Low-temperature film forming apparatus for ceramic membrane production

Abstract

The application belongs to the technical field of ceramic membrane manufacturing, and particularly relates to a low-temperature film forming device for ceramic membrane manufacturing. The device aims at long time interval between multiple operations during extrusion forming, low continuity of work efficiency, and high temperature, and the following scheme is proposed. The device comprises a working frame, a mounting opening is formed in the outer wall of one side of the working frame, the same mounting frame is fixedly connected to the inner walls on the two sides of the mounting opening, a buckling forming assembly is arranged in the mounting frame, a raw material bin is fixedly connected to the inside of the working frame, and the same feeding opening is formed in the top of the raw material bin and the top of the working frame. The low-temperature film forming device for ceramic membrane manufacturing has the effect of improving the extrusion pressing efficiency, can reduce the time interval between multiple extrusions during use, improve the work efficiency during use of the device, and is provided with an auxiliary heat dissipation function to avoid high extrusion operation temperature.

Description

Technical Field

[0001] This invention relates to the field of ceramic membrane manufacturing technology, and in particular to a low-temperature film-forming apparatus for ceramic membrane manufacturing. Background Technology

[0002] Ceramic membranes are a type of inorganic membrane, belonging to solid membrane materials in membrane separation technology. They are mainly made of inorganic ceramic materials such as alumina, zirconium oxide, titanium dioxide, and silicon dioxide of different specifications as a support, and are produced by surface coating and high-temperature firing. Commercially available ceramic membranes typically have a three-layer structure with an asymmetrical distribution, and their filtration precision covers microfiltration, ultrafiltration, and nanofiltration levels.

[0003] Depending on the support structure, ceramic membranes can be classified into three types: flat sheet, tubular, and multi-channel. Due to their resistance to acids and alkalis, high temperatures, and chemical stability in extreme environments, and because commercially available ceramic membranes have small pore sizes, they can successfully achieve molecular-level filtration. Therefore, they are mainly used for filtering and separating liquid and gas mixtures, and can replace traditional separation technologies such as centrifugation, evaporation, distillation, and filtration. This achieves the goals of improving product quality and reducing production costs, and has broad application prospects in harsh environments such as the petroleum and chemical industries.

[0004] Existing ceramic membranes require an extrusion process during manufacturing. The extrusion stroke is too long and the interval between multiple extrusions is too long, resulting in poor extrusion efficiency of the device. At the same time, the excessively long extrusion operation time can easily cause the ceramic membrane temperature to be too high, which in turn affects the working process. Summary of the Invention

[0005] This invention discloses a low-temperature film-forming apparatus for manufacturing ceramic membranes, aiming to solve the technical problems in the prior art where existing ceramic membranes require an extrusion process during manufacturing, resulting in excessively long extrusion strokes and long intervals between multiple extrusions, leading to poor extrusion efficiency and excessively high ceramic membrane temperatures, which in turn affect the working process.

[0006] This invention proposes a low-temperature film-forming device for ceramic film manufacturing, comprising a working frame, a through mounting port on one outer wall of the working frame, and the same mounting frame fixedly connected to the inner walls on both sides of the mounting port. A pressing and forming assembly is disposed inside the mounting frame. A raw material silo is fixedly connected inside the working frame, and the top of the raw material silo and the top of the working frame have the same feed inlet. A raw material dust removal assembly is disposed at the top of the working frame. A drive motor is fixedly connected to one outer wall of the working frame, and the output shaft of the drive motor is connected to a conveying screw rod via a coupling. The conveying screw rod is located inside the raw material silo, and a material distribution assembly is disposed at the bottom of the raw material silo. A hydraulic rod is fixedly connected to the bottom of the raw material silo, and an extrusion plate is fixedly connected to the bottom end of the hydraulic rod.

[0007] The system comprises an installation frame, drive motor, conveying screw, hydraulic rod, extrusion plate, pressing and forming assembly, material distribution assembly, and raw material dust removal assembly. The drive motor and telescopic screw facilitate the conveying and grinding of raw materials, while the raw material dust removal assembly removes dust from the raw materials before grinding, meeting the molding quality requirements of the device. The pressing and forming assembly enables automatic and stable molding and extrusion, increasing the continuity of operation and providing cooling assistance to meet equipment usage needs. The material distribution assembly ensures consistent raw material quantity during molding, guaranteeing overall product quality and increasing the practicality of the device.

