A glass storage device for glass production
By using an automated system driven by a motor and lifting and stacking components, the problems of low efficiency and easy damage during manual operation of glass stacking have been solved, enabling precise and safe stacking of glass sheets and improving production efficiency and safety.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DELI GLASS (CHONGQING) CO LTD
- Filing Date
- 2025-06-30
- Publication Date
- 2026-06-12
AI Technical Summary
In existing technologies, manual operation during glass stacking is inefficient and prone to damage, resulting in high labor intensity and poor consistency.
The automated system, driven by a motor, achieves precise transport and automated stacking of glass plates through the coordinated operation of a conveyor and a lifting and stacking assembly. The lifting and lowering of the lifting plate is controlled by a double-layer wheel and gear system, and the design of shock absorbers and casters ensures smooth transport and accurate stacking of the glass plates.
It enables efficient and safe automated stacking of glass panels, reducing errors from manual operation and the risk of glass breakage, and improving production efficiency and safety.
Smart Images

Figure CN224349912U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of glass storage technology, and in particular to a glass storage device for glass manufacturing. Background Technology
[0002] Glass production involves the entire process from high-temperature melting and shaping of raw materials such as quartz sand, soda ash, and limestone to cooling. It is widely used in construction, automobiles, electronics, and home furnishings. Modern glass manufacturing technologies include float glass, rolled glass, and tempered glass, ensuring high light transmittance, strength, and durability. At the same time, the storage and management of glass products are equally important, involving safe storage, classification, and damage prevention to avoid breakage and contamination. Reasonable storage methods, such as dedicated glass racks, cushioning materials, and intelligent storage systems, not only improve storage and retrieval efficiency but also ensure product quality, keeping glass products intact during transportation, storage, and use.
[0003] In the glass stacking process, manual operation is typically used for precise alignment, ensuring that the glass edges are aligned and reducing the risk of collision damage, especially for large or high-end glass products. However, manual stacking suffers from low efficiency, high labor intensity, and poor consistency, affecting production efficiency and safety. Utility Model Content
[0004] The purpose of this invention is to address the shortcomings of existing technologies, such as low efficiency and susceptibility to damage during manual glass stacking.
[0005] To achieve the above objectives, the present invention adopts the following technical solution: a glass storage device for glass manufacturing, comprising a support frame, and further comprising: a conveyor fixed on the support frame for guiding and conveying glass plates; a lifting and stacking assembly slidably mounted on one side of the support frame; and a drive assembly fixed on one side of the support frame, the drive assembly simultaneously driving the conveyor and controlling the lifting and stacking assembly to descend synchronously; wherein, the drive assembly includes a motor fixed on one side of the support frame, and a double-layered rotating wheel fixed to the output end of the motor respectively driving a first rotating wheel and a second rotating wheel, the first rotating wheel and the second rotating wheel being used to drive the conveyor to move and the lifting and stacking assembly to descend, performing automated stacking actions.
[0006] In at least some embodiments, the first roller is fixed to one end of the drive roller of the conveyor, and the drive roller is controlled to rotate when the motor drives it.
[0007] In at least some embodiments, the lifting and stacking assembly includes a support plate fixed inside the support frame, and a lifting plate is slidably mounted inside a guide frame fixed on the support plate.
[0008] In at least some embodiments, a contact plate is fixedly installed on the upper part of the lifting plate by a shock absorber, and a transverse groove is provided on the upper part of the contact plate for cooperating with a forklift.
[0009] In at least some embodiments, the lifting plate is slidably connected to the outside of a slide rod fixed inside the guide frame. A limit plate is fixedly installed on the side of the lifting plate away from the conveyor. One end of a rotating rod rotatably installed inside the support plate is fixedly connected to the second rotating wheel. A first bevel gear fixed to the other end of the rotating rod meshes with a second bevel gear. The lower part of a lead screw rotatably installed inside the guide frame is fixedly connected to the second bevel gear, and the outside of the lead screw is screwed to the lifting plate. When the motor controls the conveyor to transport glass plates, the lifting plate receives the glass and is synchronously controlled by the motor to descend and perform an automated stacking action.
[0010] In at least some embodiments, casters are fixedly installed at the four corners of the lower part of the support frame, and lifting feet are screwed to the four corners of the lower part of the support frame.
