A cassette stand
By designing the transfer and lifting mechanism of the glass storage platform, uniform force and stable transfer of the glass sheets were achieved during the transfer process, solving the problems of easy breakage and interference of glass sheets in traditional devices, and improving production efficiency and product quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI JINGLING GLASS MACHINERY
- Filing Date
- 2025-05-21
- Publication Date
- 2026-06-09
AI Technical Summary
Traditional glass storage devices have a simple structure, which makes the glass sheets prone to uneven stress and breakage during transport. Furthermore, interference can easily occur when switching between storage and transport, affecting processing efficiency and product quality.
A wafer storage platform was designed, comprising a frame, a transmission mechanism, a lifting mechanism, and multiple transmission rollers. The transmission rollers are driven to rotate synchronously by a first motor and a chain. Combined with the lifting mechanism and an auxiliary transmission system, the rotation speed of the transmission rollers is ensured to be consistent. Support members are set in the wafer storage mechanism so that the support rods form a coplanar plane to avoid jamming and collision.
This achieves uniform force distribution on the glass sheet during transport, reduces the risk of breakage, ensures stability during transport and temporary storage, avoids jamming and collisions, and improves production efficiency and product quality.
Smart Images

Figure CN224336638U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of glass transfer technology, and in particular to a glass storage platform. Background Technology
[0002] In the glass production and processing process, from the cutting of raw glass sheets to subsequent deep processing stages, it is often necessary to temporarily store and transfer the glass sheets.
[0003] Traditional glass storage devices are simple in structure, typically using only a basic support structure to hold the glass sheets. During transport, they rely on manual handling or simple conveyor rollers. Because the rotation speeds of different conveyor rollers are difficult to synchronize precisely, the glass sheets experience uneven stress, making them prone to breakage during transport. This results in material waste and increased production costs. Furthermore, the simple support structure is prone to interference during the switch between storage and transport, causing the glass sheets to jam or collide. This not only affects processing efficiency but also leads to scratches and breakage on the glass surface, reducing product quality. Utility Model Content
[0004] In order to solve the technical problems existing in the background art, this utility model proposes a wafer storage stage.
[0005] This utility model proposes a chip storage platform, comprising: a frame, a transmission mechanism and a lifting mechanism mounted on the frame, multiple transmission rollers, and a chip storage mechanism. The transmission rollers are rotatably mounted on the frame. The transmission mechanism connects to the multiple transmission rollers and can drive the multiple transmission rollers to rotate synchronously. The chip storage mechanism specifically includes: a connecting member and M supporting members. The M supporting members are all mounted on the connecting member. The supporting members include: a first connecting rod, a second connecting rod, and N supporting rods connected between the first connecting rod and the second connecting rod. The connecting member is located above or below the transmission rollers and all the supporting rods. The lifting mechanism drives the connected chip storage mechanism. The supporting members are all located between adjacent transmission rollers. When the lifting mechanism drives the chip storage mechanism to move up or down, thereby causing the supporting members to move up or down between adjacent transmission rollers, the chip storage mechanism can reach N positions. When the chip storage mechanism is in any of the N positions, there exists a one-to-one correspondence between the top supporting surfaces of the M supporting rods belonging to the M supporting members, which are all coplanar with the transmission surface formed by the multiple transmission rollers. M and N are both natural numbers greater than 1.
[0006] Preferably, the transmission mechanism includes a first motor fixedly mounted on the frame, and first sprockets fixedly mounted on the same side of the roller shafts of multiple transmission rollers. The drive end of the first motor drives the multiple first sprockets to rotate synchronously through a first chain.
[0007] Preferably, the lifting mechanism specifically includes: a bidirectional motor, a drive shaft, two second sprockets, and two second chains. The bidirectional motor is fixedly mounted on the frame, the drive shaft is fixedly mounted on the output end of the bidirectional motor, the two second sprockets are respectively fixedly mounted on both ends of the drive shaft, and first connecting parts are fixedly mounted on the side walls of the connecting parts near both ends of the drive shaft. Two third sprockets are also rotatably mounted on the frame. The two second chains correspond one-to-one with the two third sprockets and are connected by transmission through the two second chains. The two first connecting parts are hinged one-to-one with the two second chains. The hinge points of the two first connecting parts and the two second chains are located on the same first plane, and the first plane is parallel to the upper surface of the connecting parts.
[0008] Preferably, it further includes: a drive shaft, a drive chain, two fourth sprockets, and two third chains. The drive shaft and the drive shaft are connected by the drive chain. The two fourth sprockets are fixedly installed at both ends of the drive shaft. Two fifth sprockets are also rotatably installed on the frame. The two fourth sprockets correspond one-to-one with the two fifth sprockets and are connected by the two third chains. The connecting parts are fixedly installed on the side walls near both ends of the drive shaft. The two second connecting parts are hinged one-to-one with the two third chains. The hinge points of the two second connecting parts and the two third chains are located on the first plane.
