A UV curing machine assembly

By setting the substructure and transmission mechanism of the UV curing machine in a mirror-symmetric manner, it is possible to install two UV curing machines in a small space, which solves the problem of excessive equipment spacing and optimizes the equipment structure to reduce the floor space occupied.

CN118004692BActive Publication Date: 2026-07-14SUZHOU R H A C AUTOMATION TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
SUZHOU R H A C AUTOMATION TECH CO LTD
Filing Date
2024-03-07
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

The existing factory has limited space, making it impossible to install more than two UV curing machines at the same time, and the existing equipment has fixed dimensions, so the spacing cannot be reduced.

Method used

Design a UV curing machine combination device, wherein the substructure and transmission mechanism of the first UV curing machine and the second UV curing machine are arranged in a mirror symmetrical manner, and the transmission belt is also mirror symmetrical to reduce the distance between the equipment. The structure is optimized by means of water collection tank, material receiving mechanism, clamping mechanism, etc. to reduce the floor space.

Benefits of technology

It enables the installation of at least two UV curing machines in a confined space, reducing the equipment footprint and solving the problem of installing multiple UV curing machines in a confined space.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

Including first UV curing machine and second UV curing machine, first UV curing machine and second UV curing machine are arranged side by side, first UV curing furnace is provided with first conveying mechanism, first conveying mechanism includes first conveying belt, second UV curing furnace is provided with second conveying mechanism, second conveying mechanism includes second conveying belt, the structure of first UV curing machine and the structure of second UV curing machine are mirror image symmetry, first conveying belt and second conveying belt are not centrally arranged, because the structure of first UV curing machine and the structure of second UV curing machine are mirror image symmetry, so first conveying mechanism and second conveying mechanism are mirror image symmetry, that is, first conveying belt 114 and second conveying belt 24 are mirror image symmetry, with first conveying belt 114 and second conveying belt 24 to match the existing setting of factory, can reduce the interval between first UV curing machine and second UV curing machine, so as to solve the problem of reducing the interval between adjacent curing machine.
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Description

Technical Field

[0001] This invention relates to the field of solar cell manufacturing in the photovoltaic industry, and in particular to a UV curing machine assembly. Background Technology

[0002] Patent application number 2023118082363 describes an integrated UV curing machine that can be set up to work together as needed. However, existing factories or workshops have limited area and space, and often cannot install more than two UV curing machines at the same time or connect them to existing equipment. The dimensions of existing equipment are fixed, so the structure of the UV curing machine can only be improved according to the actual situation to reduce the floor space and space required.

[0003] To address the shortcomings of existing technologies, the problem to be solved is how to reduce the distance between two adjacent UV curing machines. Summary of the Invention

[0004] The purpose of this invention is to provide a UV curing machine combination device that solves the problem of installing two UV curing machines in a confined space.

[0005] To achieve the above objectives, the technical solution adopted by the present invention is as follows:

[0006] This invention provides a UV curing machine combination device, including a first UV curing machine and a second UV curing machine. The first UV curing machine includes a first UV curing oven, and the second UV curing machine includes a second UV curing oven. The first UV curing machine and the second UV curing machine are arranged side by side. The first UV curing oven is provided with a first transmission mechanism, which includes a first conveyor belt. The second UV curing oven is provided with a second transmission mechanism, which includes a second conveyor belt. The substructures of the first UV curing machine and the second UV curing machine are arranged in a mirror image symmetrical arrangement. The first transmission mechanism and the second transmission mechanism are arranged in a mirror image symmetrical arrangement. The first conveyor belt and the second conveyor belt are not centrally located.

[0007] Optionally, the second UV curing machine is provided with a water collection tank, the water collection tank including a water collection shell, a first water inlet pipe and a second water inlet pipe passing through the water collection shell, a first water outlet pipe provided on the first water inlet pipe, a second water outlet pipe provided on the second water inlet pipe, a first valve provided on the first water inlet pipe or the first water outlet pipe, and a second valve provided on the second water inlet pipe or the second water outlet pipe, both the first valve and the second valve being located inside the water collection shell.

[0008] Optionally, the second UV curing machine further includes a receiving mechanism, which includes a drive shaft, a driven shaft, and a support. The drive shaft and the driven shaft are rotatably mounted on the support. A first conveyor belt and a second conveyor belt are respectively fitted onto both ends of the drive shaft and both ends of the driven shaft. The first conveyor belt and the second conveyor belt are connected to each other.

[0009] Furthermore, the second UV curing machine also includes a storage mechanism, which is configured in conjunction with the receiving mechanism. The storage mechanism includes a linear module and a sliding plate. The sliding plate is slidably disposed on the linear module. A first side plate is disposed on the sliding plate. A top plate and a bottom plate are respectively disposed at the upper and lower ends of the first side plate. A second side plate is disposed between the top plate and the bottom plate. The first side plate and the second side plate are spaced apart. A first support column is disposed on the first side plate. A second support column is disposed on the second side plate. The first support column and the second support column are disposed opposite to each other.

[0010] Furthermore, the receiving mechanism is provided with a clamping mechanism, which includes a servo motor and a driven rod. A support belt is sleeved on the servo motor and the driven rod. A first support plate and a second support plate are respectively provided on both sides of the support belt. The first support plate and the second support plate are close to each other or far apart from each other.

