A hot glue box machine
By combining a steering mechanism, a side plate feeding mechanism, and a heating mechanism, a new production process for pearl cotton bottom boxes has been achieved, solving the problem of misalignment between the frame and the base, and improving the flatness and production efficiency of the pearl cotton bottom boxes.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONGGUAN MAOLONG MASCH MFG CO LTD
- Filing Date
- 2025-06-20
- Publication Date
- 2026-06-23
AI Technical Summary
Traditional pearl cotton bottom boxes have a misalignment between the frame and the base, and existing frame gluing machines cannot produce pearl cotton bottom boxes with the new structure.
By employing a steering mechanism, a pearl cotton side panel feeding mechanism, and a heating mechanism, a new process is used to ensure that the pearl cotton side panels and the sides of the base are thermally bonded in an orderly manner. This includes the combined use of a steering device, a side panel feeding assembly, and a heating plate to ensure precise alignment and thermal bonding between the side panels and the base.
The new structure of the pearl cotton base box achieves high flatness, solves the problem of misalignment between the frame and the base, and improves production efficiency and product quality.
Smart Images

Figure CN224391940U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of manufacturing pearl cotton bottom boxes, and more particularly to a hot-press box machine. Background Technology
[0002] Pearl cotton bottom boxes are packaging trays or bases made primarily of EPE pearl cotton. Pearl cotton also has the property of absorbing impact and is usually used to protect fragile items during transportation.
[0003] The structure of a traditional pearl cotton bottom box is as follows: Figure 1-2 As shown, it includes a base 100 and a frame 101. The frame 101 is heat-fused onto the surface of the base 100 near the edge. Since the frame 101 is assembled in another device, the rectangle formed by the frame 101 is not based on the actual area of the base 100, but on a preset value in another device. The produced base 100 inevitably has a certain error from the preset value, which results in some sides of the frame 101 not being on the same plane as the base 100, and there is a significant misalignment between the two.
[0004] The current solution is to change the structure and processing steps of the pearl cotton base box, and to heat-bond multiple individual pearl cotton side panels to the side of the base 100. This would solve the above problem. However, the current frame gluing machine can only produce traditional pearl cotton base boxes and cannot produce pearl cotton base boxes with new structures through new processing technology. Utility Model Content
[0005] To address the aforementioned problems, this utility model provides a hot-press box machine, which aims to solve the problem of not being able to use new processes to produce pearl cotton bottom boxes with new structures.
[0006] To achieve the above objectives, the technical solution adopted by this utility model is: a hot-pressing box machine, characterized in that it comprises:
[0007] The steering mechanism includes a steering device that causes the base to rotate actively, for rotating the sides of the base in various directions.
[0008] The pearl cotton side panel feeding mechanism includes a side panel feeding assembly that moves to the side of the base support. The feeding plate included in the side panel feeding assembly has a joint surface that provides adhesion to the pearl cotton side panel. The feeding plate is provided with multiple sets of orientation components for position calibration of different pearl cotton side panel lengths.
[0009] The heating mechanism includes a heating plate that moves toward the side of the base.
[0010] The beneficial effects of this utility model are:
[0011] The steering mechanism, pearl cotton side plate feeding mechanism, and heating mechanism included in this utility model are suitable for the preparation of new pearl cotton bottom boxes using a new process. Under the new process, individual side plates are thermally bonded to the side of the base in an orderly manner, resulting in a pearl cotton bottom box with better flatness and solving the misalignment problem in the prior art.
[0012] The four side panels of the pearl cotton base box are divided into first side panels and second side panels according to their length. The length of the first side panel is longer than that of the second side panel. Based on this new process, the following two structures of pearl cotton base boxes can be derived. Assembly of the first pearl cotton base box structure:
[0013] First, the second side of the base plate corresponding to the second side plate is heated. Then, the side plate feeding assembly presses the second side plate against the second side plate to complete the first heat bonding process. The steering surface of the steering device rotates 90°, driving the base plate to rotate 90°. Then, the first side of the base plate corresponding to the first side plate and the bonding surface on the second side plate that will contact the first side plate are heated. Then, the side plate feeding assembly presses the first side plate against the first side plate and the bonding surface to complete the assembly of the pearl cotton base box. In the structure of the first pearl cotton base box, considering the integrity of the entire base box assembly, the action of synchronous heat bonding of the first side plate and the second side plate is decomposed to ensure that the second side plate and the first side plate in the pearl cotton side plate can also be fully heat bonded.
