An automatic sheet conveyor for core board cutting

By designing an automatic sheeting and conveying frame for core board cutting, the problem of multiple core boards being difficult to separate and feed into the dust removal device in the cement core board production line was solved, realizing the automatic sheeting and conveying of single core boards and improving the dust removal effect.

CN224429133UActive Publication Date: 2026-06-30HUBEI HEYANG TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HUBEI HEYANG TECH CO LTD
Filing Date
2025-08-12
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

In existing technologies, cement core board production lines have difficulty feeding multiple stacked core boards into the dust removal device in batches, which affects the dust removal effect.

Method used

Design an automatic sheeting and conveying frame for core board cutting, including a frame body, a first conveying mechanism, a second conveying mechanism, an X-axis conveying mechanism, and a horizontal limiting mechanism. Through the coordinated work of these mechanisms, automatic sheeting and conveying of core boards can be achieved.

Benefits of technology

The system enables automatic sheet separation and conveying of stacked core boards, ensuring that each core board can enter the dust removal device individually, thus improving the dust removal effect.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This utility model discloses an automatic sheet-separating and conveying frame for core board cutting, relating to the field of cement core board manufacturing technology. The conveying frame includes a frame body, a first conveying mechanism, a second conveying mechanism, an X-axis conveying mechanism, and a horizontal limiting mechanism. The second conveying mechanism is located to one side of the first conveying mechanism, and the conveying directions of both are parallel to the Y-axis. The horizontal bearing surface of the second conveying mechanism is lower than the horizontal bearing surface of the first conveying mechanism in the XZ plane. After several stacked core boards are conveyed by the first conveying mechanism to the space between the horizontal limiting mechanisms, the X-axis conveying mechanism moves the core boards towards the second conveying mechanism. Core boards closer to the second conveying mechanism fall onto it sequentially at intervals and are then conveyed one by one along the Y-axis. By installing the first conveying mechanism, the second conveying mechanism, the X-axis conveying mechanism, and the horizontal limiting mechanism on the frame body, an automatic sheet-separating and conveying function can be achieved, allowing stacked core boards to be conveyed one by one to the next device.
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Description

Technical Field

[0001] This utility model relates to the field of cement core board manufacturing technology, and more specifically, to an automatic sheet conveying frame for core board cutting. Background Technology

[0002] Dust collection devices are typically installed on cement core board production lines. Finished cement core boards are first conveyed by the production line's conveyor system to the dust collection device for surface dust removal before being transferred to a new stack. Dust removal is most effective when performed on only one core board at a time, as the surfaces of a single core board are unobstructed by other core boards, allowing the dust collection system to clean all surfaces. If multiple core boards are stacked together and enter the dust collection device simultaneously, some core boards may not be thoroughly dust-removed.

[0003] However, existing production lines have a technical problem that makes it inconvenient to feed multiple stacked core boards into the dust removal mechanism in batches, thus affecting the dust removal effect. Utility Model Content

[0004] The purpose of this utility model is to overcome the shortcomings of the existing technology and provide an automatic sheet conveying frame for core board cutting.

[0005] The objective of this utility model is achieved through the following technical solution:

[0006] An automatic sheeting and conveying frame for core board cutting includes a frame body and a first conveying mechanism, a second conveying mechanism, an X-axis conveying mechanism, and a horizontal limiting mechanism, all mounted on the frame body. The second conveying mechanism is located to one side of the first conveying mechanism, and the conveying directions of both are parallel to the Y-axis. The horizontal bearing surface of the second conveying mechanism is lower than the horizontal bearing surface of the first conveying mechanism in the XZ plane. The horizontal limiting mechanism is used to prevent the core boards from tipping over. After several stacked core boards are conveyed by the first conveying mechanism to the space between the horizontal limiting mechanisms, the X-axis conveying mechanism moves several core boards toward the second conveying mechanism. Core boards closer to the second conveying mechanism fall onto the second conveying mechanism in sequence at intervals and are then conveyed one by one along the Y-axis.

[0007] Furthermore, in this utility model, the first conveying mechanism includes a plurality of conveying rollers arranged in parallel at intervals on the frame, the plurality of conveying rollers being sequentially connected in a transmission manner, the central axis of any of the conveying rollers being parallel to the X-axis; and in the XY plane, the upper generatrices of any of the conveying rollers being coplanar.

[0008] Furthermore, in this utility model, the second conveying mechanism includes a first belt conveying mechanism disposed on the frame, the conveying direction of the first belt conveying mechanism being parallel to the Y-axis; in the XZ plane, the horizontal bearing surface of the first belt conveying mechanism is lower than the upper generatrix of any of the conveying rollers.

