A dipping glazing device for ceramic processing

By designing a motor-driven placement rack and stirring system, combined with a heating ring and drying components, the problems of uneven glaze layer and operational hazards in the traditional manual glazing method have been solved, thus improving the uniformity and safety of the glaze layer.

CN121374813BActive Publication Date: 2026-06-30YANCHENG INST OF IND TECH

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
YANCHENG INST OF IND TECH
Filing Date
2025-12-10
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Traditional manual glazing methods are difficult to guarantee consistent glaze thickness, and are prone to defects such as glaze runs, uneven thickness, or fingerprints. In addition, the operating environment is harmful to health, and existing equipment relies on the experience of craftsmen, resulting in large fluctuations in the yield rate.

Method used

A ceramic glazing device with immersion glazing was designed. It adopts a motor-driven placement rack and stirring system, combined with a heating ring and drying components to achieve uniform stirring and pneumatic drying of the glaze liquid. The rotation of the placement rack and centrifugal force are used to evenly distribute the glaze liquid, ensuring the uniformity of the glaze layer, and the heating ring is used to accelerate drying.

Benefits of technology

It improves the uniformity of the glaze and the yield rate, reduces the impact of human factors, and enhances operational safety and production efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention relates to the field of glazing equipment technology, and specifically discloses an immersion-type glazing device for ceramic processing, comprising an insulated outer tube, a heating ring fixedly connected to the inner wall side of the insulated outer tube, a glazing device rotatably connected to the bottom of the inner wall of the insulated outer tube, a connecting rod fixedly connected to the top of the glazing device, a drive assembly fixedly connected to the drive shaft of a motor, a placement frame fixedly connected to the top of the drive assembly via a rotating shaft, a horizontal fixing assembly fixedly connected to the inner wall side of the placement frame, a vertical fixing assembly fixedly connected to the bottom of the inner wall of the glazing tank, a motor fixedly connected to the inner wall of the insulated outer tube via a bracket, and a top of the placement frame fixedly connected to the bottom of the connecting rod. Glazing liquid is directly introduced into the interior of the glazing tank. This immersion-type glazing device for ceramic processing achieves the purpose of facilitating automated glazing.
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Description

Technical Field

[0001] This invention relates to the field of glazing equipment technology, specifically to an immersion glazing device for ceramic processing. Background Technology

[0002] Dipping is an ancient and fundamental glazing method. Its core principle involves immersing the shaped and dried ceramic body into a glaze slurry. Utilizing the body's absorbency or direct adhesion, the glaze slurry adheres evenly to the surface. The body is then removed, excess glaze is removed, and after drying, it is fired in a kiln. This method is particularly suitable for simple, regular-shaped bodies (such as bowls, plates, cups, and bottles). While simple to operate, manual lifting can cause glaze runners, uneven thickness, or fingerprints due to the shaking of the body. Furthermore, prolonged direct contact with the glaze slurry (which may contain heavy metals and other chemicals) and the humid working environment can lead to occupational health problems. The uncontrollable nature of human factors directly results in significant fluctuations in product yield. To overcome the drawbacks of manual dipping, various semi-automatic or automatic dipping devices have emerged on the market. A typical existing glazing apparatus usually includes the following core components: a container for holding and storing glaze slurry; a stirring system (such as a stirring paddle driven by a low-speed motor) to maintain the uniformity of the glaze slurry composition and prevent sedimentation through continuous or intermittent stirring; a robotic arm, clamp, or custom tray to firmly hold the blank; a motor, cylinder, or hydraulic cylinder as the power source and for horizontal movement; and a programmable logic controller (PLC) or simple relay circuit to preset and control the glazing process parameters, such as immersion depth, immersion time, and lifting speed.

