A film cooling and drying device
By using a combination of air blowing and air guiding components in the film cooling and drying device, the guiding air force pushes the water droplets on the top surface of the film towards the center, and combined with the tapping mechanism to accelerate the dehydration of the bottom, the efficiency problem caused by the fast drying speed of the bottom of the film is solved, and uniform drying and efficient cooling are achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- DONGGUAN HONGXIANG MASCH CO LTD
- Filing Date
- 2025-08-21
- Publication Date
- 2026-06-16
AI Technical Summary
In existing technologies, the bottom of the film often dries faster than the top, requiring the top to dry before output, thus reducing drying efficiency.
The system employs a combination of air blowing, air guiding, and water removal components. By guiding the airflow, water droplets on the top surface of the film are pushed from both sides towards the center and discharged by the water removal components. Combined with a tapping mechanism, this accelerates the dehydration of the bottom of the film and improves the drying efficiency.
This speeds up the drying process and increases the efficiency of the film, ensuring uniform drying and avoiding reduced efficiency caused by waiting for the top to dry.
Smart Images

Figure CN120941619B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of film cooling and drying technology, and specifically to a film cooling and drying device. Background Technology
[0002] Rubber and plastic composites are made by mixing rubber and plastics, combining the high elasticity and flexibility of rubber with the rigidity and easy processing of plastics. They are widely used in industries such as industry, automobiles, and electronics. In the production process of rubber and plastics, the first step is the melting and mixing of raw materials. Rubber, plastic granules, and various additives are put into a mixer according to the ratio. After high-temperature heating and mechanical shearing, the materials are fully integrated and plasticized to form a uniform molten rubber compound. Then, the molten rubber compound is conveyed to a calender, where it is stretched and pressed into a continuous sheet of a set thickness by multiple sets of rollers, completing the sheeting process. At this time, a small amount of processing additives and dust may remain on the surface of the sheet. Next, it enters the cleaning process. The sheet is conveyed to the cleaning tank by guide rollers and soaked and rinsed in flowing clean water or special cleaning solution. With the help of gentle wiping by brush rollers, the surface oil, impurities, and unreacted additives are thoroughly removed. After cleaning, the sheet with surface water droplets enters the cooling dryer, where it is dried by multiple sets of fans.
[0003] In the prior art, the drying device for continuous film is usually composed of multiple conveying mechanisms arranged from top to bottom, with the conveying directions of adjacent conveying mechanisms being opposite. The cleaned continuous film is conveyed to the uppermost conveying mechanism, and then, with the operation of multiple conveying mechanisms, the continuous film passes through multiple conveying mechanisms in sequence. At the same time, during this process, multiple sets of fans are used to dry the conveyed film.
[0004] However, the above-mentioned existing technology still has the following shortcomings: the film surface after passing through the washing tank will carry some water droplets. After the film with water droplets on its surface enters the drying device, it is dried by multiple sets of fans. During the drying process, the drying speed of the bottom of the film is often faster than that of the top of the film. In order to ensure the drying effect of the film, it is necessary to dry the top of the film before it can be transported out of the drying device, which can easily reduce the drying efficiency of the film. Summary of the Invention
[0005] This invention provides a film cooling and drying device, which aims to solve the problem in related technologies where the drying speed of the bottom of the film is often faster than that of the top of the film. In this case, in order to ensure the drying effect of the film, the top of the film needs to be dried before it can be transported out of the drying device, which can easily reduce the drying efficiency of the film.
[0006] The film cooling and drying device of the present invention includes a drying mechanism, a feeding mechanism, a first conveying mechanism, a second conveying mechanism, and a third conveying mechanism, and also includes a dewatering mechanism. The dewatering mechanism includes an air blowing component, an air guiding component, a driving component, and a dewatering component. The air blowing component is connected inside the drying mechanism and can generate airflow. The air guiding component includes a first rotating ring, a first air guiding section, a second rotating ring, and a second air guiding section. The first rotating ring and the second rotating ring are rotatably connected to the air blowing component. The first air guiding section is connected to the first rotating ring, and the second air guiding section is connected to the second rotating ring. The bottom of the first air guiding section and the second air guiding section are both provided with inclined air outlets, which can guide the airflow. The driving component is connected to the air blowing component and can drive the first rotating ring and the second rotating ring to rotate in opposite directions, so that the first air guiding section and the second air guiding section push water droplets on the top surface of the continuous film from both sides to the center. The dewatering component is connected to the air blowing component and is used to remove water droplets that accumulate in the center of the top surface of the continuous film.