[0011] Furthermore, a first horizontal plate is provided on the first support plate, a second horizontal plate is provided on the second support plate, a plurality of first rollers are provided on the first horizontal plate, a plurality of second rollers are provided on the second support plate, a first clamping strap is sleeved on the plurality of first rollers, and a second clamping strap is sleeved on the plurality of second rollers.

[0012] Due to the application of the above technical solution, the present invention has the following advantages compared with the prior art:

[0013] The present invention provides a UV curing machine assembly. Since the substructures of the first UV curing machine and the second UV curing machine are mirror-symmetrically arranged, the first and second transmission mechanisms are also mirror-symmetrically arranged, that is, the first and second transmission belts are mirror-symmetrically arranged. By using the first and second transmission belts to match the existing equipment in the factory, the distance between the first and second UV curing machines can be reduced, and the floor space occupied by the two UV curing machines is reduced. At least two UV curing machines can be installed in a small space, thus solving the problem of installing two UV curing machines in a small space. Attached Figure Description

[0014] The following sections will describe some specific embodiments of the invention in detail by way of example and not limitation, with reference to the accompanying drawings. The same reference numerals in the drawings denote the same or similar parts or portions. Those skilled in the art should understand that these drawings are not necessarily drawn to scale. In the drawings:

[0015] Figure 1 This is a perspective view of a UV curing machine assembly according to an embodiment of the present invention;

[0016] Figure 2 yes Figure 1 The second UV curing machine is shown in a three-dimensional view.

[0017] Figure 3 yes Figure 2 Left view of the water collection tank shown;

[0018] Figure 4 yes Figure 2 Right view of the water collection tank shown;

[0019] Figure 5 This is a left view of the second UV curing oven;

[0020] Figure 6 This is a right view of the second UV curing oven;

[0021] Figure 7 yes Figure 6 Enlarged view of point A in the middle;

[0022] Figure 8 yes Figure 6 Enlarged view at point B in the middle;

[0023] Figure 9 yes Figure 6 The front view;

[0024] Figure 10 yes Figure 9 Enlarged view at point C;

[0025] Figure 11 yes Figure 6 Side view;

[0026] Figure 12 This is an enlarged view of the receiving and storage mechanisms;

[0027] Figure 13 This is an enlarged view of the clamping mechanism;

[0028] Figure 14 This is a diagram of the internal structure of the clamping mechanism;

[0029] Figure 15 yes Figure 13 Enlarged view of part D shown;

[0030] Figure 16It is a 3D diagram of the storage mechanism;

[0031] Figure 17 It is a 3D diagram of the transmission mechanism;

[0032] Figure 18 yes Figure 17 The left view shown;

[0033] Figure 19 yes Figure 18 Enlarged view of part E shown.

[0034] The reference numerals in the attached figures are explained as follows:

[0035] 2. Second transmission mechanism; 3. Support block; 4. Cooling box; 5. Receiving mechanism; 6. Cooling pipe; 7. Storage mechanism; 8. Clamping mechanism; 9. Slide rail; 10. Slider; 11. Lower cover; 12. UV irradiation lamp; 13. Upper cover; 14. Conveying channel; 15. Upright pole; 16. Suction hood; 17. Frame; 18. Adjusting screw; 20. Photovoltaic cell; 21. Motor; 22. Drive wheel; 23. Driven wheel; 24. Second transmission belt; 25. First adjusting frame; 26. Second adjusting frame; 27. First adjusting wheel; 28. Second adjusting wheel; 30. Groove; 33. Third clamping plate; 34. Fourth clamping plate; 35. First limiting hole 36. Second limiting hole; 40. Support frame; 41. First correction wheel; 42. Second correction wheel; 43. First limiting wheel; 44. Second limiting wheel; 45. First clamping plate; 46. Second clamping plate; 47. First hook; 48. Second hook; 49. First spring; 50. Second spring; 51. Drive shaft; 52. Driven shaft; 53. Bracket; 55. First conveyor belt; 56. Second conveyor belt; 59. Position sensor; 60. Cooling hole; 70. Second pad; 71. Linear module; 72. Slide plate; 73. First side plate; 74. Second side plate; 75. Top plate; 76. Bottom plate; 77. First support column; 78. Second 79. Support column; 81. First pad block; 82. Servo motor; 83. Driven rod; 84. Support belt; 85. Second clamping belt; 86. First support plate; 87. Second support plate; 88. First horizontal plate; 89. First clamping belt; 100. First UV curing machine; 110. First UV curing oven; 120. First transmission mechanism; 124. First transmission belt; 200. Second UV curing machine; 210. Second UV curing oven; 121. Fixing hole; 131. Air outlet; 151. Elongated hole; 161. Air inlet; 162. Collecting exhaust port; 250. Buffer layer; 300. Water collection tank; 310. Water collection shell; 3 20. Pipeline; 330. Control valve; 311. Outlet; 312. Opening; 313. First support plate; 314. Second support plate; 315. Water guide pipe; 321. First water pipe; 322. Second water pipe; 323. First clamp; 324. Second clamp; 331. First valve; 332. Second valve; 333. First outlet pipe; 334. Second outlet pipe; 751. First top hole; 752. Second top hole; 753. Third top hole; 754. Fourth top hole; 761. First bottom hole; 762. Second bottom hole; 763. Third bottom hole; 764. Fourth bottom hole; 891. Second roller; 842. Second roller. Detailed Implementation

[0036] The technical solution of the present invention will now be clearly and completely described with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of the present invention. 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.