[0003] Traditional methods rely entirely on the craftsman's touch and experience, making it difficult to guarantee that the glaze thickness is absolutely consistent for every product. When the piece is lifted manually, the shaking of the body can easily cause defects such as glaze runs, uneven thickness, or fingerprints on the glaze surface. Summary of the Invention

[0004] To solve the above technical problems, the present invention is achieved through the following technical solution: a ceramic processing glazing device, comprising an insulating outer tube, a heating ring fixedly connected to the inner wall side of the insulating outer tube, a glazing device rotatably connected to the bottom of the inner wall of the insulating outer tube, a connecting rod fixedly connected to the top of the glazing device, a drying component fixedly connected to the top of the connecting rod, and an equipment base fixedly connected to the bottom of the insulating outer tube via a bracket;

[0005] The glazing device includes a glazing tank. A motor is fixedly connected to the bottom of the glazing tank. A drive assembly is fixedly connected to the drive shaft of the motor. A placement frame is fixedly connected to the top of the drive assembly via a rotating shaft. A horizontal fixing assembly is fixedly connected to the inner side of the placement frame. A vertical fixing assembly is fixedly connected to the bottom of the inner wall of the glazing tank. The motor is fixedly connected to the inner wall of the insulation outer pipe via a bracket. The top of the placement frame is fixedly connected to the bottom of the connecting rod. Glazing liquid is directly introduced into the glazing tank. The workpiece is placed directly on the top of the placement frame. After fixing, the motor is started. The motor rotates, driving the drive assembly to rotate. The rotation of the drive assembly... The movable placement rack moves to immerse the workpiece, thus glazing its sides. Driven by the drive assembly, the placement rack and the glazing tank rotate in opposite directions, stirring the glazing liquid evenly and ensuring uniform glazing on the workpiece's sides. The placement rack lifts the workpiece, removing the liquid and facilitating even glazing. A drying assembly guides air to pneumatically dry the workpiece's sides, improving glazing quality. A heating ring heats the liquid inside the glazing tank, accelerating the drying process with high-temperature pneumatic heating while maintaining glazing quality.

[0006] Preferably, the glazing tank includes an immersion tank, the top of which is connected to a guide pipe, and an agitator blade is fixedly connected to the inner wall side of the immersion tank. A guide groove is provided on the top of the agitator blade, the bottom of the immersion tank is fixedly connected to the top of the drive assembly, and the placement rack is disposed at the bottom of the inner wall of the immersion tank and rotatably connected to the immersion tank. The side of the placement rack contacts the inner wall of the agitator blade.

[0007] Preferably, the drive assembly includes a drive bracket, with a drive gear rotatably connected to the top center of the inner wall of the drive bracket. A driven gear meshes with the side of the drive gear, and a driven gear ring meshes with the end of the driven gear away from the drive gear. The bottom of the drive gear is fixedly connected to the drive shaft of the motor, and the top of the driven gear ring is fixedly connected to the bottom of the soaking tank. When the motor is started, the drive shaft of the motor rotates, driving the drive gear to rotate. The rotation of the drive gear drives the placement frame to rotate, thereby causing the workpiece to rotate and be glazed inside the soaking tank. This uniformizes the thickness and quality of the glaze. The drive gear drives the driven gear to rotate, which in turn drives the driven gear ring to rotate. The rotation of the driven gear ring drives the soaking tank to rotate, which in turn drives the agitator blades to rotate. This agitates the glazing liquid in the opposite direction of the workpiece's rotation, and the agitation also stirs the liquid, preventing sedimentation and other problems.

[0008] Preferably, the placement rack includes a holding rack, the bottom of the inner wall of the holding rack is provided with a bottom discharge hole, the side of the inner wall of the holding rack is provided with a side discharge hole, a threaded sleeve is fixedly connected to the bottom of the inner wall of the holding rack, a support plate is fixedly connected to the side of the threaded sleeve, a stud is threadedly connected to the inner wall of the threaded sleeve, a rotating column is fixedly connected to the top of the stud, a limit ring is fixedly connected to the top of the rotating column, and the bottom of the threaded sleeve penetrates the top of the soaking tank and is fixedly connected to the top of the drive gear.

