High-efficiency hot-melt composite processing equipment for solar screens

By designing a support drive mechanism and an adjustment mechanism, the shortcomings of existing equipment in terms of stability and adaptability are solved, realizing efficient and continuous solar screen thermal fusion composite processing, and adapting to the needs of screens of different specifications.

CN117359978BActive Publication Date: 2026-06-05常州三洋精密制版股份有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
常州三洋精密制版股份有限公司
Filing Date
2023-11-01
Publication Date
2026-06-05

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Abstract

The application relates to the technical field of solar screen processing, and particularly discloses a high-efficiency hot-melt composite processing equipment for a solar screen, which comprises a base, support shafts are fixedly installed at the top of the four corners of the base, and a top base is fixedly installed at the top of the support shafts; the second motor is started to drive the transmission gears to drive the rotation of the driving shafts, the transmission gears at the ends of the driving shafts are arranged at intervals, the driving shafts provided with the interval transmission gears are in the state of synchronous rotation, the solar screen can be placed on the topmost receiving plate through the uniform rotation of the receiving plates, the hot-melt composite mechanism is started to process at this time, and the solar screen after the hot-melt composite processing can be conveyed downwards along with the rotation of the driving shafts; along with the downward movement of the solar screen, the topmost receiving plate is in the idle state at this time, the hot-melt composite mechanism can be started to run for reprocessing at this time, and therefore the equipment can realize uninterrupted continuous automatic processing.
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Description

Technical Field

[0001] This invention relates to the field of solar screen processing technology, and in particular to a high-efficiency hot-melt composite processing equipment for solar screens. Background Technology

[0002] Solar screens consist of a frame, polyester mesh, hot melt adhesive rings, and wire mesh. During production, a hot melt device is used to heat the hot melt adhesive rings and bond them to the frame, mesh, and wire mesh. However, traditional hot melt bonding equipment requires removing the newly bonded screen after heating and bonding, and then placing another screen to be bonded in the bonding position. This process has several drawbacks. Removing the newly bonded screen immediately at high temperatures can easily deform it. Furthermore, removing the bonded screen before the next bonding step is necessary adds to the complexity, significantly reducing the efficiency of the hot melt process. Therefore, we plan to research a more efficient hot melt bonding technology for solar screens and improve its equipment.

[0003] Chinese Patent Publication No. CN218463246U discloses a hot-melt composite processing equipment for solar screen panels. It includes a hot-melt installation assembly, comprising a hot-melt installation frame, an open slot on the top surface of the hot-melt installation frame, an installation rod fixed to the top edge of the hot-melt installation frame, and a top plate fixed to the top surface of the installation rod; a hot-melt feeding assembly; a support and drive assembly; and a hot-melt composite assembly. This invention, through the coordinated arrangement of the hot-melt installation structure, hot-melt feeding structure, support and drive structure, and hot-melt composite structure, achieves the goal of eliminating the need to immediately remove the hot-melt-attached solar screen panel. The hot-melt-attached solar screen panel automatically dissipates heat vertically at intervals, allowing for direct feeding of the solar screen panel to be hot-melted. Furthermore, the user can remove the hot-melt-attached solar screen panel during the heating and fusion process, thus achieving uninterrupted feeding and fusion of the solar screen panel and significantly improving fusion efficiency.

[0004] The aforementioned device uses a conveyor belt to transport placement plates during use, which in turn support the solar grid panels. However, the conveyor belt is made of a soft material, resulting in poor overall support for the solar grid panels. Furthermore, the top requires hydraulic rods to extend and compress for heat fusion bonding, and the pressure provided by the hydraulic rods further complicates the support of the soft conveyor belt at the bottom. Consequently, the overall stability of the device is poor. Moreover, the device is not adjustable during use, making it inconvenient to flexibly position and heat-melt solar grid panels of different sizes. Overall, the device has certain defects and shortcomings, thus requiring improvement.

[0005] To address these issues, we propose a high-efficiency hot-melt composite processing equipment for solar grid panels. Summary of the Invention

[0006] The purpose of this invention is to provide a high-efficiency hot-melt composite processing equipment for solar screens, in order to solve the problems mentioned in the background art, such as poor overall support stability during use and inconvenience in flexibly adapting to solar screens of different specifications during hot-melt composite.

