An integral adhesive tape application screen and its adhesive application apparatus

CN118810204BActive Publication Date: 2026-06-23SHANGHAI XIN ZHUO ZHUANG PRINTING TECH

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
SHANGHAI XIN ZHUO ZHUANG PRINTING TECH
Filing Date
2024-08-09
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

In existing technologies, the tape is prone to shifting and is inefficient during the screen application process, resulting in uneven application and time consumption.

Method used

An integrated tape bonding screen and adhesive equipment are used. By strengthening the tape connection between tape loop one and tape loop two, and using components such as positioning mechanisms and vacuum suction cups, the tape is bonded as a whole, reducing manual operation and the risk of misalignment.

Benefits of technology

It improves the efficiency and precision of tape application, reduces the possibility of tape misalignment, and enhances the production efficiency and quality of the screen printing plate.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a whole type of adhesive tape adhering screen plate and an adhering device thereof, relates to the field of solar panel screen plate, and comprises an adhering workbench, a supporting table is arranged on the adhering workbench, a placing groove is formed in the adhering workbench, four two-by-two symmetrical positioning rods are fixed in the placing groove, a feeding adhering mechanism is arranged on the adhering workbench, and a positioning mechanism is arranged on the supporting table. The corresponding structure is aligned with the center of the supporting table by the positioning mechanism, then the feeding adhering mechanism is controlled by a controller to take out the whole adhesive tape from the placing groove, the adhesive tape is adhered to the corresponding structure under the action of the feeding adhering mechanism, then the protective film on the other side of the whole adhesive tape is torn off by workers, and the corresponding structure is pasted, so that the adhesive tape can be conveniently adhered, the adhesive tape adhering efficiency is improved, and the possibility of adhesive tape deviation during adhesive tape adhering is reduced.
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Description

Technical Field

[0001] This application relates to the field of solar panel screen printing, and in particular to an integral tape-bonded screen printing and bonding equipment thereof. Background Technology

[0002] Solar panels, also known as solar cells or photovoltaic panels, are devices that convert sunlight into electrical energy. They are widely used in residential, commercial, and industrial sectors for power generation and to supplement the power grid. Solar panel screens, also known as screen printing stencils, are crucial components in the production of solar panels.

[0003] The structure of a screen generally consists of a screen, a metal mesh, a polyester mesh, and a patterned layer. The screen ensures that the solar cells can effectively collect and transmit current. With technological advancements, screen design and manufacturing processes are constantly being optimized to improve the performance and reliability of solar panels.

[0004] When fixing these structures on the screen, the most common process is to use tape for adhesion. Tape is applied between the structures to be adhered, and then the tape is used to bond and fix them. When applying tape, the structures to be tapered are usually placed on a flat adhesive board, and then a robotic arm moves the roll of tape to apply it. During the application process, adjacent tapes may shift, and the application efficiency is relatively slow. Summary of the Invention

[0005] The purpose of this application is to address the problems mentioned in the background art, which generally involve placing the structure to be taped on a flat adhesive plate and then moving the roll of tape by a robotic arm for taping. During the taping process, adjacent tapes may shift, and the taping efficiency is slow. This application provides an integral tape bonding screen and its bonding equipment.

[0006] To achieve the above objectives, this application specifically adopts the following technical solution:

[0007] An integral tape-bonded screen includes a metal screen, on which a first tape ring and a second tape ring are bonded, and a reinforcing tape is fixed between the first and second tape rings, the reinforcing tape being bonded to the metal screen.

[0008] By adopting the above technical solution, the first and second tape rings connected by reinforcing tape are directly attached as a whole, and then the corresponding structure is attached to the tape to form a screen. This reduces the trouble of manually attaching each tape strip by strip, reduces the possibility of tape misalignment during application, and improves the tape application efficiency.

[0009] An integral tape bonding device for screen printing includes a bonding worktable, a controller mounted on the bonding worktable, a support platform on the bonding worktable, a placement slot on the bonding worktable located on one side of the support platform, four symmetrically positioned rods fixed in the placement slot, a feeding bonding mechanism on the bonding worktable, and a positioning mechanism on the support platform.

[0010] By adopting the above technical solution, the positioning mechanism aligns the corresponding structure with the center of the support platform. Then, the controller controls the feeding and bonding mechanism to remove the entire tape from the placement slot. The worker then peels off the protective film on the tape, and the feeding and bonding mechanism then adheres the tape to the corresponding structure. The worker then peels off the protective film on the other side of the entire tape and applies it to the corresponding structure. This facilitates the application of the entire tape, improves the efficiency of tape application, and reduces the possibility of tape misalignment during application.

