Full-automatic silicon oil spraying device for infusion bottle gasket

Abstract

The utility model relates to the technical field of medical supplies, in particular to infusion bottle gasket full -automatic silicon oil device of spraying, and it is even to the infusion bottle gasket and is sprayed silicon oil to the upper and lower surface automatic uniform of turning over, improves the effect of siliconization, including first conveying belt and second conveying belt, still including slide one, pivot, two supporting plates, spray plate one and spray plate two, the input of second conveying belt is located below the output of first conveying belt, the input of slide one is overlapped with the output of first conveying belt, the output of slide one is downwardly inclined, pivot rotates and installs cover box, two supporting plates are oppositely installed to the outer wall both sides of pivot, two supporting plates are located above second conveying belt, when two supporting plates are horizontal, the outer edge of a supporting plate is butt jointed with the output of slide one, and spray plate one is installed above the supporting plate butt jointed with slide one, spray plate two is installed above second conveying belt, and spray plate two is located behind supporting plate.

Description

Technical Field

[0001] This utility model relates to the technical field of medical supplies, and in particular to a fully automatic silicone oil spraying device for infusion bottle pads. Background Technology

[0002] The silanization treatment of infusion bottle pads can form a dense silicon oxide layer on the material surface, effectively blocking the erosion of external corrosive media and improving the corrosion resistance of the material. Silanization treatment can also improve the surface properties of infusion bottle pads, such as surface wettability and coefficient of friction. Chinese utility model patent CN220590509U discloses a silanization treatment device for the production of infusion bottle pads. This device transports materials to different processing areas via a conveyor, cleans the pads via a stirring device, removes water and impurities during the cleaning process via a filtration device for easy and repeated cleaning, sterilizes the pad surface via a sterilization device, and coats the pad surface with a silanizing agent via a spraying device, improving the automation and practicality of the device. The device includes a conveyor, a stirring device, a filtration device, a sterilization device, and a spraying device, with the stirring device, filtration device, sterilization device, and spraying device all mounted on the conveyor.

[0003] The aforementioned device sprays silicone oil onto the upper and lower surfaces of the infusion bottle pad using two spray plates arranged vertically. However, due to the obstruction of the wire mesh conveyor belt, the lower surface of the infusion bottle pad cannot be evenly coated with silicone oil, resulting in poor silicone treatment effect. Utility Model Content

[0004] To solve the above-mentioned technical problems, this utility model provides a fully automatic silicone oil spraying device for infusion bottle pads, which flips the pads over and automatically and evenly sprays silicone oil onto the upper and lower surfaces to improve the silicone treatment effect.

[0005] This utility model discloses a fully automatic silicone oil spraying device for infusion bottle pads, comprising a first conveyor belt and a second conveyor belt, with a housing mounted on the first and second conveyor belts. The first and second conveyor belts cooperate to transport infusion bottle pads backward. It also includes a slide plate, a rotating shaft, two trays, a spray plate, and a second spray plate. The input end of the second conveyor belt is located below the output end of the first conveyor belt. The input end of the slide plate overlaps with the output end of the first conveyor belt, and the output end of the slide plate is tilted downward. The rotating shaft is rotatably installed inside the housing. Two trays are mounted opposite each other on both sides of the outer wall of the rotating shaft, and the two trays are located above the second conveyor belt. When the two trays are horizontal, the outer edge of one tray aligns with the output end of the slide plate. The first spray plate is installed above the tray that aligns with the slide plate, and the second spray plate is installed above the second conveyor belt, located behind the tray. During operation, the cleaned infusion bottle pads are transported into the housing via the first conveyor belt and then to the slide plate. The infusion bottle pad slides along the slide plate to the first tray it connects with. The spray plate sprays silicone oil onto the infusion bottle pad on the first tray. The shaft rotates the slide plate 20 degrees, causing the first tray to rotate to the other side of the shaft, causing the infusion bottle pad on it to fall onto the second conveyor belt and flip over. The second conveyor belt transports the infusion bottle pad backwards. The spray plate 2 sprays silicone oil onto the infusion bottle pads transported on the second conveyor belt, ensuring that both the upper and lower surfaces of the infusion bottle pads are automatically sprayed with silicone oil. At this point, the second tray connects with the slide plate 1, allowing the next batch of infusion bottle pads to slide onto the first tray. The above actions are repeated to automatically spray the upper and lower surfaces of the next batch of infusion bottle pads. Compared to existing technologies, this method flips the infusion bottle pads and automatically sprays silicone oil onto their upper and lower surfaces, avoiding obstruction by the second conveyor belt. Both the upper and lower surfaces of the infusion bottle pads are evenly coated with silicone oil, improving the silicone treatment effect.