[0007] To achieve the above objectives, the present invention provides a high-efficiency hot-melt composite processing equipment for solar grids, comprising a base, a support shaft fixedly installed at each of the four corners of the top of the base, a top seat fixedly installed on the top of the support shaft, an adjustment mechanism fixedly installed on the top of the top seat, a housing fixedly installed on the top of the top seat outside the adjustment mechanism, a support drive mechanism fixedly installed on both sides of the top of the adjustment mechanism, a hot-melt composite mechanism fixedly installed at the upper end of the housing, a cooling mechanism fixedly installed on the back of the housing, and a conveying mechanism fixedly installed at the bottom of the housing.

[0008] The hot melt composite mechanism includes a hydraulic rod, which is fixedly installed in the middle of the top of the housing. The bottom output end of the hydraulic rod passes through the housing and is fixedly installed with a clamping assembly. A hot melt pressure plate is fixedly installed at the bottom of the clamping assembly, and an electric heating coil is installed on the top of the hot melt pressure plate.

[0009] In a further embodiment, the clamping assembly includes a sleeve fixedly installed at the top output end of the hydraulic rod. A plug is inserted into the inner side of the sleeve, and the bottom of the plug is fixedly connected to the middle of the top of the hot-melt pressure plate. A concave frame is fixedly installed on the front side of the sleeve, and a limit spring is fixedly installed on the inner side of the concave frame. A limit block is fixedly installed at the rear end of the limit spring. A slot is fixedly installed on the front side of the plug, and the rear end of the limit block is inserted into the inner side of the slot.

[0010] In a further embodiment, a connecting shaft is fixedly installed on the front of the limiting block, and a handle is fixedly installed through the concave frame at the front end of the connecting shaft. The limiting block is inserted into the inner side of the slot, the side shape of the limiting block is a right trapezoid, and the inclined surface of the limiting block is set at the bottom front end.

[0011] In a further embodiment, the conveying mechanism includes a mounting frame, which is fixedly installed in the middle of the bottom of the body, and a conveyor belt is rotatably connected between the inner sides of the mounting frame.

[0012] In a further embodiment, guide plates are fixedly installed on both sides of the front of the top seat, and universal balls are rotatably connected to the top of the guide plates at equal intervals.

[0013] In a further embodiment, the adjustment mechanism includes a drive rail, which is fixedly installed in the middle of the bottom of the top seat. A lead screw is rotatably connected inside the drive rail, with the two ends of the lead screw having opposite thread directions. A first motor is fixedly installed at one end of the drive rail, and the output end of the first motor passes through the drive rail and is fixedly connected to one end of the lead screw. Both ends of the lead screw are threadedly connected to sliders, which are slidably connected to the inner side of the drive rail. The top of the slider is fixedly connected to the bottom of the supporting drive mechanism.

[0014] In a further embodiment, the support drive mechanism includes a support frame, which is fixedly installed on the top of the slider. A drive component is provided at the front end of the support frame, and drive shafts are fixedly installed at equal intervals at the rear end of the drive component. Receiving components are fixedly installed at equal intervals on the outer surface of the drive shaft.

[0015] In a further embodiment, the drive assembly includes a second motor and transmission gears. The second motor is fixedly installed in the middle of the front of the support frame. The transmission gears are all rotatably connected to the rear end of the support frame. The transmission gears are interconnected and drive each other. There are nine sets of transmission gears and five sets of drive shafts. The drive shafts are spaced apart by one set of transmission gears. The output end of the second motor is fixedly connected to the front end of the drive shaft located in the middle of the drive shafts.

[0016] In a further embodiment, the receiving assembly includes a receiving plate, which is fixedly installed at equal intervals on the outer surface of the drive shaft. Buffer springs are fixedly installed at equal intervals on the inner top and outer bottom of the receiving plate, and a buffer plate is fixedly installed on the outer side of the buffer springs.

[0017] In a further embodiment, the cooling mechanism includes a cold air blower, which is fixedly installed in the middle of the back of the housing. A connecting pipe bracket is fixedly installed at the output end of the cold air blower, and a cooling coil is fixedly installed at the inner end of the connecting pipe bracket. The inner ends of the cooling coil all penetrate the housing.

