A rapid drying device for electroplating
The multiple drying mechanisms, including high-speed airflow driven by a circulating pump, infrared heating, and low-temperature hot air circulation, solve the problem of rapid drying of surface moisture after electroplating, achieving efficient and uniform drying, adapting to workpieces of different shapes, and ensuring coating quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI FENGYUAN ELECTROPLATING CO LTD
- Filing Date
- 2025-08-15
- Publication Date
- 2026-07-03
AI Technical Summary
Residual moisture on the surface of electroplated workpieces is difficult to dry quickly, leading to rust, peeling of the plating layer, and spots, which affects product quality and production progress. Existing drying methods are inefficient and uneven.
The system employs a high-speed airflow driven by a circulating pump, combined with infrared heating and low-temperature hot air circulation. It heats deep moisture through infrared radiation, and combines an electric telescopic rod with a fixed clamping device. A multi-stage filtration system ensures a clean drying environment.
It significantly improves drying efficiency and uniformity, avoids coating damage, ensures product quality and production efficiency, and is adaptable to workpieces of different shapes.
Smart Images

Figure CN224455196U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of electroplating drying technology, specifically to a rapid drying device for electroplating. Background Technology
[0002] In the electroplating industry, residual moisture remains on the surface of electroplated workpieces. If not dried promptly, this can easily lead to surface corrosion, peeling of the plating, or the formation of spots. This not only affects the appearance and performance of the product but may also adversely impact subsequent assembly and coating processes. Therefore, the drying process after electroplating is a crucial step in ensuring the quality of electroplated products, and its efficiency and effectiveness directly affect production progress and product qualification rate.
[0003] Currently, the natural air drying commonly used in the electroplating industry relies on ambient temperature and humidity, resulting in a long drying cycle that cannot meet the needs of industrial mass production. Traditional hot air drying often uses static blowing, which results in poor air circulation and slow moisture evaporation. This is especially true for workpieces with complex structures or deep holes and grooves, where it is difficult to dry the interior and hidden parts quickly. Utility Model Content
[0004] The purpose of this invention is to provide a rapid drying device for electroplating to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a rapid drying device for electroplating, comprising a drying chamber and a filter chamber. The interior of the drying chamber is evenly arranged with compartments via partitions. Each compartment has an infrared heating tube installed on its inner wall, and each compartment has a U-shaped frame installed inside. Spray nozzles are evenly arranged on the inner side of the U-shaped frame. The bottom end of the U-shaped frame extends to the outside of the drying chamber and is connected to a driven gear. A servo motor is installed at the bottom of one side of the drying chamber, and a drive gear is installed at the output end of the servo motor. A chain is fixedly connected between the drive gear and the driven gear.
[0006] The top of the drying chamber is uniformly equipped with electric telescopic rods. The output end of each electric telescopic rod extends into the interior of each chamber and is equipped with a crossbar. Both ends of the crossbar are fixed with clamps through sleeves. A circulation pump and a filter box are arranged side by side on one side of the drying chamber. The input end of the circulation pump is connected to the filter box. The input end of the filter box is connected to the air extraction pipe on the back of the drying chamber through a conduit. The output end of the circulation pump extends to the bottom of the drying chamber and is connected to a distribution pipe. Branch pipes are uniformly arranged at the top of the distribution pipe. The top end of each branch pipe is connected to the airflow channel inside the U-shaped frame through a sealed bearing.
[0007] Preferably, the air extraction pipe runs through each chamber, and the inner wall of the distribution pipe is uniformly provided with air holes.
[0008] Preferably, the driven gear, the drive gear, and the bottom of the drying chamber outside the chain are equipped with protective covers.
[0009] Preferably, the bottom of the drying chamber is provided with a base frame, a controller is installed on one side of the drying chamber, and the inner wall of the drying chamber is uniformly covered with a heat insulation layer.
[0010] Preferably, each of the chambers is equipped with a temperature sensor inside, and each chamber has a sealed door hinged to the drying chamber on the outside, with a viewing window on the sealed door.
[0011] Preferably, each of the branch pipes is equipped with a solenoid valve, and each solenoid valve is individually controlled.
[0012] Preferably, the inner wall of the chamber is provided with a groove for accommodating the infrared heating tube.
[0013] Preferably, the interior of the filter box is sequentially provided with polypropylene needle-punched cotton, glass fiber felt, honeycomb activated carbon and HEPA filter paper, and the polypropylene needle-punched cotton, glass fiber felt, honeycomb activated carbon and HEPA filter paper can all be detachably installed inside the filter box.