[0011] Compared with the prior art, the advantages and positive effects of this utility model are as follows:
[0012] This invention employs a motor-driven automated system. The conveyor is responsible for precisely transporting the glass plates, ensuring their smooth arrival at the stacking area. The lifting and stacking assembly is controlled by a motor and double-layered wheels, automatically completing the stacking of the glass plates. Shock-absorbing components are designed at the contact points between the lifting plate and the glass plates to reduce impact and ensure stability and safety during the stacking process. The gear and screw system precisely controls the lifting process of the lifting plate, enabling each layer of glass plates to be accurately stacked. The casters and lifting feet at the bottom of the support frame ensure the flexible movement and stability of the device, adapting to the working requirements of different environments, ultimately achieving efficient and precise automated stacking. Attached Figure Description
[0013] Figure 1 This utility model provides a three-dimensional structural schematic diagram of a glass storage device for glass manufacturing.
[0014] Figure 2 This utility model provides a three-dimensional structural diagram of a lifting and stacking component in a glass storage device for glass manufacturing.
[0015] Figure 3 This utility model provides a three-dimensional structural diagram of the contact plate in a glass storage device for glass manufacturing.
[0016] Figure 4 This utility model presents a three-dimensional structural diagram of the second rotating wheel in a glass storage device for glass production.
[0017] Legend: 1. Support frame; 2. Transmission machine; 3. Drive assembly; 301. Motor; 302. Double-layer wheel; 303. First wheel; 304. Second wheel; 305. Rotating rod; 306. First bevel gear; 307. Second bevel gear; 308. Lead screw; 4. Lifting and stacking assembly; 401. Support plate; 402. Guide frame; 403. Slide rod; 404. Lifting plate; 405. Limiting plate; 406. Contact plate; 5. Casters; 6. Lifting feet; 7. Shock absorber. Detailed Implementation
[0018] To better understand the above-mentioned objectives, features, and advantages of this utility model, the present utility model will be further described below with reference to the accompanying drawings and embodiments. It should be noted that, unless otherwise specified, the embodiments and features described in these embodiments can be combined with each other.
[0019] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Therefore, the present invention is not limited to the specific embodiments disclosed in the following specification.
[0020] Implementation examples, based on Figures 1-4 ,like Figure 1 and Figure 2 As shown in the figure, this utility model provides a glass storage device for glass manufacturing, including a support frame 1. First, the support frame 1 serves as the foundation of the entire device, supporting and fixing various key components. Specifically, it also includes: a conveyor 2 fixed on the support frame 1 for guiding and conveying glass plates, specifically guiding and conveying the glass plates from the production line to the stacking area; a lifting and stacking assembly 4 slidably mounted on one side of the support frame 1; and a drive assembly 3 fixed on one side of the support frame 1, which simultaneously drives the conveyor 2. Under the control of the drive assembly 3, the conveyor 2 can accurately convey the glass plates to the designated position. At the same time, the conveyor 2 adjusts its speed and position as needed to ensure the smooth transmission of the glass plates and avoid damage to the glass due to imbalance. It also controls the lifting and stacking assembly 4 to descend synchronously. During the transmission process, the lifting and stacking assembly 4 will work together.
[0021] The drive assembly 3 includes a motor 301 fixed to one side of the support frame 1. A double-layered rotating wheel 302 fixed to the output end of the motor 301 drives a first rotating wheel 303 and a second rotating wheel 304. The first rotating wheel 303 and the second rotating wheel 304 are used to drive the conveyor 2 to move and the lifting and lowering part of the stacking assembly 4 to perform automated stacking. The motor 301 drives the first rotating wheel 303 and the second rotating wheel 304 through the double-layered rotating wheel 302 at its output end. The function is to drive the movement of the conveyor 2 and the lifting and lowering of the stacking assembly. When the glass plate is conveyed to the designated stacking position, the second rotating wheel 304 controls the stacking assembly to descend synchronously, so that the glass plate can be accurately stacked in the predetermined position.