[0018] Compared with the prior art, the beneficial effects of the present invention are:

[0019] Firstly, in this invention, by starting the first motor, the first motor drives the lead screw to drive the slider to slide on the inner side of the drive guide rail, which in turn can flexibly drive the two sets of support drive mechanisms to move relative to each other, thereby facilitating the adjustment of the spacing between the support drive mechanisms, so that the device can flexibly position solar screens of different lengths.

[0020] Secondly, in this invention, by starting the second motor to drive the transmission gears to rotate, all the drive shafts can be driven to rotate. Since the transmission gears at the ends of the drive shafts are spaced apart, the transmission gears on both sides of the three sets of transmission gears are in the same direction. The drive shafts with spaced transmission gears are all in a state of synchronous rotation, which makes the receiving plate rotate at a uniform speed. With the uniform rotation of the receiving plate, the solar grid panel can be placed on the top receiving plate. At this time, the hot melt composite mechanism is started for processing. After the solar grid panel is processed and hot melt composited, it can be conveyed downward with the rotation of the drive shaft. As the solar panel moves down, the top receiving plate is in an idle state. At this time, the hot melt composite mechanism can be started again for further processing.

[0021] Thirdly, in this invention, the hydraulic rod is activated to move the hot-melt pressure plate downwards. The hot-melt pressure plate can then be attached to the solar grid. The electric heating coil is activated to assist in heating and hot-melt bonding. During this process, if it is necessary to flexibly adapt to solar grids of different specifications, the handle can be pulled to move the connecting shaft to pull the limiting block against the limiting spring to retract. At this time, the limiting block leaves the slot, and the insert can be quickly pulled out from the inside of the sleeve. Then, the hot-melt pressure plate of the corresponding specification is taken out, and the insert on its top is inserted upwards into the inside of the sleeve. The limiting spring returns to its original position, which can then drive the limiting block into the slot, facilitating flexible adaptation and processing.

[0022] Fourth, in this invention, by starting the cold air blower, the cold air blower delivers air to the inside of the housing through the connecting pipe rack and the cold air coil, which can then help to achieve a better cooling effect. During the uniform downward movement of the solar grid, the solar grid completed by hot-melt composite can be cooled and dissipated by the cold air. When the solar grid moves to the bottom, it contacts the top of the conveyor belt and is driven forward by the conveyor belt. At this time, the solar grid moves to the top of the guide plate and is further conveyed by the universal ball for quick unloading. Attached Figure Description

[0023] Figure 1 This is a schematic diagram of the structure of the present invention;

[0024] Figure 2 This is a schematic diagram of the rear view structure in this invention;

[0025] Figure 3 This is a schematic diagram of the upper internal structure of the box in this invention;

[0026] Figure 4 This is a schematic diagram of the drive mechanism structure in this invention;

[0027] Figure 5 This is a schematic diagram of the cooling coil structure in this invention;

[0028] Figure 6In this invention Figure 3 A magnified structural diagram at point A;

[0029] Figure 7 In this invention Figure 4 A magnified structural diagram at point B;

[0030] Figure 8 This is a schematic diagram of the right-side support mechanism in this invention.

[0031] In the diagram: 1. Base; 2. Support shaft; 3. Top seat; 4. Adjustment mechanism; 41. Drive guide rail; 42. Lead screw; 43. Slider; 44. First motor; 5. Support drive mechanism; 51. Support frame; 52. Drive assembly; 521. Transmission gear; 522. Second motor; 53. Drive shaft; 54. Receiving assembly; 541. Receiving plate; 542. Buffer spring; 543. Buffer plate; 6. Hot melt composite mechanism; 61. Hydraulic rod; 6 2. Mounting assembly; 621. Sleeve; 622. Insert block; 623. Concave frame; 624. Limit spring; 625. Limit block; 626. Slot; 627. Coupling; 628. Handle; 63. Hot melt pressure plate; 64. Electric heating coil; 7. Cooling mechanism; 71. Air cooler; 72. Connecting pipe rack; 73. Air cooling coil; 8. Conveying mechanism; 81. Mounting frame; 82. Conveyor belt; 83. Guide plate; 84. Universal ball; 9. Housing. Implementation