[0014] Preferably, the inner diameter of the sleeve is larger than the outer diameter of the crossbar, and a locking bolt is provided on one side of the sleeve.
[0015] This invention provides a rapid drying device for electroplating, which has significant advantages over existing technologies, as detailed below:
[0016] 1. A circulating pump drives the airflow inside the drying chamber, creating a high-speed airflow that quickly removes free moisture from the workpiece surface. This significantly improves drying efficiency and shortens drying time, resulting in a substantial increase in production efficiency compared to traditional drying methods. Infrared heating tubes are evenly distributed on the inner wall of each chamber, using infrared radiation to penetrate the coating surface and directly heat deep-seated moisture. This heating method is not only fast but also provides uniform heating, avoiding coating quality problems caused by uneven heating in traditional methods.
[0017] 2. This device combines multiple drying mechanisms, including high-speed airflow stripping, infrared radiation heating, and low-temperature hot air circulation. High-speed airflow first strips surface moisture, infrared radiation heats deeper moisture, and finally, low-temperature hot air circulation removes evaporated water vapor. This synergistic effect of multiple mechanisms not only improves drying efficiency but also ensures the uniformity and thoroughness of the drying process, solving the problems of low efficiency and uneven heating associated with single drying methods.
[0018] 3. The design employs low-temperature hot air circulation to remove evaporated moisture, effectively preventing damage to the coating from high temperatures. Traditional high-temperature drying methods easily lead to problems such as coating deformation and discoloration, while this device ensures the quality and appearance of the coating through reasonable temperature control.
[0019] 4. The electric telescopic rod drives the crossbar, which clamps the workpiece and moves it up and down, ensuring that the workpiece is heated evenly during the drying process. This not only improves the drying effect but also increases the applicability of the device, making it suitable for workpieces of different shapes and sizes.
[0020] 5. The filter box contains, in sequence, polypropylene needle-punched cotton, glass fiber felt, honeycomb activated carbon, and HEPA filter paper. These filter materials are removable for easy maintenance and replacement. This filtration system effectively removes dust and harmful gases generated during the drying process, ensuring a clean drying environment and improving product quality. Attached Figure Description
[0021] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of this utility model and should not be regarded as a limitation on the scope. For those skilled in the art, other related drawings can be obtained based on these drawings without creative effort.
[0022] Figure 1 This is a schematic diagram of the internal structure of the present invention;
[0023] Figure 2 This is a schematic diagram of the U-shaped frame structure of this utility model;
[0024] Figure 3 This is a schematic diagram of the filter box structure of this utility model;
[0025] Figure 4 This is a schematic diagram of the main structure of the fixing clip of this utility model;
[0026] Figure 5 This is a side view of the fixing clip structure of this utility model;
[0027] Figure 6 This is a schematic diagram of the main structure of this utility model;
[0028] In the diagram: 1. Base frame; 2. Circulating pump; 3. Drying chamber; 4. Filter box; 5. Conduit; 6. Viewing window; 7. Chamber; 8. Electric telescopic rod; 9. Sealed door; 10. Controller; 11. Servo motor; 12. Protective cover; 13. Branch pipe; 14. Distribution pipe; 15. Exhaust pipe; 16. Partition; 17. Insulation layer; 18. U-shaped frame; 19. Air vent; 20. Groove; 21. Temperature sensor; 22. Nozzle; 23. Drive gear; 24. Chain; 25. Solenoid valve; 26. Driven gear; 27. Infrared heating tube; 28. Airflow channel; 29. Sealed bearing; 30. Fixing clamp; 31. Sleeve; 32. Locking bolt; 33. Polypropylene needle-punched cotton; 34. Fiberglass felt; 35. Honeycomb activated carbon; 36. HEPA filter paper; 37. Crossbar. Detailed Implementation
[0029] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the scope of protection of the present utility model.
[0030] Please see Figure 1-6 This utility model provides an embodiment of a rapid drying device for electroplating, comprising a drying chamber 3 and a filter chamber 4. A base frame 1 is provided at the bottom of the drying chamber 3, and a controller 10 is installed on one side of the drying chamber 3. An insulation layer 17 is evenly laid on the inner wall of the drying chamber 3, and compartments 7 are evenly arranged inside the drying chamber 3 via partitions 16. A temperature sensor 21 is installed inside each compartment 7, and a sealing door 9 is hinged to the outer side of each compartment 7 of the drying chamber 3, with a viewing window 6 provided on the sealing door 9.