[0009] Preferably, the lateral fixing assembly includes a fixed base, a fixed end of a first spring rod is fixedly connected to the side of the fixed base, a spring plate is fixedly connected to the movable end of the first spring rod, an arc-shaped guide strip is fixedly connected to the side of the spring plate, and the side of the fixed base away from the first spring rod is fixedly connected to the inner wall of the storage rack.

[0010] Preferably, the vertical fixing assembly includes a slide rail, a slider slidably connected to the bottom inner wall of the slide rail, a braking groove formed at the top of the slider, a conical tip fixedly connected to the bottom of the slider, a second spring rod fixedly connected to one end of the top of the slide rail, the fixed end of the second spring rod fixedly connected to the top of the support plate, and the conical tip positioned above the arc-shaped guide strip. The rotation of the drive gear drives the stud to rotate, and the rotation of the stud drives the threaded sleeve to move up and down along the side of the stud. The movement of the stud drives the holding rack to move. When the threaded sleeve moves the holding rack to the side of the rotating column, the threaded sleeve disengages from the side of the stud, allowing continuous rotation on the side of the rotating column. This facilitates the even distribution of the glazing liquid through centrifugal force, thereby completing the glazing of the workpiece. The workpiece is guided by the arc-shaped guide bar into the space between the support plate and the arc-shaped guide bar, thus applying pressure to the spring plate. This pressure, in turn, applies pressure to the spring plate and the first spring rod, and the reaction force keeps the workpiece fixed between the arc-shaped guide bar and the support plate. Simultaneously, the slide rail descends under the elastic force of the second spring rod. The descent of the slide rail causes the slider to descend, which in turn causes the conical tip to descend. The bottom of the conical tip presses against the top of the workpiece, preventing glaze liquid from entering the workpiece. The shape of the conical tip guides and positions the workpiece. The brake groove, under the elastic force of the second spring rod, causes the slider to engage with the top of the inner wall of the slide rail, preventing the slider from sliding and thus facilitating the fixation of the workpiece.

[0011] Preferably, the drying assembly includes a triangular support, with an electric fan rotatably connected to the bottom of the triangular support, a protective tube fixedly connected to the side of the triangular support, and an air guide pipe fixedly connected to the bottom of the protective tube. The bottom of the electric fan is fixedly connected to the top of the connecting rod, and the air guide pipe is positioned above the arc-shaped guide strip. When the electric fan is started, its rotation drives air to flow from top to bottom. The air moves along the inner wall of the protective tube and is compressed on the inner wall of the air guide pipe, thereby driving the air to pass over the surface of the workpiece for pneumatic drying. Furthermore, the airflow direction facilitates the glazing liquid to enter the interior of the soaking tank for collection, thus facilitating reuse and preventing glazing liquid from splashing.

[0012] This invention provides an immersion glazing device for ceramic processing. It has the following beneficial effects:

[0013] 1. This ceramic processing immersion glazing device is equipped with a placement rack. Glazing liquid is directly introduced into the glazing tank. The workpiece is placed directly on top of the placement rack and fixed. After that, the motor is started. The motor rotates, driving the drive component to rotate. The drive component rotates, moving the placement rack to immerse the workpiece, thus glazing the sides of the workpiece. Driven by the drive component, the placement rack and the glazing tank rotate in opposite directions, thus stirring the glazing liquid evenly and ensuring uniform glazing on the sides of the workpiece. The placement rack lifts the workpiece, thus removing the liquid and facilitating uniform glazing. A drying component guides air to pneumatically dry the sides of the workpiece, improving the glazing quality. A heating ring heats the liquid inside the glazing tank, accelerating the drying speed of the glazing liquid with high temperature pneumatics while ensuring glazing quality.

[0014] 2. This ceramic processing immersion glazing device is equipped with a motor. The rotation of the motor's drive shaft drives the rotation of the drive gear, which in turn drives the placement frame to rotate, thereby rotating the workpiece inside the immersion tank for glazing. This uniformizes the thickness and quality of the glaze. The drive gear also drives the driven gear to rotate, which in turn drives the driven gear ring to rotate. The driven gear ring then drives the immersion tank to rotate, which in turn drives the agitator blades to rotate. This agitates the glazing liquid in the opposite direction of the workpiece's rotation, preventing sedimentation and other problems.

