Nonwoven fabric packaging transfer device
By designing a nonwoven fabric packaging and transfer device, the problems of low transfer efficiency and tilting of rolls of nonwoven fabric with different heights and widths were solved, and the connection with the slitting machine and the packaging machine and rapid unloading were realized.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANDONG DAWN SWT TECH CO LTD
- Filing Date
- 2025-08-29
- Publication Date
- 2026-06-26
AI Technical Summary
Existing nonwoven fabric transfer devices cannot be connected with slitting machines and packing machines of different heights, affecting transfer efficiency. Furthermore, when transferring rolls of nonwoven fabric of different widths simultaneously, the narrower rolls are prone to tilting.
A nonwoven fabric packaging transfer device was designed, including a transfer base, a support shell, a guide plate, and a spacing positioning plate. By adjusting the height of the support shell and the angle of the guide plate, it can be connected with the slitting machine and the packing machine. The guide plate and the spacing positioning plate prevent the roll of nonwoven fabric from slipping or tilting.
It improves the transfer efficiency of rolls of nonwoven fabric, prevents tilting, and enables a fast and convenient unloading process for nonwoven fabric.
Smart Images

Figure CN224409804U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of nonwoven fabric production equipment, specifically to a nonwoven fabric packaging and transfer device. Background Technology
[0002] Nonwoven fabrics are widely used in the hygiene industry. With rising living standards, consumers are demanding higher levels of functionality, comfort, and breathability from disposable hygiene products. However, traditional spunbond nonwoven materials have limitations in elasticity. After production, long strips of nonwoven fabric are typically rolled into rolls for packaging and transportation. However, packaging is usually done manually, which is laborious. Larger rolls are difficult to completely wrap, resulting in longer packaging times and reduced production efficiency.
[0003] After being slit, the nonwoven fabric rolls are transferred to the packaging line for packaging. Each slit machine corresponds to one packaging line. The nonwoven fabric rolls complete the final process of spunlace nonwoven fabric production on the packaging line.
[0004] A prior art patent with publication number CN218199059U discloses a solution comprising an infeed conveyor line, a first redirecting and transfer conveyor line, a first packaging line, a second redirecting and transfer conveyor line, and a second packaging line. The output end of the infeed conveyor line is connected to the input end of the first redirecting and transfer conveyor line, and the output end of the first redirecting and transfer conveyor line is connected to the packaging line. A temporary storage conveyor line is located on the right side of the second redirecting and transfer conveyor line, and the right side of the first redirecting and transfer conveyor line mates with the input port of the temporary storage conveyor line. The second redirecting and transfer conveyor line is located on the right side of the temporary storage conveyor line, and the output end of the temporary storage conveyor line mates with the left side of the second redirecting and transfer conveyor line. The output end of the second redirecting and transfer conveyor line is connected to the second packaging line. This invention can transfer spunlace nonwoven fabric rolls piled up on the production line to idle packaging lines for packaging, improving the production efficiency of the packaging line, making more rational use of production resources, and contributing to the growth of enterprise economic benefits.
[0005] As existing devices are used, the shortcomings of this technology have gradually become apparent, mainly in the following aspects:
[0006] First, because the slitting machine and the packing machine are not at the same height, the existing transfer device cannot be connected with slitting machines and packing machines of different heights during use, which affects the efficiency of transferring rolls of nonwoven fabric.
[0007] Secondly, because the slitting machine cuts the roll of nonwoven fabric into several rolls of different widths at once, the narrower rolls of nonwoven fabric are prone to tilting when the existing transfer device transfers rolls of nonwoven fabric of different widths at the same time.
[0008] As can be seen from the above, the existing technology obviously has inconveniences and defects in practical use, so it is necessary to improve it. Utility Model Content
[0009] To address the shortcomings of existing technologies, this utility model provides a nonwoven fabric packaging and transfer device. This device solves the problem that traditional transfer devices cannot be connected with slitting machines and packing machines of different heights, which affects the efficiency of transferring rolls of nonwoven fabric. Furthermore, because the slitting machine cuts the roll of nonwoven fabric into several rolls of different widths at once, the narrower rolls of nonwoven fabric are prone to tilting during the simultaneous transfer of rolls of nonwoven fabric of different widths.