[0031] Base frame 1: The bottom of the drying chamber 3 is equipped with a base frame 1, which is made of high-strength steel and has good load-bearing capacity to ensure the stability and safety of the entire device. The bottom of the base frame 1 is equipped with adjustable feet to facilitate the adjustment of the device's level on different ground surfaces.
[0032] Drying chamber 3: The drying chamber 3 is the main part of the device, made of high-quality stainless steel, which has good corrosion resistance and high temperature resistance. The inner wall of the drying chamber 3 is evenly covered with a heat insulation layer 17, which is made of silicate insulation material, which can effectively reduce heat loss and improve drying efficiency.
[0033] Controller 10: A controller 10 is installed on one side of the drying chamber 3. The controller 10 is used to set and adjust parameters such as temperature and time during the drying process. The controller 10 is connected to the temperature sensor 21 in each chamber 7 via a cable to monitor and adjust the temperature of each chamber in real time.
[0034] Chamber 7: Multiple chambers 7 are evenly arranged inside the drying chamber 3 via partitions 16. Each chamber 7 has a volume of 50L. The partitions 16 are made of high-temperature resistant composite material to ensure heat insulation between the chambers 7. Each chamber 7 is equipped with a temperature sensor 21, which is a high-precision Pt100 platinum resistance sensor that can accurately measure the temperature inside the chamber.
[0035] Sealed door 9: Each compartment 7 is hinged to the drying chamber 3 on the outside. The sealed door 9 is made of the same stainless steel as the drying chamber 3, and the edges of the door are fitted with high-temperature resistant sealing strips to ensure the sealing performance of the compartment 7. A viewing window 6 is provided on the sealed door 9. The viewing window 6 is made of high-temperature resistant tempered glass, which allows the operator to observe the drying status inside the compartment.
[0036] Each chamber 7 has an infrared heating tube 27 installed on its inner wall. The inner wall of the chamber 7 has a groove 20 for accommodating the infrared heating tube 27. Each chamber 7 has a U-shaped frame 18 installed inside. Spray nozzles 22 are evenly arranged on the inner side of the U-shaped frame 18. The bottom end of the U-shaped frame 18 extends to the outside of the drying chamber 3 and is connected to a driven gear 26. A servo motor 11 is installed at the bottom of one side of the drying chamber 3. A drive gear 23 is installed at the output end of the servo motor 11. A chain 24 is fixedly connected between the drive gear 23 and the driven gear 26.
[0037] A protective cover 12 is installed at the bottom of the drying chamber 3 outside the driven gear 26, the drive gear 23, and the chain 24.
[0038] The drying equipment includes multiple chambers 7, each with an infrared heating tube 27 installed on its inner wall. The infrared heating tube 27 provides a uniform heat source, ensuring even heating of the workpiece during the drying process. To better secure and protect the infrared heating tube 27, the inner wall of the chamber 7 is specially designed with a groove 20 to accommodate it. The shape of the groove 20 matches the shape of the infrared heating tube 27, ensuring it is securely embedded and preventing displacement during equipment operation.
[0039] Inside each chamber 7, a U-shaped frame 18 is installed. The main function of the U-shaped frame 18 is to support and fix the nozzles 22, ensuring that the nozzles 22 can spray airflow evenly during the drying process. Multiple nozzles 22 are evenly arranged on the inner side of the U-shaped frame 18. The number and distribution of the nozzles 22 are optimized according to the actual drying requirements to ensure that the workpiece can be heated and dried evenly.
[0040] The bottom end of the U-shaped frame 18 extends to the outside of the drying chamber 3 and is connected to the driven gear 26. The function of the driven gear 26 is to drive the U-shaped frame 18 to rotate through the transmission mechanism, so that the nozzle 22 can spray the workpiece in all directions.
[0041] A servo motor 11 is installed at the bottom of one side of the drying chamber 3. The servo motor 11 features high precision and high reliability, providing stable power output. A drive gear 23 is installed at the output end of the servo motor 11, and the drive gear 23 is fixedly connected to the driven gear 26 via a chain 24. The chain 24 transmits the power of the servo motor 11 to the driven gear 26, thereby driving the U-shaped frame 18 to rotate.