[0037] In the description of this invention, it should be noted that the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are used only for the convenience of describing the invention and for simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on the invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.

[0038] Furthermore, the technical features involved in the different embodiments of the present invention described below can be combined with each other as long as they do not conflict with each other.

[0039] like Figure 1 and Figure 2 As shown, it includes a first UV curing machine 100 and a second UV curing machine 200, which are arranged side by side. The first UV curing machine 100 includes a first UV curing oven 110, and the second UV curing machine 200 includes a second UV curing oven 210. The first UV curing oven 110 is provided with a first transmission mechanism 120, which includes a first transmission belt 124. The second UV curing oven 210 is provided with a second transmission mechanism 2, which includes a second transmission belt 24.

[0040] The substructure of the first UV curing machine 100 is mirror-symmetrically arranged with the substructure of the second UV curing machine 200. The first transmission mechanism 120 is mirror-symmetrically arranged with the second transmission mechanism 200. Therefore, the first transmission belt 124 and the second transmission belt 24 are mirror-symmetrically arranged. The first transmission belt 124 and the second transmission belt 24 are used to connect the two machines in the factory. Usually, the two machines are very close to each other, so the first transmission belt 124 and the second transmission belt 24 also need to be close to each other. The key is the connection between the first transmission belt 114 and the second transmission belt 24. The first transmission belt 114 and the second transmission belt 24 are not centered. That is, the first transmission belt 114 is located at the edge of the first UV curing machine 100, and the second transmission belt 24 is located at the edge of the second UV curing machine 200. This makes the overall footprint of the first UV curing machine 100 and the second UV curing machine 200 small and requires less space.

[0041] like Figure 3 and Figure 4 As shown, both the first UV curing machine 100 and the second UV curing machine 200 are equipped with a water collection tank 300. In this example, the water collection tank 300 in the second UV curing machine 200 is taken as an example. The water collection tank 300 includes a water collection shell 310. A first water inlet pipe 321 and a second water inlet pipe 322 are installed on the water collection shell 310. A water outlet hole 311 is provided at the bottom of the water collection shell 310. The water collection shell 310 is an insulator. The first water inlet pipe 321 and the second water inlet pipe 322 are located above the water outlet hole 311. The water outlet hole 311 is lower than the surrounding area. Liquid in the water collection shell 310 is discharged from the water outlet hole 311.

[0042] A first water inlet pipe 321 is provided with a first water outlet pipe 333, and a second water inlet pipe 322 is provided with a second water outlet pipe 334. The first water inlet pipe 321 and the second water inlet pipe 322 are staggered vertically. A first valve 331 is provided on the first water inlet pipe 321 or the first water outlet pipe 333. A second valve 332 is provided on the second water inlet pipe 322 or the second water outlet pipe 334.

[0043] Since the water collection tank in this example is used in conjunction with the UV curing machine and is located at the bottom of the UV curing machine, and the UV curing machine is equipped with a cover, the water collection tank is also located inside the cover. One side panel of the cover is attached to the observation window 312. The one side panel of the cover is equivalent to the door at the observation window 312. Under normal use, the cover is a whole. If the water collection tank needs maintenance or inspection, the one side panel of the cover is removed.

[0044] The first valve 331 and the second valve 332 are offset to the left and right. Both the first valve 331 and the second valve 332 are located inside the water collection shell 310. In this way, the liquid seeping out at the connection between the first valve 331 and the first water inlet pipe 321 falls into the water collection shell 310, and the liquid seeping out at the connection between the second valve 332 and the second water inlet pipe 322 also falls into the water collection shell 310. Then the seeping liquid is discharged from the water outlet 311 inside the water collection shell 310. The bottom of the water collection shell 310 is grooved.

[0045] The height of the first water inlet pipe 321 is lower than the height of the second water inlet pipe 322. An observation window 312 is provided on the water collection shell 310. The first water inlet pipe 321 is close to the observation window 312. In this example, the first water inlet pipe 321 and the second water inlet pipe 322 are parallel when they enter the water collection shell 310. Inside the water collection shell 310, the first water inlet pipe 321 bends downward and then extends in a straight line. The height of the first water inlet pipe 321 is different from that of the second water inlet pipe 322, which facilitates inspection or maintenance through the observation window 312. A protective plate 316 is provided at the bottom of the observation window 312. The area enclosed by the protective plate 316 and the water collection shell 310 is a water trough. The water guide pipe 315 is located inside the water trough.