[0006] Preferably, it also includes multiple slots, with multiple slots provided on both pallets; by providing multiple slots, the weight of the two pallets is reduced, and excess silicone oil falls onto the second conveyor belt through the multiple slots, thereby reducing silicone oil residue on the two pallets.

[0007] Preferably, it also includes two sliding sleeves, two sliding rods, two springs, and a baffle. The two sliding sleeves are respectively installed on the left and right sides of the slide plate one. The lower parts of the two sliding rods are slidably mounted on the two sliding sleeves, respectively. The two ends of the two springs are respectively connected to the two sliding sleeves and the two sliding rods. The two ends of the baffle are respectively connected to the upper parts of the two sliding rods. The baffle is located above the slide plate one. The two springs elastically support the two sliding rods, so that the two sliding rods support the baffle. When the baffle is lowered, it blocks the infusion bottle pad on the slide plate one, preventing the infusion bottle pad from falling out of the gap between the tray and the slide plate one. When the baffle is raised and disengaged from the slide plate one, the infusion bottle pad on the slide plate one slides onto the tray, improving the reliability of the infusion bottle pad delivery.

[0008] Preferably, it also includes two levers and a stop block. The two levers are symmetrically mounted on the two trays, and the stop block is mounted on the slide rod. When the tray drives the levers to rotate, the stop block is moved, causing the slide rod to rise. The rotating shaft drives the two trays to rotate. When one tray aligns with the slide plate, the lever is blocked by the stop block. The lever moves the stop block upward, and the stop block causes the slide rod to rise, so that the slide rod raises the baffle to a certain height. The baffle disengages from the slide plate, and the infusion bottle pad on the slide plate slides onto the tray. When the tray rotates around the rotating shaft again, the lever disengages from the stop block. The spring force causes the slide rod to descend and reset, and the baffle falls back onto the slide plate to block the infusion bottle pad.

[0009] Preferably, it also includes an oil tank, an oil pump, and an oil delivery pipe. The oil tank is installed on the cover of the first and second conveyor belts. The oil tank stores silicone oil inside. The oil pump is installed on the outside of the oil tank. The pump's suction pipe extends into the oil tank. The input end of the oil delivery pipe is connected to the output port of the oil pump. The output end of the oil delivery pipe is connected to spray plate one and spray plate two. When the oil pump operates, it draws out the silicone oil from the oil tank and delivers it to spray plate one and spray plate two through the oil delivery pipe one, so that the silicone oil is automatically sprayed onto the upper and lower end faces of the infusion bottle gasket through spray plate one and spray plate two.

[0010] Preferably, the system also includes a second slide plate, an oil receiving trough, a return oil pump, a return oil pipe, and a filter box. The second slide plate is installed at the output end of the second conveyor belt. Multiple grooves are provided on the second slide plate, and multiple oil leakage holes are provided in each of the multiple slide grooves. The oil receiving trough is installed below the second slide plate. The oil inlet pipe of the return oil pump extends into the oil receiving trough. The input end of the return oil pipe is connected to the oil outlet of the return oil pump, and the output end of the return oil pipe is connected to the filter box. The filter box is equipped with a silicone oil filtration component. The infusion bottle pad output by the second conveyor belt slides along the second slide plate. When the infusion bottle pad passes through multiple grooves, it vibrates, causing excess silicone oil to fall off. The silicone oil falls into the oil receiving trough through the oil leakage holes for recycling. The return oil pump operates and inputs the silicone oil into the return oil pump through the return oil pipe. The filter component in the return oil pump filters the silicone oil. The filtered silicone oil is then input back into the oil tank for reuse.

[0011] Preferably, it also includes an air suction hood and a grid. The air suction hood is installed inside the hood box and is located above the first conveyor belt. An air inlet is provided at the lower end of the slide plate. The grid is installed on the air inlet. The gap between the grid and the first conveyor belt is slightly larger than the thickness of the infusion bottle pad. The air suction hood is connected to an external exhaust fan. When the exhaust fan is running, the air above the first conveyor belt enters the air suction hood through the air inlet. When the infusion bottle pad conveyed on the second conveyor belt passes through the air suction hood, it is blown onto the grid by the airflow. The airflow carries away the residual moisture on the infusion bottle pad, making the infusion bottle pad dry. When the exhaust fan stops, the infusion bottle pad falls onto the second conveyor belt and is conveyed backward by the second conveyor belt again.