[0014] In the second type of pearl cotton bottom box structure, only the side panels and the bottom support are heat-bonded, while the first side panel and the second side panel do not need to be heat-bonded. In the second type of pearl cotton bottom box structure, the lengths of the first side panel and the second side panel correspond only to the lengths of the sides of the bottom support. In other words, in the second type of pearl cotton bottom box structure, there are cases where the first side panel and the second side panel have the same length, or the length of the second side panel is longer than the length of the first side panel.
[0015] The following content will further explain the preparation of the first type of pearl cotton bottom box structure. Of course, this part also applies to the second type of pearl cotton bottom box structure.
[0016] This utility model includes an organic platform, which provides a stable assembly position for the steering mechanism, the pearl cotton side plate feeding mechanism, and the heating mechanism. The heating mechanism is located inside the machine platform, and its main purpose is to protect the safety of the operators. The heating plate is an actuator that operates at high temperatures. Its placement inside the machine platform can provide a certain degree of safety for the operators. Of course, it can also protect the heating mechanism, reduce the risk of external damage, and keep the heating mechanism warm. This technology of reducing heat diffusion can effectively improve the efficiency of heat energy utilization.
[0017] The movement of the hot plate and the side plate feeding assembly is achieved by using the existing first linear movement mechanism and the second linear movement mechanism, respectively. Both the first linear movement mechanism and the second linear movement mechanism are located inside the machine. Since the first linear movement mechanism and the second linear movement mechanism are existing technologies, their structures will not be described in detail.
[0018] As mentioned earlier, the side panel feeding assembly delivers pearl cotton side panels of different lengths. If different groups of orientation components are located on different horizontal planes, it will increase the stroke of the second linear moving mechanism. Additionally, accuracy must be considered. To address these technical issues, in this specific embodiment, the orientation components are located on the same horizontal plane. Each group of orientation components has a calibration space of different volumes, and these calibration spaces overlap. Furthermore, at least one group of orientation components is embedded within the feeding plate. For example, there are two groups of orientation components: the first orientation component corresponds to the first side panel, and the second orientation component corresponds to the second side panel. The second orientation component is located within the calibration space of the first orientation component. To avoid interference between the second orientation component and the first side panel when using the first orientation component, the second orientation component is embedded within the feeding plate. In this case, the first side panel can completely enter the calibration space and smoothly attach to the mating surface. By setting them on the same horizontal plane, the original function of feeding side panels of different lengths is retained, while the travel distance of the second linear moving mechanism is effectively reduced, optimizing the overall production process.
[0019] The above descriptions of the number of directional components and the individual functions of the first and second directional components are for illustrative purposes only. In practice, other variations are possible, such as having three or four sets of directional components. In this embodiment, the first directional component is fixed to the feeding plate. However, in other embodiments, it can be made into an embedded assembly, meaning the first directional component can also extend and retract within the feeding plate. Alternatively, after providing more sets of first directional components, all can be made into an embedded assembly.
[0020] The orientation component consists of a pair of parallel and spaced clamping plates on the same horizontal plane. The space between the clamping plates is the calibration space, and the mating surface is located in the calibration space. Continuing with the example above, the second clamping plate, which is the second orientation component, belongs to the calibration space of the first orientation component, that is, it is located between the two first clamping plates in the first orientation component. When calibrating the position of the first side plate, the second clamping plate retracts into the material release plate, the first side plate is attached to the mating surface, and under the constraint of the two first clamping plates, the first side plate is adjusted to a preset position to achieve reliable subsequent contact with the base.
[0021] The side panel feeding assembly also includes a position maintaining assembly disposed on the outer side of the feeding plate. The position maintaining assembly provides adhesion to the mating surface. In this specific embodiment, the position maintaining assembly includes a negative pressure source, and the feeding plate is provided with multiple negative pressure ports. The negative pressure ports are connected to the mating surface, and the negative pressure end of the negative pressure source is connected to the negative pressure ports, so that a negative pressure is formed on the mating surface to attract the side panel.
[0022] The negative pressure source can be an axial flow suction fan.
