Sheet transfer conveying system

By designing a plate transfer and conveying system, and utilizing the combination of overhead crane and pneumatic rotating column with rotating device, the problems of labor shortage and high labor costs were solved, automated production was achieved, costs were reduced and efficiency was improved.

CN122166490APending Publication Date: 2026-06-09PROCESS ADVANCE TECH

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
PROCESS ADVANCE TECH
Filing Date
2024-12-06
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

The existing manufacturing industry faces problems of labor shortages and high labor costs, which leads to increased production costs and reduced output. In particular, in automated production, manual operation is time-consuming and labor-intensive, making it difficult to meet the needs of rapid manufacturing and special processing.

Method used

A plate transfer and conveying system is adopted, which realizes the automated movement and resetting of the electroplating basket platform through the cooperation of the telescopic hook of the overhead crane and the pneumatic rotating column and the rotating device. The interlocking structure of the pneumatic rotating column and the rotating device is used to realize the efficient conveying of plates.

Benefits of technology

It achieves a highly automated production process, reducing labor costs, lowering production costs, and improving operational and processing efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The present application discloses a kind of plate transfer conveying system, including electroplating hanging basket platform, multiple pneumatic rotary columns and multiple rotating devices. Multiple pneumatic rotary columns are respectively vertically installed around the electroplating hanging basket platform, each of the pneumatic rotary column includes an outer cover, an inner gasket inside the outer cover, an inner column, a handle, an outer cylinder, a fixed seat, an upper gasket, a lower gasket, a base, a rotating sleeve, a C-shaped buckle and a resilient member. Multiple rotating devices are respectively installed on a positioning platform, each of the rotating device includes a cylinder fixed seat, a rotating cylinder, a connecting shaft, a rotating member and a ring member. When the overhead traveling crane device moves the electroplating hanging basket platform to the positioning platform, it will drive the mechanical operation through the internal pneumatic mode to automatically enter the final reset state, so that the electroplating hanging basket platform is stably placed.
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Description

Technical Field

[0001] This invention relates to a plate moving device, and more particularly to a plate transfer and conveying system that combines an overhead crane device and a rotating device. Background Technology

[0002] Currently, the manufacturing industry is facing labor shortages, rising environmental awareness, increased labor and operating costs, and pressure to transform from labor-intensive to technology-intensive industries. In the past, most businesses responded to rising manufacturing costs by relocating industries overseas or introducing foreign workers, which could reduce manpower, manufacturing hours, and increase production capacity. However, due to the industry's large demand for labor, there is a severe labor shortage, which has seriously affected the output of the manufacturing industry, directly affecting price fluctuations and instability, and causing a corresponding increase in labor and operating costs. Furthermore, to address the aforementioned impacts, businesses have shifted to introducing or modifying processing methods using automated equipment. Currently, automated production lines in the manufacturing industry utilize various manufacturing equipment and processing stations within the factory to perform various processing, cutting, joining, and assembly processes. To ensure stable and smooth transitions in subsequent production operations, the process of transporting workpieces to processing stations and machines using conveyor systems is particularly important. These workpieces are often large and heavy, and the smooth transitions during material handling, feeding, and changing can affect worker safety and cause equipment damage. Manually controlled processing methods are time-consuming and labor-intensive, failing to achieve rapid manufacturing and production, and are ill-suited to the demands of automated processes and specialized processing procedures.

[0003] For example, in the current electroplating process for circuit boards, the circuit boards must first be mounted on an overhead crane and then transported to the electroplating tank for electroplating. After electroplating, the plated circuit boards are returned by the overhead crane and removed, and then the circuit boards to be electroplated are placed on the overhead crane again to repeat the electroplating process. However, in developed countries, rising labor costs lead to higher product prices. To make products globally competitive, in addition to improving industrial standards, reducing production costs is also a crucial factor. Automated production is essential for effectively reducing production costs and improving product quality. Therefore, as our country moves towards becoming a developed nation, besides relocating labor-intensive industries abroad, it is necessary to provide an automated production environment within the country to ensure that the industrial base remains domestic. Thus, automated production is an urgent direction that industries must pursue today. Summary of the Invention

[0004] The main objective of this invention is to provide a plate transfer and conveying system.