[0007] Beneficial effects: When drying the cleaned continuous film, one end of the cleaned continuous film is first placed on the feeding mechanism, which then transports the continuous film to the first conveying mechanism. After the continuous film is transported to the first conveying mechanism, the air blowing device is activated to generate airflow. At the same time, the air guides 1 and 2 guide the airflow. Then, the drive device is activated, which drives the rotating rings 1 and 2 to rotate in opposite directions. When the rotating rings 1 and 2 rotate in opposite directions, the air guides 1 and 2 move in opposite directions along a circular trajectory. At this time, the airflow from the air guides 1 and 2 pushes the water droplets on the top surface of the continuous film from both sides to the center. The water removal device then discharges the water droplets that have gathered in the center of the top surface of the continuous film outward, thereby accelerating the drying speed of the continuous film.
[0008] Preferably, the dewatering mechanism further includes an automatic telescopic part, and the air blowing component is connected to the automatic telescopic part, which can drive the air blowing component to move up and down.
[0009] Its effect is that the automatic telescopic part drives the air blowing component to move up and down, so that the air blowing component drives the air guiding component, the driving component and the water removal component to move up and down, thereby adjusting the distance between the air guiding component and the water removal component and the top of the continuous film, so as to facilitate the water removal operation of continuous films of different thicknesses.
[0010] Preferably, the air blowing component includes a lifting part, an air storage cylinder, and a pump body. The air storage cylinder and the pump body are both connected to the lifting part. The pump body can generate wind and deliver the wind to the air storage cylinder. The air storage cylinder is provided with an opening 1 and an opening 2. Rotating ring 1 and rotating ring 2 are rotatably connected to the air storage cylinder. Rotating ring 1 can block opening 1, and rotating ring 2 can block opening 2. Air guide part 1 can communicate with opening 1, and air guide part 2 can communicate with opening 2.
[0011] Its effect is that the pump body generates wind power and delivers the wind power into the air storage cylinder. The wind power is then guided by the air guide section 1 and the air guide section 2, so that the water droplets on the top surface of the continuous film can be pushed from both sides to the middle through the air guide section 1 and the air guide section 2.
[0012] Preferably, the driving component includes a first bevel gear ring, a second bevel gear ring, and a bevel gear. The first bevel gear ring is connected to a first rotating ring, the second bevel gear ring is connected to a second rotating ring, and the bevel gear is rotatably connected to the air storage cylinder. The bevel gear is located between the first bevel gear ring and the second bevel gear ring, and both the first bevel gear ring and the second bevel gear ring are meshed with the bevel gear ring. The first bevel gear ring is rotatable.
[0013] Its effect is that when the bevel ring one rotates, it can mesh with the bevel gear and drive the meshing transmission between the bevel gear and the bevel ring two, so that the bevel ring one and the bevel ring two rotate in opposite directions, thereby driving the rotating ring one and the rotating ring two to rotate in opposite directions, thus providing power for the air guide section one and the air guide section two to move in opposite directions along a circular trajectory.
[0014] Preferably, the driving component further includes a driving source one, a spur gear and a spur gear ring, the driving source one being connected to the air blowing component, the spur gear being connected to the output end of the driving source one, and the spur gear ring being connected to the rotating ring one, with the spur gear ring meshing with the spur gear for transmission.
[0015] Its effect is that the drive source one can drive the meshing transmission between the spur gear and the spur gear ring, thereby providing power for the rotation of the rotating ring one.
[0016] Preferably, the water removal component includes a second pump body, a water suction section, and a water discharge section. The second pump body is connected to the air blowing component, and both the water suction section and the water discharge section are connected to the second pump body.
[0017] Its effect is that after the second pump body is started, it can suck up the water droplets gathered in the middle of the top surface of the continuous film through the suction part, and discharge the sucked water droplets through the drainage part.
[0018] Preferably, the drying mechanism is provided with a drain pipe, and a water guide is connected to the drain section, which is inserted into the drain pipe.
[0019] Its effect is that the water guide can transport the absorbed water droplets to the drain pipe and discharge them to the outside of the drying mechanism, thereby reducing the air humidity inside the drying mechanism and thus accelerating the drying speed of the continuous film.
[0020] Preferably, it also includes a tapping mechanism, which is connected within the first conveying mechanism and is used to tap the first conveying mechanism.
[0021] Its effect is that the tapping mechanism can tap the conveyor after the continuous film is transported to the conveyor, thereby accelerating the dehydration speed of the contact area between the bottom of the continuous film and the conveyor and thus speeding up the drying efficiency of the continuous film.
[0022] Preferably, the tapping mechanism includes a blocking part, a supporting part, a tapping element, and a pushing element. The blocking part is connected inside the first conveying mechanism, and a water storage cavity can be formed between the blocking part and the first conveying mechanism to hold water droplets tapped from the bottom of the continuous film. The supporting part and the pushing element are both connected to the blocking part, and the tapping element is connected to the supporting part. The pushing element can drive the tapping element so that the tapping element taps the first conveying mechanism.