[0023] The side plate feeding assembly and the heating mechanism are staggered. The side plate feeding assembly is located above the machine platform, and the second linear moving mechanism is set on the machine platform. The side plate feeding assembly is set on the movable end of the second linear moving mechanism, and the side plate feeding assembly and the turning surface are in a relative relationship on the same horizontal plane. At this time, in the process of using the second linear moving mechanism, only the lateral spatial position of the side plate feeding assembly needs to be adjusted, thus improving the fault tolerance of the entire side plate feeding.
[0024] In this specific implementation, the machine tool is also equipped with a pressing mechanism located above the steering mechanism. The pressing mechanism presses down on the bottom support on the steering surface to ensure that the bottom support does not shift in position during the heat bonding process and during rotation. Similarly, after selecting the pressing mechanism, the output end of the steering device is a rotating platform. The steering device is located inside the machine tool, and the rotating platform is located above the machine tool. The steering surface is the top surface of the rotating platform, which supports the bottom support. The advantage of using a rotating platform is that it can provide a sufficiently large bearing surface, which, together with the pressing mechanism above, can clamp the bottom support to ensure that the bottom support does not shift. Secondly, the actual length of the bottom support is determined according to the requirements. For example, if the length of the bottom support is 70cm, the rotating platform can provide a sufficiently large contact area, that is, it increases the support area, so that most of the area of the bottom support can be fully supported, while a small part, such as the side of the bottom support, can resist the bending moment caused by its own weight even if it is suspended, so that the pearl cotton side plate can also maintain a relative form with the bottom support.
[0025] The pressing mechanism includes a telescopic component and a pressure plate. The pressure plate is fitted onto the output end of the telescopic component and is rotatably connected to the output end of the telescopic component. When the steering surface drives the pearl cotton to rotate, it also drives the pressure plate to rotate.
[0026] The machine tool is also equipped with a third orientation component for calibrating the position of the base. The third orientation component includes a third linear moving mechanism and an L-shaped positioning component. The third linear moving mechanism is set on the machine tool, and the L-shaped positioning component is set on the output end of the third linear moving mechanism. After the base is placed on the turning surface, the L-shaped positioning component moves closer to the rotating platform under the action of the third linear mechanism and forms a fixed feeding area with the turning surface. The base is then manually fed directly into the fixed feeding area, so that the inner surface of the base fits against the L-shaped positioning component, thereby achieving a calibration and orientation effect.
[0027] It should be noted that the bottom surface of the rotating platform near the edge is equipped with a ejector plate, which has several ejector pins that contact the side plate. The second side plate is in partial contact with the second side surface. In actual production, the second side plate is squeezed by the feeding plate and the edge of the rotating platform. The area of the second side plate below the rotating platform will generate bending moment due to the lack of corresponding support. After using the ejector plate, the ejector pins pierce into the second side plate to provide corresponding support for the second side plate.
[0028] It should also be noted that the pearl cotton side plate has many pores, and the diameter of the ejector pin is smaller than the diameter of these pores, so it will not damage the pores.
[0029] In some embodiments, an ejector plate that works in conjunction with the first side plate may also be provided.
[0030] The specific method for producing the first pearl cotton bottom box structure according to this utility model:
[0031] S1, place the bottom support on the turning surface, put the second side plate into the joint surface, and attach it to the feeding plate by negative pressure;
[0032] S2, by manually calibrating the position of the second side plate and the base, push the base to align the base with the inner side of the L-shaped positioning piece. Similarly, manually adjust the position of the second side plate so that the direction of the second side plate is corrected by the two second clamping plates.
[0033] S3, the pressure plate presses on the base, and the hot plate also makes thermal contact with the second side of the base from inside the machine. After the second side of the base is fully heated, the hot plate retracts into the machine. At this time, the side plate feeding assembly pushes the second side plate to the second side. After the two are thermally bonded, the side plate feeding assembly resets, and the two second clamping plates retract into the feeding plate.
[0034] S4, manually insert the first side plate and perform orientation adjustment of the first side plate as in S2;
[0035] S5, perform the same steps as S3, and the first side plate is attached to the second side plate and the first side surface that are heated at the same time. Attached Figure Description
[0036] Figure 1 This is a 3D diagram of an existing pearl cotton base box.
[0037] Figure 2 yes Figure 1 Exploded view.
[0038] Figure 3 This is a perspective view of the pearl cotton bottom box produced by this utility model.