[0008] In a preferred embodiment, the pressing and forming assembly includes four conveyor rollers. The two ends of the four conveyor rollers are movably connected to the inner walls of both sides of the mounting frame. A motor is fixedly connected to one outer wall of the mounting frame. The output shaft of the motor is connected to one end of one of the conveyor rollers via a coupling. The outer walls of the four conveyor rollers are provided with the same conveyor belt. The inner walls of both sides of the mounting frame are fixedly connected with the same pressure plate, which is located inside the conveyor belt. The outer wall of the conveyor belt is provided with two fixed base plates. A mold base is fixedly connected to the top of each of the two fixed base plates. Two fixing plates are fixedly connected to the outer walls of both mold bases. Four limiting rods are fixedly connected to the top of each of the two fixing plates. The outer walls of the eight limiting rods are respectively fixed to the two mold bases. The four limiting rods on the same side are movably connected to the same molding plate on their outer walls. Each of the eight limiting rods has a pressure spring on its outer wall. The bottom ends of the eight pressure springs are fixedly connected to the two model seats, and the top ends of the two pressure springs are fixedly connected to the bottom of the two molding plates. Mounting plates are fixedly connected to the outer walls on both sides of the two molding plates. Each of the four mounting plates has a circular opening at its top. Each of the four circular openings has an adjusting port movably connected to its inner wall. Each of the four adjusting fasteners has a fixing opening on its outer wall. Each of the four fixing openings has two elastic elements inside. Each of the two model seats has a heat-conducting frame on its inner wall. Each of the two heat-conducting frames has a heat dissipation plate fixedly connected to the outer walls on both sides. Each of the four heat dissipation plates has two through holes on one side of its outer wall.

[0009] By incorporating a pressing and forming assembly, the time interval between multiple compressions can be reduced, improving the efficiency of the device. During use, the pressing and forming assembly uses adjusting fasteners, elastic elements, and fixing plates to press the forming plate and the mold base together, allowing the pressing plate to quickly separate after a single compression for subsequent compression operations. The device exhibits high molding continuity and ensures stability during manufacturing after pressing, guaranteeing the molding effect. The heat-conducting frame transfers the heat generated during pressing to the heat dissipation plate, which, along with the through holes, assists in heat dissipation, thus preventing excessively high temperatures during manufacturing.

[0010] In a preferred embodiment, the raw material dust removal assembly includes a dust collection bin, which is fixedly connected to the top of the working frame. The dust collection bin has a collection frame inside, and a handle is fixedly connected to one outer wall of the collection frame. Four conveying pipes are fixedly connected to the top of the dust collection bin. The input ends of two conveying pipes on the same side are fixedly connected to the same dust pump, and the input ends of the two dust pumps are fixedly connected to connecting pipes. Dust collection bins are fixedly connected to the input ends of the two connecting pipes. Both dust collection bins are located inside the raw material bin, on opposite sides of the conveying screw, and multiple dust suction holes are equidistantly opened on the outer walls of opposite sides of the two dust collection bins.

[0011] By incorporating a raw material dust removal component, the component can remove fine dust mixed in with the raw material during the conveying and grinding process. In use, the component can suck up the dust from the raw material before it reaches the final transformation state. The device is located in the grinding area at the front of the conveying screw, which prevents the raw material from being sucked in during dust removal, ensuring the effectiveness of the device. At the same time, dust removal can increase the quality during molding, and the dust can be collected in a collection box for easy handling by staff.

[0012] In a preferred embodiment, the material distribution assembly includes a material distribution bin, with a discharge port at the bottom of the bin. The outer wall of the material distribution bin is fixedly connected to the inner wall of the discharge port, and a fixed pipe is fixedly connected to the bottom of the bin. An anti-spill frame is fixedly connected to the output end of the fixed pipe, and a discharge component is movably connected to the bottom of the inner wall of the anti-spill frame. Two rotating plates are fixedly connected to the outer wall of the discharge component, and discharge ports are provided on both sides of the outer wall. A second motor is fixedly connected to one side of the outer wall of the material distribution bin. The output shaft of the second motor is connected to a shaft via a coupling. One end of the shaft is movably connected to the inner wall of one side of the material distribution bin, and a material distribution roller is fixedly connected to the outer wall of the shaft. The material distribution roller is located inside the material distribution bin.

[0013] By incorporating a material distribution component, the material distribution component ensures a consistent amount of raw material conveyed during each molding process, thereby guaranteeing uniform product specifications after molding and improving the overall quality of the device. Furthermore, during material discharge, the discharge component and rotating plate enable the device to automatically discharge and insert materials into the mold according to the position of the mold base, thus enhancing the device's effectiveness and practicality.

