A high-pressure autoclave for glass with an inlet / outlet rack structure

By designing the feeding and discharging rack structure and stirring device, the problems of material spillage, blockage, and uneven mixing in traditional glass autoclaves have been solved, achieving efficient feeding and uniform mixing, and improving processing quality and cleanliness.

CN224442920UActive Publication Date: 2026-07-03DANDONG HUAWEI MACHINERY MANUFACTURING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DANDONG HUAWEI MACHINERY MANUFACTURING CO LTD
Filing Date
2025-07-31
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Traditional high-pressure autoclaves for glass manufacturing suffer from problems such as material spillage or blockage, low feeding efficiency, uneven material mixing, and material adhesion to the inner wall of the autoclave during the feeding and discharging process.

Method used

An infeed and discharge rack structure was designed, including infeed auxiliary components and discharge auxiliary components. Combined with a stirring shaft and an L-shaped scraper, it can achieve stable material introduction, uniform mixing and cleaning of the vessel.

Benefits of technology

It improves feeding efficiency, ensures uniform mixing of materials, avoids adhesion to the inner wall of the reactor, simplifies cleaning and maintenance, and improves the quality of glass processing.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the field of high-pressure reactor technology and discloses a glass high-pressure reactor with an inlet / outlet rack structure. The reactor includes a reactor body arranged longitudinally. An inlet pipe is connected to the outer wall of the upper end of the reactor body. A valve is installed inside the inlet pipe. An inlet auxiliary component is located on the upper left side of the inlet pipe. An outlet pipe is connected to the bottom surface of the reactor body. A valve is installed inside the outlet pipe. An outlet auxiliary component is located below the outlet pipe. A motor is installed on the top surface of the reactor body. The output end of the motor movably passes through the top surface of the reactor body and extends into the interior of the reactor body. A stirring shaft is fixedly installed on the output end of the motor. This glass high-pressure reactor with an inlet / outlet rack structure achieves stable material introduction and precise guidance through the combination of a feeding plate, a guide plate, and a partition, preventing material from falling and improving feeding efficiency and accuracy. The discharge plate receives the material discharged from the outlet pipe, facilitating centralized collection and transportation, making the discharge process more convenient.
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Description

Technical Field

[0001] This utility model relates to the field of high-pressure reactor technology, specifically a high-pressure reactor for glass with an inlet / outlet rack structure. Background Technology

[0002] In the glass processing industry, traditional high-pressure autoclaves for glass have obvious technical defects in practical applications: First, the lack of dedicated auxiliary structures in the feeding and discharging process makes it easy for materials to spill or become blocked during transportation, resulting in low feeding efficiency and the need for frequent manual intervention; Second, the design of the stirring device inside the autoclave is unreasonable, resulting in insufficient uniformity of material mixing, and the inner wall of the autoclave is prone to material adhesion, which not only affects the quality of glass processing, but also increases the difficulty of cleaning and maintenance.

[0003] To address this issue, we propose a high-pressure autoclave for glass with an infeed / outfeed rack structure. Utility Model Content

[0004] The purpose of this invention is to provide a high-pressure autoclave for glass with an inlet / outlet rack structure, which solves the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a high-pressure vessel for glass with an inlet and outlet rack structure, comprising a vessel body arranged longitudinally, an inlet pipe connected to the outer wall of the upper end of the vessel body, a valve one installed inside the inlet pipe, an inlet auxiliary component arranged at the upper left of the inlet pipe, an outlet pipe connected to the bottom surface of the vessel body, a valve two installed inside the outlet pipe, an outlet auxiliary component arranged below the outlet pipe, a motor installed on the top surface of the vessel body, the output end of the motor movably penetrating through the top surface of the vessel body and extending into the interior of the vessel body, a stirring shaft fixedly installed on the output end of the motor, and a stirring rod and an L-shaped scraper fixedly installed on the outer wall of the stirring shaft respectively.

[0006] Preferably, a support leg is fixedly installed on the outer wall of the lower end of the vessel body. The number of the support legs is three, and the three support legs are distributed in a circular array on the outer wall of the vessel body. The installed support legs can stably support the vessel body.

[0007] Preferably, the feeding auxiliary component includes a feeding plate, which is located at the upper left of the feeding pipe. An inclined guide plate is fixedly installed at the right end of the feeding plate, and the right end of the guide plate is located at the inlet of the feeding pipe.

[0008] Preferably, a first partition is fixedly installed in pairs on the top surface of the feeding plate, and a second partition is fixedly installed in pairs on the top surface of the guide plate. The two second partitions form a triangle. The first partitions prevent materials from falling from both sides, and the second partitions facilitate the smooth entry of materials into the feed pipe.

[0009] Preferably, an L-shaped fixing rod is fixedly installed on the bottom surface of the feeding plate, and the end of the L-shaped fixing rod away from the feeding plate is fixedly installed to the outer wall of the vessel body. The feeding plate can be stably installed by the installed L-shaped fixing rod.