[0005] This invention provides a plate transfer and conveying system, particularly one that uses a telescopic hook of a crane device for movement and repositioning. The system includes an electroplating basket platform, multiple pneumatic rotating columns, and multiple rotating devices. The multiple pneumatic rotating columns are erected around the electroplating basket platform. Each column includes an outer cover, an inner gasket, an inner column, a handle, an outer cylinder, a fixing seat, an upper gasket, a lower gasket, a base, a rotating sleeve, a C-shaped buckle, and an elastic element. The multiple rotating devices are mounted on a positioning platform. Each device includes a cylinder fixing seat, a rotating cylinder, a connecting shaft, a rotating component, and an annular component. The outer cover is hollow. The inner gasket is fitted inside the outer cover and is also hollow. The inner column has an upper extension column at the top and a polygonal extension column at the bottom. The upper extension column has a through hole and a screw hole orthogonal to each other at 90 degrees, and the outer cover fits onto the upper extension column. A handle, which passes through the through hole and is mounted to the screw hole via a handle fixing member to secure the handle. An outer cylinder, in which the body of the inner column and the polygonal extension column are mounted inside the outer cylinder, wherein the outer cover is locked to the outer cylinder by a first fixing member, and the surface of the outer cylinder has a U-shaped movable groove with a limiting area at each end. A hollow fixing base, which is mounted inside the outer cylinder and locked to the outer cylinder by a second fixing member. An upper gasket, which is hollow and mounted on the fixing base and located inside the outer cylinder. A lower gasket, which is hollow and mounted below the fixing base and located inside the outer cylinder. A base, which is hollow and mounted below the fixing base and the lower gasket and located inside the outer cylinder. A rotating sleeve is disposed inside the outer cylinder and below the base. The rotating sleeve has a connecting channel extending from the top to the bottom, and its surface has a threaded hole. The rotating sleeve is installed with the outer cylinder by a limiting screw that passes through the U-shaped movable groove and is locked in the threaded hole. The inner section of the connecting channel is a polygonal channel corresponding to the cross-sectional shape of the polygonal extension column, and the bottom of the rotating sleeve is a concave cone shape. A C-shaped buckle is disposed inside the rotating sleeve. An elastic member has one end abutting against the lower side of the base, and the other end located inside the rotating sleeve and above the C-shaped buckle. The center of the elastic member is directly opposite the center of the connecting channel. A cylinder mounting base is concave, with two side wings extending and fixed to the back of the positioning platform. A rotating cylinder is disposed below the cylinder mounting base and controlled by a control signal to rotate left, right, or remain stationary. A linkage shaft, one end of which is connected to the rotary cylinder and is linked. A rotating component, the bottom of which is connected to the other end of the linkage shaft and is linked, the upper half of which is in the shape of an outwardly convex cone and has a polygonal rotating guide at its top, located at the lower end opening of the connecting channel, wherein the cross-sectional shape of the polygonal rotating guide corresponds to the polygonal channel of the inner segment of the connecting channel.An annular component is disposed around the periphery of the rotating component. The polygonal extension post penetrates the upper gasket, the fixing seat, the lower gasket, the base, and the elastic component, and the top of the polygonal extension post is located at the upper opening of the connecting channel.

[0006] In one embodiment of the present invention, when the overhead crane moves the electroplating basket platform to the positioning platform, the plurality of pneumatic rotating columns of the electroplating basket platform are aligned with the plurality of rotating devices and then move downward.

[0007] In one embodiment of the present invention, when the electroplating basket platform is placed on the positioning platform, the bottom of the rotating sleeve will contact and fit tightly with the upper half of the rotating member, and the polygonal rotating guide will be aligned with the polygonal channel entering the inner section of the connecting channel, so that the elastic member is compressed, thereby relatively aligning the polygonal extension post with the polygonal channel entering the inner section of the connecting channel, so as to complete an initial reset state of the electroplating basket platform.

[0008] In one embodiment of the present invention, when a detector detects that the initial reset state of the electroplating basket platform has been completed, the rotary cylinder rotates according to the control signal and drives the connecting shaft and the rotating component to rotate by the same amplitude, thereby causing the rotary sleeve to rotate by the same amplitude, and finally causing the handle to rotate by the same amplitude, so as to complete the final reset state of the electroplating basket platform.