[0011] Furthermore, the feeding and bonding mechanism includes a feeding block mounted on a support platform. The feeding block is equipped with multi-stage hydraulic telescopic rods, the telescopic ends of which are fixedly connected to the feeding block. A translation component is mounted on the multi-stage hydraulic telescopic rods. A first contact frame is fixed on the feeding block near the support platform, and a second contact frame is fixed on the feeding block near the support platform. Four symmetrically arranged vacuum suction cups are mounted on both the first and second contact frames. The vacuum suction cups are fixedly connected to the feeding block. An alignment component is provided between the support platform and the feeding block.

[0012] By adopting the above technical solution, the loading block is moved above the placement location using a translation component, allowing the corresponding vacuum suction cups to contact and adhere to tape ring one and tape ring two. Then, under the action of a multi-stage hydraulic telescopic rod, the loading block is raised, carrying a complete tape composed of tape ring one, tape ring two, and reinforcing tape. The translation component then moves the loading block directly above the support platform, and the loading block is lowered, allowing the complete tape on the loading block to adhere to the corresponding structure. This facilitates the adhesion of the complete tape, improves the efficiency of tape adhesion, and further reduces the possibility of misalignment during tape adhesion, thus improving the adhesion effect.

[0013] Furthermore, the alignment assembly includes a movable seat fixed to the bottom of the support platform, a movable rod 1 slidably connected through the movable seat, a movable rod 2 slidably connected through the movable seat, the movable rod 1 and the movable rod 2 being staggered and vertically distributed, the two ends of the movable rod 1 and the movable rod 2 being evenly bonded to the workbench for sliding connection, four symmetrically positioned cones fixed on the support platform, and the feeding block having positioning cone holes corresponding to the feeding cones.

[0014] By adopting the above technical solution, the positioning cone hole on the feeding block is slowly fitted onto the positioning cone head on the support platform. When there is a misalignment between the feeding block and the support platform, the inclined surface of the positioning cone hole abuts against the inclined surface of the positioning cone head. Then, the support platform moves under the support of the moving seat, moving rod one and moving rod two below, thereby further reducing the possibility of misalignment when pasting the whole tape.

[0015] Furthermore, both ends of the first and second moving rods are fixed with limit plates, and a return spring is provided between the limit plate and the moving seat. Both ends of the return spring are fixedly connected to the limit plate and the moving seat.

[0016] By adopting the above technical solution, when the positioning cone hole and the positioning cone head separate, the support platform returns to its original position under the action of the return spring. This reduces the possibility of the support platform causing excessive displacement of the structure to be pasted when applying tape, thus reducing the impact on the next application.

[0017] Furthermore, the translation component includes a support frame mounted on the bonding worktable, a translation slider slidably connected to the support frame, a multi-stage hydraulic rod fixedly connected to the translation slider, a translation threaded rod rotatably connected to the support frame, the translation threaded rod passing through the translation slider and threadedly connected to the translation slider, and a drive motor fixedly mounted on the support frame, the output end of the drive motor being fixedly connected to the translation threaded rod.

[0018] By adopting the above technical solution, the rotation of the translation threaded rod drives the translation slider, which in turn drives the multi-stage hydraulic telescopic rod, thereby enabling the feeding block to move back and forth above the placement slot and the support platform.

[0019] Furthermore, the positioning mechanism includes a support column fixed on a support platform, a positioning platform fixed on the support column, four circumferentially distributed sliding blocks slidably connected on the positioning platform, positioning clamps fixed on the sliding blocks, and a synchronization component arranged between the four sliding blocks.

[0020] By adopting the above technical solution, the corresponding structure is placed on the positioning platform, with the four corners of the corresponding mechanism facing the corresponding positioning clamps. Then, the synchronous component is used to simultaneously drive the corresponding sliding blocks, so that the four sliding blocks simultaneously drive the positioning clamps to move towards the center. This ensures that the corresponding structure is positioned in the exact center of the support platform when placed, further reducing the possibility of offset or movement when pasting the overall tape.