[0039] Figure 4 yes Figure 3 Exploded view.
[0040] Figure 5 This is a perspective view of the present invention.
[0041] Figure 6 This is a perspective view of the present invention after the base and second side plate are inserted.
[0042] Figure 7 This is a 3D view of the side panel feeding assembly.
[0043] Figure 8 yes Figure 7 Enlarged diagram of point A.
[0044] Figure 9 yes Figure 7 Enlarged diagram of point B.
[0045] Figure 10 This is a 3D view of the heating mechanism.
[0046] Figure 11 This is a diagram showing the coordination relationship between the steering mechanism and the pressing mechanism.
[0047] Figure 12 This diagram shows the usage status of the side panel feeding assembly when it corresponds to the first side panel.
[0048] Figure 13 This is a 3D diagram of the second type of pearl cotton base box.
[0049] Figure 14 yes Figure 13 Exploded view. Detailed Implementation
[0050] like Figure 2-14 As shown, a hot-press box gluing machine is characterized by comprising:
[0051] Steering mechanism 1 includes a steering device that causes the base 100 to rotate actively, for rotating the sides of the base 100 in various orientations.
[0052] The pearl cotton side panel feeding mechanism 2 includes a side panel feeding assembly 21 that moves to the side of the base 100. The feeding plate 2101 included in the side panel feeding assembly 21 has a joint surface 21a that provides adhesion to the pearl cotton side panel. The feeding plate 2101 is provided with multiple sets of orientation components for position calibration of different pearl cotton side panel lengths.
[0053] The heating mechanism 3 includes a heating plate 31 that moves to the side of the base 100.
[0054] The beneficial effects of this utility model are:
[0055] The steering mechanism 1, the pearl cotton side plate feeding mechanism 2, and the heating mechanism 3 included in this utility model are suitable for the preparation of new pearl cotton bottom boxes using a new process. Under the new process, individual side plates are thermally bonded to the side of the base 100 in an orderly manner, which makes the pearl cotton bottom box with the new structure have better flatness and solves the misalignment problem in the prior art.
[0056] The four side panels of the pearl cotton base box are divided into a first side panel 102 and a second side panel 103 according to their length. The length of the first side panel 102 is longer than the length of the second side panel 103. Based on this new process, the following two structures of pearl cotton base boxes can be derived. Assembly of the first pearl cotton base box structure:
[0057] First, the second side of the base 100 corresponding to the second side plate 103 is heated. Then, the side plate feeding assembly 21 presses the second side plate 103 against the second side to complete the first heat bonding process. After that, the steering surface 10a of the steering device rotates 90°, causing the base 100 to rotate 90°. Then, the first side 100' of the base 100 corresponding to the first side plate 102 and the bonding surface 103' of the second side plate 103 that will contact the first side plate 102 are heated. Then, the side plate feeding assembly 21 presses the first side plate 102 against the first side 100' and the bonding surface 103' to complete the assembly of the pearl cotton bottom box. In the structure of the first pearl cotton bottom box, considering the integrity of the entire bottom box assembly, the action of synchronous heat bonding of the first side plate 102 and the second side plate 103 is decomposed to ensure that the second side plate 103 and the first side plate 102 in the pearl cotton side plate can also be fully heat bonded.
[0058] In the second type of pearl cotton bottom box structure, the synchronous heat bonding action of the first side plate 102 and the second side plate 103 is also decomposed. However, in the second type of pearl cotton bottom box structure, only the heat bonding between the side plate and the bottom support 100 is performed, while the heat bonding between the first side plate 102 and the second side plate 103 is not required. In the second type of pearl cotton bottom box structure, the lengths of the first side plate 102 and the second side plate 103 correspond only to the lengths of the sides of the bottom support 100. In other words, in the second type of pearl cotton bottom box structure, there are cases where the first side plate 102 and the second side plate 103 have the same length, or the length of the second side plate 103 is longer than the length of the first side plate 102.
[0059] The following content will further explain the preparation of the first type of pearl cotton bottom box structure. Of course, this part also applies to the second type of pearl cotton bottom box structure.