[0010] To achieve the above objectives, the present invention provides the following technical solution.
[0011] A non-woven fabric packaging transfer device includes a transfer base, a horizontally arranged support shell that moves vertically up and down above the transfer base, guide plates that swing independently on both sides of the support shell in the width direction, and two independently sliding positioning plates that slide along the length direction on the top surface of the support shell.
[0012] As an optimized solution, the upper end of the support housing is provided with an opening, and a vertical plate is provided inside the support housing corresponding to each of the spacing positioning plates for horizontal sliding. A horizontal lead screw is provided inside the support housing corresponding to each of the vertical plates for horizontal rotation, and the vertical plate is threadedly connected to the horizontal lead screw.
[0013] As an optimized solution, a transverse slide rail is horizontally fixed to the bottom of the support housing along the sliding direction of the vertical plate, and a transverse slide groove matching the transverse slide rail is provided at the lower end of the vertical plate.
[0014] As an optimized solution, a transverse end seat is vertically fixed inside the support housing for each transverse lead screw. The two ends of the transverse lead screw are rotatably mounted on the transverse end seat and the inner end of the support housing. A transverse drive motor for driving the transverse lead screw to rotate is fixed on the transverse end seat.
[0015] As an optimized solution, vertical screws are vertically rotatably installed on the transfer base corresponding to both ends of the support housing, and a lifting plate that is threadedly connected to the vertical screws is horizontally fixed to the outer end of the support housing.
[0016] As an optimized solution, a side frame is vertically fixed to each of the vertical lead screws on the transfer base. Two vertical end seats are fixed in parallel from top to bottom on the side frame. The two ends of the vertical lead screw are rotatably mounted on the two vertical end seats. A vertical drive motor for driving the vertical lead screw to rotate is fixed to the lower vertical end seat.
[0017] As an optimized solution, the support housing has hinge seats fixed to its two side walls in the width direction, and the guide plate is connected to the hinge end of the hinge seat.
[0018] As an optimized solution, a drive motor is fixedly connected to the lower end of the support housing corresponding to each of the guide plates. A swing rod is fixedly connected to the output shaft of the drive motor. A connecting rod is hinged to the other end of the swing rod, and the other end of the connecting rod is hinged to the lower surface of the guide plate.
[0019] As an optimized solution, the two drive motors are arranged side by side along the length of the support housing.
[0020] As an optimized solution, the support housing is configured as a long rectangular housing.
[0021] As an optimized solution, the bottom surface of the transfer base is provided with parallel casters.
[0022] Compared with the prior art, the beneficial effects of this utility model are:
[0023] The transfer base can move back and forth between the slitting machine and the packing machine. When it is necessary to receive rolls of nonwoven fabric, the device is moved to the feeding port of the slitting machine, the guide plate away from the slitting machine is tilted and erected, and the guide plate close to the slitting machine is laid flat to receive the material. If the height of the slitting machine is high, the height of the support shell can be adjusted, and the swing end of the guide plate can be connected upward to the feeding port of the slitting machine for connection, which is convenient and quick.
[0024] Several rolls of nonwoven fabric are moved to the top of the support shell for support. Two guide plates limit the radial direction of the nonwoven fabric to prevent it from slipping. The rolls of nonwoven fabric are gathered together by moving the spacing positioning plates on both sides to prevent the rolls of nonwoven fabric from tilting during the transfer process.
[0025] Then the moving device moves to the baling machine, and the swing end of the guide plate near the baling machine is connected to the feed port of the baling machine. The spacing positioning plate is moved outward, and the roll of non-woven fabric is rolled onto the baling machine to achieve unloading, which is convenient and quick. Attached Figure Description
[0026] To more clearly illustrate the specific embodiments of this utility model or the technical solutions in the prior art, the drawings used in the description of the specific embodiments or the prior art will be briefly introduced below. In all the drawings, similar elements or parts are generally identified by similar reference numerals. In the drawings, the elements or parts are not necessarily drawn to scale.
[0027] Figure 1 This is a schematic diagram of the structure of this utility model;
[0028] Figure 2 This is a schematic diagram of the material guide plate of this utility model.