[0009] Furthermore, in this utility model, the X-axis conveying mechanism includes a lifting mechanism mounted on the frame and a plurality of second belt conveying mechanisms arranged parallel to each other at the execution end of the lifting mechanism. The lifting mechanism moves up and down along the Z-axis direction. The conveying direction of any of the second belt conveying mechanisms is parallel to the X-axis. The plurality of second belt conveying mechanisms and the plurality of conveying rollers are arranged alternately, and the distance between any two adjacent conveying rollers is greater than the width of the second belt conveying mechanism.

[0010] Furthermore, in this utility model, the aforementioned horizontal limiting mechanism includes a first limiting frame and a first telescopic mechanism both mounted on the aforementioned frame. The execution end of the aforementioned first telescopic mechanism is provided with a second limiting frame opposite to the aforementioned first limiting frame. The aforementioned second limiting frame is located above the aforementioned second conveying mechanism. The telescopic direction of the aforementioned first telescopic mechanism is parallel to the X-axis.

[0011] Furthermore, in this utility model, a limiting plate is also provided on the frame, which is used to limit the displacement of the stacked core boards in the Y-axis direction.

[0012] Furthermore, in this utility model, the frame is also provided with a pressing mechanism, which includes a second telescopic mechanism and a pressure plate at the execution end of the second telescopic mechanism. The telescopic direction of the second telescopic mechanism is parallel to the Z-axis. The pressure plate is located above the first conveying mechanism.

[0013] The beneficial effects of this utility model are:

[0014] This utility model provides an automatic sheet-separating and conveying frame for core board cutting. By installing a first conveying mechanism, a second conveying mechanism, an X-axis conveying mechanism, and a horizontal limiting mechanism on the frame, the automatic sheet-separating and conveying function can be realized to transport several stacked core boards one by one to the next device. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the structure of an embodiment of the present utility model;

[0016] Figure 2 for Figure 1 The main view;

[0017] Figure 3 This is a schematic diagram of the structure of several core boards placed on a frame according to an embodiment of the present invention.

[0018] In the diagram: 101-Frame; 201-First conveying mechanism; 301-Second conveying mechanism; 401-Core plate; 501-Lifting mechanism; 502-Second belt conveying mechanism; 601-First limiting frame; 602-First telescopic mechanism; 603-Second limiting frame; 701-Limiting plate; 801-Second telescopic mechanism; 802-Pressure plate. Detailed Implementation

[0019] The technical solution of this utility model will be clearly and completely described below with reference to the embodiments. Obviously, the described embodiments 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 are within the protection scope of this utility model.

[0020] Please see Figures 1-3 This utility model provides a technical solution:

[0021] An automatic sheet conveying frame for core board cutting includes a frame body 101, and a first conveying mechanism 201, a second conveying mechanism 301, an X-axis conveying mechanism, and a horizontal limiting mechanism, all mounted on the frame body 101. The second conveying mechanism 301 is located on one side of the first conveying mechanism 201 (from...). Figure 2 From the perspective of the first conveyor 201, the second conveyor 301 is located to the right of the first conveyor 201, and the conveying directions of both are parallel to the Y-axis. The horizontal bearing surface of the second conveyor 301 is lower than the horizontal bearing surface of the first conveyor 201 in the XZ plane. After several stacked core boards 401 are conveyed by the first conveyor 201 to the horizontal limiting mechanism, the X-axis conveyor mechanism causes several core boards 401 to move toward the second conveyor 301. The core boards 401 that are close to the second conveyor 301 fall onto the second conveyor 301 in sequence and are then conveyed along the Y-axis one by one.

[0022] Preferably, in this embodiment, the first conveying mechanism 201 includes a plurality of conveying rollers installed parallel and spaced on the frame 101. The plurality of conveying rollers are sequentially connected by transmission, and the central axis of any conveying roller is parallel to the X-axis; in the XY plane, the upper generatrices of any conveying roller are coplanar. The synchronous rotation of the plurality of conveying rollers can move the stacked core plates 401 on the frame 101. The driving method for the synchronous rotation of the plurality of conveying rollers is prior art, so it will not be described in detail in this embodiment. For example, two adjacent conveying rollers can be connected by a chain, and then the conveying roller located at the first or last end is connected to a motor. After the motor drives the conveying roller connected to it to rotate, the remaining conveying rollers will rotate synchronously under the drive of the plurality of chains.