[0023] Preferably, the striking component includes a striking part and an elastic part. The striking part is inserted into the support part, and the elastic part is connected between the striking part and the support part. The pushing component includes a rotating part, a pushing part, and a second driving source. The rotating part is rotatably connected inside the blocking part. The pushing part is elliptical in shape. The second driving source is connected to the blocking part, and the rotating part is connected to the output end of the second driving source.
[0024] Its effect is that the rotation of the rotating part driven by the second drive source can drive the pushing part to rotate. When the pushing part rotates, it can push the striking part to move down and the striking part can compress the elastic part. After the pushing part and the striking part are separated, the elastic part drives the striking part to reset and strike the first conveyor mechanism.
[0025] The beneficial effects of this invention are:
[0026] 1. When drying the cleaned continuous film, the air blowing device is activated to generate airflow. At the same time, the air guides 1 and 2 guide the airflow. Then, the drive device is activated, which drives the rotating rings 1 and 2 to rotate in opposite directions. When the rotating rings 1 and 2 rotate in opposite directions, the air guides 1 and 2 move in opposite directions along a circular trajectory. At this time, the airflow from the air guides 1 and 2 pushes the water droplets on the top surface of the continuous film from both sides to the center. The water removal device then discharges the water droplets that have gathered in the center of the top surface of the continuous film to the outside, thereby accelerating the drying speed of the continuous film.
[0027] 2. During the continuous film transport process of the conveying mechanism, when the continuous film passes through the patting mechanism, the rotating part driven by the second drive source can drive the pushing part to rotate. When the pushing part rotates, it can push the patting part to move down and the patting part can compress the elastic part. After the pushing part separates from the patting part, the elastic part drives the patting part to reset and pat the conveying mechanism to speed up the dehydration speed of the contact part between the bottom of the continuous film and the conveying mechanism, thereby speeding up the drying efficiency of the continuous film. Attached Figure Description
[0028] Figure 1This is a schematic diagram of the main structure of the present invention.
[0029] Figure 2 This is a schematic diagram of the front cross-sectional structure of the present invention.
[0030] Figure 3 This is a front view cross-sectional structural diagram of the feeding mechanism, conveying mechanism one, conveying mechanism two, and conveying mechanism three of the present invention.
[0031] Figure 4 This is a front view structural schematic diagram of the water removal mechanism of the present invention.
[0032] Figure 5 This is a three-dimensional structural diagram of the water removal mechanism of the present invention.
[0033] Figure 6 This is a front view structural schematic diagram of the air guide and drive components of the present invention.
[0034] Figure 7 This is a cross-sectional three-dimensional structural diagram of the gas storage cylinder of the present invention.
[0035] Figure 8 This is a cross-sectional structural diagram of the first and second air guide sections of the present invention.
[0036] Figure 9 This is a side view of the water removal component of the present invention.
[0037] Figure 10 This is a three-dimensional structural diagram of the striking mechanism of the present invention.
[0038] Figure label:
[0039] 1. Drying mechanism; 11. Drying box; 12. Air outlet; 13. Drain pipe; 14. Feed inlet; 15. Discharge outlet; 16. Fan unit; 2. Feeding mechanism; 3. Conveying mechanism one; 4. Conveying mechanism two; 5. Conveying mechanism three; 6. Dewatering mechanism; 61. Automatic telescopic part; 62. Air blowing component; 621. Lifting part; 622. Air storage tank; 623. Opening one; 624. Opening two; 625. Pump body one; 63. Air guide component; 631. Rotating ring one; 632. Air guide part one; 633. Rotating ring two; 634. Air guide Part 2; 64. Driving component; 641. Driving source 1; 642. Flat gear; 643. Flat gear ring; 644. Bevel gear ring 1; 645. Bevel gear ring 2; 646. Bevel gear; 65. Water removal component; 651. Pump body 2; 652. Water suction part; 653. Water discharge part; 654. Water guide part; 7. Beating mechanism; 71. Blocking part; 72. Support part; 73. Beating component; 731. Beating part; 732. Elastic part; 74. Pushing component; 741. Rotating part; 742. Pushing part; 743. Driving source 2; 75. Water supply pipe. Detailed Implementation
[0040] Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings. The embodiments described below with reference to the accompanying drawings are exemplary and intended to explain the present invention, and should not be construed as limiting the present invention.
