operator attaches the foam, presses the vacuum 2 button to adsorb the foam onto the second positioning plate 7, and then the operator places the aluminum bucket into the limiting groove 2 for positioning. The operator presses the pressing button 104, and the telescopic mechanism 6 pushes the positioning plate 7 toward the inner wall of the aluminum bucket, attaching the foam to the inner wall of the aluminum bucket. After the foam is attached, the operator presses the emergency stop reset button 105, the internal air pressure of the positioning plate 7 returns to atmospheric pressure, the telescopic mechanism 6 retracts, and the operator takes out the aluminum bucket with the foam attached and completes the operation.
[0081] like Figure 7 As shown, the limiting groove 2 is further provided with an open end away from the lifting mechanism 3, and locking components are provided on both sides;
[0082] The top of the electrical control box 1 is also provided with two fixing slots 106, which are located on both sides of the opening of the limiting slot 2.
[0083] The positioning assembly includes a positioning block 108 and a rotating rod 107 rotatably connected within the fixing groove 106; the positioning block 108 is located outside the fixing groove 106 and is connected to the rotating rod 107.
[0084] like Figure 2 and Figure 7 As shown, a second through hole 1061 is provided on the side wall of the fixing groove 106, and the rotating rod 107 is movably installed in the second through hole 1061. A damping pad 1071 is provided between the rotating rod 107 and the second through hole 1061.
[0085] When the positioning block 108 rotates, the resulting circumference radius is greater than the minimum distance from the second through hole 1061 to the opening of the limiting groove 2.
[0086] In this embodiment, after the battery aluminum can is inserted into the limiting groove 2 through the opening, the positioning block 108 is rotated to a horizontal position to prevent the battery aluminum can from moving out of the opening of the limiting groove 2, thereby ensuring that the position of the battery aluminum can does not change during the foam attachment process. The rotating rod 107 can move within the movable second through hole 1061, allowing the positioning assembly to adapt to battery aluminum cans of different lengths. It should be noted that the damping pad 1071 here serves to prevent the rotating rod 107 from rotating within the second through hole 1061, so that the positioning block 108 can maintain its position, especially its horizontal position, after rotation.
[0087] Furthermore, the rotating mechanism 4 is a rotary cylinder, which has a rotary worktable 401, and the fixing component 5 is mounted on the rotary worktable 401.
[0088] like Figure 2 As shown, in this embodiment, the fixing component 5 can be mounted on the rotary worktable 401 by welding or bolting. Furthermore, the rotating mechanism 4 here is not limited to a rotary cylinder; it can also be a motor-driven rotating structure. In short, various structures capable of rotating the fixing component 5 are possible. Since the structures and devices used to achieve rotation are existing technologies, they will not be described in detail here.
[0089] Furthermore, the lifting mechanism 3 is a slide cylinder, which has a slide 301, and the rotating mechanism 4 is mounted on the slide 301.
[0090] In this embodiment, the rotating mechanism 4 can be mounted on the slide table 301 by welding or bolting. Furthermore, the lifting mechanism 3 here is not limited to a slide table cylinder; it can also be an electric push rod or a pneumatic push rod. In short, various structures can be used to lift and lower the rotating mechanism 4. Since the structures and devices used to lift and lower the rotating mechanism 4 are existing technologies, they will not be described in detail here.
[0091] The above-described embodiments are only used to illustrate the technical solutions of this utility model, and are not intended to limit it. Although this utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of the embodiments of this utility model.
Claims
1. A battery aluminum barrel foam pasting tool, characterized in that, It includes an electrical control box (1), a lifting mechanism (3), a rotating mechanism (4), a fixing component (5), two sets of telescopic mechanisms (6) and two sets of positioning plates (7); A limit groove (2) is provided on the top of the electrical control box (1); The lifting mechanism (3), the rotating mechanism (4) and the two sets of telescopic mechanisms (6) are all controlled by the electrical control box (1); The lifting mechanism (3) is installed on the top of the electrical control box (1), and the lifting end of the lifting mechanism (3) is connected to the rotating mechanism (4); The fixing component (5) is installed on the rotating end of the rotating mechanism (4); The telescopic mechanism (6) is installed on the fixed component (5), and the extended end of the telescopic mechanism (6) is connected to one side of the positioning plate (7). The foam is attached to the other side of the positioning plate (7). The telescopic mechanism (6) drives the positioning plate (7) to move closer to the inner wall of the battery aluminum barrel. The positioning plate (7) drives the foam to squeeze and attach to the inner wall of the battery aluminum barrel.