[0009] In one embodiment of the present invention, when the electroplating basket platform is in the process of the final reset state, the limiting screw moves from one end of the U-shaped movable groove to the other end.

[0010] In one embodiment of the present invention, the rotary cylinder rotates by 90 degrees according to the control signal, so that the handle rotates by 90 degrees accordingly.

[0011] In one embodiment of the present invention, after the electroplating basket platform completes the final reset state, the crane device is unable to hook the handle of the electroplating basket platform.

[0012] In one embodiment of the present invention, the polygonal extension column, the polygonal channel, and the polygonal rotation guide are all of the same size and shape.

[0013] In one embodiment of the present invention, the polygonal extension column is a rectangular extension column, the polygonal channel is a rectangular channel, and the polygonal rotation guide is a rectangular rotation guide.

[0014] In one embodiment of the present invention, the polygonal extension post is a triangular extension post, the polygonal channel is a triangular channel, and the polygonal rotation guide is a triangular rotation guide.

[0015] In one embodiment of the present invention, before the electroplating basket platform is to be released from the final reset state for movement, the rotary cylinder rotates in the opposite direction according to the control signal and drives the connecting shaft and the rotating component to rotate in the opposite direction with the same amplitude, thereby causing the rotary sleeve to rotate in the opposite direction with the same amplitude, and finally causing the handle to rotate in the opposite direction with the same amplitude, so that the crane device can hook the handle of the electroplating basket platform.

[0016] In one embodiment of the present invention, when the electroplating basket platform is in the process of releasing the final reset state, the limiting screw moves from one end to the other end of the U-shaped movable groove.

[0017] In one embodiment of the present invention, when the crane device hooks the handle of the electroplating basket platform by means of the telescopic hook, the electroplating basket platform will move upward away from the positioning platform, and the compressed elastic element in the pneumatic rotating column will return to its original state.

[0018] In summary, the plate transfer and conveying system provided by this invention can bring the following benefits:

[0019] 1. Highly automated manufacturing process;

[0020] 2. Reduce labor costs and lower production costs; and

[0021] 3. Improve operational and processing efficiency.

[0022] The following detailed description through specific embodiments will make it easier to understand the purpose, technical content, features and effects achieved by the present invention. Attached Figure Description

[0023] Figure 1 This is a schematic diagram of the plate transfer and conveying system of the present invention.

[0024] Figure 2 This is a schematic diagram of the pneumatic rotating column and rotating device of the plate transfer and conveying system of the present invention.

[0025] Figure 3 This is an exploded perspective view of the pneumatic rotating column and rotating device of the plate transfer and conveying system of the present invention.

[0026] Figure 4 This is a cross-sectional view of the pneumatic rotating column and rotating device of the plate transfer and conveying system of the present invention.

[0027] Figure 5 This is a diagram illustrating the operation of the pneumatic rotating column and rotating device of the plate transfer and conveying system of the present invention.

[0028] Figure 6This is a schematic diagram of the polygonal rotation guide of the present invention rotating 90 degrees within the polygonal channel.

[0029] Figure 7 This is a schematic diagram of the plate transfer and conveying system of the present invention with the handle rotated 90 degrees.

[0030] Figure 8 This is a schematic diagram of the overhead crane device of the plate transfer and conveying system of the present invention hooking up the electroplating basket platform.

[0031] Explanation of reference numerals in the attached drawings: 1000 - Plate transfer and conveying system; 100 - Electroplating basket platform; 200 - Pneumatic rotating column; 201 - Outer cover; 202 - Inner gasket of outer cover; 203 - Inner column; 203A - Upper extension column; 203A1 - Through hole; 203A2 - Screw hole; 203B - Polygonal extension column; 204 - Handle; 204FT - Handle fixing component; 205 - Outer cylinder; 205A - U-shaped movable groove; 205B - ​​Limiting area; 206 - Fixed base; 207 - Upper gasket; 208 - Lower gasket; 209 - Base; 210 - Rotary column Rotating sleeve; 210A-Connecting channel; 210AP-Polygonal channel; 210B-Screw hole; 210FT-Limiting screw; 211-C-shaped thread; 212-Elastic element; 300-Rotating device; 301-Cylinder mounting seat; 302-Rotating cylinder; 303-Connecting shaft; 304-Rotating element; 304A-Polygonal rotating guide; 305-Annular element; 400-Heavy crane device; 410-Telescopic hook; CS-Control signal; FT1-First fixing element; FT2-Second fixing element; 600-Detector; 700-Controller. Detailed Implementation

[0032] After years of research and development, the inventors have improved upon the shortcomings of existing products. The following sections will detail how this invention achieves the most efficient functional requirements with a plate transfer and conveying system.

