A high-efficiency static electricity elimination device for release film processing
By using an ion generator and ion fan to remove static electricity, combined with tension rollers and filter cotton to filter air, the problem of static electricity accumulation and contaminant adhesion in release film processing is solved, achieving efficient static electricity removal and pollution reduction.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN SAISHENG DECHENG TECH CO LTD
- Filing Date
- 2025-06-07
- Publication Date
- 2026-06-09
Smart Images

Figure CN224343422U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of release film processing technology, and in particular to a high-efficiency static elimination device for release film processing. Background Technology
[0002] Release film refers to a film whose surface can be distinguished. When in contact with specific materials under limited conditions, release film has no stickiness or only slight stickiness. It is widely used in the processing of various products, such as electronics and power, IT displays, mobile phones, medical devices, home appliances, anti-counterfeiting materials, semiconductors, automobiles, nameplates, ceramic sheet manufacturing, tape production, and die-cutting industries.
[0003] However, in the existing technology, when the release film comes into contact with other materials and moves relative to them during the processing of the release film, friction will occur. This friction will cause electrons to transfer from one material to another, thereby accumulating static charge on the surface of the release film. Static electricity will also attract tiny particles in the surrounding environment, such as dust and fibers, causing these contaminants to easily adhere to the surface of the release film, thus affecting the product quality of the release film and bringing safety hazards. Summary of the Invention
[0004] The purpose of this invention is to solve the problem in the prior art: during the processing of release film, when the release film comes into contact with other materials and moves relative to them, friction occurs. This friction causes electrons to transfer from one material to another, thereby accumulating static charge on the surface of the release film. Furthermore, static electricity attracts tiny particles from the surrounding environment, such as dust and fibers, causing these contaminants to easily adhere to the surface of the release film, thus affecting the product quality of the release film and posing safety hazards.
[0005] To achieve the above objectives, this utility model adopts the following technical solution: a high-efficiency static elimination device for release film processing, comprising: a working box; two drive motors, mounted on the surface of the working box at symmetrical locations via a frame; and further comprising:
[0006] Two rotary joints are disposed on the output end surfaces of the two drive motors, and winding rollers are detachably provided on the surfaces of the two rotary joints.
[0007] An ion generator is installed on the inner wall of the working chamber. Electrodes are provided on the symmetrical surface of the ion generator, and ion rods are provided on the symmetrical surface of the ion generator. Two ion rods are sleeved on the outside of the electrodes.
[0008] A hydraulic cylinder is mounted on the surface of the working box.
[0009] Preferably, the output end of the hydraulic cylinder is provided with a mounting bracket, and tension rollers are provided on the surface bearings symmetrically located on the mounting bracket.
[0010] The technical effect of adopting the above-mentioned further solution is that when the hydraulic cylinder works, it drives the tension roller on the surface of the mounting frame to move down and contact the release film to perform tensioning work.
[0011] Preferably, a channel is provided on one side surface of the working box, and an ion fan is detachably installed inside the channel.
[0012] The technical effect of adopting the above-mentioned further solution is that when the ion fan inside the channel is working, it blows ions toward the target area.
[0013] Preferably, the inner wall of the channel at symmetrical locations has slots, and connecting blocks are slidably embedded inside the two slots.
[0014] The technical advantage of adopting the above-mentioned further solution is that the slots opened in the inner wall of the channel facilitate the installation of the connecting blocks.
[0015] Preferably, a positioning hole is provided on one side surface of the two connecting blocks, and the two connecting blocks are connected by a U-shaped frame.
[0016] The technical effect of adopting the above-mentioned further solution is that the positioning hole opened on the surface of the connecting block facilitates the positioning work, and at the same time provides connection and fixation for the U-shaped frame.
[0017] Preferably, the inside of the spiral frame is fitted with filter cotton, and the outer surface of the channel at the symmetrical part is provided with springs.
[0018] The technical effect of adopting the above-mentioned further solution is that the filter cotton inside the recurved frame filters impurities and particles in the air, reducing contamination of the release film, while providing fixation for the spring.
[0019] Preferably, one end of each of the two springs is provided with a positioning pin, and one end of each positioning pin is movably embedded inside the positioning hole.
[0020] The technical effect of adopting the above-mentioned further solution is that when the locating pin on the surface of the spring is pulled, the locating pin moves inside the locating hole, thereby facilitating the positioning and disassembly of the connecting block.
