Vibrating feed guide

By designing a vibratory feeding guide structure and utilizing a lifting and distributing feeding structure, automatic sorting and feeding of roll paper was achieved, solving the problem of low efficiency in manual sorting and feeding and improving the degree of automation.

CN224449248UActive Publication Date: 2026-07-03HANGZHOU TIANSHI PRINTING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HANGZHOU TIANSHI PRINTING CO LTD
Filing Date
2025-08-29
Publication Date
2026-07-03

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    Figure CN224449248U_ABST
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Abstract

The utility model provides a kind of vibration feeding guide structure, belong to reel paper field.It includes material placing device and vibration device, the vibration device is equipped with transfer channel, the material placing device is equipped with material placing bin, the material placing bin is equipped with jacking movement structure, the transfer channel is located above material placing bin and is equipped with transverse gap in the side close to material placing bin, the jacking movement structure can be moved to the transverse gap close to transfer channel upwards, the outlet of the transfer channel is connected with material distribution feeding structure, according to the length of paper tube is classified after paper tube and corresponding is carried out feeding work, the length of paper tube is distributed by material distribution feeding structure, and transfer by vibration device, manual identification and placement are not needed.
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Description

Technical Field

[0001] This utility model belongs to the field of roll paper, and particularly relates to a vibrating feeding guide structure. Background Technology

[0002] After the roll paper is manufactured, a film needs to be applied to the outer surface of the roll paper to display product information or advertising content. Usually, the packaging company is responsible for adhering the outer film to the outer surface of the paper roll, while the step of making the roll paper into paper rolls is outsourced to another manufacturer. When paper rolls are transported in in bulk, paper rolls of different lengths are usually purchased in bulk, so it is necessary to classify and feed the paper rolls according to their length. Utility Model Content

[0003] The purpose of this invention is to address the above-mentioned problems by providing a vibration feeding guide structure.

[0004] To achieve the above objectives, the present invention adopts the following technical solution:

[0005] A vibrating feeding guide structure includes a material placement device and a vibrating device. The vibrating device is provided with a transfer channel. The material placement device is provided with a material placement bin. The material placement bin is provided with a lifting and moving structure. The transfer channel is located above the material placement bin and has a transverse notch on the side near the material placement bin. The lifting and moving structure can move upward to a position close to the transverse notch of the transfer channel. The outlet of the transfer channel is connected to a material feeding structure.

[0006] In the above-mentioned vibratory feeding guide structure, the bottom inner wall of the material placement bin is inclined, the lifting and moving structure is located at the lower end of the bottom inner wall of the material placement bin, and the side of the lifting and moving structure away from the material placement bin has an abutment surface.

[0007] In the above-mentioned vibratory feeding guide structure, the lifting and moving structure includes a lifting plate disposed between the material placement bin and the abutment surface. The lifting plate is connected to a lifting drive. The lifting plate and the abutment surface abut against each other. The abutment surface has a pouring surface above it. The side of the pouring surface away from the abutment surface is connected to a transverse notch. The lifting plate and the pouring surface are inclined.

[0008] In the above-mentioned vibratory feeding guide structure, a rotating roller is provided above the pouring surface on the material placement device, and a transverse placement drop channel is formed between the rotating roller and the pouring surface.

[0009] In the aforementioned vibratory feeding guide structure, the lifting plate has an anti-reverse rod protruding from the side near the material placement bin.

[0010] In the aforementioned vibratory feeding guide structure, the material distribution feeding structure includes a transition channel disposed on the vibrating device and connected to the transfer channel. A material distribution space is provided at the outlet of the transition channel. The material distribution space is connected to two feeding channels. A material pushing structure is provided in the material distribution space.

[0011] In the aforementioned vibration feeding guide structure, the pushing structure includes push plates disposed on both sides of the material distribution space. The push plates are connected to a linear actuator, and in the initial state, the push plates are flush with the side walls of the material distribution space.

[0012] In the above-mentioned vibration feeding guide structure, a guide block is provided between the two feeding channels, and the outer surfaces of the two sides of the guide block are inclined.

[0013] In the aforementioned vibratory feeding guide structure, a pressure plate is provided above the transition channel on the vibratory device, and the pressure plate is connected to the lifting driver.

[0014] Compared with existing technologies, the advantages of this utility model are:

[0015] 1. After classifying the paper tubes according to their length, the paper tubes are fed accordingly. The paper tubes are divided by length through the material feeding structure and transferred by the vibration device, eliminating the need for manual identification and placement.

[0016] 2. The paper tubes placed in the material placement bin will automatically move to the lifting and moving structure under the inclined guidance of the bottom wall of the material placement bin. After the lifting and moving structure moves some of the paper tubes into the transfer channel, they fall back to the initial position. The remaining paper tubes in the material placement bin will automatically move to the lifting and moving structure to achieve automatic material replenishment without the need for manual handling.