[0009] Preferably, the axis of the drive shaft and the axis of the transmission shaft are both located in a second plane, which is parallel to the first plane. The axes of the two third sprockets and the axes of the two fifth sprockets are both located in a third plane, which is parallel to the first plane.
[0010] The glass storage platform proposed in this utility model has the following advantages: multiple transmission rollers are evenly distributed and driven synchronously by a first motor, a first chain, and a first sprocket, ensuring that the rotational speed of each transmission roller is consistent. This ensures that the glass sheet is subjected to uniform force during transmission, allowing it to move smoothly and reducing the risk of glass sheet breakage. The design of the glass storage mechanism prevents interference during the switching between glass storage and transmission. Furthermore, when the glass storage mechanism is in different positions, the support surface at the top of the support rod of the support member is coplanar with the transmission surface formed by the transmission rollers, effectively avoiding problems such as jamming and collision of the glass sheet during transmission and temporary storage. The lifting mechanism, through the cooperation of a bidirectional motor, drive shaft, sprocket, and chain, can drive the glass storage mechanism to move up or down. The added auxiliary transmission system (including components such as a drive shaft, drive chain, sprocket, and third chain) can ensure that multiple connection points of the connecting member can be raised and lowered simultaneously, maintaining the stability of the connecting member. Multiple sets of auxiliary transmission systems can be added as needed to further enhance the stability and reliability of the lifting process. The overall structure and the coordinated operation of each mechanism are rationally designed in all aspects, from the transfer and temporary storage of glass plates to lifting and lowering, ensuring the efficient and safe operation of the glass plate storage platform. Attached Figure Description
[0011] Figure 1This is an overall structural diagram of a wafer storage platform proposed in this utility model;
[0012] Figure 2 This is a side view of a wafer storage stage proposed in this utility model;
[0013] Figure 3 This is a front view of the wafer storage mechanism of a wafer storage stage proposed in this utility model;
[0014] Figure 4 This is a side view of the wafer storage mechanism of a wafer storage stage proposed in this utility model. Detailed Implementation
[0015] refer to Figure 1-4 This utility model proposes a glass plate storage platform, including: a frame 1, which provides a stable mounting base for other components; a transmission mechanism and a lifting mechanism installed on the frame 1, which work together to be the power source for moving the glass plates; and multiple transmission rollers 2, which are evenly distributed and rotated on the frame 1 to ensure stable transmission of the glass plates.
[0016] The storage mechanism 3 specifically includes: a connector 4 and M support members 5. The M support members 5 are all installed on the connector 4 to form a whole. The support members 5 include: a first connecting rod 6, a second connecting rod 7, and N support rods 8 connected between the first connecting rod 6 and the second connecting rod 7. Among the M support members 5, a glass sheet can be placed on the M consecutive support rods 8 that are located on a certain plane. The connector 4 is located above or below the transmission roller 2 and all the support rods 8 to ensure that there is no interference during the storage and transmission switching process. The lifting mechanism drives the storage mechanism 3. When the lifting mechanism drives the storage mechanism 3 to move up or down, so that the support members 5 move up or down between adjacent transmission rollers 2, the storage mechanism 3 can reach N positions. When the storage mechanism 3 is in any of the N positions, there is a one-to-one correspondence between the top support surfaces of the M support rods 8 belonging to the M support members 5 and the transmission surface formed by the multiple transmission rollers 2. The glass sheet effectively avoids problems such as jamming and collision during the transmission and temporary storage process. M and N are both natural numbers greater than 1.
[0017] In terms of the transmission mechanism, it specifically includes a first motor fixedly installed on the frame 1, and a first sprocket fixedly installed on the same side of the roller shafts of multiple transmission rollers 2. The drive end of the first motor drives multiple first sprockets to rotate synchronously through the first chain. This transmission method not only has high transmission efficiency, but also ensures that the rotation speed of each transmission roller 2 is consistent, so that the glass sheet is subjected to uniform force during transmission and moves forward smoothly, which greatly reduces the risk of glass sheet breakage.
[0018] The lifting mechanism specifically includes: a bidirectional motor 9, a drive shaft 10, two second sprockets 11, and two second chains 12. The bidirectional motor 9 is fixedly installed on the frame 1 and can control the lifting action. The drive shaft 10 is fixedly installed on the output end of the bidirectional motor 9. The two second sprockets 11 are respectively fixedly installed on both ends of the drive shaft 10. The connecting parts 4 are fixedly installed on the side walls near both ends of the drive shaft 10. Two third sprockets 14 are also rotatably installed on the frame 1. The two second chains 12 and the two third sprockets 14 are in one-to-one correspondence and are connected by transmission through the two second chains 12. The two first connecting parts 13 are hinged to the two second chains 12 in one-to-one correspondence. The hinge points of the two first connecting parts 13 and the two second chains 12 are located on the same first plane. The first plane is parallel to the upper surface of the connecting parts 4. When the bidirectional motor 9 drives the two second chains 12 to rotate, the connecting parts 4 can be driven to rise or fall through the two first connecting parts 13.