2. The battery aluminum drum foam-attaching fixture according to claim 1, characterized in that, The fixing component (5) includes a connecting plate (501) and two support plates (502) respectively installed on the top and bottom of the connecting plate (501), the two support plates (502) being parallel to each other; The connecting plate (501) is connected to the rotating mechanism (4).
3. The battery aluminum bucket foam-attaching fixture according to claim 2, characterized in that, Each set of telescopic mechanisms (6) is connected to a set of positioning plates (7); The telescopic mechanism (6) is mounted on one of the support plates (502), and a plurality of first through holes (503) are provided on another support plate (502). The extended end of the telescopic mechanism (6) passes through the first through hole (503) and is connected to one side of the positioning plate (7).
4. The battery aluminum bucket foam-attaching fixture according to claim 3, characterized in that, Each of the telescopic mechanisms (6) has at least one telescopic cylinder; The number of the first through holes (503) is equal to the number of the telescopic cylinders, and their positions correspond one-to-one.
5. The battery aluminum bucket foam-attaching fixture according to claim 1, characterized in that, Each of the positioning plates (7) includes a base plate (701) and an adsorption plate (702) that overlap each other. The base plate (701) is disposed on the outside of the fixing component (5) and is connected to the telescopic mechanism (6). Each of the positioning plates (7) is also provided with an adsorption structure. The electrical control box (1) is provided with a vacuum button one (101) and a vacuum button two (102) to control the adsorption structures on the two positioning plates (7) respectively.
6. The battery aluminum bucket foam-attaching fixture according to claim 5, characterized in that, The adsorption structure includes an air extraction hole (7031) on one side of the base plate (701) and a plurality of suction holes (7032) on the adsorption plate (702). An air groove (703) is provided on the side of the base plate (701) near the adsorption plate (702), and the air extraction hole (7031) and the suction hole (7032) are both connected to the air groove (703). The base plate (701) and the adsorption plate (702) are sealed together; The air extraction port (7031) is connected to an external air extraction device via an air pipe; The adsorption plate (702) has multiple protruding limiting structures (7021) on the side away from the telescopic mechanism (6).
7. The battery aluminum bucket foam-attaching fixture according to claim 1, characterized in that, The electrical control box (1) is also equipped with a rotary button (103), a pressing button (104), and an emergency stop reset button (105). The rotary button (103) controls the rotary mechanism (4) to start; The pressing button (104) controls the activation of the two sets of telescopic mechanisms (6); The emergency stop reset button (105) is used to pause and reset the entire battery aluminum barrel foam-coated fixture.
8. The battery aluminum drum foam-attaching fixture according to claim 1, characterized in that, The limiting groove (2) is open at one end away from the lifting mechanism (3), and has locking components on both sides; The top of the electrical control box (1) is also provided with two fixing slots (106), and the two fixing slots (106) are respectively located on both sides of the opening of the limiting slot (2); The positioning assembly includes a positioning block (108) and a rotating rod (107) rotatably connected in the fixing groove (106); the positioning block (108) is located outside the fixing groove (106) and is connected to the rotating rod (107); A second through hole (1061) is provided on the side wall of the fixing groove (106), and the rotating rod (107) is movably installed in the second through hole (1061). A damping pad (1071) is provided between the rotating rod (107) and the second through hole (1061). When the positioning block (108) rotates, the circumference of the circle formed is greater than the minimum distance from the second through hole (1061) to the opening of the limiting groove (2).
9. The battery aluminum bucket foam-attaching fixture according to claim 1, characterized in that, The rotating mechanism (4) is a rotary cylinder with a rotary worktable (401), and the fixing component (5) is mounted on the rotary worktable (401).
10. The battery aluminum bucket foam-attaching fixture according to claim 1, characterized in that, The lifting mechanism (3) is a slide cylinder with a slide (301) and the rotating mechanism (4) is mounted on the slide (301).