[0015] 3. This ceramic processing glazing device is equipped with a drive gear. The rotation of the drive gear drives the stud to rotate, and the rotation of the stud drives the screw sleeve to move up and down along the side of the stud. The movement of the stud drives the holding rack to move. When the screw sleeve drives the holding rack to the side of the rotating column, the screw sleeve disengages from the side of the stud, thus continuously rotating on the side of the rotating column. This facilitates the even distribution of the glazing liquid by centrifugal force, thereby completing the glazing of the workpiece. The workpiece is guided by the arc-shaped guide bar into the space between the support plate and the arc-shaped guide bar, thereby generating pressure on the spring plate, which facilitates the glazing of the spring plate and the first spring. The rod generates pressure, which in turn causes the workpiece to be fixed between the arc-shaped guide bar and the support plate through the reaction force. At the same time, the slide rail descends under the elastic force of the second spring rod. The descent of the slide rail causes the slider to descend, which in turn causes the conical tip to descend. The bottom of the conical tip presses against the top of the workpiece, thereby preventing the glaze liquid from entering the workpiece. The shape of the conical tip guides and positions the workpiece. Through the braking groove and the inner wall of the slide rail, the slider is driven to engage with the top of the inner wall of the slide rail under the elastic force of the second spring rod, thereby preventing the slider from sliding and facilitating the fixation of the workpiece.

[0016] 4. The ceramic processing immersion glazing device is equipped with an electric fan. The electric fan rotates and drives the air to flow from top to bottom. The air moves along the inner wall of the protective tube and is compressed on the inner wall of the air guide tube, thereby driving the air to pass over the surface of the workpiece for pneumatic drying. The air flow direction facilitates the glazing liquid to enter the interior of the immersion tank for collection, which is convenient for reuse and at the same time prevents the glazing liquid from splashing. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the immersion glazing device for ceramic processing according to the present invention.

[0018] Figure 2 This is a schematic diagram of the glazing device of the present invention;

[0019] Figure 3 This is a schematic diagram of the internal structure of the glazing device of the present invention;

[0020] Figure 4 This is a schematic diagram of the glazing tank structure of the present invention;

[0021] Figure 5 This is a schematic diagram of the drive component structure of the present invention;

[0022] Figure 6 This is a schematic diagram of the placement rack structure of the present invention;

[0023] Figure 7 This is a schematic diagram of the transverse fixing component structure of the present invention;

[0024] Figure 8This is a schematic diagram of the vertical fixing component structure of the present invention;

[0025] Figure 9 This is a schematic diagram of the drying component structure of the present invention.

[0026] In the diagram: 1. Insulation outer pipe; 2. Heating ring; 3. Glazing device; 4. Connecting rod; 5. Drying assembly; 6. Equipment base; 301. Glazing tank; 302. Motor; 303. Drive assembly; 304. Placement rack; 305. Horizontal fixing assembly; 306. Vertical fixing assembly; 3011. Immersion tank; 3012. Guide pipe; 3013. Stirring blade; 3014. Guide groove; 3031. Drive bracket; 3032. Drive gear; 3033. Driven gear; 3034. Driven gear ring; 3041. Container rack; 3042, Lower discharge hole; 3043, Side discharge hole; 3044, Screw sleeve; 3045, Support plate; 3046, Stud; 3047, Rotating column; 3048, Limiting ring; 3051, Fixed base; 3052, First spring rod; 3053, Spring plate; 3054, Arc-shaped guide strip; 3061, Slide rail; 3062, Slider; 3063, Brake groove; 3064, Conical tip; 3065, Second spring rod; 501, Triangular bracket; 502, Electric fan; 503, Protective pipe; 504, Air duct. Detailed Implementation

[0027] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0028] For the first embodiment, please refer to... Figures 1-2 The present invention provides a technical solution: a ceramic processing glazing device, including an insulating outer tube 1, a heating ring 2 fixedly connected to the inner wall side of the insulating outer tube 1, a glazing device 3 rotatably connected to the bottom of the inner wall of the insulating outer tube 1, a connecting rod 4 fixedly connected to the top of the glazing device 3, a drying component 5 fixedly connected to the top of the connecting rod 4, and an equipment base 6 fixedly connected to the bottom of the insulating outer tube 1 through a bracket.