[0010] Preferably, the discharge auxiliary component includes a discharge plate, which is located below the discharge pipe. Two pairs of fixing rods are fixedly installed on the top surface of the discharge plate. The end of the fixing rod away from the discharge plate is fixedly installed to the bottom surface of the vessel body. The fixing rods can securely install the discharge plate, and the installed discharge plate facilitates material discharge.

[0011] Preferably, a fixing base is fixedly installed on the top surface of the motor, and the bottom of both ends of the fixing base is fixedly installed to the top surface of the vessel body. The fixing base can stably install the motor and enable the motor to operate normally.

[0012] This invention provides a high-pressure autoclave for glass with an inlet / outlet rack structure. This high-pressure autoclave for glass with an inlet / outlet rack structure has the following advantages:

[0013] (1) The glass autoclave with inlet and outlet rack structure achieves stable material introduction and precise guidance through the combination of feeding plate, guide plate and partition, avoids falling, improves feeding efficiency and accuracy, and the discharge plate receives the material discharged from the discharge pipe, which is convenient for centralized collection and transportation, making the discharge process more convenient.

[0014] (2) The glass autoclave with inlet and outlet rack structure is driven by a motor to fully mix the materials with the stirring shaft and stirring rod. The L-shaped scraper removes the adhering material from the autoclave wall, ensuring that the material is processed evenly and the autoclave is clean. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the overall three-dimensional structure of a high-pressure autoclave for glass with an inlet / outlet rack structure according to the present invention;

[0016] Figure 2 This utility model relates to a high-pressure autoclave for glass with an inlet / outlet rack structure. Figure 1 A schematic diagram of the isometric structure;

[0017] Figure 3 This is a schematic diagram of the feeding auxiliary component in a glass autoclave with an inlet / outlet rack structure according to the present invention.

[0018] Figure 4 This is a cross-sectional view of the vessel body in a high-pressure autoclave for glass with an inlet / outlet rack structure according to the present invention.

[0019] In the diagram: 1. Kettle body; 2. Feed pipe; 3. Discharge pipe; 4. Support leg; 5. L-shaped fixing rod; 6. Feeding plate; 7. Guide plate; 8. First partition; 9. Second partition; 10. Fixing rod; 11. Discharge plate; 12. Fixing seat; 13. Motor; 14. Stirring shaft; 15. Stirring rod; 16. L-shaped scraper. Detailed Implementation

[0020] To provide a clearer understanding of the technical features, objectives, and effects of this utility model, the specific embodiments of this utility model are now described with reference to the accompanying drawings.

[0021] like Figure 1-4 As shown, this utility model provides a technical solution: a high-pressure autoclave for glass with an inlet / outlet rack structure, including an autoclave body 1, arranged longitudinally. Three support legs 4 are fixedly installed on the outer wall of the lower end of the autoclave body 1, arranged in a circular array on the outer wall of the autoclave body 1. The installed support legs 4 provide stable support for the autoclave body 1. A feed pipe 2 is connected to the outer wall of the upper end of the autoclave body 1. A valve (not shown in the figure) is installed inside the feed pipe 2. A feed auxiliary component is located on the upper left side of the feed pipe 2. The auxiliary component includes a feeding plate 6, which is positioned at the upper left of the feed pipe 2. An inclined guide plate 7 is fixedly installed at the right end of the feeding plate 6, with the right end of the guide plate 7 located at the inlet of the feed pipe 2. A first partition 8 is fixedly installed in pairs on the top surface of the feeding plate 6, and a second partition 9 is fixedly installed in pairs on the top surface of the guide plate 7. The two second partitions 9 form a triangle. The first partitions 8 prevent material from falling from both sides, while the second partitions 9 facilitate the smooth entry of material into the feed pipe 2. An L-shaped guide plate is fixedly installed on the bottom surface of the feeding plate 6. L-shaped fixing rod 5, with one end of the fixing rod 5 away from the feeding plate 6, is fixedly installed to the outer wall of the vessel body 1. The feeding plate 6 can be stably installed by the installed L-shaped fixing rod 5. The bottom surface of the vessel body 1 is connected to the discharge pipe 3, and a valve 2 (not shown in the figure) is installed inside the discharge pipe 3. The discharge auxiliary assembly is set below the discharge pipe 3, including a discharge plate 11. The discharge plate 11 is set below the discharge pipe 3, and two pairs of fixing rods 10 are fixedly installed on the top surface of the discharge plate 11. The fixing rods 10 are away from the discharge plate 1. One end of the motor 1 is fixedly installed to the bottom surface of the vessel body 1. The top surface of the vessel body 1 is equipped with a motor 13. A fixed base 12 is fixedly installed on the top surface of the motor 13. The bottom ends of both ends of the fixed base 12 are fixedly installed to the top surface of the vessel body 1. The fixed base 12 can securely install the motor 13, allowing the motor 13 to operate normally. The output end of the motor 13 moves through the top surface of the vessel body 1 and extends into the interior of the vessel body 1. A stirring shaft 14 is fixedly installed on the output end of the motor 13. A stirring rod 15 and an L-shaped scraper 16 are fixedly installed on the outer wall of the stirring shaft 14.