[0032] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0033] Please see Figures 1-8In this embodiment of the invention, a high-efficiency hot-melt composite processing equipment for solar grids is provided. The hot-melt pressure plate 63 of this equipment has a melting temperature range of 100-300 degrees Celsius, the hydraulic rod 61 has a pressure range of 0.5 MPa to 5 MPa, the processing speed range of this equipment is 1 m / min to 10 m / min, the melting width range of this equipment is 100 mm to 2000 mm, and the melting thickness range is 0.01 mm to 1 mm. The equipment includes a base 1, with support shafts 2 fixedly installed at the four corners of the top of the base 1. A top seat 3 is fixedly installed on the top of the support shaft 2. An adjustment mechanism 4 is fixedly installed on the top of the top seat 3. A housing 9 is fixedly installed on the top of the top seat 3 outside the adjustment mechanism 4. Support drive mechanisms 5 are fixedly installed on both sides of the top of the adjustment mechanism 4. A hot-melt composite mechanism 6 is fixedly installed at the upper end of the housing 9. A cooling mechanism 7 is fixedly installed on the back of the housing 9. A conveying mechanism 8 is fixedly installed at the bottom of the housing 9.

[0034] The hot melt composite mechanism 6 includes a hydraulic rod 61, which is fixedly installed in the middle of the top of the housing 9. The bottom output end of the hydraulic rod 61 passes through the housing 9 and is fixedly installed with a clamping assembly 62. A hot melt pressure plate 63 is fixedly installed at the bottom of the clamping assembly 62, and an electric heating coil 64 is installed on the top of the hot melt pressure plate 63.

[0035] Please see Figure 8 The clamping assembly 62 includes a sleeve 621, which is fixedly installed at the top output end of the hydraulic rod 61. A plug block 622 is inserted into the inner side of the sleeve 621. The bottom of the plug block 622 is fixedly connected to the middle of the top of the hot melt pressure plate 63. A concave frame 623 is fixedly installed on the front side of the sleeve 621. A limit spring 624 is fixedly installed on the inner side of the concave frame 623. A limit block 625 is fixedly installed at the rear end of the limit spring 624. A slot 626 is fixedly installed on the front side of the plug block 622. The rear end of the limit block 625 is inserted into the inner side of the slot 626. By setting the clamping assembly 62, the device can be inserted into the slot 626 by the limit spring 624 abutting against the limit block 625 during use, thereby stably clamping the limit block 625. By clamping the limit block 625, hot melt pressure plates 63 of different corresponding specifications can be stably fixed, improving the stability and ease of use of the device.

[0036] Please see Figure 8A connecting shaft 627 is fixedly installed on the front of the limiting block 625. A handle 628 is fixedly installed at the front end of the connecting shaft 627 through the concave frame 623. The limiting block 625 is inserted into the inner side of the slot 626. The side shape of the limiting block 625 is a right trapezoid, and the inclined surface of the limiting block 625 is set at the bottom front end. By setting the connecting shaft 627, during the use of this device, the limiting block 625 can be pulled out by pulling the handle 628 to retract the connecting shaft 627. At this time, the limiting block 625 can be quickly pulled out of the slot 626, and the hot melt pressure plate 63 can be quickly replaced. This allows the device to flexibly replace hot melt pressure plates 63 of different specifications, improving the stability of the device.

[0037] Please see Figure 1 The conveying mechanism 8 includes a mounting frame 81, which is fixedly installed in the middle of the bottom of the body. A conveyor belt 82 is rotatably connected between the inner sides of the mounting frame 81. Guide plates 83 are fixedly installed on both sides of the front of the top seat 3. Universal balls 84 are rotatably connected to the top of the guide plates 83 at equal intervals. By setting the conveying mechanism 8 of the mounting frame 81, the device can receive the bottom solar grid panel through the conveyor belt 82 during use. At this time, by starting the conveyor belt 82, the solar grid panel can be moved forward, so that the device can quickly move the solar grid panel to the front guide plate 83. Then, the universal balls 84 on the guide plate 83 roll further, which facilitates the rapid transfer of the solar grid panel.