[0046] Multiple first water outlet pipes 333 are provided on the first water inlet pipe 321. A first valve 331 is provided on the first water outlet pipe 333. The multiple first valves 331 are evenly distributed, so the multiple first water outlet pipes 333 are also evenly distributed. Multiple second water outlet pipes 334 are provided on the second water inlet pipe 322. A second valve 332 is provided on the second water outlet pipe 334. The multiple second valves 332 are evenly distributed, and the multiple second water outlet pipes 334 are also evenly distributed. The multiple first water outlet pipes 333 and the multiple second water outlet pipes 334 are staggered in the vertical direction to ensure that each first water outlet pipe 333 and each second water outlet pipe 334 can be observed from the observation window 312. Both the first water outlet pipes 333 and the second water outlet pipes 334 extend upward through the water collection shell 310.

[0047] The water collection shell 310 is provided with a first support plate 313 and a second support plate 314. The first water inlet pipe 321 is set on the first support plate 313 and the second water inlet pipe 322 is set on the second support plate 314. The first support plate 313 supports the first water inlet pipe 321 and the second support plate 314 supports the second water inlet pipe 322, so as to prevent the first water inlet pipe 321 and the second water inlet pipe 322 from bending and reducing the liquid flow rate.

[0048] The first water inlet pipe 321 is fitted with a first clamp 323, which is fastened to the first support plate 313. The second water inlet pipe 322 is fitted with a second clamp 324, which is fastened to the second support plate 314. The number of first clamps 323 and second clamps 324 is unlimited. The first clamp 323 prevents the first water inlet pipe 321 from shaking, and the second clamp 324 prevents the second water inlet pipe 322 from shaking.

[0049] A water guide pipe 315 is provided inside the water outlet 311. The water guide pipe 315 extends to the outside of the cover. In this example, the water guide pipe 315 is straight, but it can also be set to be curved.

[0050] The observation window 312 faces the extension direction of the first water inlet pipe 321 and the second water inlet pipe 322. That is, the extension direction of the first water inlet pipe 321 and the second water inlet pipe 322 does not pass through the observation window 312, which makes it convenient for the operator to view the first water inlet pipe 321 and the second water inlet pipe 322 from the observation window 312. In other words, there is no obstruction when viewing the first water inlet pipe 321 and the second water inlet pipe 322 from the observation window 312.

[0051] like Figure 5 As shown, the second UV curing oven 210 includes a lower cover 11, a UV irradiation lamp 12 and an upper cover 13, and the second transmission mechanism 2 includes a motor 21, a drive wheel 22 and a driven wheel 23.

[0052] The UV lamp 12 is connected to the lower cover 11, and the upper cover 13 is adjustable. When the upper cover 13 is raised, the distance between the upper cover 13 and the lower cover 11 increases, which facilitates the maintenance of the UV lamp 12.

[0053] The lower cover 11 is provided with a material conveying channel 14, and the UV irradiation lamp 12 is located above the material conveying channel 14. The UV irradiation lamp 12 is used to irradiate the product on the material conveying channel 14.

[0054] A cooling box 4 is provided on the rotation path of the second conveyor belt 24. The second conveyor belt 24 passes through the cooling box 4. Inside the cooling box 4, both the second conveyor belt 24 and the photovoltaic cell 20 are cooled.

[0055] like Figure 6 As shown, several uprights 15 are provided on the edge of the lower cover 11. The uprights 15 are used to connect the UV irradiation lamps 12. The drive end of the motor 21 is connected to the drive wheel 22 via a chain. The drive wheel 22 and the driven wheel 23 are fitted onto the second conveyor belt 24. The material conveying channel 14 is located on the conveying path of the second conveyor belt 24. Photovoltaic cells 20 are placed on the second conveyor belt 24. Then, the photovoltaic cells 20 on the second conveyor belt 24 are irradiated by the UV irradiation lamps 12. The UV irradiation lamps 12 generate heat during the irradiation process. There is a gap between the lower cover 11 and the upper cover 13 for gas circulation. In this way, the hot gas generated by the UV irradiation lamps 12 during the irradiation process is automatically dispersed, thus achieving heat dissipation.

[0056] like Figure 7 As shown, Figure 3 yes Figure 2 As shown in the enlarged view of part A, each upright 15 has two parallel, vertically extending elongated holes 151.

[0057] like Figure 8As shown, the top of the upright 15 extends inward to form an extension 152. An adjusting screw 18 is rotatably installed in the extension 152. The adjusting screw 18 extends vertically downward and is threadedly connected to the UV lamp 12. The adjusting screw 18 has a bolt head at the top. By turning the bolt head, the adjusting screw 18 can be rotated, thereby fine-tuning the height of the UV lamp 12. After fine-tuning, the UV lamp 12 is tightened back into the elongated hole 151. Due to the lifting effect of the adjusting screw 18 on the UV lamp 12, the UV lamp 12 will not fall during the adjustment process, and no additional parts are needed to support the UV lamp 12.

[0058] like Figure 9 As shown, Figure 9 yes Figure 8 The enlarged view at point C shows that the UV lamp 12 has a fixing hole 121. The UV lamp 12 can be secured by passing a bolt through the elongated hole 151 and screwing it into the fixing hole 121. Moreover, the height of the UV lamp 12 can be adjusted within the length of the elongated hole 151. Only one elongated hole 151 needs to be provided in a single pole 15, but providing two elongated holes 151 is beneficial for stabilizing the UV lamp 12.