[0033] Please see Figures 1 to 8 , Figure 1 This is a schematic diagram of the plate transfer and conveying system of the present invention. Figure 2 This is a schematic diagram of the pneumatic rotating column and rotating device of the plate transfer and conveying system of the present invention. Figure 3 This is an exploded perspective view of the pneumatic rotating column and rotating device of the plate transfer and conveying system of the present invention. Figure 4 This is a cross-sectional view of the pneumatic rotating column and rotating device of the plate transfer and conveying system of the present invention. Figure 5 This is a diagram illustrating the operation of the pneumatic rotating column and rotating device of the plate transfer and conveying system of the present invention. Figure 6 This is a schematic diagram of the polygonal rotation guide of the present invention rotating 90 degrees within the polygonal channel. Figure 7This is a schematic diagram of the plate transfer and conveying system of the present invention with the handle rotated 90 degrees. Figure 8 This is a schematic diagram of the overhead crane device of the plate transfer and conveying system of the present invention hooking the electroplating basket platform. As shown, the plate transfer and conveying system 1000, particularly through the telescopic hook 410 of an overhead crane device 400, moves and resets the electroplating basket platform 100. The overhead crane device 400, which moves on the track, has the telescopic hook 410. Figures 1 to 3 As shown, the plate transfer and conveying system 1000 includes an electroplating basket platform 100, multiple pneumatic rotating columns 200, and multiple rotating devices 300. The electroplating basket platform 100 is used to load electroplating baskets containing multiple plates or circuit boards. Multiple pneumatic rotating columns 200 are respectively erected around the electroplating basket platform 100. Each pneumatic rotating column 200 includes an outer cover 201, an inner gasket 202, an inner column 203, a handle 204, an outer cylinder 205, a fixing base 206, an upper gasket 207, a lower gasket 208, a base 209, a rotating sleeve 210, a C-shaped buckle 211, and an elastic element 212. Multiple rotating devices 300 are respectively mounted on a positioning platform (not shown), which can be a table with a front and a back. Each of the rotating devices 300 includes a cylinder mounting base 301, a rotating cylinder 302, a connecting shaft 303, a rotating component 304, and an annular component 305. The outer cover 201 is hollow. An internal gasket 202 is fitted inside the outer cover 201 and is also hollow.

[0034] Furthermore, the inner column 203 has an upper extension column 203A at the top and a polygonal extension column 203B at the bottom. The upper extension column 203A has a through hole 203A1 and a screw hole 203A2, which are orthogonal to each other at 90 degrees. The outer cover 201 is fitted onto the upper extension column 203A. The handle 204 passes through the through hole 203A1 and is mounted to the screw hole 203A2 by a handle fixing member 204FT so as to press and fix the handle 204 with a positive force. Regarding the outer cylinder 205, the inner column 203 and the polygonal extension column 203B are installed inside the outer cylinder 205. The outer cover 201 is locked to the outer cylinder 205 by a first fixing member FT1. The surface of the outer cylinder 205 has a U-shaped movable groove 205A, and each of its left and right ends has a limiting area 205B. The fixing base 206 is hollow and installed inside the outer cylinder 205, and is locked to the outer cylinder 205 by a second fixing member FT2. The upper gasket 207 is hollow and installed above the fixing base 206, located inside the outer cylinder 205. The lower gasket 208 is hollow and installed below the fixing base 206, located inside the outer cylinder 205. The base 209 is hollow and installed below the fixing base 206 and the lower gasket 208, located inside the outer cylinder 205.