[0023] Preferably, in this embodiment, the second conveying mechanism 301 includes a first belt conveying mechanism mounted on the frame 101, the conveying direction of which is parallel to the Y-axis; and in the XZ plane, the horizontal bearing surface of the first belt conveying mechanism is lower than the upper generatrix of any conveying roller.

[0024] Preferably, in this embodiment, the X-axis conveying mechanism includes a lifting mechanism 501 mounted on the frame 101 and a plurality of second belt conveying mechanisms 502 installed parallel to each other at the actuating end of the lifting mechanism 501. The lifting mechanism 501 moves up and down along the Z-axis direction; the conveying direction of any second belt conveying mechanism 502 is parallel to the X-axis; the plurality of second belt conveying mechanisms 502 and a plurality of conveying rollers are installed alternately, and the distance between any two adjacent conveying rollers is greater than the width of the second belt conveying mechanism 502. In this embodiment, the lifting mechanism 501 uses a hydraulic rod, and a frame (not shown in the figure) is mounted on the actuating end of the hydraulic rod. The plurality of second belt conveying mechanisms 502 are all mounted on the frame, and the plurality of second belt conveying mechanisms 502 move up and down synchronously under the action of the lifting mechanism 501.

[0025] Specifically, refer to Figures 1-3 In this embodiment, the horizontal limiting mechanism includes a first limiting frame 601 and a first telescopic mechanism 602, both mounted on the frame 101. The actuating end of the first telescopic mechanism 602 is equipped with a second limiting frame 603 opposite to the first limiting frame 601. The second limiting frame 603 is located above the second conveying mechanism 301. The telescopic direction of the first telescopic mechanism 602 is parallel to the X-axis. Figure 2 From the perspective of the frame, the first limiting frame 601 is located on the left side of the frame 101, while the first telescopic mechanism 602 and the second limiting frame 603 are both located on the right side of the frame 101. In this embodiment, the first telescopic mechanism 602 also uses a hydraulic rod.

[0026] During the movement of the stacked core boards 401 on the first conveying mechanism 201, in order to keep the stacked core boards 401 in an appropriate position, in this embodiment, a limiting plate 701 is also installed on the frame 101. The length direction of the limiting plate 701 is parallel to the X-axis, and the limiting plate 701 can limit the displacement of the stacked core boards 401 in the Y-axis direction.

[0027] from Figure 2From this perspective, when several stacked core boards 401 move between the first limiting frame 601 and the second limiting frame 603, if the distance between the first limiting frame 601 and the second limiting frame 603 is large and the number of core boards 401 is small, the core boards 401 are prone to tilting to the left or right. To solve this problem, in this embodiment, a pressing mechanism is also installed on the frame 101. The pressing mechanism includes a second telescopic mechanism 801 installed on the frame 101 and a pressure plate 802 installed on the execution end of the second telescopic mechanism 801. The telescopic direction of the second telescopic mechanism 801 is parallel to the Z-axis; the pressure plate 802 is located above the first conveying mechanism 201. Thus, when the aforementioned situation occurs, after the stacked core boards 401 move between the first limiting frame 601 and the second limiting frame 603, the second telescopic mechanism 801 causes the pressure plate 802 to move downwards, so that the pressure plate 802 abuts against the top surface of the core boards 401, or the distance between the pressure plate 802 and the top surface of the core boards 401 is small, thus preventing the aforementioned situation from occurring. In this embodiment, the second telescopic mechanism 801 also uses a hydraulic rod.

[0028] Working principle:

[0029] When splitting, from Figure 2 From a perspective of perspective, several stacked core boards 401 gradually move on the first conveying mechanism 201. When the core boards 401 abut against the limiting plate 701, the first conveying mechanism 201 stops conveying, at which point the core boards 401 are located between the first limiting frame 601 and the second limiting frame 603. Then, the lifting mechanism 501 moves several second belt conveyor mechanisms 502 upwards until the bottom surface of the core boards 401 separates from the conveying rollers. At this point, the lifting mechanism 501 stops working, and the several second belt conveyor mechanisms 502 work synchronously (from...). Figure 2 From the perspective of the second belt conveyor mechanism 502, the conveyor belts rotate clockwise, causing the core plates 401 to move towards the first belt conveyor mechanism (from...). Figure 2 From the perspective of [the device], several core boards 401 move to the right. When the rightmost core board 401 comes into contact with the second limiting frame 603, if it still cannot fall onto the conveyor belt of the first belt conveyor mechanism, the first telescopic mechanism 602 controls the second limiting frame 603 to move to the right until the rightmost core board 401 can fall onto the conveyor belt of the first belt conveyor mechanism. When the rightmost core board 401 falls onto the conveyor belt of the first belt conveyor mechanism, several second belt conveyors 502 stop conveying, and the first belt conveyor mechanism starts working, conveying the core board 401 on it along the Y-axis. After the core board 401 leaves this frame 101, the above steps are repeated, and several second belt conveyors 502 continue to work, so that the next core board 401 falls onto the conveyor belt of the first belt conveyor mechanism... thus conveying the core boards 401 one by one to the next device.