[0041] like Figures 1 to 10 As shown, the film cooling and drying device of the present invention includes a drying mechanism 1, a feeding mechanism 2, a first conveying mechanism 3, a second conveying mechanism 4, a third conveying mechanism 5, a dehydration mechanism 6, and a tapping mechanism 7. The drying mechanism 1 can blow air onto the continuous film to be dried, thereby performing a drying operation on the continuous film to be dried. The feeding mechanism 2 is connected to the right side of the drying mechanism 1. The first conveying mechanism 3, the second conveying mechanism 4, and the third conveying mechanism 5 are all connected inside the drying mechanism 1. The first conveying mechanism 3, the second conveying mechanism 4, and the third conveying mechanism 5 are arranged sequentially from top to bottom, and the first conveying mechanism 3 and the second conveying mechanism 4, as well as the second conveying mechanism 4 and the third conveying mechanism 5, all operate in opposite directions. The feeding mechanism 2 can convey the cleaned continuous film upward to the first conveying mechanism 3. The first conveying mechanism 3, the second conveying mechanism 4, and the third conveying mechanism 5 operate in opposite directions. The third conveyor 5 conveys the continuous film, thereby extending the continuous film's running trajectory within the drying mechanism 1 to facilitate drying. The first, second, and third conveyor 5 are all equipped with running conveyor belts with mesh openings to facilitate drying the bottom of the continuous film. The dewatering mechanism 6 removes water from the top of the continuous film after it is conveyed to the first conveyor 3, accelerating the drying process. The tapping mechanism 7 is connected within the first conveyor 3 and taps the first conveyor 3 after it is conveyed, accelerating the dewatering speed at the contact point between the bottom of the continuous film and the first conveyor 3, thus further accelerating the drying process.
[0042] During the film drying process, one end of the cleaned continuous film is first placed on the feeding mechanism 2, which then transports it to the conveyor mechanism 3. Conveyor mechanism 3, conveyor mechanism 4, conveyor mechanism 5, and drying mechanism 1 are then activated. While conveyor mechanism 3 is transporting the continuous film, dehydration mechanism 6 is activated to remove water from the top of the film. Simultaneously, tapping mechanism 7 is activated to tap conveyor mechanism 3, causing vibration at the point where the conveyor belt contacts the bottom of the continuous film, thus accelerating the dehydration of the film's bottom. The portion of the continuous film that has passed through dehydration mechanism 6 and tapping mechanism 7 is continued to be transported by conveyor mechanism 3. The drying mechanism 1 then continuously dries the continuous film until it passes through conveyor mechanism 4 and conveyor mechanism 5 before being discharged.
[0043] like Figure 1 and Figure 2 As shown, the drying mechanism 1 includes a drying chamber 11, a drain pipe 13, and a fan unit 16. The drain pipe 13 is connected inside the drying chamber 11. Two fan units 16 are configured, one connected to the top and one to the rear of the drying chamber 11, respectively. The fan units 16 supply air into the drying chamber 11, thereby drying the continuous film inside. The lower rear end of the drying chamber 11 is used to discharge the air after the continuous film drying operation. The upper right side of the drying chamber 11... The drying chamber 11 is equipped with an inlet 14, and a feeding mechanism 2 is connected inside the inlet 14. The feeding mechanism 2 can transport the cleaned continuous film to the conveying mechanism 3 through the inlet 14. The lower left side of the drying chamber 11 is provided with an outlet 15. The conveying mechanism 3 5 passes through the outlet 15, and the dried continuous film is conveyed out of the drying chamber 11 through the outlet 15. The lower rear side of the inner wall of the drying chamber 11 is provided with an air vent 12 to discharge the humid air inside the drying chamber 11 to the outside.
[0044] like Figures 2 to 9 As shown, the dehydration mechanism 6 includes an automatic telescopic part 61, an air blowing component 62, an air guiding component 63, a driving component 64, and a dehydration component 65. The automatic telescopic part 61 is connected to the inner top wall of the drying box 11 near the inlet 14. The automatic telescopic part 61 is a cylinder with the telescopic end facing downwards. The air blowing component 62 is connected to the telescopic end of the automatic telescopic part 61 and can generate airflow. The air guiding component 63 is connected to the air blowing component 62 and can dehydrate the contents of the air blowing component 65. The wind guides the water droplets on the top of the continuous film from both sides to the center. The drive unit 64 is connected to the air blowing unit 62 and the air guiding unit 63 to drive the air guiding unit 63 to operate, thereby providing power for the air guiding unit 63 to push the water droplets on the top of the continuous film from both sides to the center. The water removal unit 65 is connected to the air blowing unit 62. The water removal unit 65 can remove the water droplets that gather in the center of the top surface of the continuous film to speed up the drying efficiency of the continuous film.