[0021] Furthermore, the synchronization component includes a rectangular plate rotatably connected to a support column, with synchronization rods rotatably connected to each of the four corners of the rectangular plate. The synchronization rods are rotatably connected to corresponding sliding blocks. An electric telescopic rod is fixed on the support column, and the telescopic end of the electric telescopic rod is fixedly connected to one of the sliding blocks.

[0022] By adopting the above technical solution, the telescopic end of the electric telescopic rod drives one of the sliding blocks to move, then the sliding block drives the corresponding synchronous link, then the synchronous link drives the rectangular plate, the rectangular plate rotates on the support column, and then drives the other synchronous links, thus making it convenient for the sliding blocks to move simultaneously, and for the positioning clamps on the sliding blocks to move simultaneously.

[0023] In summary, this application includes at least one of the following beneficial effects;

[0024] 1. This application achieves the goal of reducing the trouble of manually pasting tape strip by strip when tape needs to be applied to these structures, by directly pasting the tape ring one and tape ring two connected by reinforcing tape as a whole, and then pasting the corresponding structure on the tape to form a screen, thereby reducing the trouble of manually pasting tape strip by strip, reducing the possibility of tape misalignment during pasting, and improving the tape pasting efficiency.

[0025] 2. In this application, when applying the integral tape, a drive motor drives a translation threaded rod, which in turn drives a translation slider. The translation slider drives a multi-stage hydraulic telescopic rod, positioning the loading block directly above the placement groove. The multi-stage hydraulic telescopic rod then extends the loading block into the placement groove, causing the first and second contact frames on the loading block to contact the corresponding tape rings. This causes the corresponding vacuum suction cups to contact and adhere to the tape rings. The multi-stage hydraulic telescopic rod then lifts the loading block, reverses the translation threaded rod, and moves the loading block above the support platform. A worker then removes the protective film from the integral tape, allowing the loading block to descend and adhere the integral tape to the support platform. In terms of structure, as the feeding block descends to apply the overall tape, the positioning cone hole on the feeding block slowly fits onto the positioning cone head on the support platform. When there is a misalignment between the feeding block and the support platform, the inclined surface of the positioning cone hole abuts against the inclined surface of the positioning cone head. Then, the support platform moves under the support of the moving seat, moving rod one, and moving rod two below. When the overall tape is completely applied to the corresponding structure, the positioning cone head and the positioning cone hole are fully aligned, aligning the overall tape with the corresponding structure to be applied, thus completing the application of the overall tape. This achieves the goal of facilitating the application of the overall tape, further improving the efficiency of tape application, and reducing the possibility of tape misalignment during application.

[0026] 3. In this application, when placing the structure to be taped, the corresponding structure is first placed on the positioning platform, with the four corners of the corresponding mechanism facing the corresponding positioning clamps. Then, the corresponding sliding blocks are driven simultaneously by the synchronous component, so that the four sliding blocks simultaneously drive the positioning clamps to move towards the center. Under the constraint of the positioning clamps, the structure to be taped is located in the center of the positioning platform, which achieves the purpose of ensuring that the corresponding structure is located in the center of the support platform when placed, further reducing the possibility of offset or movement when taping the whole structure. Attached Figure Description

[0027] Figure 1 This is a first three-dimensional structural schematic diagram of the integral tape bonding screen and its bonding equipment in this application;

[0028] Figure 2 This is a first exploded structural diagram of the integral tape bonding screen and its bonding equipment in this application;

[0029] Figure 3 This is a second exploded structural diagram of the integral tape bonding screen and its bonding equipment in this application;

[0030] Figure 4 This application Figure 2 Enlarged view of point A in the middle;

[0031] Figure 5 This application Figure 2 Enlarged diagram of point B in the middle.

[0032] Explanation of reference numerals in the attached figures:

[0033] 1. Metal mesh plate; 21. Tape ring one; 22. Tape ring two; 23. Reinforcing tape; 3. Controller; 4. Adhesion worktable; 5. Support table; 6. Feeding and bonding mechanism; 61. Feeding block; 62. Contact frame one; 63. Contact frame two; 64. Multi-stage hydraulic telescopic rod; 65. Translation assembly; 651. Support frame; 652. Translation threaded rod; 653. Translation slider; 66. Alignment assembly; 661. Moving... 662. Base; 663. Moving rod one; 664. Moving rod two; 665. Positioning cone head; 666. Positioning cone hole; 667. Limiting plate; 668. Return spring; 69. Vacuum suction cup; 70. Positioning mechanism; 71. Support column; 72. Positioning platform; 73. Sliding block; 74. Positioning clamp; 75. Synchronization assembly; 751. Rectangular plate; 752. Synchronization link; 753. Electric telescopic rod; 8. Placement slot; 9. Positioning rod. Detailed Implementation

[0034] The following is in conjunction with the appendix Figure 1 —5 provides further detailed description of this application.