[0060] This utility model includes an organic platform 4. The platform 4 provides a stable assembly position for the steering mechanism 1, the pearl cotton side plate feeding mechanism 2, and the heating mechanism 3. The heating mechanism 3 is located inside the platform 4, and its main purpose is to protect the safety of the operators. The heating plate 31 is an actuator that operates at high temperatures. Its placement inside the platform 4 can provide a certain degree of safety for the operators. Of course, it can also protect the heating mechanism 3, reduce the risk of external damage, and keep the heating mechanism 3 warm. This technology of reducing heat diffusion can effectively improve the utilization efficiency of heat energy.
[0061] The movement of the hot plate 31 and the side plate feeding assembly 21 is achieved by using the existing first linear movement mechanism and second linear movement mechanism, respectively. The first linear movement mechanism and the second linear movement mechanism are both set in the machine base 4. Since the first linear movement mechanism and the second linear movement mechanism are existing technologies, their structures will not be described in detail.
[0062] As mentioned earlier, the side panel feeding assembly 21 feeds out pearl cotton side panels of different lengths. If different groups of orientation components are located on different horizontal planes, it will increase the stroke of the second linear moving mechanism. Furthermore, accuracy must be considered. To solve these technical problems, in this specific embodiment, the orientation components are located on the same horizontal plane, and each group of orientation components has a calibration space of different volumes. The calibration spaces overlap, and at least one group of orientation components is embedded in the feeding plate 2101. For example, there are two groups of orientation components: the first orientation component 2102 corresponds to the first side panel 102, and the second orientation component 21... 03 corresponds to the second side plate 103. The second orientation component 2103 is located in the calibration space of the first orientation component 2102. In order to avoid the second orientation component 2103 interfering with the first side plate 102 when using the first orientation component 2102, the second orientation component 2103 is embedded in the feeding plate 2101. At this time, the first side plate 102 can be completely entered into the calibration space and can be smoothly attached to the mating surface 21a. After being set on the same horizontal plane, it retains the original function of feeding side plates of different lengths and can also effectively reduce the path of the second linear moving mechanism and optimize the overall production process.
[0063] The above description of the number of orientation components and the separate explanation of the function of the first orientation component 2102 and the second orientation component 2103 is for illustrative purposes only. In fact, there may be other variations, such as having three or four sets of orientation components.
[0064] In the above embodiment, the first directional component 2102 is fixed on the feeding plate 2101. Of course, in other embodiments, it can also be made into an embedded assembly method. That is, the first directional component 2102 can also perform telescopic movements within the feeding plate 2101. Alternatively, after providing more sets of first directional components 2102, all of them can be made into an embedded assembly method.
[0065] The orientation component is a pair of parallel and spaced clamping plates located on the same horizontal plane. The space between the clamping plates is the calibration space, and the mating surface 21a is located in the calibration space. Continuing the example above, the second clamping plate, which is the second orientation component 2103, belongs to the calibration space of the first orientation component 2102, that is, it is located between the two first clamping plates in the first orientation component 2102. When calibrating the position of the first side plate 102, the second clamping plate retracts into the material release plate 2101, and the first side plate 102 is attached to the mating surface 21a. Under the constraint of the two first clamping plates, the first side plate 102 is adjusted to a preset position to achieve reliable contact with the base 100.
[0066] The driving source for moving the second clamping plate includes a cylinder 2105 and a cylinder plate 2106. Two second clamping plates are mounted on the cylinder plate 2106, and the output end of the cylinder 2105 is connected to the cylinder plate 2106. The first directional component 2102 and the second directional component 2103 use an interlocking mechanism to prevent the first directional component 2102 and the second directional component 2103 from working simultaneously. The interlocking means that the side plate feeding assembly 21 is used in an orderly manner by the existing PLC. For example, when the first side plate 102 is thermally bonded to the base 100, the cylinder 2105 will not push the second clamping plate out under the control of the PLC. Especially when there are multiple sets of side plate feeding assemblies 21 suitable for side plates of different sizes, each cylinder 2105 is controlled by the PLC individually. In this case, during the thermal bonding process of one side plate to the base 100, other cylinders 2105 will not push the clamping plate, thus avoiding damage to the side plate.
[0067] The side panel feeding assembly 21 also includes a position maintaining assembly disposed on the outer side of the feeding plate 2101. The position maintaining assembly provides adhesion to the mating surface 21a. In this specific embodiment, the position maintaining assembly includes a negative pressure source 2104, and the feeding plate 2101 is provided with a plurality of negative pressure ports 21'-a. The negative pressure ports 21'-a are connected to the mating surface 21a. The negative pressure end of the negative pressure source 2104 is connected to the negative pressure ports 21'-a, so that a negative pressure is formed on the mating surface 21a to attract the side panel.
