A transport mechanism having a double deck platform

By designing a transmission mechanism with upper and lower double-layer platforms, and using a synchronous feeding device and lifting cylinder to drive the lifting frame, the problem of low efficiency in traditional feeding mechanisms is solved, achieving efficient feeding and low-cost production.

CN224376873UActive Publication Date: 2026-06-19DONGGUAN MINA PRECISION EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DONGGUAN MINA PRECISION EQUIP CO LTD
Filing Date
2025-07-18
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Traditional feeding mechanisms are single-layer structures, resulting in low feeding efficiency, high production costs, and a significant amount of waiting time wasted during the individual feeding and unloading processes.

Method used

The transmission mechanism adopts a double-layer platform, and the first and second feeding devices simultaneously carry out the feeding and unloading work. The lifting cylinder drives the lifting frame and the loading platform to achieve efficient conveying of ceramic sheets. Combined with the baffle assembly and buffer, the stability of the material is ensured.

Benefits of technology

It effectively shortens waiting time, improves feeding efficiency, reduces production costs, ensures the stability and safety of materials during transportation, and reduces human intervention.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224376873U_ABST
    Figure CN224376873U_ABST
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Abstract

This utility model relates to the field of feeding platform technology, and more particularly to a transmission mechanism with a double-layer platform. It includes a first feeding device, a first linear module driven and connected to the first feeding device, a second feeding device used in conjunction with the first feeding device, and a second linear module driven and connected to the second feeding device. The first and second feeding devices have the same structure and are arranged in an upper and lower layer. The first feeding device includes a base, a lifting cylinder inclinedly disposed on the base, a lifting frame driven and connected to the lifting cylinder, and a loading platform disposed on the lifting frame. The lifting frame is equipped with a material blocking component to prevent material from contacting the material placed on the loading platform. This utility model adopts a double-layer feeding structure, and the first and second feeding devices simultaneously perform loading and unloading operations, effectively shortening waiting time, reducing production costs, and improving feeding efficiency.
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Description

Technical Field

[0001] This utility model relates to the field of feeding platform technology, and in particular to a transmission mechanism with a double-layer platform. Background Technology

[0002] Due to their excellent thermal, mechanical, chemical, and dielectric properties, ceramic sheets have a wide range of applications. To facilitate assembly and use, ceramic sheets often require processing such as chamfering, cutting, trimming, and drilling to aid in subsequent shaping. This involves the feeding mechanism for the ceramic sheets. Traditional feeding mechanisms are mostly single-layer chain conveyors or stepper conveyors. Such mechanisms waste significant waiting time during each individual loading and unloading operation, increasing production costs and resulting in low feeding efficiency. Utility Model Content

[0003] The purpose of this invention is to address the shortcomings of existing technologies by providing a transmission mechanism with a double-layer platform. This mechanism employs a double-layer feeding structure, where the first and second feeding devices simultaneously perform loading and unloading operations, thereby efficiently shortening waiting time, reducing production costs, and improving feeding efficiency.

[0004] To achieve the above objectives, this utility model provides a transmission mechanism with a double-layer platform, comprising a first feeding device, a first linear module driven and connected to the first feeding device, a second feeding device used in conjunction with the first feeding device, and a second linear module driven and connected to the second feeding device. The first feeding device and the second feeding device have the same structure and are arranged in two layers, one above the other. The first feeding device includes a base, a lifting cylinder inclinedly disposed on the base, a lifting frame driven and connected to the lifting cylinder, and a loading platform disposed on the lifting frame. The lifting frame is provided with a material blocking component, which is used to block and prevent material placed on the loading platform from contacting it.

[0005] Preferably, one end of the lifting frame is provided with a first hinge seat, the output end of the lifting cylinder is provided with a connector, a first hinge shaft is connected between the first hinge seat and the connector, the other end of the lifting frame is provided with a second hinge seat, the base is provided with a connector, and a second hinge shaft is connected between the second hinge seat and the connector.