[0035] This application discloses an integral tape bonding screen and its bonding equipment.

[0036] Reference Figure 1 , Figure 2 and Figure 3 An integral tape-bonded screen includes a metal screen 1, on which tape ring 1 21 and tape ring 22 are bonded, and a reinforcing tape 23 is fixed between tape ring 1 21 and tape ring 22, and the reinforcing tape 23 is bonded to the metal screen 1.

[0037] In the production of solar panel mesh, to improve the overall structural strength of the mesh, tape is usually used to bond the polyester mesh to the mesh and the metal mesh. When tape needs to be applied to these structures, the tape loop 1 21 and tape loop 22, which are connected by reinforcing tape 23, are directly applied as a whole. Then, the corresponding structures are attached to the tape to form the mesh. By connecting tape loop 1 21, tape loop 22, and reinforcing tape 23 into a whole and then attaching it to the corresponding structures, the hassle of manually applying tape strip by strip is reduced, the possibility of tape misalignment during application is reduced, and the tape application efficiency is improved.

[0038] Reference Figure 1 , Figure 2 and Figure 3An integral adhesive tape bonding screen is provided, comprising an adhesive worktable 4, a controller 3 installed on the adhesive worktable 4, a support platform 5 provided on the adhesive worktable 4, a placement groove 8 provided on the adhesive worktable 4, the placement groove 8 being located on one side of the support platform 5, four symmetrical positioning rods 9 fixed in the placement groove 8, a feeding adhesive mechanism 6 provided on the adhesive worktable 4, and a positioning mechanism 7 provided on the support platform 5.

[0039] When bonding a single tape consisting of tape loop 21, tape loop 22, and reinforcing tape 23, firstly, several tapes assembled together are placed into the placement slot 8 on the bonding worktable 4. Positioning rods 9 are used to limit the alignment of the assembled tapes, ensuring they remain neat within the placement slot 8. Then, the structure to be bonded is placed onto the positioning mechanism 7 on the support table 5. The positioning mechanism 7 aligns the corresponding structure with the center of the support table 5. Finally, the controller 3 controls the feeding bonding mechanism 6 to feed the entire tape from the placement slot 8. The adhesive tape is removed, and then the worker peels off the protective film on the tape. Then, under the action of the feeding and bonding mechanism 6, the tape is adhered to the corresponding structure. Then, the worker peels off the protective film on the other side of the whole tape and applies it to the corresponding structure. By making the tape to be pasted into a whole, and then using the feeding and bonding mechanism 6 to take out the whole tape and paste it onto the corresponding structure on the support platform 5, which is restricted by the positioning mechanism 7, the whole tape can be pasted conveniently, improving the efficiency of tape pasting and reducing the possibility of tape deviation during pasting.

[0040] Reference Figure 2 , Figure 3 and Figure 4 The feeding and bonding mechanism 6 includes a feeding block 61 mounted on a support platform 5. The feeding block 61 is equipped with a multi-stage hydraulic telescopic rod 64. The telescopic ends of the multi-stage hydraulic telescopic rod 64 are fixedly connected to the feeding block 61. A translation component 65 is mounted on the multi-stage hydraulic telescopic rod 64. A first contact frame 62 is fixed on the side of the feeding block 61 near the support platform 5, and a second contact frame 63 is fixed on the side of the feeding block 61 near the support platform 5. Four symmetrically arranged vacuum suction cups 67 are mounted on both the first contact frame 62 and the second contact frame 63. The vacuum suction cups 67 are fixedly connected to the feeding block 61. An alignment component 66 is arranged between the support platform 5 and the feeding block 61.