[0059] like Figure 6 The top of the upper cover 13 is provided with three suction hoods 16, and each suction hood 16 has four air inlets 161 on its side. The top of the upper cover 13 also has four air outlets 131 corresponding to each suction hood 16, which are connected to the inside of the upper cover 13. The air outlets 131 and the air inlets 161 are connected by a connecting pipe (not shown in the figure). The top of the suction hoods 16 is provided with a combined exhaust port 162. Connecting the combined exhaust port 162 to a negative pressure pipe allows for the extraction of hot air generated inside the upper cover 13 during operation. The three suction hoods 16 are distributed along the length of the upper cover 13, thereby improving extraction efficiency. In other embodiments, the number of suction hoods 16 is not particularly limited.

[0060] like Figure 6 and Figure 11 The second UV curing oven 210 also includes a stand 17, on which a vertically extending slide rail 9 is provided. A slider 10 is provided on the rear side of the upper cover 3. The slider 10 is slidably connected to the slide rail 9, so the upper cover 13 can be raised and lowered on the stand 17. This example also includes a lifting drive component not shown in the figure. The lifting drive component is a cylinder. The drive end of the cylinder is connected to the upper cover 13, and the cylinder can drive the upper cover 13 to rise and fall.

[0061] like Figure 12As shown, a receiving mechanism 5 is provided on the outside of the second transmission mechanism 2. The receiving mechanism 5 includes a drive shaft 51, a driven shaft 52 and a bracket 53. The drive shaft 51 and the driven shaft 52 are rotatably mounted on the bracket 53. The drive shaft 51 is connected to the drive end of the driver via a belt. The driver is not shown in the figure. The drive end rotates the drive shaft 51 via a belt. The bracket 53 is attached to the second transmission mechanism 2.

[0062] A first conveyor belt 55 and a second conveyor belt 56 are respectively mounted on both ends of the drive shaft 51 and the driven shaft 52. The first conveyor belt 55 and the second conveyor belt 56 are connected to the second conveyor belt 24. The photovoltaic cells 20 coming from the second conveyor belt 24 are moved to the first conveyor belt 55 and the second conveyor belt 56. The second conveyor belt 24 rotates cyclically between the drive wheel 22 and the driven wheel 23. The upper half of the second conveyor belt 24 is used to place the photovoltaic cells 20.

[0063] The number of receiving mechanisms 5 is unlimited. In this example, multiple receiving mechanisms 5 are provided. The photovoltaic cells 20 can dissipate heat on the receiving mechanism 5. Multiple receiving mechanisms 5 are set on the flow path of the receiving mechanism 5.

[0064] A storage mechanism 7 is provided in conjunction with the receiving mechanism 5. The storage mechanism 7 and the clamping mechanism 8 are respectively provided on the adjacent receiving mechanism 5. The storage mechanism 7 includes a linear module 71 and a sliding plate 72. The sliding plate 72 is slidably provided on the linear module 71. A first side plate 73 is provided on the sliding plate 72. The first side plate 73 is arranged in parallel with the linear module 71. A top plate 75 and a bottom plate 76 are respectively provided at the upper and lower ends of the first side plate 73. A second side plate 74 is provided between the top plate 75 and the bottom plate 76. The first side plate 73 and the second side plate 74 are spaced apart and are arranged opposite to each other. The space between the first side plate 73 and the second side plate 74 accommodates the cured photovoltaic cell 20. The distance between the first side plate 73 and the second side plate 74 is adjustable.

[0065] A first support column 77 is provided on the first side plate 73, and a second support column 78 is provided on the second side plate 74. The first support column 77 and the second support column 78 are arranged opposite to each other. The first support column 77 and the second support column 78 are used to support the cured photovoltaic cell 20 in the same direction. The width of the photovoltaic cell 20 is more than the distance between the first conveyor belt 55 and the second conveyor belt 56. That is, both ends of the photovoltaic cell 20 extend to the outside of the first conveyor belt 55 and the second conveyor belt 56, respectively. At the same time, the first support column 77 is flush with the first conveyor belt 55, and the second support column 78 is flush with the second conveyor belt 56.

[0066] like Figure 13 and Figure 14As shown, the receiving mechanism 5 is equipped with a clamping mechanism 8, which includes a servo motor 81 and a driven rod 82. A support belt 83 is sleeved on the drive end of the servo motor 81 and the driven rod 82. A first support plate 85 and a second support plate 86 are respectively provided on both sides of the support belt 83. The servo motor 81 drives the support belt 83 to rotate back and forth. The moving length of the support belt 83 is limited, and the corresponding first support plate 85 and second support plate 86 move back and forth, so that the first support plate 85 and the second support plate 86 move closer to each other or further away from each other.

[0067] A first horizontal plate 87 is provided on the first support plate 85, and a second horizontal plate 88 is provided on the second support plate 86. Multiple first rollers 89 are provided on the first horizontal plate 87, and multiple second rollers 84 are provided on the second support plate 86. A first clamping belt 891 is fitted on the multiple first rollers 89, and a second clamping belt 842 is fitted on the multiple second rollers 84. The photovoltaic cell 20 is placed on the first conveyor belt 55 and the second conveyor belt 56. The photovoltaic cell 20 may tilt while entering the storage mechanism 7. The first conveyor belt 55 and the second conveyor belt 56 are located between the first clamping belt 891 and the second clamping belt 842, so the first clamping belt 891 and the second clamping belt 842 can be adjusted to jointly clamp the tilted photovoltaic cell 20. The first clamping belt 891 and the second clamping belt 842 correct the tilted photovoltaic cell 20.