[0006] Preferably, the material blocking assembly includes a sliding seat, a material blocking plate disposed on the sliding seat, and a drive cylinder drivenly connected to the sliding seat. The sliding seat is driven by the drive cylinder to move along the width direction of the loading platform so that the outer side of the material blocking plate stops and abuts against the outer side of the material placed on the loading platform.

[0007] Preferably, the sliding seat is provided with a slider, the lifting frame is provided with a guide rail that is slidably connected to the slider, the lifting frame is provided with a mounting base, and the lifting frame is connected to the drive cylinder through the mounting base.

[0008] Preferably, a buffer is provided at one end of the base near the lifting frame. Multiple buffers are provided, spaced apart, and the multiple buffers prevent contact with the bottom surface of the lifting frame.

[0009] Preferably, the top of the loading platform is provided with suction holes for suctioning the material it carries, and there are multiple suction holes arranged in a rectangular array. The bottom of the loading platform is provided with vacuum connectors, and there are multiple vacuum connectors connected to the multiple suction holes.

[0010] Preferably, the base is provided with a hollowed-out groove, and there are multiple hollowed-out grooves, which are recessed from the outer surface of the base.

[0011] The beneficial effects of this utility model are: by adopting a double-layer feeding structure, the feeding and unloading operations are carried out synchronously by the first feeding device and the second feeding device, which effectively shortens the waiting time, reduces production costs, and improves feeding efficiency. Attached Figure Description

[0012] Figure 1 This is a schematic diagram of the structure of this utility model.

[0013] Figure 2 This is an exploded structural diagram of the present invention.

[0014] Figure 3 This is a schematic diagram of the double-layer structure of the first feeding device and the second feeding device of this utility model.

[0015] Figure 4 This is a schematic diagram of the front structure of the lifting frame of this utility model.

[0016] Figure 5 This is a schematic diagram of the rear structure of the lifting frame of this utility model.

[0017] Figure 6 for Figure 4 A magnified schematic diagram of part A in the diagram.

[0018] The reference numerals in the figures include:

[0019] 1—First feeding device; 11—Base; 12—Lifting cylinder

[0020] 13—Lifting frame; 131—Guide rail; 132—Mounting base

[0021] 14 – Carrying platform; 141 – Suction hole; 142 – Vacuum connector

[0022] 15—Blocking assembly; 151—Sliding seat; 152—Blocking plate

[0023] 153 — Drive cylinder 154 — Slider

[0024] 16—First hinge seat; 17—Connector; 18—First hinge shaft

[0025] 19—Second hinge seat; 110—Connecting seat; 111—Second hinge shaft

[0026] 112 - Buffer; 113 - Hollowed-out groove

[0027] 2 - First linear module; 3 - Second feeding device; 4 - Second linear module. Detailed Implementation

[0028] The present invention will now be described in detail with reference to the accompanying drawings.

[0029] like Figures 1 to 6 As shown, the present invention discloses a transmission mechanism with a double-layer platform, including a first feeding device 1, a first linear module 2 driven and connected to the first feeding device 1, a second feeding device 3 used in conjunction with the first feeding device 1, and a second linear module 4 driven and connected to the second feeding device 3. The first feeding device 1 and the second feeding device 3 have the same structure and are arranged in two layers, one above the other. The first feeding device 1 includes a base 11, a lifting cylinder 12 inclinedly disposed on the base 11, a lifting frame 13 driven and connected to the lifting cylinder 12, and a loading platform 14 disposed on the lifting frame 13. The lifting frame 13 is provided with a material blocking component 15, which is used to block the material placed on the loading platform 14.