[0041] After the structure requiring tape is placed, the loading block 61 is first moved above the placement location using the translation component 65. Then, the multi-stage hydraulic telescopic rod 64 extends the loading block 61 into the placement groove 8, allowing the first contact frame 62 and the second contact frame 63 on the loading block 61 to contact the corresponding tape rings 21 and 22, and the corresponding vacuum suction cups 67 to contact and adhere to the tape rings 21 and 22. Then, under the action of the multi-stage hydraulic telescopic rod 64, the loading block 61 is raised, and then the loading block 61 carries a whole tape composed of tape rings 21, 22, and reinforcing tape 23. Then, the worker peels off the protective film on the whole tape, and then, under the action of the translation component 65, it is moved directly above the support platform 5. Then, the loading block 61 is lowered, allowing the whole tape on the loading block 61 to be attached to the corresponding structure. During the process of lowering and applying the overall tape, the feeding block 61 presses against the alignment component 66, which in turn moves the support platform 5. The alignment component 66 further limits the support platform 5, aligning it with the feeding block 61. The overall tape is then applied to the corresponding structure. Afterward, the feeding block 61 moves upward, and the worker removes the other protective film from the overall tape. The corresponding structure is then pasted together. The overall tape is then attracted by the vacuum suction cup 67 on the feeding block 61 and moved above the corresponding structure for application. During the application process, the alignment component 66 further limits the feeding block 61 and the support platform 5, facilitating the application of the overall tape, improving the efficiency of tape application, and reducing the possibility of misalignment during application, thus improving the application effect.

[0042] Reference Figure 2 , Figure 3 and Figure 4 The alignment component 66 includes a movable seat 661 fixed to the bottom of the support platform 5. A movable rod 662 is slidably connected through the movable seat 661, and a movable rod 663 is slidably connected through the movable seat 661. The movable rod 662 and the movable rod 663 are staggered and vertically distributed. The two ends of the movable rod 662 and the movable rod 663 are evenly bonded to the worktable 4 for sliding connection. Four symmetrical positioning cones 664 are fixed on the support platform 5. The feeding block 61 is provided with positioning cone holes 665 corresponding to the feeding cones.

[0043] When the feeding block 61 descends to apply the overall tape, the positioning cone hole 665 on the feeding block 61 slowly fits onto the positioning cone head 664 on the support platform 5. When there is a misalignment between the feeding block 61 and the support platform 5, the inclined surface of the positioning cone hole 665 abuts against the inclined surface of the positioning cone head 664. Then, the support platform 5 moves under the support of the lower movable seat 661, movable rod one 662, and movable rod two 663. When the overall tape is completely applied to the corresponding structure, the positioning cone head 664 and the positioning cone hole 665 are completely aligned, aligning the overall tape with the corresponding structure to be applied. By allowing the positioning cone hole 665 on the feeding block 61 to fit onto the positioning cone head 664 on the support platform 5 when the feeding block 61 descends, and under the constraint of the positioning cone head 664 and the positioning cone hole 665, the center of the feeding block 61 and the support platform 5 are aligned, thereby further reducing the possibility of misalignment when applying the overall tape.

[0044] Reference Figure 2 and Figure 4 Limiting discs 666 are fixed at both ends of the first moving rod 662 and the second moving rod 663. A return spring 667 is provided between the limiting disc 666 and the moving seat 661. Both ends of the return spring 667 are fixedly connected to the limiting disc 666 and the moving seat 661.

[0045] When the positioning cone hole 665 on the feeding block 61 is fitted onto the positioning cone head 664 on the support platform 5, when the moving seat 661 moves, the moving seat 661 compresses the corresponding return spring 667. When the positioning cone hole 665 and the positioning cone head 664 separate, the support platform 5 returns to its original position under the action of the return spring 667. By using the return spring 667 to reset the support platform 5, the possibility of the support platform 5 causing excessive displacement of the structure to be pasted when pasting tape can be reduced, thus reducing the impact on the next pasting.

[0046] Reference Figure 2 and Figure 3 The translation component 65 includes a support frame 651 mounted on the bonding worktable 4. A translation slider 653 is slidably connected to the support frame 651. A multi-stage hydraulic rod is fixedly connected to the translation slider 653. A translation threaded rod 652 is rotatably connected to the support frame 651. The translation threaded rod 652 passes through the translation slider 653 and is threadedly connected to the translation slider 653. A drive motor is fixedly mounted on the support frame 651. The output end of the drive motor is fixedly connected to the translation threaded rod 652.

