A printing and dyeing fabric drying equipment with static electricity elimination function
By introducing a synchronous rotation mechanism into the dyeing and printing fabric drying equipment, and using the meshing transmission of the transmission chain and sprocket to achieve synchronous movement of the fixed arc plate, the problems of fabric entanglement and incomplete static elimination caused by static accumulation are solved, and the static elimination effect is improved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUANGGANG YUHE TEXTILE CO LTD
- Filing Date
- 2025-07-14
- Publication Date
- 2026-06-12
AI Technical Summary
During the drying process of printed and dyed fabrics, static electricity accumulation causes the fabric to attract dust, entangle equipment, or affect subsequent processing. Existing technologies rely on manual handheld conductive brushes to eliminate static electricity, which is not very effective and makes it difficult to ensure that the fabric can fully stretch.
Design a drying device for printed and dyed fabrics with static elimination function. It adopts a synchronous rotation mechanism driven by a bidirectional lead screw, transmission sleeve, transmission chain and servo motor. Through the meshing transmission of transmission sprocket and chain, the synchronous movement of the fixed arc plate is realized to ensure that the fabric is fully extended and flattened, and the static electricity is effectively eliminated by conductive bristles.
This allows the fabric to be fully stretched and laid flat, improving the quality of static electricity elimination and ensuring that the conductive bristles are in full contact with the fabric surface, thus enhancing the static electricity elimination effect.
Smart Images

Figure CN224353525U_ABST
Abstract
Description
Technical Field
[0001] This utility model applies to the field of printing and dyeing fabric processing technology, and in particular relates to a printing and dyeing fabric drying equipment with static electricity elimination function. Background Technology
[0002] Currently, fabrics are commonly used in decorative materials. These include various types of fabrics such as synthetic fiber carpets, non-woven wall coverings, linen, nylon, colored adhesive tape, and flannel. However, static electricity accumulation is a common problem during the drying process of printed and dyed fabrics. This can cause the fabric to attract dust, entangle equipment, or affect subsequent processing. Therefore, after drying, it is necessary to eliminate the static electricity accumulated on the surface of the fabric.
[0003] However, currently, when eliminating static electricity from dried fabrics, the operator often holds a conductive brush and brushes it against the fabric surface. The conductive plastic and bristles on the brush guide away the accumulated static electricity. During this process, to ensure sufficient contact with the fabric surface, the operator needs to pull the fabric to fully extend and flatten it, avoiding wrinkles that could affect the contact between the conductive brush and the fabric surface, thus easily impacting the quality of static electricity elimination. Therefore, we propose a drying device for printed and dyed fabrics with static electricity elimination function. Utility Model Content
[0004] The main purpose of this invention is to provide a drying device for printed and dyed fabrics with static electricity elimination function, which can effectively solve the problems in the background art.
[0005] To achieve the above objectives, the technical solution adopted by this utility model is as follows:
[0006] A fabric drying device with static electricity elimination function, wherein support plates are vertically fixedly installed on both sides of the top of the mounting base, and a fixing pipe is fixedly installed through the inside of the top side of each support plate, and a fixing frame is fixedly installed at the top of the side of the fixing pipe.
[0007] A connecting arc plate is movably arranged on the outside of the fixed frame, and a fixed arc plate is fixedly installed on the outside of the connecting arc plate. A driving mechanism is arranged inside the fixed frame, and a connecting mechanism is arranged between the outside of the driving mechanism and the outside of the connecting arc plate.
[0008] A hollow frame is fixedly installed between the outer top ends of the two sets of support plates. A synchronous rotation mechanism is provided inside the hollow frame, and the synchronous rotation mechanism and the drive mechanism are connected in transmission.
[0009] As an optional solution to the technical solution of this application, the driving mechanism includes a bidirectional lead screw, and transmission sleeves are threadedly connected to both sides of the bidirectional lead screw. A fixing rod is vertically fixedly installed on the top of the outer side of each transmission sleeve. Limiting grooves are opened inside both ends of the side of each fixing frame, and the top of the side of the fixing rod is slidably inserted into the limiting groove. Transmission frames are slidably installed on both sides of the outer side of the fixing frame, and the top of the side of the fixing rod is fixedly connected to the side of the transmission frame. Conductive bristles are fixedly installed on the outer side of the fixing arc plate, and the number of conductive bristles is several sets.