[0068] The negative pressure source 2104 can be an axial flow suction fan.
[0069] The side plate feeding assembly 21 is offset from the heating mechanism 3. The side plate feeding assembly 21 is located above the machine base 4. The second linear moving mechanism is set on the machine base 4. The side plate feeding assembly 21 is set on the movable end of the second linear moving mechanism. The side plate feeding assembly 21 and the turning surface 10a are opposite to each other on the same horizontal plane. At this time, in the process of using the second linear moving mechanism, only the lateral spatial position of the side plate feeding assembly 21 needs to be adjusted. Therefore, the fault tolerance of the entire side plate feeding is improved.
[0070] In this specific embodiment, the machine base 4 is also equipped with a pressing mechanism 5 located above the steering mechanism 1. The pressing mechanism 5 presses down on the bottom support 100 on the steering surface 10a to ensure that the bottom support 100 does not shift position during the heat bonding process and during rotation. Similarly, with the pressing mechanism 5 selected, the output end of the steering device is a rotating platform 10. The steering device is located inside the machine base 4, and the rotating platform 10 is located above the machine base 4. The steering surface 10a is the top surface of the rotating platform 10, and the steering surface 10a supports the bottom support 100. The advantage of using the rotating platform 10 is that it can provide a sufficiently large... The bearing surface, together with the pressing mechanism 5 above, can clamp the base 100, ensuring that the base 100 will not shift. Secondly, the actual length of the base 100 is determined according to the requirements. For example, if the length of the base 100 is 70cm, the rotating platform 10 can provide a sufficiently large contact area, that is, it increases the support area, so that most of the area of the base 100 can be fully supported, while a small part, such as the side of the base 100, can resist the bending moment caused by its own weight even if it is suspended, so that the pearl cotton side plate can also maintain a relative form with the base 100.
[0071] The pressing mechanism 5 includes a telescopic component 51 and a pressing plate 52. The pressing plate 52 is sleeved on the output end of the telescopic component 51 and is rotatably connected to the output end of the telescopic component 51. When the turning surface 10a drives the pearl cotton to rotate, it also drives the pressing plate 52 to rotate.
[0072] The pressure plate 52 can have various shapes, such as round or rectangular.
[0073] The machine base 4 is also equipped with a third orientation component for calibrating the position of the base 100. The third orientation component includes a third linear moving mechanism 62 and an L-shaped positioning component 61. The third linear moving mechanism 62 is set on the machine base 4, and the L-shaped positioning component 61 is set on the output end of the third linear moving mechanism 62. After the base 100 is placed on the turning surface 10a, the L-shaped positioning component 61 moves towards the rotating platform 10 in advance under the action of the third linear moving mechanism 62, and forms a fixed feeding area with the turning surface 10a. By manually feeding material directly into the fixed feeding area, the base 100 is made to fit against the inner surface of the L-shaped positioning component 61, thereby achieving a calibration and orientation effect.
[0074] It should be noted that a pin plate 71 is provided on the bottom surface of the rotating platform 10 near the edge, and a number of pins 72 are provided on the pin plate 71 that contact the side plate. The second side plate 103 is in partial contact with the second side surface. In actual production, the second side plate 103 is squeezed by the feeding plate 2101 and the edge of the rotating platform 10. The area of the second side plate 103 below the rotating platform 10 will generate bending moment due to the lack of corresponding support. After using the pin plate 71, the pins 72 pierce into the second side plate 103 to provide corresponding support for the second side plate 103.
[0075] It should also be noted that the pearl cotton side plate has many pores, and the diameter of the ejector pin 72 is smaller than the diameter of these pores, so it will not damage the pores.
[0076] In some embodiments, an ejector plate that cooperates with the first side plate 102 may also be provided;
[0077] The specific method for producing the first pearl cotton bottom box structure according to this utility model:
[0078] S1, place the base 100 on the turning surface 10a, and place the second side plate 103 on the mating surface 21a, and attach it to the feeding plate 2101 by negative pressure;
[0079] S2, by manually calibrating the position of the second side plate 103 and the base 100, push the base 100 to align the base 100 with the inner side of the L-shaped positioning piece 61. Similarly, manually adjust the position of the second side plate 103 so that the direction of the second side plate 103 is corrected by the two second clamping plates.