[0012] Compared with the prior art, the beneficial effects of this utility model are as follows: by flipping the infusion bottle pad and automatically spraying silicone oil on the upper and lower surfaces of the infusion bottle pad, the obstruction of the second conveyor belt is avoided, and the upper and lower surfaces of the infusion bottle pad can be evenly sprayed with silicone oil, thereby improving the siliconization effect. Attached Figure Description

[0013] Figure 1 This is a schematic diagram of the structure of this utility model;

[0014] Figure 2 This is a partial cross-sectional structural schematic diagram of the present invention;

[0015] Figure 3 This is a schematic diagram of the isometric structure of this utility model;

[0016] Figure 4 It is a structural diagram of components such as the shaft, support plate, sliding sleeve, sliding rod, spring, and baffle.

[0017] Figure 5 yes Figure 4 A magnified schematic diagram of the partial structure at point A in the middle;

[0018] Figure 6 It is a structural diagram of the spray plate 1, spray plate 2, oil tank, oil pump, oil pipeline 1, oil receiving tank, return oil pump and filter box, etc.

[0019] Figure 7 This is a structural diagram of the air intake hood and grid, etc.

[0020] The attached diagram is labeled as follows: 1. First conveyor belt; 2. Second conveyor belt; 3. Slide plate one; 4. Rotary shaft; 5. Pallet; 6. Spray plate one; 7. Spray plate two; 8. Groove; 9. Sliding sleeve; 10. Sliding rod; 11. Spring; 12. Baffle; 13. Toggle lever; 14. Stop block; 15. Oil tank; 16. Oil pump; 17. Oil delivery pipe one; 18. Slide plate two; 19. Oil receiving trough; 20. Return oil pump; 21. Return oil pipe; 22. Filter box; 23. Suction hood; 24. Grid. Detailed Implementation

[0021] To facilitate understanding of this utility model, a more complete description will be given below with reference to the accompanying drawings. This utility model can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to make the disclosure of this utility model more thorough and complete.

[0022] Example 1

[0023] like Figures 1 to 5As shown, the fully automatic silicone oil spraying device for infusion bottle pads includes a first conveyor belt 1 and a second conveyor belt 2, with a cover box installed on the first conveyor belt 1 and the second conveyor belt 2. The first conveyor belt 1 and the second conveyor belt 2 cooperate to convey the infusion bottle pads backward. It also includes a slide plate 3, a rotating shaft 4, two trays 5, a spray plate 6, and a spray plate 7. The input end of the second conveyor belt 2 is located below the output end of the first conveyor belt 1. The input end of the slide plate 3 overlaps with the output end of the first conveyor belt 1. The output end of the slide plate 3 is inclined downward. The rotating shaft 4 is rotatably installed inside the cover box. Two trays 5 are installed opposite each other on both sides of the outer wall of the rotating shaft 4. The two trays 5 are located above the second conveyor belt 2. When the two trays 5 are in a horizontal state, the outer edge of one tray 5 is aligned with the output end of the slide plate 3. The spray plate 6 is installed on the slide plate 7. Above the pallet 5 connected to the first pallet 3, the second spray plate 7 is installed above the second conveyor belt 2 and is located behind the pallet 5; it also includes two sliding sleeves 9, two sliding rods 10, two springs 11 and a baffle 12. The two sliding sleeves 9 are respectively installed on the left and right sides of the first pallet 3. The lower parts of the two sliding rods 10 are respectively slidably installed on the two sliding sleeves 9. The two ends of the two springs 11 are respectively connected to the two sliding sleeves 9 and the two sliding rods 10. The two ends of the baffle 12 are respectively connected to the upper parts of the two sliding rods 10 and are located above the first pallet 3; it also includes two levers 13 and a stop block 14. The two levers 13 are symmetrically installed on the two pallets 5, and the stop block 14 is installed on the sliding rods 10. When the pallet 5 drives the levers 13 to rotate, it moves the stop block 14 to raise the sliding rods 10.