[0038] Please see Figure 5 The adjustment mechanism 4 includes a drive rail 41, which is fixedly installed in the middle of the bottom of the top seat 3. A lead screw 42 is rotatably connected inside the drive rail 41, with the two ends of the lead screw 42 having opposite thread directions. A first motor 44 is fixedly installed at one end of the drive rail 41, and the output end of the first motor 44 passes through the drive rail 41 and is fixedly connected to one end of the lead screw 42. Both ends of the lead screw 42 are threadedly connected to sliders 43, which are slidably connected to the inner side of the drive rail 41. The top of the sliders 43 is fixedly connected to the bottom of the support drive mechanism 5. By setting the adjustment mechanism 4, during use, the device can be adjusted by starting the first motor 44 to drive the lead screw 42 to drive the sliders 43 to slide against each other on the inner side of the drive rail 41, thereby flexibly adjusting the distance between the two sets of support drive mechanisms 5, making it convenient for the device to flexibly adapt to solar grids of different specifications.

[0039] Please see Figure 4 and Figure 6The support drive mechanism 5 includes a support frame 51, which is fixedly installed on the top of the slider 43. A drive component 52 is provided at the front end of the support frame 51, and a drive shaft 53 is fixedly installed at equal intervals at the rear end of the drive component 52. A receiving component 54 is fixedly installed at equal intervals on the outer surface of the drive shaft 53. By setting the support drive mechanism 5, the device can be operated through the drive component 52 during use, which facilitates the flexible start of the drive shaft 53 to rotate. The rotation of the drive shaft 53 can then adaptively drive the receiving component 54 to rotate, making it easier for the device to stably move the solar grid panel up and down. This allows the device to quickly and stably transmit downwards while maintaining good stability.

[0040] Please see Figure 6 The drive assembly 52 includes a second motor 522 and transmission gears 521. The second motor 522 is fixedly installed in the middle of the front of the support frame 51. The transmission gears 521 are rotatably connected to the rear end of the support frame 51 and are interconnected. There are nine sets of transmission gears 521 and five sets of drive shafts 53. Each drive shaft 53 is spaced apart by one set of transmission gears 521. The output end of the second motor 522 is fixedly connected to the front end of the middle drive shaft 53. By setting the drive assembly 52, the device can drive the transmission gears 521 to rotate during use through the second motor 522. Since each drive shaft 53 is spaced apart by one set of transmission gears 521, the inner sides of the transmission gears 521 at the ends of the two sets of drive shafts 53 are spaced apart by one set of transmission gears 521. The transmission gears 521 on both sides of the three sets of transmission gears 521 are in the same direction of rotation, enabling the device to stably transmit rotation in the same direction.

[0041] Please see Figure 7 The receiving component 54 includes a receiving plate 541, which is fixedly installed at equal intervals on the outer surface of the drive shaft 53. Buffer springs 542 are fixedly installed at equal intervals on the inner top and outer bottom of the receiving plate 541, and buffer plates 543 are fixedly installed on the outer side of the buffer springs 542. By setting up the receiving component 54, during the use of this equipment, when the processed solar screen is falling, the top of the buffer plate 543 can catch the solar screen. At this time, the buffer springs 542 and the buffer plate 543 assist in buffering, thereby achieving a better buffering and protection effect.

[0042] Please see Figure 2 , Figure 3 and Figure 5The cooling mechanism 7 includes a cooler 71, which is fixedly installed in the middle of the back of the housing 9. A connecting pipe bracket 72 is fixedly installed at the output end of the cooler 71, and a cooling coil 73 is fixedly installed at the inner end of the connecting pipe bracket 72. The inner ends of the cooling coil 73 all penetrate the housing 9. By setting up the cooling mechanism 7, the equipment can generate cool air by starting the cooler 71 during use. The cool air connecting pipe bracket 72 and the cooling coil 73 deliver the air to the interior of the housing 9, thereby achieving a good cooling effect and enabling the solar grid to cool down quickly.