[0042] To ensure the safe operation of the equipment, a protective cover 12 is installed on the bottom of the drying chamber 3 outside the driven gear 26, drive gear 23, and chain 24. The function of the protective cover 12 is to prevent foreign objects from entering the transmission mechanism and avoid equipment failure caused by foreign objects getting stuck. At the same time, the protective cover 12 can also effectively prevent dust and impurities from entering the transmission mechanism, extending the service life of the equipment.
[0043] Electric telescopic rods 8 are evenly arranged on the top of the drying chamber 3. The output end of each electric telescopic rod 8 extends into the interior of each chamber 7 and is provided with a crossbar 37. Both ends of the crossbar 37 are provided with fixing clamps 30 through sleeves 31. The inner diameter of the sleeves 31 is larger than the outer diameter of the crossbar 37, and a locking bolt 32 is provided on one side of the sleeves 31.
[0044] The electric telescopic rod 8 is installed on the top of the drying chamber 3 and its telescopic function is realized by an electric drive device. The output end of the electric telescopic rod 8 extends into the interior of the chamber 7 and is used to support and adjust the position of the crossbar 37.
[0045] Inside each chamber 7, a crossbar 37 is provided at the output end of the electric telescopic rod 8. The two ends of the crossbar 37 are connected to the fixing clamp 30 through sleeves 31. The main function of the crossbar 37 is to suspend or place items to be dried, ensuring that the items are heated evenly during the drying process.
[0046] The inner diameter of the sleeve 31 is larger than the outer diameter of the crossbar 37, allowing the crossbar 37 to slide freely within the sleeve 31. A locking bolt 32 is provided on one side of the sleeve 31 to fix the position of the crossbar 37. The fixing clamp 30 is connected to the sleeve 31 via the locking bolt 32 to ensure that the crossbar 37 is fixed in the required position.
[0047] A circulation pump 2 and a filter box 4 are arranged side by side on one side of the drying chamber 3. The filter box 4 contains polypropylene needle-punched cotton 33, glass fiber felt 34, honeycomb activated carbon 35 and HEPA filter paper 36 in sequence. All of the polypropylene needle-punched cotton 33, glass fiber felt 34, honeycomb activated carbon 35 and HEPA filter paper 36 can be detached and installed inside the filter box 4.
[0048] A circulation pump 2 and a filter box 4 are arranged side by side on one side of the drying chamber 3. The circulation pump 2 is used to drive the air circulation inside the drying chamber, while the filter box 4 is used to perform multi-stage filtration of the circulating air to ensure the air quality inside the drying chamber.
[0049] The interior of filter box 4 contains, in sequence, polypropylene needle-punched cotton 33, glass fiber felt 34, honeycomb activated carbon 35, and HEPA filter paper 36. These filter materials are arranged in a specific order to achieve step-by-step filtration of air.
[0050] Polypropylene needle-punched cotton 33: Located at the very front of filter box 4, it is mainly used to filter large particulate impurities in the air. Polypropylene needle-punched cotton 33 has good air permeability and high filtration efficiency, and can effectively intercept larger dust particles.
[0051] Fiberglass mat 34: Following polypropylene needle-punched cotton 33, it is used for further filtration of fine particles in the air. Fiberglass mat 34 has a fine fiber structure, which can effectively capture smaller dust particles.
[0052] Honeycomb activated carbon 35: Located after glass fiber felt 34, it is mainly used to adsorb harmful gases and odors in the air. Honeycomb activated carbon 35 has a large specific surface area and strong adsorption capacity, and can effectively remove harmful substances from the air.
[0053] HEPA filter paper 36: Located at the rear of filter chamber 4, it is used for high-efficiency filtration of tiny particles in the air, including bacteria and viruses. HEPA filter paper 36 has extremely high filtration efficiency, ensuring that the air inside the drying chamber reaches a high level of cleanliness.
[0054] The input end of the circulating pump 2 is connected to the filter box 4. The input end of the filter box 4 is connected to the air extraction pipe 15 set on the back of the drying box 3 through the conduit 5. The air extraction pipe 15 runs through each chamber 7, and the inner wall of the distribution pipe 14 is evenly provided with air holes 19.
[0055] The output end of the circulating pump 2 extends to the bottom of the drying chamber 3 and is connected to a distribution pipe 14. The top of the distribution pipe 14 is evenly provided with branch pipes 13, and the top of each branch pipe 13 is connected to the airflow channel 28 provided inside the U-shaped frame 18 through a sealed bearing 29.