[0021] Compared with the prior art, the advantages and positive effects of this utility model are as follows:
[0022] 1. In this utility model, when working with the hydraulic cylinder, the tension roller on the surface of the mounting frame moves down and contacts the release film to tighten it. It then approaches the ion bar, and the high-voltage power supply inside the ion generator is activated. Under the action of high voltage, the electrodes generate corona discharge, thereby generating a large number of ions. The ions generated by the electrodes are evenly distributed to the target area through the ion bar. With the ion fan working, the ion flow can directly cover the surface of the release film to remove static electricity from the release film.
[0023] 2. In this utility model, the filter cotton inside the forming frame filters the adsorbed air to prevent dust or impurities in the air from contaminating the release film. After the work is completed, the positioning pin on the spring surface is pulled to disengage the positioning pin from the inside of the positioning hole. The connecting block on the surface of the forming frame is then removed along the inside of the groove, and the filter cotton is disassembled and cleaned to reduce contamination of the release film. Attached Figure Description
[0024] Figure 1 A side view of the structure of a high-efficiency static elimination device for release film processing is provided in this utility model.
[0025] Figure 2 This utility model presents a partially unfolded structural diagram of a high-efficiency static elimination device for release film processing;
[0026] Figure 3 This utility model presents a partial cross-sectional structural diagram of a high-efficiency static elimination device for release film processing;
[0027] Figure 4 This invention proposes a high-efficiency static elimination device for release film processing. Figure 3 Enlarged structural diagram at point A in the middle.
[0028] Legend:
[0029] 1. Working box; 101. Drive motor; 1011. Rotary joint; 1012. Winding roller; 102. Channel; 1021. Groove; 1022. Reverse frame; 1023. Connecting block; 1024. Positioning hole; 1025. Spring; 1026. Positioning pin; 1027. Filter cotton; 1028. Ion fan; 103. Ion generator; 1031. Electrode; 1032. Ion rod; 104. Hydraulic cylinder; 1041. Mounting bracket; 1042. Tension roller. Detailed Implementation
[0030] To better understand the above-mentioned objectives, features, and advantages of this utility model, the present utility model will be further described below with reference to the accompanying drawings and embodiments. It should be noted that, unless otherwise specified, the embodiments and features described in these embodiments can be combined with each other.
[0031] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Therefore, the present invention is not limited to the specific embodiments disclosed in the following specification.
[0032] Example 1, as Figure 1-4 As shown, this utility model provides a high-efficiency static elimination device for release film processing, including: a working box 1; two drive motors 101, which are mounted on the surface of the working box 1 at symmetrical locations via a frame; and two rotary joints 1011, which are mounted on the output end surfaces of the two drive motors 101, with winding rollers 1012 detachably mounted on the surfaces of the two rotary joints 1011; an ion generator 103, which is mounted on the inner wall of the working box 1, with electrodes 1031 mounted on the surface of the ion generator 103 at symmetrical locations, and ion rods 1032 mounted on the surface of the ion generator 103 at symmetrical locations, with the two ion rods 1032 sleeved on the outside of the electrodes 1031; and a hydraulic cylinder 104, which is mounted on the surface of the working box 1.
[0033] In this embodiment, when working with the hydraulic cylinder 104, the tension roller 1042 on the surface of the mounting frame 1041 moves down and contacts the release film to tighten it. It then approaches the ion bar 1032, and the high-voltage power supply inside the ion generator 103 is activated. Under the action of high voltage, the electrode 1031 generates corona discharge, thereby generating a large number of ions. The ions generated by the electrode 1031 are evenly distributed to the target area through the ion bar 1032. With the operation of the ion fan 1028, the ion flow can directly cover the surface of the release film to remove static electricity from the release film.
[0034] In Example 2, a mounting bracket 1041 is provided at the output end of the hydraulic cylinder 104. A tension roller 1042 is provided on the bearing surface of the mounting bracket 1041 at a symmetrical location. A channel 102 is provided on one side surface of the working box 1. An ion fan 1028 is disassembled and installed inside the channel 102. A slot 1021 is opened on the inner wall of the channel 102 at a symmetrical location. A connecting block 1023 is slidably embedded inside the two slots 1021. A positioning hole 1024 is opened on one side surface of the two connecting blocks 1023. The two connecting blocks 1023 are connected by a U-shaped frame 1022. A filter cotton 1027 is slidably embedded inside the U-shaped frame 1022. A spring 1025 is provided on the outer surface of the channel 102 at a symmetrical location. A positioning pin 1026 is provided at one end of the two springs 1025. One end of the two positioning pins 1026 is movably embedded inside the positioning hole 1024.