[0043] The working principle of this invention is as follows: During use, the first motor 44 is started, driving the lead screw 42 to drive the slider 43 to slide inside the drive guide rail 41. This assists in flexibly moving the two sets of support drive mechanisms 5 relative to each other, facilitating the adjustment of the spacing between the support drive mechanisms 5. This allows the device to flexibly position solar screens of different lengths, thus improving its adaptability. By setting the support drive mechanisms 5, during use, the solar screen can be placed on top of the receiving plate 541. At this time, the second motor 522 is started, driving the transmission gear 521 to rotate. Through the mutual transmission of the transmission gears 521, all drive shafts 53 can be rotated. The transmission gears 521 at the ends of the drive shaft 53 are spaced apart. Therefore, the transmission gears 521 on both sides of the three sets of transmission gears 521 are in the same direction. Thus, the drive shaft 53 with spaced transmission gears 521 is in a state of synchronous rotation, which causes the receiving plate 541 to rotate at a uniform speed. Through the uniform rotation of the receiving plate 541, the solar grid panel can be placed on the top receiving plate 541. At this time, the hot melt composite mechanism 6 is started for processing. After the solar grid panel is processed and hot melt composited, it can be conveyed downward with the rotation of the drive shaft 53. As the solar panel moves down, the top receiving plate 541 is in an idle state. At this time, the hot melt composite mechanism 6 can be started again for further processing. It can be seen that this equipment can achieve uninterrupted operation. The continuous automated processing, with its strong overall stability achieved through the gear, drive shaft 53, and receiving plate 541, enables stable hot-melt composite processing. The hot-melt composite mechanism 6 allows the device to be activated during use. The hydraulic rod 61 moves, causing the hot-melt pressure plate 63 to move downwards, allowing it to adhere to the solar grid. The electric heating coil 64 then assists in heating, thus achieving a good hot-melt processing function. Furthermore, if different specifications of solar grid panels need to be flexibly adapted, the handle 628 can be pulled to move the connecting shaft 627, causing the limit block 625 to retract against the limit spring 624, thus disengaging the limit block 625. By using the slot 626, the insert 622 can be quickly pulled out from the inside of the sleeve 621. Then, the corresponding specification hot-melt pressure plate 63 is taken out, and its top insert 622 is inserted upwards into the inside of the sleeve 621. The insert 622 abuts against the inclined surface of the limiting block 625, causing the inclined surface of the limiting block 625 to contract under pressure. When the limiting block 625 contacts the slot 626, the limiting spring 624 resets, allowing the limiting block 625 to be inserted into the slot 626. This facilitates the flexible disassembly and replacement of the hot-melt pressure plate 63, improving the adaptability of the equipment. By setting a cooling mechanism 7, the equipment can be operated by starting the cooling fan 71. The cooling fan 71 blows air through the connecting pipe rack 72 and the cooling coil 73 to the interior of the housing 9.This facilitates better cooling. During the uniform downward movement of the solar screen, cool air can be used to cool and dissipate heat from the hot-melt composite solar screen. When the solar screen reaches the bottom, it contacts the top of the conveyor belt 82, which then drives it forward. At this point, the solar screen moves to the top of the guide plate 83 and is further conveyed by the universal ball 84. This allows for rapid material unloading, resulting in high overall processing efficiency and convenient production.