[0024] During operation, the cleaned infusion bottle pads are conveyed into the housing via the first conveyor belt 1 and onto the slide plate 3. Two springs 11 elastically support two sliding rods 10, which in turn support the baffle 12. When the baffle 12 descends, it blocks the infusion bottle pads on the slide plate 3, preventing them from falling out through the gap between the support plate 5 and the slide plate 3. The rotating shaft 4 drives the two support plates 5 to rotate. When one support plate 5 aligns with the slide plate 3, the lever 13... Blocked by stop 14, lever 13 moves stop 14 upward, causing stop 14 to raise slide 10, which in turn raises baffle 12. Baffle 12 disengages from slide plate 3, and the infusion bottle pad on slide plate 3 slides onto the first tray 5 it connects to. Spray plate 6 sprays silicone oil onto the infusion bottle pad on the first tray 5. Rotating shaft 4 rotates slide plate 2 180 degrees. When tray 5 rotates around rotating shaft 4 again, lever 13 and stop 14... When spring 11 is released, slide bar 10 descends and resets due to the elastic force of spring 11. Baffle 12 falls back onto slide plate 3, blocking the infusion bottle pad. This causes the first tray 5 to rotate to the other side of the shaft 4, causing the infusion bottle pad on it to fall onto the second conveyor belt 2 and flip over. The second conveyor belt 2 transports the infusion bottle pad backward. Spray plate 7 sprays silicone oil onto the infusion bottle pads transported on the second conveyor belt 2, so that both the upper and lower surfaces of the infusion bottle pads are automatically sprayed with silicone oil. At this time, the second tray 5 connects with slide plate 3, allowing the next batch of infusion bottle pads to slide onto the first tray 5. The above actions are repeated to automatically spray the upper and lower surfaces of the next batch of infusion bottle pads. Compared with the existing technology, by flipping the infusion bottle pads over and automatically spraying silicone oil onto the upper and lower surfaces of the infusion bottle pads, the obstruction of the second conveyor belt 2 is avoided. Both the upper and lower surfaces of the infusion bottle pads can be evenly sprayed with silicone oil, improving the silicone treatment effect.

[0025] Example 2

[0026] like Figure 1 , Figure 2 , Figure 3 and Figure 6As shown, based on Embodiment 1, it also includes multiple slots 8, with multiple slots 8 provided on both support plates 5; it also includes an oil tank 15, an oil pump 16, and an oil delivery pipe 17. The oil tank 15 is installed on the cover of the first conveyor belt 1 and the second conveyor belt 2, and the inside of the oil tank 15 stores silicone oil. The oil pump 16 is installed on the outside of the oil tank 15, and the pumping pipe of the oil pump 16 extends into the oil tank 15. The input end of the oil delivery pipe 17 is connected to the output port of the oil pump 16, and the output end of the oil delivery pipe 17 is connected to the spray plate 6 and the spray plate 7. The system includes a slide plate 2 18, an oil receiving tank 19, a return oil pump 20, a return oil pipe 21, and a filter box 22. The slide plate 2 18 is installed at the output end of the second conveyor belt 2. Multiple grooves are provided on the slide plate 2 18, and multiple oil leakage holes are provided in the grooves of the multiple slide rods 10. The oil receiving tank 19 is installed below the slide plate 2 18. The oil inlet pipe of the return oil pump 20 extends into the oil receiving tank 19. The input end of the return oil pipe 21 is connected to the oil outlet of the return oil pump 20, and the output end of the return oil pipe 21 is connected to the filter box 22. The filter box 22 is equipped with a silicone oil filter component.

[0027] By setting multiple slots 8 to reduce the weight of the two pallets 5, and allowing excess silicone oil to fall onto the second conveyor belt 2 through the slots 8, the silicone oil residue on the two pallets 5 is reduced. The oil pump 16 operates to extract the silicone oil from the oil tank 15 and transport it to the spray plate 6 and spray plate 7 through the oil delivery pipe 17. This allows the silicone oil to be automatically sprayed onto the upper and lower end faces of the infusion bottle pad through the spray plate 6 and spray plate 7. The infusion bottle pad output from the second conveyor belt 2 slides along the slide plate 18 and vibrates when it passes through multiple grooves, causing excess silicone oil to fall off. The silicone oil falls into the oil collection tank 19 through the oil leakage hole for recycling. The return oil pump 20 operates to input the silicone oil into the return oil pump 20 through the return oil pipe 21. The filter component in the return oil pump 20 filters the silicone oil, and the filtered silicone oil is input back into the oil tank 15 for reuse.