[0022] Working principle:

[0023] Feeding process

[0024] Material introduction: The material is placed on the feeding plate 6 of the feeding auxiliary component. The first partition 8 on the top surface of the feeding plate 6 can prevent the material from falling from both sides and ensure that the material is concentrated.

[0025] Guided feeding: The inclined guide plate 7 at the right end of the feed plate 6 guides the material to the inlet of the feed pipe 2. The second partition 9 on the top surface of the guide plate 7 has a triangular structure, which further regulates the flow of the material and allows it to enter the feed pipe 2 smoothly.

[0026] Feed control: The valve inside the feed pipe 2 can control the opening and closing of the feed to ensure that the material enters the reactor body 1 as required.

[0027] In-vessel processing

[0028] Stirring and mixing: The motor 13 on the top surface of the vessel body 1 is securely installed through the fixed base 12. Its output end drives the stirring shaft 14 to rotate. The stirring rod 15 on the outer wall of the stirring shaft 14 thoroughly stirs the materials in the vessel to achieve uniform mixing.

[0029] Anti-sticking scraping: The L-shaped scraper 16 on the stirring shaft 14 rotates with the stirring shaft 14, which can scrape off the material adhering to the inner wall of the vessel body 1, avoid material residue, and ensure the treatment effect and cleanliness of the vessel body.

[0030] Stable support: The three support legs 4 at the lower end of the vessel body 1 are arranged in a ring array to provide stable support for the vessel body 1 and ensure that the equipment remains balanced during operation.

[0031] Discharge process

[0032] Discharge control: Valve 2 inside the discharge pipe 3 at the bottom of the vessel 1 controls the start and stop of discharge. When discharge is required, valve 2 is opened.

[0033] Material discharge: The material falls through the discharge pipe 3 to the discharge plate 11 below. The discharge plate 11 is fixed to the bottom surface of the vessel body 1 by the fixing rod 10, which can receive and guide the material, making it convenient for subsequent collection or transportation.

[0034] The above are merely illustrative embodiments of this utility model and are not intended to limit the scope of this utility model. Any equivalent changes and modifications made by those skilled in the art without departing from the concept and principles of this utility model should fall within the protection scope of this utility model. Furthermore, it should be noted that the components of this utility model are not limited to the overall application described above. Each technical feature described in the specification can be used individually or in combination as needed. Therefore, this utility model naturally covers other combinations and specific applications related to the points of this utility model.

Claims

1. A high pressure vessel for glass with an in-out material rack structure, comprising a vessel body (1) arranged longitudinally, characterized in that: The upper end of the vessel body (1) is connected to the outer wall of the feed pipe (2), and the feed pipe (2) is equipped with a valve. The upper left of the feed pipe (2) is equipped with a feed auxiliary component. The bottom surface of the vessel body (1) is connected to the discharge pipe (3), and the discharge pipe (3) is equipped with a valve. The discharge pipe (3) is equipped with a discharge auxiliary component below the discharge pipe (3). The top surface of the vessel body (1) is equipped with a motor (13). The output end of the motor (13) moves through the top surface of the vessel body (1) and extends into the interior of the vessel body (1). The output end of the motor (13) is fixedly installed with a stirring shaft (14). The outer wall of the stirring shaft (14) is fixedly installed with a stirring rod (15) and an L-shaped scraper (16). The feeding auxiliary component includes a feeding plate (6), which is located at the upper left of the feeding pipe (2). An inclined guide plate (7) is fixedly installed at the right end of the feeding plate (6), and the right end of the guide plate (7) is located at the opening of the feeding pipe (2). The discharge auxiliary component includes a discharge plate (11), which is located below the discharge pipe (3). Two pairs of fixing rods (10) are fixedly installed on the top surface of the discharge plate (11). The end of the fixing rod (10) away from the discharge plate (11) is fixedly installed on the bottom surface of the vessel body (1).

2. The high pressure vessel with access shelf structure for glass according to claim 1, characterized in that: The lower end of the vessel body (1) is fixedly equipped with support legs (4), and there are three support legs (4). The three support legs (4) are arranged in a ring array on the outer wall of the vessel body (1).

3. The high pressure vessel with access shelf structure for glass according to claim 1, characterized in that: The top surface of the feeding plate (6) is fixedly equipped with a pair of first partitions (8), and the top surface of the guide plate (7) is fixedly equipped with a pair of second partitions (9), forming a triangle between the two second partitions (9).

4. The high-pressure autoclave for glass with an inlet / outlet rack structure according to claim 1, characterized in that: An L-shaped fixing rod (5) is fixedly installed on the bottom surface of the feeding plate (6), and the end of the L-shaped fixing rod (5) away from the feeding plate (6) is fixedly installed on the outer wall of the vessel body (1).

5. A high-pressure autoclave for glass with an inlet / outlet rack structure according to claim 1, characterized in that: The top surface of the motor (13) is fixedly mounted with a mounting base (12), and the bottom of both ends of the mounting base (12) is fixedly mounted with the top surface of the vessel body (1).