[0047] When it is necessary to move the loading block 61 above the placement slot 8, the drive motor drives the translation threaded rod 652. When the translation threaded rod 652 rotates, it drives the translation slider 653. The translation slider 653 drives the multi-stage hydraulic telescopic rod 64. When it is necessary to move the loading block 61 above the support platform 5, the translation threaded rod 652 is rotated in the opposite direction, so that the translation slider 653 drives the loading block 61 to move above the support platform 5. By using the forward and reverse rotation of the translation threaded rod 652 to drive the translation slider 653, the loading block 61 can move back and forth between the placement slot 8 and the support platform 5.

[0048] Reference Figure 1 , Figure 2 and Figure 5 The positioning mechanism 7 includes a support column 71 fixed on the support platform 5, a positioning platform 72 fixed on the support column 71, four circumferentially distributed sliding blocks 73 slidably connected on the positioning platform 72, a positioning clamp 74 fixed on the sliding blocks 73, and a synchronization component 75 arranged between the four sliding blocks 73.

[0049] With the support column 71 fixed in place, the positioning platform 72 is located in the center of the support platform 5. When placing the structure to be taped, the corresponding structure is first placed on the positioning platform 72, with the four corners of the corresponding structure facing the corresponding positioning clips 74. Then, the synchronization component 75 simultaneously drives the corresponding sliding blocks 73, causing the four sliding blocks 73 to simultaneously move the positioning clips 74 towards the center. Under the constraint of the positioning clips 74, the structure to be taped is positioned in the center of the positioning platform 72. By restricting the structure to be taped with the four positioning clips 74, the corresponding structure can be positioned in the center of the support platform 5 when placed, further reducing the possibility of offset or movement when taping the entire structure.

[0050] Reference Figure 2 and Figure 5 The synchronization component 75 includes a rectangular plate 751 rotatably connected to a support column 71. Synchronization rods 752 are rotatably connected to each of the four corners of the rectangular plate 751. Each synchronization rod 752 is rotatably connected to a corresponding sliding block 73. An electric telescopic rod 753 is fixedly mounted on the support column 71, and the telescopic end of the electric telescopic rod 753 is fixedly connected to one of the sliding blocks 73. When the four sliding blocks 73 move, the telescopic end of the electric telescopic rod 753 first moves one of the sliding blocks 73. Then, the sliding block 73 moves its corresponding synchronization rod 752, which in turn moves the rectangular plate 751. The rectangular plate 751 rotates on the support column 71, which in turn moves the other synchronization rods 752, causing the other synchronization rods 752 to move their corresponding sliding blocks 73. By rotating the rectangular plate 751 while simultaneously moving its corresponding synchronization rods 752, the sliding blocks 73 can move simultaneously, allowing the positioning clamps 74 on the sliding blocks 73 to move simultaneously as well.

[0051] Working principle: When bonding the integral tape composed of tape ring 1 21, tape ring 22 and reinforcing tape 23, firstly, several tapes are placed together in the placement groove 8 on the bonding worktable 4. The positioning rod 9 is used to limit the assembled tapes, keeping them neat in the placement groove 8. When placing the structure to be bonded, firstly, the corresponding structure is placed on the positioning table 72, with the four corners of the corresponding mechanism facing the corresponding positioning clamp 74. Then, the synchronous component 75 simultaneously drives the corresponding sliding block 73, causing the four sliding blocks 73 to simultaneously drive the positioning clamp 74 to move towards the center. Under the constraint of the positioning clamp 74, the structure to be bonded is positioned in the exact center of the positioning table 72.

[0052] Then, the drive motor drives the translation threaded rod 652, which in turn drives the translation slider 653. The translation slider 653 drives the multi-stage hydraulic telescopic rod 64, positioning the loading block 61 directly above the placement groove 8. The multi-stage hydraulic telescopic rod 64 then extends the loading block 61 into the placement groove 8, allowing the first contact frame 62 and the second contact frame 63 on the loading block 61 to contact the corresponding tape ring 21 and tape ring 22. The corresponding vacuum suction cup 67 then contacts and adheres to the tape ring 21 and tape ring 22. Under the action of the multi-stage hydraulic telescopic rod 64, the loading block 61 is raised. The translation threaded rod 652 is reversed, moving the loading block 61 above the support platform 5. Then, the worker peels off the protective film on the overall tape, allowing the loading block 61 to descend and adhere the overall tape on the loading block 61 to the corresponding structure.