[0010] By adopting the above technical solution, the transmission sleeve can be synchronously and relatively translated when the bidirectional lead screw rotates, thus providing the driving force required for the horizontal movement of the transmission frame.
[0011] As an optional solution to the technical solution of this application, connecting blocks are fixedly installed at both ends of the connecting arc plate near the fixed frame. The bottom of each connecting block is inclinedly hinged to a push rod through a rotating shaft, and the sides of the push rod are rotatably hinged to the outside of the transmission frame through the rotating shaft. Limiting slide rods are vertically fixedly installed at the four corners of the connecting arc plate near the fixed frame. Guide slide grooves are vertically opened inside the four corners of the outside of the fixed frame, and the limiting slide rods are slidably inserted into the guide slide grooves.
[0012] By adopting the above technical solution, the horizontal moving force of the transmission frame can be converted into a vertical pushing force on the connecting arc plate by the connecting conversion action of the push rod, so that the connecting arc plate can move vertically outside the fixed frame and adjust the distance between the sides of the two sets of connecting arc plates.
[0013] As an optional solution to the technical solution of this application, the synchronous rotation mechanism includes a transmission chain and a transmission sprocket. A transmission rod is fixedly installed on the top side of each of the bidirectional lead screws, and the top side of the transmission rod is rotatably installed inside the hollow frame through a bearing. A transmission sprocket is fixedly sleeved on the outside of each of the transmission rods. A transmission chain is meshed between the outer sides of the two sets of transmission sprockets, and both the transmission sprocket and the transmission chain are rotatably disposed inside the hollow frame. A servo motor is fixedly installed on the outer side of the hollow frame, and the transmission shaft of the servo motor is fixedly connected to the top side of the transmission rod through a coupling.
[0014] By adopting the above technical solution, the servo motor can provide synchronous driving force to the transmission rod and the bidirectional lead screw after the servo motor is running, through the meshing transmission action of the transmission sprocket and the transmission chain. This ensures the synchronous movement and adjustment of the two sets of fixed arc plates, and ensures that the fixed arc plates exert the same force on both sides of the printed and dyed fabric, further ensuring the full extension and flattening of the printed and dyed fabric.
[0015] Compared with the prior art, the present invention has the following beneficial effects:
[0016] 1. The present application discloses a drying device for printed and dyed fabrics with static elimination function. This device comprises two sets of fixed frames on the outside of the drying chamber, and connecting arc plates and fixed arc plates positioned one above and one below the two sets of fixed frames. After drying, the fabric can pass through the outer wall of the fixed arc plates from top to bottom. Simultaneously, the rotation of the transmission sleeves on both sides of the fixed frame, driven by a bidirectional screw rod inside the fixed frame, causes the two sets of transmission sleeves to move relative to each other within the fixed frame. This movement, connected by a fixed rod, drives the transmission frame to move horizontally relative to each other outside the fixed frame. The horizontal movement force of the transmission frame is then converted into a vertical pushing force on the connecting arc plates by a push rod. This allows the two sets of connecting arc plates and the fixed arc plates to move synchronously relative to each other, increasing the distance between the fixed arc plates and simultaneously pushing and spreading the printed and dyed fabric on its outer side. This allows the fabric to fully extend and flatten, ensuring that the conductive brush can fully contact the fabric surface and brush away the accumulated static electricity, thus improving the quality of static elimination on the printed and dyed fabric surface.
[0017] 2. The present application provides a drying device for printed and dyed fabrics with electrostatic elimination function. By setting a transmission chain inside the hollow frame and a transmission sprocket outside the transmission rod, the servo motor can provide synchronous driving force to the transmission rod and the bidirectional lead screw after the servo motor is running. This ensures the synchronous movement and adjustment of the two sets of fixed arc plates, and ensures that the fixed arc plates exert the same force on both sides of the printed and dyed fabric, further ensuring the full stretching and flattening of the printed and dyed fabric. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the overall three-dimensional structure of a drying equipment for printed and dyed fabrics with static electricity elimination function according to this utility model.
[0019] Figure 2 This is a schematic diagram of the internal side cross-sectional structure of the fixing frame of a printing and dyeing fabric drying device with static electricity elimination function according to the present invention.
[0020] Figure 3 This is a schematic diagram of the internal side cross-sectional structure of the hollow frame of a drying device for printed and dyed fabrics with static electricity elimination function according to this utility model.