[0035] Furthermore, a rotating sleeve 210 is disposed inside the outer cylinder 205 and below the base 209. The rotating sleeve 210 has a connecting channel 210A extending from the top to the bottom, and its surface has a threaded hole 210B. The rotating sleeve 210 passes through the U-shaped movable groove 205A and is locked in the threaded hole 210B to be installed with the outer cylinder 205 (at this time, the top of the limiting screw 210FT is located in one of the limiting areas 205B). The internal section of the connecting channel 210A is a polygonal channel 210AP, corresponding to the cross-sectional shape of the polygonal extension column 203B, and the bottom of the rotating sleeve 210 is a concave cone shape. A C-shaped buckle 211 is disposed inside the rotating sleeve 210. One end of the elastic element 212 abuts against the lower side of the base 209, and the other end is located inside the rotating sleeve 210 and above the C-shaped buckle 211, wherein the center of the elastic element 212 is directly opposite the center of the connecting channel 210A. The cylinder mounting base 301 is concave, and its two side wings extend and are fixed to the back of the positioning platform. The rotary cylinder 302 is mounted below the cylinder mounting base 301 and is controlled by a control signal CS to rotate left, right, or remain stationary. One end of the linkage shaft 303 is connected to the rotary cylinder 302 and is linked to it.

[0036] Furthermore, the bottom of the rotating member 304 is connected to the other end of the connecting shaft 303 for linkage. The upper half of the rotating member 304 is convex conical in shape, and its top has a polygonal rotating guide 304A located at the lower opening of the connecting channel 210A. The cross-sectional shape of the polygonal rotating guide 304A corresponds to the polygonal channel 210AP of the inner segment of the connecting channel 210A. An annular member 305 is arranged around the periphery of the rotating member 304. The polygonal extension post 203B is inserted into the interior of the outer cylinder 205 and passes through the upper gasket 207, the fixing seat 206, the lower gasket 208, the base 209, and the elastic member 212. The top of the polygonal extension post 203B is located at the upper opening of the connecting channel 210A. The upper opening of the connecting channel 210A is a circular opening, and the lower opening of the connecting channel 210A connects to the inner polygonal channel 210AP.

[0037] When the overhead crane 400 moves the electroplating basket platform 100 to the positioning platform, the plurality of pneumatic rotating columns 200 of the electroplating basket platform 100 align with the plurality of rotating devices 300 and then move downwards. The four pneumatic rotating columns 200 correspond to the four rotating devices 300 respectively. Figure 1As shown. Next, after the electroplating basket platform 100 is placed on the positioning platform, the bottom of the rotating sleeve 210 will contact and fit tightly with the upper half of the rotating member 304, and the polygonal rotating guide member 304A will align with the polygonal channel 210AP entering the inner section of the connecting channel 210A to engage. This compression force will compress the elastic member 212, thereby causing the polygonal extension post 203B to align with the polygonal channel 210AP entering the inner section of the connecting channel 210A to engage, thus completing an initial reset state of the electroplating basket platform 100. At this time, the limiting screw member 210FT moves upward and leaves the limiting area 205B. The next operation stage will then begin, as described below.

[0038] Subsequently, when a detector 600 detects that the initial reset state of the electroplating basket platform 100 has been completed, the rotary cylinder 302 will rotate according to the control signal CS, driving the connecting shaft 303 and the rotating component 304 to rotate in the same amplitude and direction, thereby causing the rotary sleeve 210 to rotate in the same amplitude and direction, and finally causing the handle 204 to rotate in the same amplitude and direction, thus completing the final reset state of the electroplating basket platform 100. Figure 6 and Figure 7 As shown. It should be noted that during the final reset process of the electroplating basket platform 100, the limiting screw 210FT moves from one end limiting area 205B of the U-shaped movable groove 205A to the other end limiting area 205B, for example, from the right limiting area 205B to the left limiting area 205B. It is worth mentioning that the polygonal extension post 203B, the polygonal channel 210AP, and the polygonal rotary guide 304A are all of corresponding and identical size and shape, so that the polygonal channel 210AP serves as a bridge connecting the polygonal extension post 203B and the polygonal rotary guide 304A.

[0039] Specifically, in this embodiment, the rotary cylinder 302 rotates 90 degrees according to the control signal CS, so that the handle 204 rotates 90 degrees accordingly. Figure 6 and Figure 7 As shown. It is worth mentioning that after the electroplating basket platform 100 completes the final reset state, the overhead crane device 400 can no longer hook the handle 204 of the electroplating basket platform 100.