[0045] When the dewatering mechanism 6 removes water from the top of the continuous film, the automatic telescopic unit 61 is activated to move the air blowing component 62 downwards. This causes the air blowing component 62 to move the air guiding component 63, the driving component 64, and the dewatering component 65 downwards until the dewatering component 65 is close to the middle of the top of the continuous film. Then, the air blowing component 62 is activated to generate high-pressure air. Subsequently, the driving component 64 is activated, which drives the air guiding component 63 to operate. This causes the airflow in the air blowing component 62 to be delivered to the top of the continuous film through the air guiding component 63. The air guiding component 63 divides the airflow into two streams, which push the water droplets on the top of the continuous film from both sides towards the middle. Finally, the dewatering component 65 is activated to discharge the water droplets that have gathered in the middle of the top surface of the continuous film.
[0046] Continue to refer to Figures 2 to 9 As shown, the air blowing component 62 includes a lifting part 621, an air storage cylinder 622, and a pump body 625. The lifting part 621 is connected to the telescopic end of the automatic telescopic part 61. The air storage cylinder 622 is connected to the bottom of the lifting part 621. The pump body 625 is connected to the lifting part 621. The pump body 625 is an air pump that can generate wind and deliver the wind to the air storage cylinder 622. The air storage cylinder 622 is provided with an opening 623 and an opening 624. The wind entering the air storage cylinder 622 can be delivered to the air guide component 63 through the opening 623 and the opening 624. The air guide component 63 divides the wind into two streams to push the water droplets on the top surface of the continuous film from both sides to the middle.
[0047] The pump body 625 is activated to generate airflow, which is then directed into the air storage cylinder 622. The airflow entering the air storage cylinder 622 is then directed into the air guide 63 through openings 623 and 624. The air guide 63 divides the airflow into two streams. Subsequently, the drive unit 64 is activated to drive the air guide 63 to operate. The two streams of airflow push the water droplets on the top surface of the continuous film from both sides toward the middle. Finally, the water removal unit 65 is activated to remove the water droplets that have gathered in the middle of the top surface of the continuous film.
[0048] Continue to refer to Figures 2 to 9As shown, the air guide component 63 includes a first rotating ring 631, a first air guide section 632, a second rotating ring 633, and a second air guide section 634. Both the first rotating ring 631 and the second rotating ring 633 are rotatably connected to the air storage cylinder 622. The first rotating ring 631 and the second rotating ring 633 are coaxially arranged. The first rotating ring 631 can block the first opening 623, and the second rotating ring 633 can block the second opening 624. There are three first air guide sections 632, all connected to the first rotating ring 631, with one section communicating with the first opening 623. Similarly, there are three second air guide sections 634, all connected to the second rotating ring 633, with one section communicating with the second opening 624. The first air guide section 632 and the second air guide section 634... Air outlets are provided at the bottom of each of the 634 sections. The air outlets at the bottom of the first air guide section 632 and the second air guide section 634 are inclined. After the drive unit 64 is activated, the first rotating ring 631 and the second rotating ring 633 can be driven to rotate in opposite directions. When the first rotating ring 631 rotates, it can drive the three first air guide sections 632 to move along a circular trajectory. When the second rotating ring 633 rotates, it can drive the three second air guide sections 634 to move along a circular trajectory. The direction in which the three first air guide sections 632 move along the circular trajectory is opposite to the direction in which the three second air guide sections 634 move along the circular trajectory. Thus, the water droplets on the top surface of the continuous film can be pushed from both sides to the middle position through the reverse-moving air guide sections 632 and the second air guide section 634, so that the water droplets gathered in the middle of the top surface of the continuous film can be removed by the water removal unit 65.
[0049] When rotating ring 631 rotates, only one air guide part 632 is connected to opening 623. When rotating ring 633 rotates, only one air guide part 634 is connected to opening 624. This ensures that when pushing water droplets from the top surface of the continuous film, only one air guide part 632 and one air guide part 634 can guide the airflow. After the air guide parts 632 and 634 move to a parallel state and continue moving, they separate from openings 623 and 624 respectively, ceasing to guide the airflow. The other air guide part 632 and... The second air guide section 634 is connected to the first opening 623 and the second opening 624, and continues to guide the air force to achieve the alternating use of the three first air guide sections 632 and the three second air guide sections 634. After the first air guide section 632 and the second air guide section 634 for guiding the air force move to a parallel state, there is a distance between the first air guide section 632 and the second air guide section 634 along the width direction of the continuous film. At this time, after the first air guide section 632 and the second air guide section 634 continue to move and stop guiding the air, it can avoid the air guiding operation of the first air guide section 632 and the second air guide section 634 for guiding the air force from intersecting, thereby avoiding affecting the pushing operation of water droplets on the top surface of the continuous film.