[0029] In the diagram: 1-Transfer base; 2-Support housing; 3-Horizontal lead screw; 4-Vertical plate; 5-Spacing positioning plate; 6-Rolled nonwoven fabric; 7-Horizontal drive motor; 8-Horizontal lead screw; 9-Side frame; 10-Vertical lead screw; 11-Vertical drive motor; 12-Vertical slide rail; 13-Moving wheel; 14-Guide plate; 15-Hinge seat; 16-Connecting rod; 17-Swing rod; 18-Driver; 19-Lifting plate. Detailed Implementation
[0030] The embodiments of the present invention will now be described in detail with reference to the accompanying drawings. These embodiments are merely illustrative of the present invention and should not be construed as limiting the scope of protection of the present invention.
[0031] like Figures 1 to 2 As shown, the non-woven fabric packaging transfer device includes a transfer base 1, a horizontally arranged support shell 2 that moves vertically up and down above the transfer base 1, guide plates 14 that swing independently on both sides of the support shell 2 in the width direction, and two independently sliding positioning plates 5 that slide along the length direction on the top surface of the support shell 2.
[0032] The upper end of the support housing 2 is open. Inside the support housing 2, a vertical plate 4 is provided for each spacing positioning plate 5 and slides horizontally. Inside the support housing 2, a horizontal screw is provided for each vertical plate 4 and rotates horizontally. The vertical plate 4 is threadedly connected to the horizontal screw.
[0033] The bottom of the support housing 2 is horizontally fixed with a transverse slide rail along the sliding direction of the vertical plate 4, and the lower end of the vertical plate 4 is provided with a transverse slide groove that matches the transverse slide rail.
[0034] Inside the support housing 2, a transverse end seat is vertically fixed to each transverse lead screw. The two ends of the transverse lead screw are rotatably mounted on the transverse end seat and the inner end of the support housing 2. A transverse drive motor 7 for driving the transverse lead screw to rotate is fixed to the transverse end seat.
[0035] Vertical screws 10 are vertically rotatably installed on both ends of the transfer base 1 corresponding to the support housing 2. A lifting plate 19, which is threadedly connected to the vertical screws 10, is horizontally fixed to the outer end of the support housing 2.
[0036] A side frame 9 is vertically fixed to each vertical lead screw 10 on the transfer base 1. Two vertical end seats are fixed to the side frame 9 in parallel from top to bottom. The two ends of the vertical lead screw 10 are rotatably mounted on the two vertical end seats. A vertical drive motor 11 for driving the vertical lead screw 10 to rotate is fixed to the lower vertical end seat.
[0037] A vertical slide rail is fixedly connected to the side frame 9, and a vertical slide groove matching the vertical slide rail 12 is provided on the lifting plate 19.
[0038] The support housing 2 has hinge seats 15 fixedly connected to the two side walls in the width direction, and the guide plate 14 is connected to the hinge end of the hinge seat 15.
[0039] The lower end of the support housing 2 is fixedly connected to a drive motor 18 corresponding to each guide plate 14. The output shaft of the drive motor 18 is fixedly connected to a swing rod 17. The other end of the swing rod 17 is hinged to a connecting rod 16. The other end of the connecting rod 16 is hinged to the lower surface of the guide plate 14.
[0040] Two drive motors 18 are arranged side by side along the length of the support housing 2.
[0041] The supporting housing 2 is a long rectangular housing.
[0042] The bottom surface of the transfer base 1 is connected in parallel with the movable wheels 13, which can be electric rotating wheels or ordinary wheels.
[0043] The drive unit is equipped with a worm gear set to achieve self-locking.
[0044] A stepper motor or a servo motor can be connected to the drive motor 18, so that the controller can send pulse signals to control the number of rotation steps of the stepper motor or servo motor, thereby precisely controlling the rotation angle of the swing arm 17 (each pulse corresponds to a fixed angle increment).
[0045] The working principle of this device is as follows:
[0046] The transfer base 1 can move back and forth between the slitting machine and the packing machine. When it is necessary to receive rolls of non-woven fabric 6, the device is moved to the unloading port of the slitting machine, the guide plate 14 away from the slitting machine is tilted and erected, and the guide plate 14 close to the slitting machine is laid flat to receive the material. If the height of the slitting machine is high, the height of the support housing 2 can be adjusted, and the swing end of the guide plate 14 can be connected upward to the unloading port of the slitting machine for connection, which is convenient and quick.