[0014] As can be seen from the above, the low-temperature film-forming device for ceramic film manufacturing provided by the present invention has the effect of improving the extrusion pressing efficiency. During use, it can reduce the time interval between multiple extrusions, improve the working efficiency of the device, and is equipped with an auxiliary heat dissipation function to avoid excessively high extrusion operation temperature. Attached Figure Description

[0015] Figure 1This is a schematic diagram of the overall structure of a low-temperature film-forming device for ceramic film manufacturing proposed in this invention;

[0016] Figure 2 This is a schematic diagram of the overall front view of a low-temperature film-forming device for ceramic film manufacturing proposed in this invention;

[0017] Figure 3 This is a schematic diagram of the combined structure of the conveyor belt and forming plate of a low-temperature film-forming device for ceramic film manufacturing proposed in this invention;

[0018] Figure 4 This is a schematic diagram of the pressing and forming component structure of a low-temperature film forming apparatus for ceramic film manufacturing proposed in this invention;

[0019] Figure 5 This is a schematic diagram of the conveying screw structure of a low-temperature film-forming device for ceramic film manufacturing proposed in this invention;

[0020] Figure 6 This is a schematic diagram of the raw material dust removal component of a low-temperature film-forming device for ceramic film manufacturing proposed in this invention;

[0021] Figure 7 This is a schematic diagram of the material distribution component of a low-temperature film-forming device for ceramic film manufacturing proposed in this invention.

[0022] In the diagram: 1. Working frame; 2. Raw material dust removal assembly; 201. Dust collection bin; 202. Conveying pipe; 203. Handle; 204. Dust suction hole; 205. Collection frame; 206. Dust suction bin; 207. Connecting pipe; 208. Dust pump; 3. Feed inlet; 4. Press forming assembly; 401. Forming plate; 402. Conveying belt; 403. Conveying roller; 404. Motor 1; 405. Fixed base plate; 406. Model base; 407. Limiting rod; 408. Pressure spring; 409. Mounting plate; 410 411. Fixed plate; 412. Adjustable fastener; 413. Elastic component; 414. Heat dissipation plate; 415. Through hole; 416. Heat conduction frame; 5. Mounting frame; 6. Material distribution assembly; 601. Material distribution bin; 602. Shaft; 603. Material distribution roller; 604. Motor II; 605. Discharge component; 606. Rotating plate; 607. Discharge port; 608. Anti-spill frame; 609. Fixed pipe; 7. Extrusion plate; 8. Hydraulic rod; 9. Drive motor; 10. Raw material bin; 11. Conveying screw; 12. Pressure plate. Detailed Implementation

[0023] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.

[0024] The low-temperature film-forming device for ceramic film manufacturing disclosed in this invention is mainly used in scenarios where the interval between multiple operations during extrusion molding is long, the continuous working efficiency is low, and the temperature is easily too high.

[0025] Reference Figure 1-7 A low-temperature film-forming device for ceramic film manufacturing includes a working frame 1. A through mounting port is provided on one outer wall of the working frame 1. The same mounting frame 5 is fixedly connected to the inner walls on both sides of the mounting port. A pressing and forming component 4 is provided inside the mounting frame 5. A raw material silo 10 is fixedly connected inside the working frame 1. The top of the raw material silo 10 and the top of the working frame 1 have the same feed inlet 3. A raw material dust removal component 2 is provided on the top of the working frame 1. A drive motor 9 is fixedly connected to one outer wall of the working frame 1. The output shaft of the drive motor 9 is connected to a conveying screw 11 through a coupling. The conveying screw 11 is located inside the raw material silo 10. A material distribution component 6 is provided at the bottom of the raw material silo 10. A hydraulic rod 8 is fixedly connected to the bottom of the raw material silo 10. An extrusion plate 7 is fixedly connected to the bottom end of the hydraulic rod 8.

[0026] Specifically, the drive motor 9 and the telescopic screw facilitate the conveying and grinding of raw materials, and during this process, the raw material dust removal component 2 can remove dust from the inside of the raw materials in the grinding stage, meeting the molding quality requirements of the device; the pressing and forming component 4 can automatically and stably perform molding and extrusion during use, while increasing the operational continuity of the device, and is equipped with cooling assistance to meet the equipment usage requirements; the material distribution component 6 ensures that the amount of raw materials used in the manufacturing and molding process is consistent, thereby guaranteeing the overall quality of the product and increasing the practicality of the device.