[0029] The glazing device 3 includes a glazing tank 301, a motor 302 fixedly connected to the bottom of the glazing tank 301, a drive assembly 303 fixedly connected to the drive shaft of the motor 302, a placement rack 304 fixedly connected to the top of the drive assembly 303 via a rotating shaft, a horizontal fixing assembly 305 fixedly connected to the inner wall side of the placement rack 304, a vertical fixing assembly 306 fixedly connected to the bottom of the inner wall of the glazing tank 301, the motor 302 fixedly connected to the inner wall of the heat-insulating outer tube 1 via a bracket, and the top of the placement rack 304 fixedly connected to the bottom of the connecting rod 4.

[0030] The glazing liquid is directly introduced into the glazing tank 301. The workpiece is placed directly on top of the placement rack 304 and fixed. Then, the motor 302 is started. The rotation of the motor 302 drives the drive component 303 to rotate, which in turn moves the placement rack 304 to immerse the workpiece and glaze its sides. Driven by the drive component 303, the placement rack 304 and the glazing tank 301 rotate in opposite directions, which stirs the glazing liquid evenly and ensures uniform glazing on the sides of the workpiece. The placement rack 304 lifts the workpiece, removing the liquid and facilitating uniform glazing. The drying component 5 guides the air to pneumatically dry the sides of the workpiece, improving the glazing quality. The heating ring 2 heats the liquid inside the glazing tank 301, accelerating the drying speed of the glazing liquid while ensuring glazing quality.

[0031] Second embodiment, please refer to Figures 1-4 Based on the first embodiment, the present invention provides a technical solution: the glazing tank 301 includes an immersion tank 3011, the top of the immersion tank 3011 is connected to a guide pipe 3012, the inner wall side of the immersion tank 3011 is fixedly connected to an agitator blade 3013, the top of the agitator blade 3013 is provided with a guide groove 3014, the bottom of the immersion tank 3011 is fixedly connected to the top of the drive assembly 303, the placement rack 304 is disposed at the bottom of the inner wall of the immersion tank 3011 and is rotatably connected to the immersion tank 3011, and the side of the placement rack 304 contacts the inner wall of the agitator blade 3013.

[0032] The drive assembly 303 includes a drive bracket 3031. A drive gear 3032 is rotatably connected to the top center of the inner wall of the drive bracket 3031. A driven gear 3033 meshes with the side of the drive gear 3032. A driven gear ring 3034 meshes with the end of the driven gear 3033 away from the drive gear 3032. The bottom of the drive gear 3032 is fixedly connected to the drive shaft of the motor 302. The top of the driven gear ring 3034 is fixedly connected to the bottom of the soaking tank 3011.

[0033] The motor 302 is started, and the drive shaft of the motor 302 rotates, which drives the drive gear 3032 to rotate. The rotation of the drive gear 3032 drives the placement rack 304 to rotate, thereby rotating the workpiece inside the soaking tank 3011 for glazing. This uniformizes the thickness and quality of the glaze. The drive gear 3032 drives the driven gear 3033 to rotate, which in turn drives the driven gear ring 3034 to rotate. The rotation of the driven gear ring 3034 drives the soaking tank 3011 to rotate, which in turn drives the stirring blade 3013 to rotate. This stirs the glazing liquid in the opposite direction of the workpiece's rotation, and the stirring also prevents sedimentation and other problems.