[0021] Reference numerals: 1. Mounting base; 11. Drying oven; 12. Support plate; 13. Fixing tube; 14. Fixing frame; 2. Two-way lead screw; 21. Transmission sleeve; 22. Fixing rod; 23. Transmission frame; 24. Connecting arc plate; 25. Connecting block; 26. Push rod; 27. Fixing arc plate; 28. Conductive brush bristles; 29. Limiting slide groove; 3. Hollow frame; 31. Transmission sprocket; 32. Transmission chain; 33. Servo motor; 4. Limiting slide rod; 41. Guide slide groove. Detailed Implementation
[0022] like Figure 1-3 As shown, this utility model provides a technical solution: a drying device for printed and dyed fabrics with static electricity elimination function. A drying box 11 is provided on the top side of the mounting base 1. A warm air mechanism is provided inside the drying box 11, which can generate corresponding hot air during operation, so that the surface of the fabric passing through the drying box 11 can be dried. A connecting arc plate 24 is movably provided on the outside of the fixed frame 14. A fixed arc plate 27 is fixedly installed on the outside of the connecting arc plate 24. Conductive bristles 28 are fixedly installed on the outside of the fixed arc plate 27, and there are several sets of conductive bristles 28. The two sets of fixed arc plates 27 are diagonally arranged, one above the other, on the outside of the drying box 11, so that when the fabric passes through the drying box 11 after drying, it adheres to the outer wall of the two sets of fixed arc plates 27 from top to bottom.
[0023] In this technical solution (through Figure 1 , Figure 2 and Figure 3 As shown, each bidirectional lead screw 2 has a transmission rod fixedly installed on its side top, and the transmission rod side top is rotatably installed inside the hollow frame 3 through a bearing. Each transmission rod has a transmission sprocket 31 fixedly sleeved on its outer side. A transmission chain 32 is meshed between the outer sides of the two sets of transmission sprockets 31. Both the transmission sprockets 31 and the transmission chain 32 are rotatably set inside the hollow frame 3. A servo motor 33 is fixedly installed on the outer side of the hollow frame 3, and the transmission shaft side of the servo motor 33 is fixedly connected to the transmission rod side top through a coupling.
[0024] In this technical solution (through Figure 1 , Figure 2 and Figure 3 As shown, both sides of the bidirectional lead screw 2 are threadedly connected to transmission sleeves 21. Each transmission sleeve 21 has a fixed rod 22 vertically fixedly installed on the top of its outer side. Both sides of the fixed frame 14 are slidably installed with transmission frames 23. The top of the side of the fixed rod 22 is fixedly connected to the side of the transmission frame 23. Each fixed frame 14 has a limit groove 29 inside both ends of its side. The top of the side of the fixed rod 22 is slidably inserted into the limit groove 29.
[0025] In this technical solution (through Figure 1 , Figure 2 and Figure 3 As shown, connecting blocks 25 are fixedly installed at both ends of the connecting arc plate 24 near the fixed frame 14. The bottom of each connecting block 25 is inclinedly hinged to the push rod 26 through a rotating shaft, and the sides of the push rod 26 are rotatably hinged to the outside of the transmission frame 23 through a rotating shaft.
[0026] In some technical solutions (through Figure 1 , Figure 2 and Figure 3 As shown, the four corners of the connecting arc plate 24 near the fixed frame 14 are vertically fixed with limiting slide rods 4, and the four corners of the outer side of the fixed frame 14 are vertically provided with guide grooves 41, and the limiting slide rods 4 are slidably inserted into the guide grooves 41.