[0053] As the feeding block 61 descends to apply the overall tape, the positioning cone hole 665 on the feeding block 61 slowly fits onto the positioning cone head 664 on the support platform 5. When there is a misalignment between the feeding block 61 and the support platform 5, the inclined surface of the positioning cone hole 665 abuts against the inclined surface of the positioning cone head 664. Then, the support platform 5 moves under the support of the moving seat 661, the first moving rod 662, and the second moving rod 663 below. When the overall tape is completely adhered to the corresponding structure, the positioning cone head 664 and the positioning cone hole 665 are completely aligned, aligning the overall tape with the corresponding structure to be adhered, thus completing the application of the overall tape.

Claims

1. An adhesive bonding device for an integral tape bonding screen, the integral tape bonding screen comprising a metal mesh screen (1), characterized in that: A first tape ring (21) is attached to the metal mesh (1), a second tape ring (22) is attached to the metal mesh (1), and a reinforcing tape (23) is fixed between the first tape ring (21) and the second tape ring (22). The reinforcing tape (23) is attached to the metal mesh (1). The bonding equipment includes a bonding worktable (4), a controller (3) is installed on the bonding worktable (4), a support platform (5) is provided on the bonding worktable (4), a placement slot (8) is opened on the bonding worktable (4), the placement slot (8) is located on one side of the support platform (5), four symmetrical positioning rods (9) are fixed in the placement slot (8), a feeding bonding mechanism (6) is provided on the bonding worktable (4), and a positioning mechanism (7) is provided on the support platform (5). The feeding and bonding mechanism (6) includes a feeding block (61) set on a support platform (5). The feeding block (61) is provided with a multi-stage hydraulic telescopic rod (64). The telescopic end of the multi-stage hydraulic telescopic rod (64) is fixedly connected to the feeding block (61). The multi-stage hydraulic telescopic rod (64) is provided with a translation component (65). A first abutment frame (62) is fixed on the side of the feeding block (61) near the support platform (5). A second abutment frame (63) is fixed on the side of the feeding block (61) near the support platform (5). Four symmetrical vacuum suction cups (67) are provided on both the first abutment frame (62) and the second abutment frame (63). The vacuum suction cups (67) are fixedly connected to the feeding block (61). An alignment component (66) is provided between the support platform (5) and the feeding block (61). The alignment component (66) includes a movable seat (661) fixed to the bottom of the support platform (5). A movable rod (662) is slidably connected through the movable seat (661), and a movable rod (663) is slidably connected through the movable seat (661). The movable rod (662) and the movable rod (663) are staggered and vertically distributed. Both ends of the movable rod (662) and the movable rod (663) are slidably connected to the bonding worktable (4). Four symmetrical positioning cones (664) are fixed on the support platform (5). The loading block (61) has positioning cone holes (665) corresponding to the positioning cones (664). Limiting discs (666) are fixed at both ends of the first moving rod (662) and the second moving rod (663). A return spring (667) is provided between the limiting disc (666) and the moving seat (661). Both ends of the return spring (667) are fixedly connected to the limiting disc (666) and the moving seat (661).

2. The bonding equipment for an integral tape-bonded screen according to claim 1, characterized in that: The translation component (65) includes a support frame (651) mounted on the bonding worktable (4), a translation slider (653) slidably connected to the support frame (651), a multi-stage hydraulic telescopic rod (64) fixedly connected to the translation slider (653), a translation threaded rod (652) rotatably connected to the support frame (651), the translation threaded rod (652) passing through the translation slider (653) and threadedly connected to the translation slider (653), a drive motor fixedly mounted on the support frame (651), and the output end of the drive motor fixedly connected to the translation threaded rod (652).

3. The bonding equipment for integral tape bonding screen according to claim 1, characterized in that: The positioning mechanism (7) includes a support column (71) fixed on a support platform (5), a positioning platform (72) fixed on the support column (71), four circumferentially distributed sliding blocks (73) slidably connected on the positioning platform (72), a positioning clamp (74) fixed on the sliding block (73), and a synchronization component (75) provided between the four sliding blocks (73).

4. The bonding equipment for integral tape bonding screen according to claim 3, characterized in that: The synchronization component (75) includes a rectangular plate (751) rotatably connected to a support column (71). Synchronization rods (752) are rotatably connected to the four corners of the rectangular plate (751). The synchronization rods (752) are rotatably connected to the corresponding sliding blocks (73). An electric telescopic rod (753) is fixed on the support column (71). The telescopic end of the electric telescopic rod (753) is fixedly connected to one of the sliding blocks (73).