[0034] Third embodiment, please refer to Figures 1-7 Based on the second embodiment, the present invention provides a technical solution: the placement rack 304 includes a holding rack 3041, the bottom of the inner wall of the holding rack 3041 is provided with a lower discharge hole 3042, the side of the inner wall of the holding rack 3041 is provided with a side discharge hole 3043, a screw sleeve 3044 is fixedly connected to the bottom of the inner wall of the holding rack 3041, a support plate 3045 is fixedly connected to the side of the screw sleeve 3044, a stud 3046 is threadedly connected to the inner wall of the screw sleeve 3044, a rotating column 3047 is fixedly connected to the top of the stud 3046, a limit ring 3048 is fixedly connected to the top of the rotating column 3047, and the bottom of the screw sleeve 3044 penetrates the top of the soaking tank 3011 and is fixedly connected to the top of the drive gear 3032.

[0035] The horizontal fixing assembly 305 includes a fixed base 3051, a fixed end of a first spring rod 3052 is fixedly connected to the side of the fixed base 3051, a spring plate 3053 is fixedly connected to the movable end of the first spring rod 3052, an arc-shaped guide strip 3054 is fixedly connected to the side of the spring plate 3053, and the side of the fixed base 3051 away from the first spring rod 3052 is fixedly connected to the inner wall of the holding rack 3041.

[0036] The vertical fixing component 306 includes a slide rail 3061, a slider 3062 slidably connected to the bottom inner wall of the slide rail 3061, a braking groove 3063 opened at the top of the slider 3062, a conical tip 3064 fixedly connected to the bottom of the slider 3062, a second spring rod 3065 fixedly connected to one end of the top of the slide rail 3061, the fixed end of the second spring rod 3065 fixedly connected to the top of the support plate 3045, and the conical tip 3064 is positioned above the arc-shaped guide strip 3054.

[0037] The rotation of the drive gear 3032 drives the stud 3046 to rotate. The rotation of the stud 3046 drives the threaded sleeve 3044 to move up and down along the side of the stud 3046. The movement of the stud 3046 drives the holding rack 3041 to move. When the threaded sleeve 3044 drives the holding rack 3041 to the side of the rotating column 3047, the threaded sleeve 3044 disengages from the side of the stud 3046, thus continuously rotating on the side of the rotating column 3047. This facilitates the even distribution of the glazing liquid by centrifugal force, thereby completing the glazing of the workpiece. The workpiece is guided by the arc-shaped guide bar 3054 and enters between the support plate 3045 and the arc-shaped guide bar 3054, thereby generating pressure on the spring plate 3053, which in turn generates pressure on the spring plate 3053 and the first spring rod 3052. The reaction force keeps the workpiece fixed between the arc-shaped guide bar 3054 and the support plate 3045. At the same time, the slide rail 3061 descends under the elastic force of the second spring rod 3065. The descent of the slide rail 3061 causes the slider 3062 to descend, which in turn causes the conical tip 3064 to descend. The bottom of the conical tip 3064 presses against the top of the workpiece, thus preventing the glaze liquid from entering the workpiece. The shape of the conical tip 3064 guides and positions the workpiece. The brake groove 3063, under the elastic force of the second spring rod 3065, causes the slider 3062 to engage with the top of the inner wall of the slide rail 3061, thus preventing the slider 3062 from sliding and facilitating the fixation of the workpiece.

[0038] For the fourth embodiment, please refer to [link / reference]. Figures 1-9 Based on the third embodiment, the present invention provides a technical solution: the drying component 5 includes a triangular bracket 501, an electric fan 502 is rotatably connected to the bottom of the triangular bracket 501, a protective tube 503 is fixedly connected to the side of the triangular bracket 501, an air guide tube 504 is fixedly connected to the bottom of the protective tube 503, the bottom of the electric fan 502 is fixedly connected to the top of the connecting rod 4, and the air guide tube 504 is positioned above the arc-shaped guide strip 3054.

[0039] Start the electric fan 502. The electric fan 502 rotates and drives the air to flow from top to bottom. The air moves along the inner wall of the protective tube 503 and is compressed on the inner wall of the air guide tube 504, thereby driving the air to pass over the surface of the workpiece for pneumatic drying. The air flow direction facilitates the glazing liquid to enter the immersion tank 3011 for collection, so as to facilitate reuse and prevent the glazing liquid from splashing.