[0030] During operation, the first linear module 2 drives the first feeding device 1 to move back and forth, and the second linear module 4 drives the second feeding device 3 to move back and forth. Since the first feeding device 1 and the second feeding device 3 have the same structure and are arranged in two layers, the first feeding device 1 and the second feeding device 3 can simultaneously and efficiently feed and unload ceramic pieces, effectively shortening the intermediate waiting time. The two will not interfere with each other due to structural interference or collision. The baffle assembly 15 is used to stop the ceramic pieces placed on the loading platform 14 from hitting each other, ensuring that the ceramic pieces do not shift position or fall accidentally during transportation. After the ceramic pieces are cut, the lifting cylinder 12, which is tilted on the base 11, drives the loading platform 14 to tilt and lift through the lifting frame 13. The angle between the central axis of the lifting cylinder 12 and the base 11 is 0° to 30°, preferably 15°, so that the ceramic pieces can slide down the loading platform 14 under the action of gravity and be collected in the external material box. This utility model adopts a double-layer feeding structure, and the first feeding device 1 and the second feeding device 3 simultaneously carry out the feeding and unloading work, which effectively shortens the waiting time, reduces production costs, and improves feeding efficiency.

[0031] In this embodiment, a first hinge seat 16 is provided at one end of the lifting frame 13, and a connector 17 is provided at the output end of the lifting cylinder 12. A first hinge shaft 18 is connected between the first hinge seat 16 and the connector 17. A second hinge seat 19 is provided at the other end of the lifting frame 13, and a connector 110 is provided at the base 11. A second hinge shaft 111 is connected between the second hinge seat 19 and the connector 110. Specifically, the connector 17 of the lifting cylinder 12 is movably hinged to the first hinge seat 16 of the lifting frame 13 through the first hinge shaft 18. At the same time, the second hinge seat 19 of the lifting frame 13 is movably hinged to the connector 110 of the base 11 through the second hinge shaft 111. This improves the flexibility of the loading platform 14 in turning, so that the ceramic pieces placed on the loading platform 14 can slide down along the loading platform 14 under the action of gravity, realizing a fast unloading operation. The operation is time-saving and labor-saving, and no manual intervention is required throughout the process, reducing labor costs.

[0032] The material blocking assembly 15 in this embodiment includes a sliding base 151, a baffle plate 152 disposed on the sliding base 151, and a drive cylinder 153 drivenly connected to the sliding base 151. The sliding base 151 is driven by the drive cylinder 153 to move along the width direction of the loading platform 14, so that the outer side of the baffle plate 152 stops and abuts against the outer side of the material on the loading platform 14. Specifically, the sliding base 151 is driven by the drive cylinder 153 to move along the width direction of the loading platform 14. Since the ceramic sheets have different specifications and sizes, by arbitrarily adjusting the position of the baffle plate 152 on the loading platform 14 in advance, the outer side of the baffle plate 152 is accurately stopped and abuts against the outer side of the ceramic sheet on the loading platform 14. This provides high operational compatibility and effectively avoids the ceramic sheets from shifting position during transportation or even accidentally falling off.

[0033] In this embodiment, the sliding base 151 is equipped with a slider 154, and the lifting frame 13 is equipped with a guide rail 131 that is slidably connected to the slider 154. The lifting frame 13 is also equipped with a mounting base 132, and the lifting frame 13 is connected to the drive cylinder 153 via the mounting base 132. Specifically, the lifting frame 13 is fixedly connected to the drive cylinder 153 via the mounting base 132, and the sliding base 151 is slidably connected to the guide rail 131 via the slider 154. When used in conjunction with the drive cylinder 153, it can achieve efficient linear motion, ensuring the smoothness and accuracy of the motion.

[0034] In this embodiment, a buffer 112 is provided at one end of the base 11 near the lifting frame 13. Multiple buffers 112 are provided, spaced apart, and prevent contact with the bottom surface of the lifting frame 13. Specifically, when the lifting cylinder 12 drives the loading platform 14 to descend via the lifting frame 13, the spaced-apart buffers 112 prevent contact with the bottom surface of the lifting frame 13, thus buffering and decelerating the vertically moving lifting frame 13. This also provides good protection and limiting for the lifting frame 13, improving operational safety and stability.