[0040] In another embodiment, the polygonal extension post 203B is a rectangular extension post, the polygonal channel 210AP is a rectangular channel, and the polygonal rotation guide 304A is a rectangular rotation guide. In another embodiment, the polygonal extension post 203B is a triangular extension post, the polygonal channel 210AP is a triangular channel, and the polygonal rotation guide 304A is a triangular rotation guide.

[0041] The following will describe the final reset state of the electroplating basket platform 100 in order to provide a more complete understanding of the operation of the plate transfer and conveying system 1000 of the present invention.

[0042] Before the electroplating basket platform 100 is to be released from its final reset state and moved, the rotary cylinder 302 will rotate in the opposite direction according to the control signal CS, driving the connecting shaft 303 and the rotating component 304 to rotate in the same direction with the same amplitude. This causes the rotary sleeve 210 to rotate in the opposite direction with the same amplitude, and finally causes the handle 204 to rotate in the opposite direction with the same amplitude, so that the overhead crane device 400 can hook the handle 204 of the electroplating basket platform 100. It should be noted that when the electroplating basket platform 100 is released from its final reset state, the limiting screw 210FT will move from the other end limiting area 205B of the U-shaped movable groove 205A to one end limiting area 205B, for example, from the left limiting area 205B to the right limiting area 205B. Afterwards, as Figure 8 As shown, when the overhead crane device 400 hooks the handle 204 of the electroplating basket platform 100 with the telescopic hook 410, the electroplating basket platform 100 will move upward away from the positioning platform, and the compressed elastic element 212 in the pneumatic rotating column 200 will return to its original state.

[0043] In summary, the plate transfer and conveying system provided by this invention can bring the following benefits:

[0044] 1. Highly automated manufacturing process;

[0045] 2. Reduce labor costs and lower production costs; and

[0046] 3. Improve operational and processing efficiency.

[0047] However, the above description is merely a preferred embodiment of the present invention and is not intended to limit the scope of the invention. Therefore, all equivalent variations or modifications made in accordance with the features and spirit described in the claims of the present invention should be included within the scope of the present invention.

Claims

1. A plate transfer and conveying system, characterized in that, the plate is moved and reset via a telescopic hook of a crane device, and that, The plate transfer and conveying system includes: An electroplating hanging basket platform; Multiple pneumatic rotating columns are erected around the perimeter of the electroplating basket platform, and each pneumatic rotating column includes: The outer cover is hollow; An inner gasket for the outer cover is fitted inside the outer cover and is hollow; An inner column has an upper extension column at the top and a polygonal extension column at the bottom of its body. The upper extension column has a through hole and a screw hole that are orthogonal to each other at 90 degrees. The outer cover is fitted onto the upper extension column. A handle is inserted through the through hole and installed into the screw hole by a handle fixing member to secure the handle; An outer cylinder, wherein the body of the inner column and the polygonal extension column are installed inside the outer cylinder, wherein the outer cover is locked to the outer cylinder by a first fixing member, and the surface of the outer cylinder has a U-shaped movable groove, and each end of the groove has a limiting area. A fixed base, which is hollow and installed inside the outer cylinder, is locked to the outer cylinder by a second fixing member; A gasket, which is hollow, is installed on the fixing base and located inside the outer cylinder; A gasket, which is hollow, is installed below the fixing base and located inside the outer cylinder; A base, which is hollow and is installed below the fixing seat and the lower pad and located inside the outer cylinder; A rotating sleeve is disposed inside the outer cylinder and located below the base. The interior of the rotating sleeve has a connecting channel extending through the top and bottom, and the surface of the rotating sleeve has a screw hole. The rotating sleeve is installed with the outer cylinder by passing through the U-shaped movable groove and locking it in the screw hole through a limiting screw. The interior section of the connecting channel is a polygonal channel, which corresponds to the cross-sectional shape of the polygonal extension column, and the bottom of the rotating sleeve is a concave cone shape. A C-shaped buckle, which is disposed inside the rotating sleeve; and An elastic element, one end of which abuts against the lower side of the base, and the other end of which is located and abuts against the inside of the rotating sleeve and is located above the C-shaped buckle, wherein the center of the elastic element is directly opposite the center of the connecting channel. Multiple rotating devices are mounted on a positioning platform, each of the rotating devices comprising: A cylinder mounting base, which is concave in shape, has two side wings that extend and are fixed to the back of the positioning platform; A rotary cylinder is mounted below a cylinder mounting base and controlled by a control signal to rotate left, rotate right, or remain stationary; A linkage shaft, one end of which is connected to the rotary cylinder and is linked to it; A rotating component, its bottom connected to the other end of the linkage shaft for linkage, the upper half of the rotating component is in the shape of an outwardly convex cone and its top has a polygonal rotary guide located at the lower end opening of the connecting channel, wherein the cross-sectional shape of the polygonal rotary guide corresponds to the polygonal channel of the inner segment of the connecting channel; and A ring-shaped component is arranged around the periphery of the rotating component. The polygonal extension post passes through the upper gasket, the fixing seat, the lower gasket, the base and the elastic member, and the top of the polygonal extension post is located at the upper opening of the connecting channel.