[0050] Continue to refer to Figures 2 to 9 As shown, the driving component 64 includes a first driving source 641, a spur gear 642, a spur gear ring 643, a first bevel gear ring 644, a second bevel gear ring 645, and a bevel gear 646. The first driving source 641 is connected to the bottom of the lifting part 621 and is a motor with its output end facing downwards. The spur gear 642 is connected to the output end of the first driving source 641. The spur gear ring 643 is connected to the top of the rotating ring 631 and is sleeved on the air storage cylinder 622. On the outer side, the flat toothed ring 643 is coaxially arranged with the rotating ring 631, and the flat toothed ring 643 meshes with the flat gear 642. This allows the drive source 641 to drive the flat gear 642 and the flat toothed ring 643 to mesh and transmit power. The flat toothed ring 643 then drives the rotating ring 631 to rotate, thereby causing the three air guides 632 to move along a circular trajectory. The bevel toothed ring 644 is connected to the rotating ring 631, and the bevel toothed ring 644... Rotating ring 631 is coaxially arranged, and bevel ring 645 is connected to rotating ring 633, with bevel ring 645 and rotating ring 633 being coaxially arranged. Bevel gear 646 is rotatably connected to air storage cylinder 622, and is located between bevel ring 644 and bevel ring 645. Both bevel ring 644 and bevel ring 645 are meshed with bevel gear 646, so that when rotating ring 631 rotates, it drives bevel ring 644 and bevel gear 645. Wheel 646 and bevel ring 645 mesh and drive each other, so that bevel ring 645 drives rotating ring 633 to rotate in the opposite direction to rotating ring 631. As a result, rotating ring 631 drives the three air guides 634 to move along a circular trajectory, the air guides 634 and air guides 632 move in opposite directions, so as to push the water droplets on the top surface of the continuous film from both sides to the middle, so that the water removal component 65 can remove water droplets in the middle of the top surface of the continuous film.
[0051] The drive source 641 is activated to drive the meshing transmission between the flat gear 642 and the flat gear ring 643, so that the flat gear ring 643 drives the rotating ring 631 to rotate. When the rotating ring 631 rotates, it can drive the three air guides 632 to move along a circular trajectory. At the same time, when the rotating ring 631 rotates, it drives the bevel ring 644, the bevel gear 646 and the bevel ring 645 to mesh. The bevel ring 645 drives the rotating ring 633 to rotate in the opposite direction to the rotating ring 631. So that when the rotating ring 631 drives the three air guides 634 to move along a circular trajectory, the air guides 634 and the air guides 632 move in opposite directions. At this time, the air guides the air in the air storage cylinder 622 through one of the air guides 632 and one of the air guides 634, thereby pushing the water droplets on the top surface of the continuous film from both sides to the middle.
[0052] Continue to refer to Figures 2 to 9As shown, the water removal component 65 includes a second pump body 651, a suction section 652, a drainage section 653, and a guide section 654. The second pump body 651 is connected to the bottom of the air storage cylinder 622. The suction section 652 is connected to the suction end of the second pump body 651 and is located near the center of the top surface of the continuous film. The drainage section 653 is connected to the drainage end of the second pump body 651. After the second pump body 651 is started, it can remove water droplets collected in the center of the top surface of the continuous film through the suction section 652. The system draws in water droplets, which are then discharged by the drain section 653. The water guide section 654 is connected to the end of the drain section 653 away from the pump body 651. The water guide section 654 is inserted into the drain pipe 13. The water droplets discharged by the drain section 653 can be transported into the drain pipe 13 under the action of the water guide section 654, and then discharged out of the drying chamber 11 by the drain pipe 13 to reduce the air humidity inside the drying chamber 11, thereby accelerating the drying speed of the continuous film.
[0053] The automatic telescopic unit 61 drives the air blowing component 62, the air guiding component 63, the driving component 64, and the water removal component 65 to move downwards until the water suction part 652 on the water removal component 65 approaches the center of the top surface of the continuous film. After the air blowing component 62 generates wind, the driving component 64 drives the air guiding component 63 to guide the wind and push the water droplets on the top surface of the continuous film to the center position. Then, the pump body 651 inside the water removal component 65 is activated. The water suction part 652 sucks up the water droplets gathered in the center of the top surface of the continuous film, and the drain part 653 discharges the sucked water droplets. The water droplets discharged by the drain part 653 are transported to the drain pipe 13 through the water guiding part 654, and the water droplets are discharged to the outside of the drying box 11 by the drain pipe 13.