[0035] In this embodiment, the filter cotton 1027 inside the forming frame 1022 filters the adsorbed air to prevent dust or impurities in the air from contaminating the release film. After the work is completed, the positioning pin 1026 on the surface of the spring 1025 is pulled to disengage the positioning pin 1026 from the inside of the positioning hole 1024. The connecting block 1023 on the surface of the forming frame 1022 is then removed along the inside of the slot 1021, and the filter cotton 1027 is disassembled and cleaned to reduce contamination of the release film.
[0036] Working principle: During use, by starting two drive motors 101, the winding rollers 1012 are rotated via the rotary joint 1011. The two winding rollers 1012 are the placement roller and the take-up roller, respectively. When working with the hydraulic cylinder 104, the tension roller 1042 on the surface of the mounting frame 1041 moves down and contacts the release film to tighten it. It then approaches the ion bar 1032. The high-voltage power supply inside the ion generator 103 is then activated. Under the action of high voltage, the electrode 1031 generates corona discharge, thereby producing a large number of ions. The ions generated by the electrode 1031 are evenly distributed to the target area by the ion bar 1032. In conjunction with the ion fan 1028, the ion stream can directly cover the surface of the release film to remove static electricity. After operation, the filter cotton 1027 inside the forming frame 1022 filters the adsorbed air to prevent dust or impurities in the air from contaminating the release film. After operation, the positioning pin 1026 on the surface of the spring 1025 is pulled to disengage the positioning pin 1026 from the interior of the positioning hole 1024. The connecting block 1023 on the surface of the forming frame 1022 is then removed along the interior of the slot 1021, and the filter cotton 1027 is disassembled and cleaned to reduce contamination of the release film.
[0037] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the technical solution of the present utility model.
Claims
1. A high efficiency static elimination apparatus for release film processing, comprising: Workbox (1); Two drive motors (101) are mounted on the surface of the work box (1) symmetrically via a frame; characterized in that it further includes: Two rotary joints (1011) are disposed on the output end surfaces of the two drive motors (101), and winding rollers (1012) are detachably disposed on the surfaces of the two rotary joints (1011). An ion generator (103) is disposed on the inner wall of the working box (1). Electrodes (1031) are disposed on the surface of the ion generator (103) at a symmetrical location. Ion rods (1032) are disposed on the surface of the ion generator (103) at a symmetrical location. Two ion rods (1032) are sleeved on the outside of the electrodes (1031). A hydraulic cylinder (104) is disposed on the surface of the working box (1).
2. The efficient electrostatic elimination device for release film processing according to claim 1, characterized in that: The output end of the hydraulic cylinder (104) is provided with a mounting bracket (1041), and tension rollers (1042) are provided on the surface bearings at the symmetrical positions of the mounting bracket (1041).
3. The efficient electrostatic elimination device for release film processing according to claim 2, characterized in that: A channel (102) is provided on one side surface of the working box (1), and an ion fan (1028) is disassembled and installed inside the channel (102).
4. The efficient electrostatic elimination device for release film processing according to claim 3, characterized in that: The inner wall of the channel (102) at the symmetrical location is provided with slots (1021), and connecting blocks (1023) are slidably embedded in the two slots (1021).
5. The efficient electrostatic elimination device for release film processing according to claim 4, characterized in that: Positioning holes (1024) are provided on one side surface of the two connecting blocks (1023), and the two connecting blocks (1023) are connected by a spiral bracket (1022).
6. The efficient electrostatic elimination device for release film processing according to claim 5, characterized in that: The filter cotton (1027) is slidably embedded inside the spiral frame (1022), and springs (1025) are provided on the outer surface of the channel (102) at the symmetrical position.
7. The efficient electrostatic elimination device for release film processing according to claim 6, characterized in that: One end of each of the two springs (1025) is provided with a positioning pin (1026), and one end of each positioning pin (1026) is movably embedded in the positioning hole (1024).