[0022] During the stacking process, the motor 301 and the roller system of the drive component 3 ensure the smooth stacking of each layer of glass, avoiding errors and potential damage caused by manual operation. By precisely controlling the descent speed of the lifting component, the stability and safety of the glass stacking are ensured. At the same time, the double-layer roller design makes the transmission and stacking process smoother and avoids collisions between glass plates during stacking. Through this intelligent stacking method, the device can achieve efficient and automated glass stacking, effectively reducing errors caused by manual operation and minimizing glass breakage, thereby improving production efficiency and safety.
[0023] like Figure 1 and Figure 2 As shown, the first rotating wheel 303 is fixed to one end of the drive roller of the conveyor 2. When the motor 301 drives, it controls the drive roller to rotate. When the motor 301 drives, it controls the drive roller of the conveyor 2 to rotate, thus pushing the glass plate to be smoothly conveyed in the device.
[0024] Next, the lifting and stacking assembly 4 operates inside the support frame 1. The lifting and stacking assembly 4 includes a support plate 401 fixed inside the support frame 1, and a lifting plate 404 slidably installed inside the guide frame 402 fixed on the support plate 401. A contact plate 406 is fixedly installed on the upper part of the lifting plate 404 through a shock absorber 7 to reduce the vibration and impact of the glass plates during the stacking process and ensure the safe stacking of the glass. The upper part of the contact plate 406 has a transverse groove for cooperation with a forklift to facilitate the subsequent handling of the stacked glass. Thus, the glass plates can smoothly transition during the conveying and stacking process, avoiding breakage or damage. At the same time, the cooperative design of the shock absorber 7 and the groove improves the stability and ease of operation of the entire system.
[0025] In this embodiment, as Figure 2 , Figure 3 and Figure 4 As shown, the synchronous control mechanism driven by motor 301 ensures the smooth transport and automated stacking of glass plates.
[0026] First, the motor 301 drives the conveyor 2 to operate. By controlling the rotation of the drive roller of the conveyor 2, the glass plate is sent to the stacking area. The slide rod 403 fixed inside the guide frame 402 is slidably connected to the lifting plate 404. A limit plate 405 is fixedly installed on the side of the lifting plate 404 away from the conveyor 2. When the glass plate reaches the predetermined position, the connection between the slide rod 403 fixed inside the guide frame 402 and the lifting plate 404 begins to function. The slide rod 403 is slidably connected to the lifting plate 404 to ensure that the lifting plate 404 can move up and down smoothly. The limit plate 405 is fixedly installed on the side of the lifting plate 404 away from the conveyor 2 to ensure that the lifting plate 404 will not move beyond the predetermined range during the stacking process, thereby ensuring the accurate stacking position of each layer of glass plate.
[0027] One end of a rotating rod 305, rotatably mounted inside the support plate 401, is fixedly connected to a second rotating wheel 304, which is driven by a motor 301. A first bevel gear 306 and a second bevel gear 307, fixedly mounted on the other end of the rotating rod 305, mesh with each other. The lower part of a lead screw 308, rotatably mounted inside the guide frame 402, is fixedly connected to the second bevel gear 307. This gear system transmits rotational power to the lifting plate 404 via the lead screw 308, and the lead screw 308 is screwed to the outside of the lifting plate 404, ensuring precise lifting of the lifting plate 404. When the motor 301 controls the conveyor 2 to transport glass plates, the lifting plate 404 receives the glass and is synchronously controlled by the motor 301 to descend and perform automated stacking. This achieves efficient automated stacking. Under the control of the motor 301, the descent of the lifting plate 404 and the operation of the conveyor 2 are coordinated to ensure the stable stacking of the glass plates, reduce the risk of manual operation, and improve stacking efficiency. The cooperation of the gears and lead screw 308 ensures the stability and accuracy of the system, enabling the glass plates to complete the stacking process in a short time, meeting the needs of large-scale production.
[0028] In this embodiment, as Figure 1 As shown, casters 5 are fixedly installed at the four corners of the lower part of the support frame 1, which realizes the mobility of the device and facilitates flexible adjustment of its position during production. Lifting feet 6 are screwed to the four corners of the lower part of the support frame 1 to adjust the height of the support frame 1, ensuring that the device works stably in different environments and avoiding tilting or instability of the equipment due to uneven ground, thus ensuring the safety and accuracy of the glass stacking process.