[0019] The glass storage stage has been further optimized with the addition of an auxiliary transmission system, which includes: a drive shaft 15, a drive chain 16, two fourth sprockets 17, and two third chains 18. The drive shaft 10 is connected to the drive shaft 15 via the drive chain 16. The two fourth sprockets 17 are fixedly mounted at both ends of the drive shaft 15. Two fifth sprockets 19 are also rotatably mounted on the frame 1. The two fourth sprockets 17 and the two fifth sprockets 19 correspond one-to-one and are connected via the two third chains 18. The connecting piece 4 is located near the two ends of the drive shaft 15. Each wall is fixedly equipped with a second connecting part 20. The two second connecting parts 20 are hinged to the two third chains 18 one by one. The hinge points of the two second connecting parts 20 and the two third chains 18 are located on the first plane. By adding an auxiliary transmission system, it can be ensured that multiple connection points of the connecting part 4 can rise or fall simultaneously to maintain the stability of the connecting part 4. Similarly, multiple auxiliary transmission systems can be added to increase the stability of the lifting mechanism, further enhance the stability and reliability of the lifting process, and comprehensively ensure the efficient and safe operation of the glass storage platform.
[0020] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and concept of the present utility model, should be included within the protection scope of the present utility model.
Claims
1. A wafer storage stage, characterized in that, include: The frame (1), the transmission mechanism and lifting mechanism installed on the frame (1), multiple transmission rollers (2), and the chip storage mechanism (3) are included. The transmission rollers (2) are rotatably installed on the frame (1). The transmission mechanism connects multiple transmission rollers (2) and can drive multiple transmission rollers (2) to rotate synchronously. The chip storage mechanism (3) specifically includes: a connector (4) and M support members (5). The M support members (5) are all installed on the connector (4). The support members (5) include: a first connecting rod (6), a second connecting rod (7), and N support rods (8) connected between the first connecting rod (6) and the second connecting rod (7). The connector (4) is located on the frame (1). Above or below the conveying roller (2) and all the support rods (8), the lifting mechanism drives the storage mechanism (3). The support members (5) are all located between the gaps of adjacent conveying rollers (2). When the lifting mechanism drives the storage mechanism (3) to move up or down, so that the support members (5) move up or down between adjacent conveying rollers (2), the storage mechanism (3) can reach N positions. When the storage mechanism (3) is in any of the N positions, there is a one-to-one correspondence between the top support surfaces of the M support rods (8) belonging to the M support members (5) and the transmission surfaces formed by the multiple conveying rollers (2). M and N are both natural numbers greater than 1.
2. A wafer storage stage according to claim 1, characterized in that, The transmission mechanism includes a first motor fixedly installed on the frame (1), and first sprockets fixedly installed on the same side of the roller shafts of multiple transmission rollers (2). The drive end of the first motor drives multiple first sprockets to rotate synchronously through the first chain.
3. A wafer storage stage according to claim 1, characterized in that, The lifting mechanism specifically includes: a bidirectional motor (9), a drive shaft (10), two second sprockets (11) and two second chains (12). The bidirectional motor (9) is fixedly installed on the frame (1). The drive shaft (10) is fixedly installed at the output end of the bidirectional motor (9). The two second sprockets (11) are respectively fixedly installed at both ends of the drive shaft (10). The connecting piece (4) is fixedly installed with a first connecting part (13) on the side wall near both ends of the drive shaft (10). Two third sprockets (14) are also rotatably installed on the frame (1). The two second chains (12) and the two third sprockets (14) are connected one-to-one through the transmission of the two second chains (12). The two first connecting parts (13) are hinged one-to-one on the two second chains (12). The hinge points of the two first connecting parts (13) and the two second chains (12) are located on the first plane. The first plane is parallel to the upper surface of the connecting piece (4).
4. A wafer storage stage according to claim 3, characterized in that, Also includes: The drive shaft (15), drive chain (16), two fourth sprockets (17), and two third chains (18) are connected to the drive shaft (15) via the drive chain (16). The two fourth sprockets (17) are fixedly installed at both ends of the drive shaft (15). Two fifth sprockets (19) are also rotatably installed on the frame (1). The two fourth sprockets (17) and the two fifth sprockets (19) correspond one-to-one and are connected by the two third chains (18). The connecting parts (4) are fixedly installed with second connecting parts (20) on the side walls near both ends of the drive shaft (15). The two second connecting parts (20) are hinged one-to-one on the two third chains (18). The hinge points of the two second connecting parts (20) and the two third chains (18) are located on the first plane.
5. A wafer storage stage according to claim 4, characterized in that, The axis of the drive shaft (10) and the axis of the transmission shaft (15) are both located in the second plane, which is parallel to the first plane. The axes of the two third sprockets (14) and the axes of the two fifth sprockets (19) are both located in the third plane, which is parallel to the first plane.