[0028] Example 3

[0029] like Figure 1 , Figure 2 and Figure 7 As shown, based on Embodiment 1, it also includes an air suction hood 23 and a grid 24. The air suction hood 23 is installed inside the hood box and is located above the first conveyor belt 1. An air inlet is provided at the lower end of the slide plate 3. The grid 24 is installed on the air inlet. The gap between the grid 24 and the first conveyor belt 1 is slightly larger than the thickness of the infusion bottle pad. The air suction hood 23 is connected to an external exhaust fan. When the exhaust fan is running, the air above the first conveyor belt 1 enters the air suction hood 23 through the air inlet. When the infusion bottle pad conveyed on the second conveyor belt 2 passes through the air suction hood 23, it is blown onto the grid 24 by the airflow. The airflow carries away the residual moisture on the infusion bottle pad, making the infusion bottle pad dry. When the exhaust fan stops, the infusion bottle pad falls onto the second conveyor belt 2 and is conveyed backward by the second conveyor belt 2 again.

[0030] like Figures 1 to 7 As shown, the fully automatic silicone oil spraying device for infusion bottle pads of this utility model operates as follows: First, the cleaned infusion bottle pads are conveyed into the housing via the first conveyor belt 1 and onto the slide plate 3. The infusion bottle pads slide along the slide plate 3 onto the first tray 5 that it connects with. The baffle 12 is raised, causing the infusion bottle pads on the slide plate 3 to slide onto the tray 5. The spray plate 6 then sprays silicone oil onto the infusion bottle pads on the first tray 5. Afterward, the rotating shaft 4 rotates the slide plate 2 180 degrees, causing the first tray 5 to rotate to the other side of the rotating shaft 4, causing the infusion bottle pads on it to fall onto the second conveyor belt 2 and flip over. The second conveyor belt 2 conveys the infusion bottle pads backward, and the spray plate 7 sprays silicone oil onto the infusion bottle pads conveyed on the second conveyor belt 2, causing the infusion bottle pads to... Both the upper and lower surfaces are automatically sprayed with silicone oil. Then, during the rotation of the rotating shaft 4 and the two pallets 5, the baffle 12 descends and blocks the infusion bottle pads on the slide plate 1 3. At this time, the second pallet 5 docks with the slide plate 1 3, allowing the next batch of infusion bottle pads to slide onto the first pallet 5. The above action is repeated to automatically spray the upper and lower surfaces of the next batch of infusion bottle pads. Finally, the infusion bottle pads output by the second conveyor belt 2 slide along the slide plate 2 18. When the infusion bottle pads pass through multiple grooves, they vibrate, causing excess silicone oil to fall off. The silicone oil falls into the oil collection tank 19 through the oil leakage hole for recycling. The return oil pump 20 runs and inputs the silicone oil into the return oil pump 20 through the return oil pipe 21. The filter component in the return oil pump 20 filters the silicone oil. The filtered silicone oil is then input back into the oil tank 15 for reuse.

[0031] The main functions achieved by this utility model are:

[0032] 1. By flipping the infusion bottle pad and automatically spraying silicone oil on the upper and lower surfaces of the infusion bottle pad, the obstruction of the second conveyor belt 2 is avoided, and the upper and lower surfaces of the infusion bottle pad can be evenly sprayed with silicone oil, thus improving the silicone treatment effect.

[0033] 2. Excess silicone oil can be recycled and reused;

[0034] 3. It can dry the infusion bottle pads.

[0035] The fully automatic silicone oil spraying device for infusion bottle pads of this utility model uses common mechanical methods for installation, connection, or setting. Any method that achieves the desired beneficial effect can be implemented. The first conveyor belt 1, second conveyor belt 2, rotating shaft 4, support plate 5, spray plate 1 6, spray plate 2 7, baffle 12, spring 11, oil tank 15, oil pump 16, oil delivery pipe 17, oil receiving trough 19, return oil pump 20, return oil pipe 21, filter box 22, suction hood 23, and grid 24 of the fully automatic silicone oil spraying device for infusion bottle pads of this utility model are commercially available. Technical personnel in this industry only need to install and operate it according to the accompanying instruction manual, without requiring any creative work from those skilled in the art.

[0036] All technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and / or" as used herein includes any and all combinations of one or more of the associated listed items.