[0030] The above description is merely a preferred embodiment of this utility model. It should be understood that this utility model is not limited to the forms disclosed herein and should not be construed as excluding other embodiments. It can be used in various other combinations, modifications, and environments, and can be altered within the scope of the concept described herein through the above teachings or related technologies or knowledge. Modifications and variations made by those skilled in the art that do not depart from the spirit and scope of this utility model should be protected within the scope of the appended claims.

Claims

1. An automatic sheet conveying frame for core board cutting, characterized in that: The system includes a frame (101), and a first conveying mechanism (201), a second conveying mechanism (301), an X-axis conveying mechanism, and a horizontal limiting mechanism, all mounted on the frame (101). The second conveying mechanism (301) is located on one side of the first conveying mechanism (201), and the conveying directions of both are parallel to the Y-axis. The horizontal bearing surface of the second conveying mechanism (301) is lower than the horizontal bearing surface of the first conveying mechanism (201) in the XZ plane. The horizontal limiting mechanism is used to prevent the core board (401) from tipping over. After several stacked core boards (401) are conveyed by the first conveying mechanism (201) to the horizontal limiting mechanism, the X-axis conveying mechanism causes several core boards (401) to move toward the second conveying mechanism (301). The core boards (401) that are close to the second conveying mechanism (301) fall onto the second conveying mechanism (301) in sequence and are then conveyed along the Y-axis one by one.

2. The core board cutting automatic sheet conveying frame according to claim 1, characterized in that: The first conveying mechanism (201) includes a plurality of conveying rollers arranged in parallel at intervals on the frame (101), the plurality of conveying rollers being connected in sequence, the central axis of any conveying roller being parallel to the X-axis; in the XY plane, the upper generatrices of any conveying roller are coplanar.

3. The core board cutting automatic sheet conveying frame according to claim 2, characterized in that: The second conveying mechanism (301) includes a first belt conveying mechanism disposed on the frame (101), the conveying direction of the first belt conveying mechanism being parallel to the Y-axis; in the XZ plane, the horizontal bearing surface of the first belt conveying mechanism is lower than the upper generatrix of any of the conveying rollers.

4. The automatic sheet conveying frame for core board cutting according to claim 3, characterized in that: The X-axis conveying mechanism includes a lifting mechanism (501) mounted on the frame (101) and a plurality of second belt conveying mechanisms (502) arranged parallel to each other at the execution end of the lifting mechanism (501). The lifting mechanism (501) moves up and down along the Z-axis direction. The conveying direction of any second belt conveying mechanism (502) is parallel to the X-axis. The plurality of second belt conveying mechanisms (502) and the plurality of conveying rollers are arranged alternately, and the distance between any two adjacent conveying rollers is greater than the width of the second belt conveying mechanism (502).

5. An automatic sheet conveying frame for core board cutting according to any one of claims 1-4, characterized in that: The horizontal limiting mechanism includes a first limiting frame (601) and a first telescopic mechanism (602) both mounted on the frame (101). The execution end of the first telescopic mechanism (602) is provided with a second limiting frame (603) opposite to the first limiting frame (601). The second limiting frame (603) is located above the second conveying mechanism (301). The telescopic direction of the first telescopic mechanism (602) is parallel to the X-axis.

6. The core board cutting automatic sheet conveying frame according to claim 5, characterized in that: The frame (101) is also provided with a limiting plate (701), which is used to limit the displacement of several stacked core boards (401) in the Y-axis direction.

7. The core board cutting automatic sheet conveying frame according to claim 5, characterized in that: The frame (101) is also provided with a pressing mechanism, which includes a second telescopic mechanism (801) provided on the frame (101) and a pressure plate (802) provided at the execution end of the second telescopic mechanism (801). The telescopic direction of the second telescopic mechanism (801) is parallel to the Z-axis. The pressure plate (802) is located above the first conveying mechanism (201).