2. The plate transfer and conveying system as described in claim 1, characterized in that, When the overhead crane moves the electroplating basket platform to the positioning platform, the multiple pneumatic rotating columns of the electroplating basket platform align with the multiple rotating devices and then move downwards.

3. The plate transfer and conveying system as described in claim 2, characterized in that, When the electroplating basket platform is placed on the positioning platform, the bottom of the rotating sleeve and the upper half of the rotating component touch and fit together, and the polygonal rotating guide is aligned with the polygonal channel entering the inner section of the connecting channel, so that the elastic member is compressed, thereby relatively aligning the polygonal extension post with the polygonal channel entering the inner section of the connecting channel, so as to complete the initial reset state of the electroplating basket platform.

4. The plate transfer and conveying system as described in claim 3, characterized in that, Once a detector detects that the initial reset state of the electroplating basket platform has been completed, the rotary cylinder rotates according to the control signal, causing the connecting shaft and the rotating component to rotate by the same amplitude, which in turn causes the rotary sleeve to rotate by the same amplitude, and finally causes the handle to rotate by the same amplitude, thereby completing the final reset state of the electroplating basket platform.

5. The plate transfer and conveying system as described in claim 4, characterized in that, When the electroplating basket platform is in the process of resetting to its final state, the limiting screw moves from one end of the U-shaped movable groove to the other end.

6. The plate transfer and conveying system as described in claim 4, characterized in that, The rotary cylinder rotates 90 degrees according to the control signal, so that the handle rotates 90 degrees accordingly.

7. The plate transfer and conveying system as described in claim 5, characterized in that, Once the electroplating basket platform has completed its final reset, the overhead crane cannot hook the handle of the electroplating basket platform.

8. The plate transfer and conveying system as described in claim 1, characterized in that, The size and shape of the polygonal extension column, the polygonal channel, and the polygonal rotary guide are all corresponding to each other and identical.

9. The plate transfer and conveying system as described in claim 1, characterized in that, The polygonal extension column is a rectangular extension column, the polygonal channel is a rectangular channel, and the polygonal rotary guide is a rectangular rotary guide.

10. The plate transfer and conveying system as described in claim 1, characterized in that, The polygonal extension column is a triangular extension column, the polygonal channel is a triangular channel, and the polygonal rotary guide is a triangular rotary guide.

11. The plate transfer and conveying system as described in claim 4, characterized in that, Before the electroplating basket platform is to be released from its final reset state and moved, the rotary cylinder rotates in the opposite direction according to the control signal, causing the connecting shaft and the rotating component to rotate in the opposite direction with the same amplitude. This causes the rotary sleeve to rotate in the opposite direction with the same amplitude, and finally causes the handle to rotate in the opposite direction with the same amplitude, so that the overhead crane can hook the handle of the electroplating basket platform.

12. The plate transfer and conveying system as described in claim 11, characterized in that, When the electroplating basket platform is in the process of being released from its final reset state, the limiting screw moves from one end to the other end of the U-shaped movable groove.

13. The plate transfer and conveying system as described in claim 11, characterized in that, When the overhead crane device hooks the handle of the electroplating basket platform using the telescopic hook, the electroplating basket platform moves upward away from the positioning platform, and the compressed elastic element in the pneumatic rotating column returns to its original state.