[0054] like Figure 2 , Figure 3 , Figure 4 , Figure 9 and Figure 10As shown, the tapping mechanism 7 includes a blocking part 71, a supporting part 72, a tapping element 73, a pushing element 74, and a water supply pipe 75. The blocking part 71 is connected inside the conveying mechanism 3, and a water storage cavity can be formed between the blocking part 71 and the conveying mechanism 3 to hold water droplets tapped from the bottom of the continuous film. The supporting part 72 and the pushing element 74 are both connected to the blocking part 71. The tapping element 73 is connected to the supporting part 72. Multiple tapping elements 73 are provided, and the tapping elements 73 can tap the conveying mechanism 3 to cause the continuous film to vibrate, thereby... To accelerate the dehydration speed at the contact point between the bottom of the continuous film and the conveyor belt on the conveyor mechanism 3, the pusher 74 can drive multiple beating elements 73, thereby providing power for the beating elements 73 to beat the conveyor mechanism 3. The water supply pipe 75 is connected to the rear side of the conveyor mechanism 3 and is connected to the water storage chamber. The end of the water supply pipe 75 away from the conveyor mechanism 3 is connected to the drain pipe 13. The water droplets collected in the water storage chamber can be transported to the drain pipe 13 through the water supply pipe 75 and discharged to the outside of the drying box 11 through the drain pipe 13.
[0055] Continue to refer to Figure 2 , Figure 3 , Figure 4 , Figure 9 and Figure 10 As shown, the striking component 73 includes a striking part 731 and an elastic part 732. The striking part 731 is inserted into the support part 72, and the elastic part 732 is a compression spring. The elastic part 732 is connected between the striking part 731 and the support part 72 and is used to drive the striking part 731 to reset. The striking part 731 can be pushed downward by the pushing member 74 so that the striking part 731 moves down and compresses the elastic part 732. When the pushing member 74 separates from the striking part 731, the elastic part 732 can drive the striking part 731 to reset quickly and beat the conveyor belt on the conveyor mechanism 3.
[0056] Continue to refer to Figure 2 , Figure 3 , Figure 4 , Figure 9 and Figure 10As shown, the pushing member 74 includes a rotating part 741, a pushing part 742, and a second driving source 743. The rotating part 741 is rotatably connected to the blocking part 71. Multiple pushing parts 742 are provided, and each of the multiple pushing parts 742 is respectively arranged corresponding to multiple striking parts 73. The pushing parts 742 are elliptical in shape. The second driving source 743 is a motor, which is connected to the blocking part 71. The rotating part 741 is connected to the output end of the second driving source 743. Activating the second driving source 743 can drive the rotating part 741 to rotate, so that the rotating part 741 drives the rotating part 741 to rotate. The driving part 742 rotates, and when multiple driving parts 742 rotate, they can push the patting part 731 in multiple patting parts 73 to move down and compress the elastic part 732. When the driving part 74 separates from the patting part 731, the elastic part 732 can drive the patting part 731 to quickly reset and pat the conveyor belt on the conveyor mechanism 3 so that the water droplets at the bottom of the continuous film fall into the water storage chamber. The water droplets in the water storage chamber are then transported to the drain pipe 13 by the water supply pipe 75, and the water droplets are transported to the outside of the drying box 11 by the drain pipe 13.
[0057] Working principle:
[0058] After cleaning, one end of the continuous film is placed on the feeding mechanism 2, which then transports the cleaned continuous film to the first conveying mechanism 3. The first conveying mechanism 3, the second conveying mechanism 4, the third conveying mechanism 5, and the drying mechanism 1 are then activated to transport the continuous film and perform the drying operation.
[0059] Activate the automatic telescopic unit 61 to drive the air blowing component 62 to move downward, so that the air blowing component 62 drives the air guiding component 63, the driving component 64 and the water removal component 65 to move downward until the water absorption part 652 on the water removal component 65 approaches the center of the top surface of the continuous film.
[0060] The pump body 625 is activated to generate airflow, which is then directed into the air storage tank 622. The airflow entering the air storage tank 622 is delivered through openings 623 and 624 to air guide sections 632 and 634, respectively. Subsequently, the drive source 641 is activated to drive the meshing transmission between the spur gear 642 and the spur ring 643. This causes the spur ring 643 to rotate the rotating ring 631. As the rotating ring 631 rotates, it drives the three air guide sections 632 to move along a circular path. Simultaneously, as the rotating ring 631 rotates... When the bevel gear ring 644, bevel gear 646, and bevel gear ring 645 mesh and drive each other, the bevel gear ring 645 drives the rotating ring 633 to rotate in the opposite direction to the rotating ring 631. When the rotating ring 631 drives the three air guides 634 to move along a circular trajectory, the air guides 634 and the air guides 632 move in opposite directions. At this time, the air guides the air in the air storage cylinder 622 through one of the air guides 632 and one of the air guides 634, thereby pushing the water droplets on the top surface of the continuous film from both sides to the middle.
[0061] The pump body 651 is started, and the water droplets gathered in the middle of the top surface of the continuous film are sucked up by the water suction part 652. The water droplets are discharged by the drainage part 653. The water droplets discharged by the drainage part 653 are transported to the drainage pipe 13 through the water guide part 654, and the water droplets are discharged to the outside of the drying box 11 by the drainage pipe 13.