[0035] In this embodiment, the top of the loading platform 14 is provided with suction holes 141 for adhering to the material it carries. Multiple suction holes 141 are arranged in a rectangular array. Multiple vacuum connectors 142 are provided at the bottom of the loading platform 14, and these connectors are connected to the suction holes 141. Specifically, the multiple suction holes 141 are arranged in a rectangular array at the top of the loading platform 14, and the multiple vacuum connectors 142 are arranged in a rectangular array at the bottom. Since the multiple vacuum connectors 142 are connected to the multiple suction holes 141, they are connected to an external air pump through multiple connecting pipes (not shown). After the air pump is started, air is drawn from the multiple suction holes 141 through the multiple vacuum connectors 142, thereby allowing the multiple suction holes 141 of the loading platform 14 to stably hold multiple ceramic sheets.

[0036] In this embodiment, the base 11 is provided with a plurality of hollowed-out grooves 113, which are recessed from the outer surface of the base 11. Specifically, the multiple hollowed-out grooves 113 are recessed from the outer surface of the base 11, which effectively reduces the weight of the base 11 and improves its shock absorption capacity, thus ensuring the working stability of the base 11.

[0037] The above description is only a preferred embodiment of this utility model. For those skilled in the art, there will be changes in the specific implementation method and application scope based on the idea of ​​this utility model. The content of this specification should not be construed as a limitation of this utility model.

Claims

1. A transmission mechanism with a dual-layer platform, characterized in that: The device includes a first feeding device, a first linear module driven and connected to the first feeding device, a second feeding device used in conjunction with the first feeding device, and a second linear module driven and connected to the second feeding device. The first feeding device and the second feeding device have the same structure and are arranged in two layers, one above the other. The first feeding device includes a base, a lifting cylinder inclinedly disposed on the base, a lifting frame driven and connected to the lifting cylinder, and a material carrier platform disposed on the lifting frame. The lifting frame is provided with a material blocking component, which is used to block and prevent material placed on the material carrier platform.

2. The transmission mechanism with a dual-layer platform according to claim 1, characterized in that: One end of the lifting frame is provided with a first hinge seat, the output end of the lifting cylinder is provided with a connector, a first hinge shaft is connected between the first hinge seat and the connector, the other end of the lifting frame is provided with a second hinge seat, the base is provided with a connector, and a second hinge shaft is connected between the second hinge seat and the connector.

3. The transmission mechanism with a dual-layer platform according to claim 1, characterized in that: The material blocking assembly includes a sliding seat, a material blocking plate disposed on the sliding seat, and a drive cylinder driven by the sliding seat. The sliding seat is driven by the drive cylinder to move along the width direction of the loading platform so that the outer side of the material blocking plate stops and abuts against the outer side of the material placed on the loading platform.

4. The transmission mechanism with a dual-layer platform according to claim 3, characterized in that: The sliding seat is equipped with a slider, the lifting frame is equipped with a guide rail that is slidably connected to the slider, the lifting frame is equipped with a mounting base, and the lifting frame is connected to the drive cylinder through the mounting base.

5. The transmission mechanism with a dual-layer platform according to claim 1, characterized in that: A buffer is provided at one end of the base near the lifting frame. Multiple buffers are provided, spaced apart, and the multiple buffers prevent contact with the bottom surface of the lifting frame.

6. The transmission mechanism with a dual-layer platform according to claim 1, characterized in that: The top of the loading platform is provided with suction holes for suctioning the material it carries. There are multiple suction holes arranged in a rectangular array. The bottom of the loading platform is provided with vacuum connectors. There are multiple vacuum connectors connected to the multiple suction holes.

7. The transmission mechanism with a dual-layer platform according to claim 1, characterized in that: The base is provided with a hollowed-out groove, and there are multiple hollowed-out grooves, which are recessed from the outer surface of the base.