[0056] Each branch pipe 13 is equipped with a solenoid valve 25, and each solenoid valve 25 is controlled independently.
[0057] The input end of the circulating pump 2 is connected to the output end of the filter box 4 via a conduit. The input end of the filter box 4 is connected to the air extraction pipe 15 located on the back of the drying chamber 3 via a conduit 5. The air extraction pipe 15 runs through each chamber 7 inside the drying chamber 3, ensuring that air can be evenly extracted from each chamber. The inner wall of the air extraction pipe 15 is evenly provided with air holes 19. The design of these air holes 19 makes the air extraction process more efficient and can evenly extract moisture from each chamber.
[0058] The output end of the circulating pump 2 extends to the bottom of the drying chamber 3 and is connected to a distribution pipe 14. Several branch pipes 13 are evenly arranged on the top of the distribution pipe 14, and the top end of each branch pipe 13 is connected to the airflow channel 28 inside the U-shaped frame 18 via a sealed bearing 29. The design of the sealed bearing 29 ensures smooth airflow while preventing gas leakage.
[0059] Each branch pipe 13 is equipped with a solenoid valve 25, which independently controls the opening and closing of the corresponding branch pipe 13. Through the individual control of the solenoid valve 25, independent drying of each chamber 7 can be achieved, thereby improving drying efficiency and drying effect.
[0060] When this application embodiment is used,
[0061] Open the sealing door 9 on the outer drying chamber 3 of the chamber 7. According to the size of the workpiece to be dried, loosen the locking bolt 32 on one side of the sleeve 31, slide the position of the sleeve 31 on the crossbar 37, adjust the distance between the two fixing clamps 30, then clamp and fix the workpiece through the fixing clamps 30, tighten the locking bolt 32 to fix the position of the sleeve 31, and close the sealing door 9.
[0062] The drying temperature, drying time and other parameters are set by the controller 10 on one side of the drying chamber 3. The temperature sensor 21 will monitor the internal temperature of the chamber 7 in real time and feed it back to the controller 10.
[0063] The device is started by the controller 10, and the servo motor 11, circulation pump 2, infrared heating tube 27 and other components start to work; the infrared heating tube 27 heats the inside of the chamber 7, and its heat is evenly distributed into the chamber 7 through the groove 20.
[0064] The circulating pump 2 operates, drawing air from each chamber 7 through the air extraction pipe 15 on the back of the drying chamber 3 (using the air holes 19 on its inner wall). The air enters the filter box 4 through the duct 5, and is filtered and purified in sequence through polypropylene needle-punched cotton 33, glass fiber felt 34, honeycomb activated carbon 35, and HEPA filter paper 36. The purified air is then transported by the circulating pump 2 to the distribution pipe 14, and then through the branch pipe 13 at the top of the distribution pipe 14 (which is individually controlled by the solenoid valve 25). The air then enters the airflow channel 28 inside the U-shaped frame 18 through the sealed bearing 29, and finally is sprayed out from the nozzle 22 on the inner side of the U-shaped frame 18 as a high-speed airflow, which can quickly remove free moisture from the surface of the workpiece. After a period of time, the power of the air extraction pipe 15 and the infrared heating tube 27 is reduced to form a low-temperature hot air circulation, which carries away the water vapor evaporated from the workpiece.
[0065] The drive gear 23 at the output end of the servo motor 11 rotates, which drives the driven gear 26 to rotate through the chain 24, thereby driving the U-shaped frame 18 to rotate, so that the nozzle 22 can spray airflow onto the workpiece from all directions; at the same time, the electric telescopic rod 8 can drive the crossbar 37 and the workpiece to move up and down, ensuring that all parts of the workpiece are heated and the airflow is blown evenly.
[0066] Operators can observe the drying status of the workpieces inside the chamber 7 through the viewing window 6 on the sealed door 9. The controller 10 adjusts the working status of the infrared heating tube 27 in real time based on the feedback from the temperature sensor 21 to maintain the set temperature.
[0067] After the drying time reaches the set value, the device will automatically stop running. Once the internal temperature of the chamber 7 drops to a suitable range, open the sealed door 9, loosen the fixing clamp 30 to remove the dried workpiece, and turn off the controller 10.
[0068] Obviously, the embodiments described above are only some embodiments of this utility model, and not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort should fall within the protection scope of this utility model.