[0017] 3. Some of the paper tubes that are moved to the lifting plate are placed vertically. The rollers can prevent the vertically placed paper tubes from moving into the transfer channel. Only the horizontally placed paper tubes can roll into the transfer channel through the drop channel.

[0018] 4. As the lifting plate moves the paper tube upwards, the paper tube will shake and move. The anti-backward rod can prevent the paper tube from falling back into the material storage bin. Attached Figure Description

[0019] Figure 1 This is a schematic diagram of the present invention;

[0020] Figure 2 It is a two-dimensional schematic diagram;

[0021] Figure 3 This is a schematic diagram of a material placement device.

[0022] In the diagram: 10 Material placement device, 11 Vibration device, 12 Transfer channel, 13 Material placement bin, 14 Lifting and moving structure, 15 Lateral notch, 16 Material distribution and feeding structure, 17 Abutting surface, 18 Lifting plate, 19 Pouring surface, 20 Rotary roller, 21 Lateral placement and falling channel, 22 Anti-backward movement rod, 23 Transition channel, 24 Material distribution space, 25 Feeding channel, 26 Push plate, 27 Guide block, 28 Pressure plate. Detailed Implementation

[0023] The present invention will now be described in further detail with reference to the accompanying drawings and specific embodiments.

[0024] This embodiment provides a vibration feeding guide structure, combined with Figure 1-3 As shown, the device includes a material placement device 10 and a vibration device 11. The vibration device 11 is provided with a transfer channel 12. The material placement device 10 is provided with a material placement bin 13. The material placement bin 13 is provided with a lifting and moving structure 14. The transfer channel 12 is located above the material placement bin 13 and has a horizontal notch 15 on the side close to the material placement bin 13. The lifting and moving structure 14 can move upward to the horizontal notch 15 close to the transfer channel 12. The outlet of the transfer channel 12 is connected to a material feeding structure 16.

[0025] In this embodiment, the rolled paper tubes are placed in the material placement bin 13. Some of the paper tubes are placed on the lifting and moving structure 14. The upward movement of the lifting and moving structure 14 drives some of the paper tubes to move upward to the side of the transverse notch 15. The paper tubes fall from the transverse notch 15 into the transfer channel 12. The vibration of the vibration device 11 causes the paper tubes in the transfer channel 12 to move towards their outlet and to the material distribution and feeding structure 16. The paper tubes are classified according to their length and fed accordingly. The material distribution and feeding structure 16 divides the paper tubes by length, and the transfer is carried out by the vibration device 11. No manual identification and placement are required.

[0026] The bottom inner wall of the material placement bin 13 is inclined, and the lifting and moving structure 14 is located at the lower end of the bottom inner wall of the material placement bin 13. The side of the lifting and moving structure 14 away from the material placement bin 13 has an abutment surface 17.

[0027] In this embodiment, the paper tubes placed in the material placement bin 13 will automatically move to the lifting and moving structure 14 under the inclined guiding action of the bottom wall of the material placement bin 13. After the lifting and moving structure 14 transfers part of the paper tubes into the transfer channel 12, they fall back to the initial position. The remaining paper tubes in the material placement bin 13 will automatically move to the lifting and moving structure 14 to achieve automatic material replenishment without the need for manual handling.

[0028] The lifting and moving structure 14 includes a lifting plate 18 disposed between the material placement bin 13 and the abutment surface 17. The lifting plate 18 is connected to a lifting drive. The lifting plate 18 abuts against the abutment surface 17. The abutment surface 17 has a pouring surface 19 above it. The side of the pouring surface 19 away from the abutment surface 17 is connected to a transverse notch 15. The lifting plate 18 and the pouring surface 19 are inclined.

[0029] In this embodiment, as the lifting plate 18 moves upward with part of the paper tube, the paper tube will move upward against the abutment surface 17. When the lifting plate 18 moves upward to a high position, the paper tube moves downward to the pouring surface 19 under the action of the inclined surface of the lifting plate 18, and moves into the transfer channel 12 through the transverse notch 15 under the inclination of the pouring surface 19.

[0030] Above the pouring surface 19 is a rotating roller 20 mounted on the material placement device 10, and the rotating roller 20 and the pouring surface 19 form a horizontal placement and dropping channel 21.

[0031] In this embodiment, some of the paper tubes that are moved to the lifting plate 18 are placed vertically. The vertically placed paper tubes are prevented from moving into the transfer channel 12 by the blocking of the rotating roller 20. Only the horizontally placed paper tubes can roll into the transfer channel 12 through the drop channel 21.

[0032] The lifting plate 18 is provided with an anti-reverse rod 22 on the side near the material placement bin 13.

[0033] In this embodiment, as the lifting plate 18 moves the paper tube upward, the paper tube will shake and move. The anti-reverse rod 22 can prevent the paper tube from falling back into the material placement bin 13.

[0034] The material feeding structure 16 includes a transition channel 23 mounted on the vibration device 11 and connected to the transfer channel 12. The outlet of the transition channel 23 is provided with a material feeding space 24, which is connected to two feeding channels 25. A material pushing structure is provided in the material feeding space 24.