[0027] During operation, the dyed fabric is conveyed to the drying chamber 11 via guide rollers. The warm air mechanism inside the drying chamber 11 dries the fabric. The dried fabric is then passed from the bottom of the left fixed arc plate 27 to the top of the right fixed arc plate 27, where its side ends are wrapped around the take-up roller. The servo motor 33 is then activated, driving the transmission sprocket 31 to rotate synchronously. The meshing of the transmission chain 32 and the transmission sprocket 31 provides synchronous driving force to the transmission rods and the bidirectional lead screw 2, ensuring the synchronized movement of the two fixed arc plates 27. This synchronously drives the two transmission rods and the bidirectional lead screw 2 to rotate within the fixed frame 14. The bidirectional lead screw 2 then rotates the transmission sleeve 21. Under the transmission action and the guiding and limiting action of the limiting slide groove 29 on the fixed rod 22, the two sets of transmission sleeves 21 sleeved on its surface can be driven to move synchronously relative to each other. Under the connection action of the fixed rod 22, the transmission frame 23 is driven to move horizontally relative to each other on the outside of the fixed frame 14. Then, under the transmission conversion action of the push rod 26, the horizontal movement force of the transmission frame 23 can be converted into a vertical pushing force on the connecting arc plate 24, so that the two sets of connecting arc plates 24 and the fixed arc plate 27 can move synchronously relative to each other. While increasing the distance between the fixed arc plates 27, it can push and stretch the printed fabric on its outside, so that the fabric can be fully extended and flattened. Then, when the take-up roller rotates to take up the fabric, the fabric can move and the conductive bristles 28 can continuously brush the surface of the fabric, brushing away the static electricity accumulated on the surface of the fabric, thereby eliminating the static electricity.
Claims
1. A drying device for printed and dyed fabrics with static electricity elimination function, comprising a mounting base (1) and a drying chamber (11), wherein the drying chamber (11) is provided on the top side of the mounting base (1), characterized in that: The mounting base (1) has support plates (12) fixedly installed vertically on both sides of the top. Each support plate (12) has a fixed tube (13) fixedly installed through the inside of the top side. The fixed tube (13) has a fixed frame (14) fixedly installed at the top of the side. A connecting arc plate (24) is movably provided on the outside of the fixed frame (14), and a fixed arc plate (27) is fixedly installed on the outside of the connecting arc plate (24). A driving mechanism is provided inside the fixed frame (14), and a connecting mechanism is provided between the outside of the driving mechanism and the outside of the connecting arc plate (24). A hollow frame (3) is fixedly installed between the outer tops of the two sets of support plates (12). A synchronous rotation mechanism is provided inside the hollow frame (3), and the synchronous rotation mechanism and the drive mechanism are connected in transmission.
2. The fabric drying equipment with electrostatic elimination function according to claim 1, characterized in that: The driving mechanism includes a bidirectional lead screw (2), and transmission sleeves (21) are threadedly connected to both sides of the bidirectional lead screw (2). A fixing rod (22) is vertically fixedly installed on the top of the outer side of each transmission sleeve (21). A transmission frame (23) is slidably installed on both sides of the outer side of the fixing frame (14), and the top of the side of the fixing rod (22) is fixedly connected to the side of the transmission frame (23).
3. The fabric drying equipment with static elimination function according to claim 2, characterized in that: The outer side of the fixed arc plate (27) is fixedly equipped with conductive bristles (28), and the number of conductive bristles (28) is several groups.
4. The fabric drying equipment with electrostatic elimination function according to claim 2, characterized in that: The connecting mechanism includes a push rod (26). The connecting arc plate (24) is fixedly installed with connecting blocks (25) at both ends on the side near the fixed frame (14). The bottom of each connecting block (25) is inclinedly hinged to the push rod (26) through a rotating shaft. The side of the push rod (26) is rotatably hinged to the outside of the transmission frame (23) through a rotating shaft. The inside of each side end of the fixed frame (14) is provided with a limiting groove (29). The top of the side of the fixed rod (22) is slidably inserted into the limiting groove (29).
5. The fabric drying equipment with electrostatic elimination function according to claim 2, characterized in that: The synchronous rotation mechanism includes a transmission chain (32) and a transmission sprocket (31). A transmission rod is fixedly installed on the top side of each of the two-way screws (2), and the top side of the transmission rod is rotatably installed inside the hollow frame (3) through a bearing. A transmission sprocket (31) is fixedly sleeved on the outside of each of the transmission rods. A transmission chain (32) is meshed between the outer sides of the two sets of transmission sprockets (31). A servo motor (33) is fixedly installed on the outer side of the hollow frame (3), and the transmission shaft side of the servo motor (33) is fixedly connected to the top side of the transmission rod through a coupling.
6. The fabric drying equipment with electrostatic elimination function according to claim 1, characterized in that: The connecting arc plate (24) has four vertically fixed limit slide rods (4) installed at the four corners of the side near the fixed frame (14). The four corners of the outer side of the fixed frame (14) are vertically provided with guide slide grooves (41), and the limit slide rods (4) are slidably inserted into the guide slide grooves (41).