[0069] It should be noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the exemplary embodiments according to this application. As used herein, the singular form is intended to include the plural form as well, unless the context clearly indicates otherwise. Furthermore, it should be understood that when the terms "comprising" and / or "including" are used in this specification, they indicate the presence of features, steps, operations, devices, components, and / or combinations thereof.
[0070] It should be noted that the terms "first," "second," etc., used in the specification, claims, and accompanying drawings of this application are used to distinguish similar objects and are not necessarily used to describe a specific order or sequence. It should be understood that such data can be interchanged where appropriate so that the embodiments of this application described herein can be implemented in sequences other than those illustrated or described herein.
[0071] The above are merely preferred embodiments of this utility model and are not intended to limit the scope of this utility model. Various modifications and variations can be made to this utility model by those skilled in the art. Any modifications, equivalent substitutions, or improvements made within the spirit and principles of this utility model should be included within the protection scope of this utility model.
Claims
1. A quick drying device for electroplating comprising a drying chamber (3) and a filtering chamber (4), characterized in that: The drying chamber (3) is equipped with compartments (7) evenly arranged inside through partitions (16). Each compartment (7) has an infrared heating tube (27) installed on its inner wall. Each compartment (7) is also equipped with a U-shaped frame (18). Spray nozzles (22) are evenly arranged on the inner side of the U-shaped frame (18). The bottom end of the U-shaped frame (18) extends to the outside of the drying chamber (3) and is connected to a driven gear (26). A servo motor (11) is installed at the bottom of one side of the drying chamber (3). A drive gear (23) is installed at the output end of the servo motor (11). A chain (24) is fixedly connected between the drive gear (23) and the driven gear (26). The top of the drying chamber (3) is uniformly provided with electric telescopic rods (8). The output end of each electric telescopic rod (8) extends into the interior of each chamber (7) and is provided with a crossbar (37). Both ends of the crossbar (37) are provided with fixing clips (30) through sleeves (31). A circulation pump (2) and a filter box (4) are arranged side by side on one side of the drying chamber (3). The input end of the circulation pump (2) is connected to the filter box (4). The input end of the filter box (4) is connected to the air extraction pipe (15) provided on the back of the drying chamber (3) through a conduit (5). The output end of the circulation pump (2) extends to the bottom of the drying chamber (3) and is connected to a distribution pipe (14). The top of the distribution pipe (14) is uniformly provided with branch pipes (13). The top end of each branch pipe (13) is connected to the airflow channel (28) provided inside the U-shaped frame (18) through a sealed bearing (29).
2. A rapid drying device for electroplating according to claim 1, characterized in that: The air extraction pipe (15) penetrates each chamber (7), and the inner wall of the distribution pipe (14) is uniformly provided with air holes (19).
3. A rapid drying device for electroplating according to claim 1, characterized in that: A protective cover (12) is installed at the bottom of the drying chamber (3) outside the driven gear (26), the drive gear (23) and the chain (24).
4. A rapid drying device for electroplating according to claim 1, characterized in that: The bottom of the drying chamber (3) is provided with a base frame (1), a controller (10) is installed on one side of the drying chamber (3), and the inner wall of the drying chamber (3) is evenly covered with a heat insulation layer (17).
5. A rapid drying device for electroplating according to claim 1, characterized in that: Each of the chambers (7) is equipped with a temperature sensor (21), and each chamber (7) is hinged to a sealing door (9) on the outside of the drying chamber (3), with a viewing window (6) on the sealing door (9).
6. A rapid drying device for electroplating according to claim 1, characterized in that: Each of the branch pipes (13) is equipped with a solenoid valve (25), and each solenoid valve (25) is individually controlled.
7. The rapid drying apparatus for electroplating according to claim 1, characterized in that: The inner wall of the chamber (7) is provided with a groove (20) for accommodating the infrared heating tube (27).
8. A rapid drying device for electroplating according to claim 1, characterized in that: The filter box (4) is provided with polypropylene needle-punched cotton (33), glass fiber felt (34), honeycomb activated carbon (35) and HEPA filter paper (36) in sequence, and the polypropylene needle-punched cotton (33), glass fiber felt (34), honeycomb activated carbon (35) and HEPA filter paper (36) can all be detached and installed inside the filter box (4).
9. A rapid drying device for electroplating according to claim 1, characterized in that: The inner diameter of the sleeve (31) is greater than the outer diameter of the crossbar (37), and one side of the sleeve (31) is provided with a locking bolt (32).