[0044] It will be apparent to those skilled in the art that the present invention is not limited to the details of the exemplary embodiments described above, and that the invention can be implemented in other specific forms without departing from its spirit or essential characteristics. Therefore, the embodiments should be considered in all respects as exemplary and non-limiting, and the scope of the invention is defined by the appended claims rather than the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within the present invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0045] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A high-efficiency hot-melt composite processing equipment for solar screens, characterized in that, Includes a base (1), with a support shaft (2) fixedly installed at each of the four corners of the top of the base (1), a top seat (3) fixedly installed on the top of the support shaft (2), an adjustment mechanism (4) fixedly installed on the top of the top seat (3), a box (9) fixedly installed on the top of the top seat (3) outside the adjustment mechanism (4), a support drive mechanism (5) fixedly installed on both sides of the top of the adjustment mechanism (4), a hot melt composite mechanism (6) fixedly installed at the upper end of the box (9), a cooling mechanism (7) fixedly installed on the back of the box (9), and a conveying mechanism (8) fixedly installed at the bottom of the box (9). The hot melt composite mechanism (6) includes a hydraulic rod (61), which is fixedly installed in the middle of the top of the housing (9). The bottom output end of the hydraulic rod (61) passes through the housing (9) and is fixedly installed with a clamping assembly (62). A hot melt pressure plate (63) is fixedly installed at the bottom of the clamping assembly (62), and an electric heating coil (64) is installed on the top of the hot melt pressure plate (63). The adjustment mechanism (4) includes a drive rail (41), which is fixedly installed in the middle of the bottom of the top seat (3). A lead screw (42) is rotatably connected inside the drive rail (41). The two ends of the lead screw (42) have opposite thread directions. A first motor (44) is fixedly installed at one end of the drive rail (41). The output end of the first motor (44) passes through the drive rail (41) and is fixedly connected to one end of the lead screw (42). Both ends of the lead screw (42) are threadedly connected to sliders (43). The sliders (43) are slidably connected to the inner side of the drive rail (41). The top of the sliders (43) is fixedly connected to the bottom of the support drive mechanism (5). The support drive mechanism (5) includes a support frame (51), which is fixedly installed on the top of the slider (43). The front end of the support frame (51) is provided with a drive assembly (52), and the rear end of the drive assembly (52) is fixedly installed with drive shafts (53) at equal intervals. The outer surface of the drive shaft (53) is fixedly installed with receiving assemblies (54) at equal intervals. The drive assembly (52) includes a second motor (522) and transmission gears (521). The second motor (522) is fixedly installed in the middle of the front of the support frame (51). The transmission gears (521) are all rotatably connected to the rear end of the support frame (51). The transmission gears (521) are connected to each other for transmission. The output end of the second motor (522) is fixedly connected to the front end of the drive shaft (53) located in the middle.

2. The high-efficiency hot-melt composite processing equipment for solar screens according to claim 1, characterized in that, The mounting assembly (62) includes a sleeve (621), which is fixedly installed at the top output end of the hydraulic rod (61). A plug (622) is inserted into the inner side of the sleeve (621). The bottom of the plug (622) is fixedly connected to the top of the hot melt pressure plate (63). A concave frame (623) is fixedly installed on the front side of the sleeve (621). A limit spring (624) is fixedly installed on the inner side of the concave frame (623). A limit block (625) is fixedly installed at the rear end of the limit spring (624). A slot (626) is fixedly installed on the front side of the plug (622). The rear end of the limit block (625) is inserted into the inner side of the slot (626).

3. The high-efficiency hot-melt composite processing equipment for solar screens according to claim 2, characterized in that, The front of the limiting block (625) is fixedly installed with a connecting shaft (627), and the front end of the connecting shaft (627) is fixedly installed with a handle (628) through the concave frame (623). The limiting block (625) is inserted into the inner side of the slot (626). The side shape of the limiting block (625) is a right trapezoid, and the inclined surface of the limiting block (625) is set at the bottom front end.

4. The high-efficiency hot-melt composite processing equipment for solar screens according to claim 1, characterized in that, The conveying mechanism (8) includes a mounting frame (81), which is fixedly installed in the middle of the bottom of the body, and a conveyor belt (82) is rotatably connected between the inner sides of the mounting frame (81).

5. The high-efficiency hot-melt composite processing equipment for solar screens according to claim 4, characterized in that, Guide plates (83) are fixedly installed on both sides of the front of the top seat (3), and universal balls (84) are rotatably connected to the top of the guide plates (83) at equal intervals.

6. The high-efficiency hot-melt composite processing equipment for solar screens according to claim 1, characterized in that, The receiving assembly (54) includes a receiving plate (541), which is fixedly installed on the outer surface of the drive shaft (53) at equal intervals. Buffer springs (542) are fixedly installed at equal intervals on the inner top and outer bottom of the receiving plate (541), and buffer plates (543) are fixedly installed on the outer side of the buffer springs (542).

7. The high-efficiency hot-melt composite processing equipment for solar screens according to claim 6, characterized in that, The cooling mechanism (7) includes a cooler (71), which is fixedly installed in the middle of the back of the housing (9). A connecting pipe rack (72) is fixedly installed at the output end of the cooler (71), and a cooling coil (73) is fixedly installed at the inner end of the connecting pipe rack (72). The inner ends of the cooling coil (73) all penetrate the housing (9).