[0037] The above description is only a preferred embodiment of the present utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the technical principles of the present utility model, and these improvements and modifications should also be considered within the protection scope of the present utility model.

Claims

1. An automatic silicone oil spraying device for infusion bottle pads, comprising a first conveyor belt (1) and a second conveyor belt (2), wherein a cover box is installed on the first conveyor belt (1) and the second conveyor belt (2), and the first conveyor belt (1) and the second conveyor belt (2) cooperate to convey infusion bottle pads backward; characterized in that, It also includes a slide plate 1 (3), a rotating shaft (4), two pallets (5), a spray plate 1 (6) and a spray plate 2 (7). The input end of the second conveyor belt (2) is located below the output end of the first conveyor belt (1). The input end of the slide plate 1 (3) overlaps with the output end of the first conveyor belt (1). The output end of the slide plate 1 (3) is tilted downward. The rotating shaft (4) is rotated and installed inside the housing. Two pallets (5) are installed opposite each other on the outer walls of the rotating shaft (4). The two pallets (5) are located above the second conveyor belt (2). When the two pallets (5) are in a horizontal state, the outer edge of one pallet (5) is connected to the output end of the slide plate 1 (3). The spray plate 1 (6) is installed above the pallet (5) connected to the slide plate 1 (3). The spray plate 2 (7) is installed above the second conveyor belt (2). The spray plate 2 (7) is located behind the pallet (5).

2. The fully automatic silicone oil spraying device for infusion bottle pads as described in claim 1, characterized in that, It also includes multiple slots (8), and multiple slots (8) are provided on both trays (5).

3. The fully automatic silicone oil spraying device for infusion bottle gaskets as described in claim 1, characterized in that, It also includes two sliding sleeves (9), two sliding rods (10), two springs (11) and a baffle (12). The two sliding sleeves (9) are respectively installed on the left and right sides of the slide plate (3). The lower parts of the two sliding rods (10) are respectively slidably installed on the two sliding sleeves (9). The two ends of the two springs (11) are respectively connected to the two sliding sleeves (9) and the two sliding rods (10). The two ends of the baffle (12) are respectively connected to the upper part of the two sliding rods (10). The baffle (12) is located above the slide plate (3).

4. The fully automatic silicone oil spraying device for infusion bottle pads as described in claim 3, characterized in that, It also includes two levers (13) and a stop block (14). The two levers (13) are symmetrically mounted on two support plates (5), and the stop block (14) is mounted on the slide rod (10). When the support plate (5) drives the levers (13) to rotate, it moves the stop block (14) to raise the slide rod (10).

5. The fully automatic silicone oil spraying device for infusion bottle pads as described in claim 1, characterized in that, It also includes an oil tank (15), an oil pump (16), and an oil delivery pipe (17). The oil tank (15) is installed on the cover of the first conveyor belt (1) and the second conveyor belt (2). The inside of the oil tank (15) stores silicone oil. The oil pump (16) is installed on the outside of the oil tank (15). The pumping pipe of the oil pump (16) extends into the oil tank (15). The input end of the oil delivery pipe (17) is connected to the output port of the oil pump (16). The output end of the oil delivery pipe (17) is connected to the spray plate (6) and the spray plate (7).

6. The fully automatic silicone oil spraying device for infusion bottle pads as described in claim 5, characterized in that, It also includes a second slide plate (18), an oil receiving tank (19), a return oil pump (20), a return oil pipe (21), and a filter box (22). The second slide plate (18) is installed at the output end of the second conveyor belt (2). Multiple grooves are provided on the second slide plate (18), and multiple oil leakage holes are provided in the grooves of multiple slide bars (10). The oil receiving tank (19) is installed below the second slide plate (18). The oil inlet pipe of the return oil pump (20) extends into the oil receiving tank (19). The input end of the return oil pipe (21) is connected to the oil outlet of the return oil pump (20). The output end of the return oil pipe (21) is connected to the filter box (22). The filter box (22) is equipped with a silicone oil filter component.

7. The fully automatic silicone oil spraying device for infusion bottle gaskets as described in claim 1, characterized in that, It also includes a suction hood (23) and a grid (24). The suction hood (23) is installed inside the hood box and is located above the first conveyor belt (1). An air inlet is provided at the lower end of the slide plate (3). The grid (24) is installed on the air inlet. The gap between the grid (24) and the first conveyor belt (1) is slightly larger than the thickness of the infusion bottle pad.

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