[0035] In this embodiment, under the action of vibration, the paper tube located in the transfer channel 12 moves to the material distribution space 24 through the transition channel 23, and is pushed to the entrance of the corresponding feeding channel 25 by the pushing structure.

[0036] The pushing structure includes push plates 26 disposed on both sides of the material distribution space 24. The push plates 26 are connected to the linear actuator. In the initial state, the push plates 26 are flush with the side walls of the material distribution space 24.

[0037] A guide block 27 is provided between the two feeding channels 25, and the outer surfaces of the two sides of the guide block 27 are inclined.

[0038] In this embodiment, the outer surfaces of both sides of the guide block 27 are inclined, making the entrance of the feeding channel 25 funnel-shaped, so that the paper tube can smoothly enter the corresponding feeding channel 25.

[0039] Above the transition channel 23 is a pressure plate 28 disposed on the vibration device 11, and the pressure plate 28 is connected to the lifting drive.

[0040] In this embodiment, after the previous paper tube enters the material distribution space 24, the pressure plate 28 moves downward to press down on the next paper tube to prevent it from entering the material distribution space 24, until the previous paper tube enters the corresponding feeding channel 25.

[0041] The specific embodiments described herein are merely illustrative examples illustrating the spirit of this utility model. Those skilled in the art to which this utility model pertains may make various modifications or additions to the described specific embodiments or use similar methods to substitute them, without departing from the spirit of this utility model or exceeding the scope defined by the appended claims.

[0042] Although this article uses terms such as material placement device 10, vibration device 11, transfer channel 12, material placement bin 13, lifting and moving structure 14, transverse notch 15, material distribution and feeding structure 16, abutment surface 17, lifting plate 18, pouring surface 19, rotating roller 20, transverse placement and falling channel 21, anti-reverse shift rod 22, transition channel 23, material distribution space 24, feeding channel 25, push plate 26, guide block 27, pressure plate 28, etc., these terms are used only for the convenience of describing and explaining the essence of this utility model; interpreting them as any kind of additional limitation would be contrary to the spirit of this utility model.

Claims

1. A vibratory feed guide structure comprising a material placement device (10) and a vibrating device (11), said vibrating device (11) having a transfer channel (12) formed therein, characterized in that, The material placement device (10) is provided with a material placement bin (13), and the material placement bin (13) is provided with a lifting and moving structure (14). The transfer channel (12) is located above the material placement bin (13) and has a horizontal notch (15) on the side close to the material placement bin (13). The lifting and moving structure (14) can move upward to the horizontal notch (15) close to the transfer channel (12). The outlet of the transfer channel (12) is connected to a material feeding structure (16).

2. A vibratory feed guide according to claim 1, wherein The bottom inner wall of the material placement bin (13) is inclined, and the lifting and moving structure (14) is located at the lower end of the bottom inner wall of the material placement bin (13). The side of the lifting and moving structure (14) away from the material placement bin (13) has an abutment surface (17).

3. A vibratory feed guide according to claim 2, wherein, The lifting and moving structure (14) includes a lifting plate (18) disposed between the material placement bin (13) and the abutment surface (17). The lifting plate (18) is connected to a lifting drive. The lifting plate (18) abuts against the abutment surface (17). The abutment surface (17) has a pouring surface (19) above it. The side of the pouring surface (19) away from the abutment surface (17) is connected to a transverse notch (15). The lifting plate (18) and the pouring surface (19) are inclined.

4. A vibratory feed guide according to claim 3, wherein Above the pouring surface (19) is a rotating roller (20) mounted on the material placement device (10), and a horizontal placement and dropping channel (21) is formed between the rotating roller (20) and the pouring surface (19).

5. A vibratory feed guide according to claim 3, wherein, The lifting plate (18) has an anti-reverse rod (22) protruding on the side near the material placement bin (13).

6. A vibratory material feed and guide structure as claimed in claim 1, wherein, The material feeding structure (16) includes a transition channel (23) installed on the vibration device (11) and connected to the transfer channel (12). The outlet of the transition channel (23) is provided with a material feeding space (24). The material feeding space (24) is connected to two feeding channels (25). The material feeding space (24) is provided with a pushing structure.

7. A vibratory material feeding and guiding structure according to claim 6, characterized in that The pushing structure includes push plates (26) disposed on both sides of the material distribution space (24). The push plates (26) are connected to a linear actuator. In the initial state, the push plates (26) are flush with the side wall of the material distribution space (24).

8. A vibratory material feed guide structure as claimed in claim 6, wherein, A guide block (27) is provided between the two feeding channels (25), and the outer surfaces of the two sides of the guide block (27) are inclined.

9. A vibratory material feeding and guiding structure according to claim 6, characterized in that The transition channel (23) has a pressure plate (28) above it, which is mounted on the vibration device (11) and is connected to the lifting drive.