[0068] Meanwhile, the first clamping belt 891 can rotate on the first roller 89, and the second clamping belt 842 can rotate on the second roller 84, so the photovoltaic cell 20 rolls and rubs against the first roller 89 and the second clamping belt 842.

[0069] A position sensor 59 is provided between the first conveyor belt 55 and the second conveyor belt 56. When the photovoltaic cell 20 reaches the set position, the position sensor 59 is signal-connected to the linear module 71. The position sensor 59 sends a signal to the linear module 71, and the linear module 71 drives the slide plate 72 to move upward. In this way, the storage mechanism 7 completes one storage operation when the photovoltaic cell 20 is located between the first side plate 73 and the second side plate 74.

[0070] Furthermore, two or more first pillars 77 can be set at the same height, and two or more second pillars 78 can be set at the same height. In the vertical direction, multiple first pillars 77 and second pillars 78 can be set symmetrically. Two adjacent first pillars 77 and two second pillars 78 in the vertical direction are used to accommodate photovoltaic cells 20. The first pillars 77 and the second pillars 78 can be cylinders or flat plates.

[0071] like Figure 15As shown, two support blocks 3 are arranged between the drive shaft 51 and the driven shaft 52, with the two support blocks 3 spaced apart. The support blocks 3 are provided with grooves 30, which extend to the outer edges of both ends of the support blocks 3. The first conveyor belt 55 and the second conveyor belt 56 are located on the corresponding grooves 30. Because the photovoltaic cell 20 has weight, the middle part of the first conveyor belt 55 and the second conveyor belt 56 may bend downwards. In this way, the lowered part of the first conveyor belt 55 and the second conveyor belt 56 falls into the groove 30. However, the first conveyor belt 55 and the second conveyor belt 56 do not contact the bottom wall of the groove 30. When the first conveyor belt 55 and the second conveyor belt 56 sink, the photovoltaic cell 20 will not fall onto the support block 3, that is, it will not fall onto the top of the two side walls of the groove 30.

[0072] like Figure 16 As shown, the top plate 75 is provided with a first top hole 751, a second top hole 752, a third top hole 753 and a fourth top hole 754, and the bottom plate 76 is provided with a first bottom hole 761, a second bottom hole 762, a third bottom hole 763 and a fourth bottom hole 764. The first side plate 73 is movably disposed in the first top hole 751, the second top hole 752, the first bottom hole 761 and the second bottom hole 762, and the second side plate 74 is movably disposed in the third top hole 753, the fourth top hole 754, the third bottom hole 763 and the fourth bottom hole 764. The first side plate 73 and the second side plate 74 can move closer to each other or move further away from each other.

[0073] The first top hole 751, the second top hole 752, the third top hole 753 and the fourth top hole 754 are all oblong holes, or they can be rectangular holes. The first bottom hole 761, the second bottom hole 762, the third bottom hole 763 and the fourth bottom hole 764 are all oblong holes, or they can be rectangular holes.

[0074] At least two first pillars 77 and two second pillars 78 are provided in the horizontal direction. That is, at least two first pillars 77 and two second pillars 78 are provided in the horizontal direction. In this way, the photovoltaic cell 20 can remain stable when placed on two first pillars 77 and two second pillars 78. The first pillars 77 and two pillars 78 are preferably cylindrical, so that the contact area between the photovoltaic cell 20 and the cylinder is small and the photovoltaic cell 20 dissipates heat quickly. The first pillars 77 and two pillars 78 can also be cubic, so that the contact area between the first pillars 77 and the second pillars 78 and the photovoltaic cell 20 is large, but the stability is even better.

[0075] Multiple first pillars 77 and second pillars 78 are evenly spaced in the vertical direction. When the first pillars 77 and second pillars 78 of the upper layer support the photovoltaic cell 20, the linear module 71 drives the slide plate to move upward. Then, the first pillars 77 and second pillars 78 of the second layer are aligned with the first conveyor belt 55 and the second conveyor belt 56 respectively, waiting for the next photovoltaic cell 20 to arrive at the set position.

[0076] A position sensor 59 is provided between the first conveyor belt 55 and the second conveyor belt 56. When the photovoltaic cell 20 reaches the set position, the position sensor 59 is signal-connected to the linear module 71.

[0077] The bottom of the base plate 76 is symmetrically provided with a first pad 79 and a second pad 70. The first pad 79 and the second pad 70 are spaced apart. The first pad 79 and the second pad 70 mainly play a buffering role. During the descent or transportation process, the base plate 76 always touches the ground first. If photovoltaic cells 20 are placed on the first support column 77 and the second support column 78, then the first pad 79 and the second pad 70 can reduce the vibration of the photovoltaic cells 20 and prevent some of the photovoltaic cells 20 from slipping off.