[0029] The working principle of this utility model is as follows: The transmission machine 2 and the lifting and stacking assembly 4 are driven by motor 301 to work together, achieving automated and precise glass stacking. First, the support frame 1 serves as the foundation, supporting and fixing all key components. The transmission machine 2 guides and conveys the glass plates to the stacking area. Motor 301 drives the drive rollers of the transmission machine 2 to rotate, ensuring the glass plates are smoothly conveyed to the designated position. The lifting and stacking assembly 4 is driven by motor 301 and double-layer rotating wheels 302, precisely controlling the up-and-down movement of the lifting plate 404. The contact surface between the lifting plate 404 and the glass plate is designed with shock absorbers 7 to reduce vibration and ensure... To ensure glass safety during the stacking process, the motor 301 control system ensures that the conveyor 2 and the lifting plate 404 work synchronously, automatically adjusting the position of the glass plates to reduce human error. Through the cooperation of the lead screw 308 and the gear system, the rotational power is precisely transmitted to the lifting plate 404, ensuring the stability and accuracy of its lifting process. In addition, the universal wheels 5 at the four corners of the lower part of the support frame 1 improve the mobility of the device, while the lifting feet 6 adjust the height of the support frame 1 to ensure stable operation of the device in different environments. The entire system reduces the risk of manual operation and improves stacking efficiency and production safety.
[0030] The above are merely preferred embodiments of this utility model and are not intended to limit the utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of this utility model without departing from the technical solution of this utility model shall still fall within the protection scope of this utility model.
Claims
1. A glass storage device for glass manufacturing, comprising a support frame (1), characterized in that, Also includes: A conveyor (2) is fixed on the support frame (1) for guiding and conveying the glass plate; A lifting stacking assembly (4) is slidably mounted on one side of the support frame (1); A drive assembly (3) is fixed on one side of the support frame (1). The drive assembly (3) simultaneously drives the transmission machine (2) to work and controls the lifting and stacking assembly (4) to descend synchronously. The drive assembly (3) includes a motor (301) fixed on one side of the support frame (1), and a double-layer wheel (302) fixed at the output end of the motor (301) respectively drives a first wheel (303) and a second wheel (304). The first wheel (303) and the second wheel (304) are used to drive the conveyor (2) to work and the lifting part of the lifting stacking assembly (4) to descend, respectively, to perform automated stacking operations.
2. The glass storage device for glass manufacturing according to claim 1, characterized in that: The first rotating wheel (303) is fixed to one end of the drive roller of the conveyor (2). When the motor (301) is driven, it controls the rotation of the drive roller.
3. The glass storage device for glass manufacturing according to claim 1, characterized in that: The lifting and stacking assembly (4) includes a support plate (401) fixed inside the support frame (1), and a lifting plate (404) is slidably installed inside the guide frame (402) fixed on the support plate (401).
4. The glass storage device for glass manufacturing according to claim 3, characterized in that: A contact plate (406) is fixedly installed on the upper part of the lifting plate (404) by a shock absorber (7). The upper part of the contact plate (406) has a transverse groove for cooperating with a forklift.
5. A glass storage device for glass manufacturing according to claim 3, characterized in that: The sliding rod (403) fixed inside the guide frame (402) is slidably connected to the lifting plate (404) on the outside. A limit plate (405) is fixedly installed on the side of the lifting plate (404) away from the conveyor (2). One end of the rotating rod (305) rotatably mounted inside the support plate (401) is fixedly connected to the second rotating wheel (304). The first bevel gear (306) fixed at the other end of the rotating rod (305) meshes with the second bevel gear (307). The lower part of the lead screw (308) rotatably installed inside the guide frame (402) is fixedly connected to the second bevel gear (307), and the outside of the lead screw (308) is screwed to the lifting plate (404). When the motor (301) controls the conveyor (2) to transport the glass plate, the lifting plate (404) receives the glass and is synchronously controlled by the motor (301) to descend and perform an automated stacking action.
6. A glass storage device for glass manufacturing according to claim 1, characterized in that: The support frame (1) is fixedly installed with casters (5) at the four corners of the lower part. The support frame (1) has lifting feet (6) screwed to the four corners at the bottom.