[0080] S3, the pressure plate 52 presses on the base 100, and the heating plate 31 also makes thermal contact with the second side of the base 100 from inside the machine base 4. After the second side of the base 100 is fully heated, the heating plate 31 retracts into the machine base 4. At this time, the side plate feeding assembly 21 pushes the second side plate 103 to the second side. After the two are thermally bonded, the side plate feeding assembly 21 resets, and the two second clamping plates retract into the feeding plate 2101.
[0081] S4, manually insert the first side plate 102 and perform orientation adjustment of the first side plate 102 as in S2;
[0082] S5, perform the same steps as S3, and the first side plate 102 is attached to the second side plate 103 and the first side surface 100' which are heated at the same time.
[0083] The above embodiments are merely preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model. Various modifications and improvements made to the technical solutions of the present utility model by those skilled in the art without departing from the spirit of the present utility model should fall within the protection scope defined by the claims of the present utility model.
Claims
1. A hot-press box gluing machine, characterized in that, Includes: The steering mechanism includes a steering device that causes the base to rotate actively, for rotating the sides of the base in various directions. The pearl cotton side panel feeding mechanism includes a side panel feeding assembly that moves to the side of the base support. The feeding plate included in the side panel feeding assembly has a joint surface that provides adhesion to the pearl cotton side panel. The feeding plate is provided with multiple sets of orientation components for position calibration of different pearl cotton side panel lengths. The heating mechanism includes a heating plate that moves toward the side of the base.
2. The hot-pressing box machine according to claim 1, characterized in that, It also includes a drive source, orientation components located on the same horizontal plane, each set of orientation components having a calibration space of different volume, the calibration spaces overlapping each other, and at least one set of orientation components is embedded in the feeding plate, the orientation components embedded in the feeding plate being connected to the output end of a single drive source.
3. A hot-press box machine according to claim 2, characterized in that, The drive source includes a cylinder and a cylinder plate. The orientation component embedded in the feeding plate is disposed on the cylinder plate, and the output end of the cylinder is connected to the cylinder plate.
4. A hot-press box machine according to claim 2, characterized in that, The orientation component consists of a pair of parallel and spaced clamping plates located on the same horizontal plane. The space between the clamping plates is the calibration space, and the mating surface is located in the calibration space.
5. A hot-press box-gluing machine according to claim 1, characterized in that, The side plate feeding assembly also includes a position holding component disposed on the outer side of the feeding plate, which provides adhesion to the mating surface.
6. A hot-press box machine according to claim 5, characterized in that, The position maintaining component includes a negative pressure source, and the feeding plate is provided with multiple negative pressure ports. The negative pressure ports are connected to the mating surface. The negative pressure end of the negative pressure source is connected to the negative pressure ports, so that a negative pressure is formed on the mating surface to attract the side plate.
7. A hot-press box-gluing machine according to claim 1, characterized in that, It includes an organic platform and a second linear moving mechanism. The heating mechanism is located inside the machine platform. The side plate feeding assembly is offset from the heating mechanism and is located above the machine platform. The second linear moving mechanism is set on the machine platform, and the side plate feeding assembly is set on the movable end of the second linear moving mechanism. The side plate feeding assembly is opposite to the turning surface of the turning device.
8. A hot-press box machine according to claim 7, characterized in that, It also includes a pressing mechanism located above the steering mechanism. The pressing mechanism presses down on the bottom support on the steering surface. The output end of the steering mechanism is a rotating platform, and the steering surface is the top surface of the rotating platform. The steering surface supports the bottom support.
9. A hot-press box-gluing machine according to claim 8, characterized in that, The pressing mechanism includes a telescopic component and a pressure plate, wherein the pressure plate is sleeved on the output end of the telescopic component and is rotatably connected to the output end of the telescopic component; the machine base is also provided with a third orientation component for calibrating the position of the base, the third orientation component includes a third linear moving mechanism and an L-shaped positioning component, the L-shaped positioning component being disposed on the output end of the third linear moving mechanism.
10. A hot-press box machine according to claim 9, characterized in that, The bottom surface of the rotating platform near the edge is provided with a ejector plate, and the ejector plate is provided with several ejector pins that contact the side plate.