[0078] The top plate 75 is provided with a first fixing groove 755, and the bottom plate 76 is provided with a second fixing groove 756. The first fixing groove 755 and the second fixing groove 756 are arranged opposite to each other. The first side plate 73 and the second side plate 74 are arranged at a distance from each other in the first fixing groove 755 and the second fixing groove 756. The first side plate 73 is movable in the first fixing groove 755 and the second fixing groove 756, and the second side plate 74 is movable in the first fixing groove 755 and the second fixing groove 756.

[0079] The first top hole 751, the second top hole 752, the third top hole 753, and the fourth top hole 754 are all located in the first fixing groove 755, and the first bottom hole 761, the second bottom hole 762, the third bottom hole 763, and the fourth bottom hole 764 are all located in the second fixing groove 756. The extending direction of the first fixing groove 755 is the same as the extending direction of the first top hole 751, the second top hole 752, the third top hole 753, and the fourth top hole 754, and the extending direction of the second fixing groove 756 is the same as the extending direction of the first bottom hole 761, the second bottom hole 762, the third bottom hole 763, and the fourth bottom hole 764.

[0080] like Figure 17 and Figure 18 and Figure 19 As shown, a cooling pipe 6 is provided on the second transmission mechanism 2, and a cooling hole 60 is provided on the cooling pipe 6. The cooling hole 60 is aligned with the second transmission belt 24. High-pressure gas is passed through the cooling pipe 6. Because the second transmission belt 24 is also heated when the photovoltaic cell 20 is cured, and the second transmission belt 24 is continuously at a high temperature during the cyclic rotation, high-pressure gas is blown out of the cooling pipe 6 and blown to the second transmission belt 24 through the cooling hole 60 to further cool the second transmission belt 24.

[0081] A buffer layer 250 is provided on the outer layer of the second conveyor belt 24. The buffer layer 250 is attached to the outer surface of the second conveyor belt 24, and the photovoltaic cell 20 will be elastic when the buffer layer 250 is subjected to external force.

[0082] High-pressure gas is circulated inside the cooling pipe 6 because the second conveyor belt 24 is also heated during the curing of the photovoltaic cell 20. The second conveyor belt 24 is continuously at a high temperature during the cyclic rotation process. Therefore, high-pressure gas is circulated through the cooling pipe 6 and blown to the second conveyor belt 24 through the cooling hole 60 to further cool the second conveyor belt 24.

[0083] The second conveyor belt 24 has a first adjusting frame 25 and a second adjusting frame 26 arranged on its rotation path. The first adjusting frame 25 and the second adjusting frame 26 are spaced apart, meaning the distance between them is adjustable. The driving wheel 22 and the driven wheel 23 are respectively above the first adjusting frame 25 and the second adjusting frame 26. When the second conveyor belt 24 is used for a long time at high temperatures, it becomes loose on the driving wheel 22 and the driven wheel 23.

[0084] The first adjusting frame 25 is rotatably equipped with a first adjusting wheel 27, and the second adjusting frame 26 is rotatably equipped with a second adjusting wheel 28. The second conveyor belt 24 is fitted onto the first adjusting wheel 27 and the second adjusting wheel 28, so that the second conveyor belt 24 can maintain the set slack and return to its original state when cooling down.

[0085] A support frame 40 is provided between the first adjusting frame 25 and the second adjusting frame 26. The rotation path of the second conveyor belt 24 is located on the upper part of the support frame 40. The first adjusting frame 25 and the second adjusting frame 26 cannot be too far apart or too close together. When the temperature of the second conveyor belt 24 is too high, the second conveyor belt 24 between the first adjusting wheel 27 and the second adjusting wheel 28 will sag, and the sagning second conveyor belt 24 will fall onto the support frame 40.

[0086] The support frame 40 is provided with a first correction wheel 41 and a second correction wheel 42 on both sides. The rotation path of the second transmission belt 24 is located between the first correction wheel 41 and the second correction wheel 42. That is, the second transmission belt 24 is located between the first correction wheel 41 and the second correction wheel 42. The second transmission belt 24 will move its position during rotation. The first correction wheel 41 and the second correction wheel 42 are both rotatable. Therefore, the displaced second transmission belt 24 rolls and rubs against the first correction wheel 41 and the second correction wheel 42. The position of the second transmission belt 24 is corrected by the first correction wheel 41 and the second correction wheel 42.

[0087] Furthermore, the first correction wheel 41 and the second correction wheel 42 are symmetrically arranged, and multiple first correction wheels 41 and multiple second correction wheels 42 can be symmetrically arranged, so that the correction effect of the second conveyor belt 24 is better.

[0088] A first limiting wheel 43 is provided between the first adjusting frame 25 and the driving wheel 22. A first clamping plate 45 and a second clamping plate 46 are respectively provided at both ends of the first limiting wheel 43. The first clamping plate 45 and the second clamping plate 46 are hinged together and overlapped on the curing machine (not shown in the curing machine diagram). The second conveyor belt 24 is wound around the first limiting wheel 43. When the first clamping plate 45 and the second clamping plate 46 are rotated, the first limiting wheel 43 can press against the second conveyor belt 24, or the first limiting wheel 43 can move away from the second conveyor belt 24. The first limiting wheel 43 is adjusted according to the slack of the second conveyor belt 24.