[0040] Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all of them. All other embodiments obtained by those skilled in the art and related fields based on the embodiments of the present invention without inventive effort should fall within the scope of protection of the present invention. Structures, devices, and operating methods not specifically described and explained in the present invention, unless otherwise specified or limited, shall be implemented according to conventional means in the art.

Claims

1. A glazing apparatus for ceramic processing by dip glazing, characterized by: The device includes an insulated outer tube, a heating ring fixedly connected to the inner wall side of the insulated outer tube, a glazing device rotatably connected to the bottom of the inner wall of the insulated outer tube, a connecting rod fixedly connected to the top of the glazing device, a drying component fixedly connected to the top of the connecting rod, and an equipment base fixedly connected to the bottom of the insulated outer tube via a bracket. The glazing device includes a glazing tank, a motor is fixedly connected to the bottom of the glazing tank, a drive assembly is fixedly connected to the drive shaft of the motor, a placement frame is fixedly connected to the top of the drive assembly via a rotating shaft, a horizontal fixing assembly is fixedly connected to the inner side of the placement frame, a vertical fixing assembly is fixedly connected to the bottom of the inner wall of the glazing tank, the motor is fixedly connected to the inner wall of the heat-insulating outer tube via a bracket, and the top of the placement frame is fixedly connected to the bottom of the connecting rod. The glazing tank includes an immersion tank, the top of which is connected to a guide pipe, and an agitator blade is fixedly connected to the inner wall side of the immersion tank. A guide groove is provided on the top of the agitator blade, the bottom of the immersion tank is fixedly connected to the top of the drive assembly, and the placement rack is set at the bottom of the inner wall of the immersion tank and rotatably connected to the immersion tank. The side of the placement rack is in contact with the inner wall of the agitator blade. The drive assembly includes a drive bracket, a drive gear is rotatably connected to the top center of the inner wall of the drive bracket, a driven gear meshes with the side of the drive gear, a driven gear ring meshes with the end of the driven gear away from the drive gear, the bottom of the drive gear is fixedly connected to the drive shaft of the motor, and the top of the driven gear ring is fixedly connected to the bottom of the soaking tank. The placement rack includes a holding rack, the bottom of the inner wall of the holding rack is provided with a bottom discharge hole, the side of the inner wall of the holding rack is provided with a side discharge hole, a threaded sleeve is fixedly connected to the bottom of the inner wall of the holding rack, a support plate is fixedly connected to the side of the threaded sleeve, a stud is threadedly connected to the inner wall of the threaded sleeve, a rotating column is fixedly connected to the top of the stud, a limit ring is fixedly connected to the top of the rotating column, and the bottom of the threaded sleeve penetrates the top of the soaking tank and is fixedly connected to the top of the drive gear. The horizontal fixing assembly includes a fixed base, a fixed end of a first spring rod is fixedly connected to the side of the fixed base, a spring plate is fixedly connected to the movable end of the first spring rod, an arc-shaped guide strip is fixedly connected to the side of the spring plate, and the side of the fixed base away from the first spring rod is fixedly connected to the inner wall of the storage rack. The vertical fixing component includes a slide rail, a slider is slidably connected to the bottom inner wall of the slide rail, a braking groove is provided on the top of the slider, a conical tip is fixedly connected to the bottom of the slider, and a second spring rod is fixedly connected to one end of the top of the slide rail.

2. A glazing apparatus for ceramic processing according to claim 1, wherein: The fixed end of the second spring rod is fixedly connected to the top of the support plate, and the conical tip is positioned above the arc-shaped guide strip.

3. A glazing apparatus for ceramic processing according to claim 1, wherein: The drying assembly includes a triangular support frame, an electric fan is rotatably connected to the bottom of the triangular support frame, a protective tube is fixedly connected to the side of the triangular support frame, and an air guide tube is fixedly connected to the bottom of the protective tube.

4. A glazing apparatus for ceramic processing according to claim 3, wherein: The bottom of the electric fan is fixedly connected to the top of the connecting rod, and the air guide tube is positioned above the arc-shaped guide strip.