[0047] Several rolls of nonwoven fabric 6 are moved to the support shell 2 for support. The nonwoven fabric is radially limited by two guide plates 14 to prevent it from slipping. The rolls of nonwoven fabric 6 are gathered together by moving the spacing positioning plates 5 on both sides to prevent the rolls of nonwoven fabric 6 from tilting during the transfer process.
[0048] Then the moving device moves to the packing machine, and the swing end of the guide plate 14 near the packing machine is connected to the feed port of the packing machine. The spacing positioning plate 5 is moved outward, and the roll of non-woven fabric 6 is rolled onto the packing machine to achieve unloading, which is convenient and quick.
[0049] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this utility model, and not to limit it. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some or all of the technical features. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the scope of the technical solutions of the embodiments of this utility model, and they should all be covered within the scope of the claims and specification of this utility model.
Claims
1. A non-woven fabric packaging and transfer device, characterized in that: The system includes a transfer base (1), above which a horizontally arranged support housing (2) is vertically raised and lowered. The two side walls of the support housing (2) in the width direction are independently swingable with guide plates (14). The top surface of the support housing (2) is provided with two independently sliding spacing positioning plates (5) in the length direction.
2. The nonwoven fabric packaging and transfer device according to claim 1, characterized in that: The upper end of the support housing (2) is provided with an opening. Inside the support housing (2), a vertical plate (4) is provided horizontally to slide for each of the spacing positioning plates (5). Inside the support housing (2), a horizontal screw is provided to rotate horizontally for each of the vertical plates (4). The vertical plate (4) is threadedly connected to the horizontal screw.
3. The nonwoven fabric packaging and transfer device according to claim 2, characterized in that: The bottom of the support housing (2) is horizontally fixed with a transverse slide rail along the sliding direction of the vertical plate (4), and the lower end of the vertical plate (4) is provided with a transverse slide groove that matches the transverse slide rail.
4. The nonwoven fabric packaging and transfer device according to claim 3, characterized in that: The support housing (2) has a horizontal end seat vertically fixed to each horizontal lead screw. The two ends of the horizontal lead screw are rotatably mounted on the horizontal end seat and the inner end of the support housing (2). A horizontal drive motor (7) for driving the horizontal lead screw to rotate is fixed to the horizontal end seat.
5. The nonwoven fabric packaging and transfer device according to claim 1, characterized in that: Vertical screws (10) are vertically rotatably installed on the transfer base (1) at both ends corresponding to the support housing (2), and a lifting plate (19) is horizontally fixed to the outer end of the support housing (2) and threadedly connected to the vertical screws (10).
6. The nonwoven fabric packaging and transfer device according to claim 5, characterized in that: The transfer base (1) has a side frame (9) vertically fixed to each vertical screw (10). The side frame (9) has two vertical end seats fixed in parallel from top to bottom. The two ends of the vertical screw (10) are rotatably mounted on the two vertical end seats. A vertical drive motor (11) for driving the vertical screw (10) to rotate is fixed to the lower vertical end seat.
7. The nonwoven fabric packaging and transfer device according to claim 1, characterized in that: The support housing (2) has hinge seats (15) fixed to its two side walls in the width direction, and the guide plate (14) is connected to the hinge end of the hinge seat (15).
8. The nonwoven fabric packaging and transfer device according to claim 1, characterized in that: The lower end of the support housing (2) is fixedly connected to a drive motor (18) corresponding to each of the guide plates (14). The output shaft of the drive motor (18) is fixedly connected to a swing rod (17). The other end of the swing rod (17) is hinged to a connecting rod (16). The other end of the connecting rod (16) is hinged to the lower surface of the guide plate (14).
9. The nonwoven fabric packaging and transfer device according to claim 8, characterized in that: The two drive motors (18) are arranged side by side along the length of the support housing (2).
10. The nonwoven fabric packaging and transfer device according to claim 1, characterized in that: The supporting shell (2) is a long rectangular shell.