[0062] The start-up drive source 743 can drive the rotating part 741 to rotate, so that the rotating part 741 drives the pushing part 742 to rotate. When the multiple pushing parts 742 rotate, they can push the multiple patting parts 731 in the patting parts 73 to move down and compress the elastic part 732. When the pushing part 74 separates from the patting part 731, the elastic part 732 can drive the patting part 731 to quickly reset and pat the conveyor belt on the conveyor mechanism 3, so that the water droplets at the bottom of the continuous film drip into the water storage chamber. The water droplets in the water storage chamber are then transported to the drain pipe 13 by the water supply pipe 75, and the water droplets are transported to the outside of the drying box 11 by the drain pipe 13.
[0063] Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention. Those skilled in the art can make changes, modifications, substitutions and variations to the above embodiments within the scope of the present invention.
Claims
1. A film cooling and drying device, comprising a drying mechanism, a feeding mechanism, a first conveying mechanism, a second conveying mechanism, and a third conveying mechanism, characterized in that, It also includes a water removal mechanism, which includes an air blowing component, an air guiding component, a driving component, and a water removal component. The air blowing component is connected inside the drying mechanism and can generate airflow. The air guiding component includes a rotating ring one, an air guiding part one, a rotating ring two, and an air guiding part two. Both rotating ring one and rotating ring two are rotatably connected to the air blowing component. Air guiding part one is connected to rotating ring one, and air guiding part two is connected to rotating ring two. Both air guiding part one and air guiding part two have inclined air outlets at their bottoms, which can guide the airflow. The driving component is connected to the air blowing component and can drive rotating ring one and rotating ring two to rotate in opposite directions so that air guiding part one and air guiding part two push water droplets on the top surface of the continuous film from both sides to the center. The water removal component is connected to the air blowing component and is used to remove water droplets that gather in the center of the top surface of the continuous film. It also includes a striking mechanism, which is connected to the first conveyor mechanism and is used to strike the first conveyor mechanism; The tapping mechanism includes a blocking part, a supporting part, a tapping element, and a pushing element. The blocking part is connected inside the first conveying mechanism, and a water storage cavity can be formed between the blocking part and the first conveying mechanism to hold water droplets tapped from the bottom of the continuous film. The supporting part and the pushing element are both connected to the blocking part, and the tapping element is connected to the supporting part. The pushing element can drive the tapping element so that the tapping element taps the first conveying mechanism. The striking component includes a striking part and an elastic part. The striking part is inserted into the support part, and the elastic part is connected between the striking part and the support part. The pushing component includes a rotating part, a pushing part, and a second driving source. The rotating part is rotatably connected inside the blocking part. The pushing part is elliptical in shape. The second driving source is connected to the blocking part, and the rotating part is connected to the output end of the second driving source.
2. The film cooling and drying apparatus according to claim 1, characterized in that, The dewatering mechanism also includes an automatic telescopic part, and the air blowing component is connected to the automatic telescopic part. The automatic telescopic part can drive the air blowing component to move up and down.
3. The film cooling and drying apparatus according to claim 1, characterized in that, The air blowing component includes a lifting part, an air storage cylinder, and a pump body. The air storage cylinder and the pump body are both connected to the lifting part. The pump body can generate air force and deliver the air force into the air storage cylinder. The air storage cylinder is provided with an opening 1 and an opening 2. Rotating ring 1 and rotating ring 2 are rotatably connected to the air storage cylinder. Rotating ring 1 can block opening 1, and rotating ring 2 can block opening 2. Air guide part 1 can communicate with opening 1, and air guide part 2 can communicate with opening 2.
4. The film cooling and drying apparatus according to claim 1, characterized in that, The driving component includes a bevel ring one, a bevel ring two, and a bevel gear. The bevel ring one is connected to a rotating ring one, the bevel ring two is connected to a rotating ring two, and the bevel gear is rotatably connected to the air storage cylinder. The bevel gear is located between the bevel ring one and the bevel ring two, and both the bevel ring one and the bevel ring two are meshed with the bevel gear. The bevel ring one can rotate.
5. The film cooling and drying apparatus according to claim 4, characterized in that, The driving component also includes a driving source, a spur gear, and a spur gear ring. The driving source is connected to the air blowing component, the spur gear is connected to the output end of the driving source, and the spur gear ring is connected to the rotating ring. The spur gear ring meshes with the spur gear for transmission.
6. The film cooling and drying apparatus according to claim 1, characterized in that, The water removal component includes a second pump body, a water suction section, and a water discharge section. The second pump body is connected to the air blowing component, and both the water suction section and the water discharge section are connected to the second pump body.
7. The film cooling and drying apparatus according to claim 6, characterized in that, The drying mechanism is equipped with a drain pipe, and a water guide is connected to the drain section, which is inserted into the drain pipe.