[0089] The first limiting wheel 43 is provided with a first hook 47, and the first hook 47 is provided with a first spring 49. The second clamping plate 46 is provided with a second hook 48, and the second hook 48 is provided with a second spring 50. The first spring 49 and the second spring 50 are arranged side by side and symmetrically. The first spring 49 and the second spring 50 are used to engage with the curing machine, so that the first limiting wheel 43 can be freely adjusted according to the slack of the second conveyor belt 24.

[0090] A second limiting wheel 44 is provided between the second adjusting frame 26 and the driven wheel 23. A third clamping plate 33 and a fourth clamping plate 34 are respectively provided at both ends of the second limiting wheel 44. The third clamping plate 33 and the fourth clamping plate 34 are movably set on the curing machine. The second conveyor belt 24 is wound around the second limiting wheel 44. The positions of the third clamping plate 33 and the fourth clamping plate 34 are adjusted according to the slack of the second conveyor belt 24 so that the second conveyor belt 24 maintains the set slack.

[0091] The third clamping plate 33 is provided with a plurality of first limiting holes 35, and the fourth clamping plate 34 is provided with a plurality of second limiting holes 36. The first limiting holes 35 and the second limiting holes 36 are symmetrically arranged. The centers of the plurality of first limiting holes 35 are on a straight line, and the centers of the plurality of second limiting holes 36 are also on a straight line. The first limiting holes 35 and the second limiting holes 36 to be fixed are determined according to the slack of the second conveyor belt 24.

[0092] The above embodiments are only for illustrating the technical concept and features of the present invention. Their purpose is to enable those skilled in the art to understand the content of the present invention and implement it accordingly. They should not be used to limit the scope of protection of the present invention. All equivalent changes or modifications made in accordance with the spirit and essence of the present invention should be covered within the scope of protection of the present invention.

Claims

1. A UV curing machine assembly, comprising a first UV curing machine (100) and a second UV curing machine (200), wherein the first UV curing machine (100) includes a first UV curing oven (110), and the second UV curing machine (200) includes a second UV curing oven (210), wherein the first UV curing machine (100) and the second UV curing machine (200) are arranged side by side, characterized in that, The first UV curing oven (110) is provided with a first transmission mechanism (120), the first transmission mechanism (120) includes a first transmission belt (114), the second UV curing oven (210) is provided with a second transmission mechanism (2), the second transmission mechanism (2) includes a second transmission belt (24), the substructure of the first UV curing machine (100) and the substructure of the second UV curing machine (200) are mirror-symmetrically arranged, the first transmission mechanism (120) and the second transmission mechanism (2) are mirror-symmetrically arranged, and the first transmission belt (114) and the second transmission belt (24) are not centered; The second UV curing machine (200) is provided with a water collection tank (300), which includes a water collection shell (310). A first water inlet pipe (321) and a second water inlet pipe (322) are provided on the water collection shell (310). A first water outlet pipe (333) is provided on the first water inlet pipe (321), and a second water outlet pipe (334) is provided on the second water inlet pipe (322). A first valve (331) is provided on the first water inlet pipe (321) or the first water outlet pipe (333), and a second valve (332) is provided on the second water inlet pipe (322) or the second water outlet pipe (334). The first valve (331) and the second valve (332) are both located inside the water collection shell (310). The second UV curing machine (200) also includes a receiving mechanism (5), which includes a drive shaft (51), a driven shaft (52) and a bracket (53). The drive shaft (51) and the driven shaft (52) are rotatably mounted on the bracket (53). A first conveyor belt (55) and a second conveyor belt (56) are respectively sleeved on both ends of the drive shaft (51) and the driven shaft (52). The first conveyor belt (55) and the second conveyor belt (56) are connected to the transmission belt (24). The second UV curing machine (200) also includes a storage mechanism (7), which is configured in conjunction with the receiving mechanism (5). The storage mechanism (7) includes a linear module (71) and a sliding plate (72). The sliding plate (72) is slidably disposed on the linear module (71). A first side plate (73) is disposed on the sliding plate (72). A top plate (75) and a bottom plate (76) are respectively disposed at the upper and lower ends of the first side plate (73). A second side plate (74) is disposed between the top plate (75) and the bottom plate (76). The first side plate (73) and the second side plate (74) are spaced apart. A first support column (77) is disposed on the first side plate (73). A second support column (78) is disposed on the second side plate (74). The first support column (77) and the second support column (78) are disposed opposite to each other.

2. The UV curing machine assembly according to claim 1, characterized in that, The receiving mechanism (5) is provided with a clamping mechanism (8), which includes a servo motor (81) and a driven rod (82). A support belt (83) is sleeved on the servo motor (81) and the driven rod (82). A first support plate (85) and a second support plate (86) are respectively provided on both sides of the support belt (83). The first support plate (85) and the second support plate (86) are close to each other or far away from each other.

3. The UV curing machine assembly according to claim 2, characterized in that, The first support plate (85) is provided with a first horizontal plate (87), the second support plate (86) is provided with a second horizontal plate (88), the first horizontal plate (87) is provided with a plurality of first rollers (89), the second support plate (86) is provided with a plurality of second rollers (84), the plurality of first rollers (89) are fitted with a first clamping strap (891), and the plurality of second rollers (84) are fitted with a second clamping strap (842).