[0027] Reference Figure 1 , Figure 3 and Figure 4In a preferred embodiment, the pressing and forming assembly 4 includes four conveying rollers 403. The two ends of the four conveying rollers 403 are respectively connected to the inner walls of both sides of the mounting frame 5 via bearings. A motor 404 is fixedly connected to one side of the outer wall of the mounting frame 5. The output shaft of the motor 404 is connected to one end of one of the conveying rollers 403 via a coupling. The outer walls of the four conveying rollers 403 are provided with the same conveying belt 402. The inner walls of both sides of the mounting frame 5 are fixedly connected with the same pressure plate 12, which is located inside the conveying belt 402. The outer wall of the conveying belt 402 is provided with two fixed base plates 405. A mold base 406 is fixedly connected to the top of each of the two fixed base plates 405. Two fixing plates 410 are fixedly connected to the outer walls of both sides of the two mold bases 406. Four limiting rods 407 are fixedly connected to the top of each of the two fixing plates 410. The outer walls of the eight limiting rods 407 are respectively connected to the outer walls of the two mold bases 406. 6. Fixed connection: The outer walls of the four limiting rods 407 on the same side are all slidably connected to the same molding plate 401, and the outer walls of the eight limiting rods 407 are all provided with pressure springs 408. The bottom ends of the eight pressure springs 408 are fixedly connected to the two model seats 406 respectively, and the top ends of the two pressure springs 408 are fixedly connected to the bottom of the two molding plates 401 respectively. The outer walls of the two molding plates 401 are fixedly connected with mounting plates 409. The top of the four mounting plates 409 is opened with a circular opening. The inner walls of the four circular openings are connected with adjusting ports through bearings. The outer walls of the four adjusting fasteners 411 are opened with fixing ports. The interior of the four fixing ports is provided with two elastic elements 412. The inner walls of the two model seats 406 are provided with heat-conducting frames 415. The outer walls of the two heat-conducting frames 415 are fixedly connected with heat dissipation plates 413. The outer walls of the four heat dissipation plates 413 are opened with two through holes 414 on one side.

[0028] Specifically, during the molding operation, motor 404 starts, driving the conveyor belt 402 to move, which in turn moves the mold base 406 to below the extrusion plate 7. At this time, hydraulic rod 8 starts, driving the extrusion plate 7 to press down. Meanwhile, the molding plate 401 moves on the limit rod 407 and extrudes the raw material inside the mold base 406. Simultaneously, as the molding plate 401 descends, it drives the adjusting fastener 411 to descend and move it between the fixed plates 410, so that the elastic element 412 engages with the fixed plates 410, completing the pressing and molding. The conveyor belt 402 moves, allowing the extrusion plate 7 to perform the next molding operation. The single molding operation is fast. After molding is completed, the operator rotates the adjusting fastener 411, causing the elastic element 412 to move to the gap between the fixed plates 410. At this time, the pressure spring 408 resets, thereby driving the molding plate 401 to rise, making it easier for the operator to collect the mold.

[0029] In specific application scenarios, the pressing and forming component 4 is suitable for the ceramic film manufacturing and forming process. That is, the pressing and forming component 4 can reduce the time interval between multiple extrusions and improve the working efficiency of the device. When in use, the pressing and forming component 4 can press the forming plate 401 and the mold base 406 together through the adjusting fastener, elastic element 412 and fixed plate 410. Thus, after a single extrusion, the extrusion plate 7 can be quickly separated from it for subsequent extrusion operations. The device has high forming continuity and can ensure the stability of manufacturing and forming after pressing, thus ensuring the forming effect.

[0030] It should be noted that the heat generated during the pressing process can be transferred to the heat sink 413 through the heat conduction frame 415. The heat sink 413 and the through hole 414 assist in heat dissipation, thereby avoiding excessive temperature during manufacturing.

[0031] Reference Figure 1 , Figure 2 , Figure 5 and Figure 6 In a preferred embodiment, the raw material dust removal assembly 2 includes a dust collection bin 201, which is fixedly connected to the top of the working frame 1. The dust collection bin 201 has a collection frame 205 inside, and a handle 203 is fixedly connected to one side of the outer wall of the collection frame 205. Four conveying pipes 202 are fixedly connected to the top of the dust collection bin 201. The input ends of two conveying pipes 202 on the same side are fixedly connected to the same dust pump 208, and the input ends of the two dust pumps 208 are fixedly connected to connecting pipes 207. The input ends of the two connecting pipes 207 are fixedly connected to dust collection bins 206. The two dust collection bins 206 are located inside the raw material bin 10. The two dust collection bins 206 are located on both sides of the conveying screw 11, and multiple dust collection holes 204 are equally spaced on the outer walls of opposite sides of the two dust collection bins 206.

[0032] Specifically, during use, the raw materials are conveyed into the raw material silo 10 through the feed inlet 3. At this time, the drive motor 9 is started, which drives the conveying screw 11 to rotate. During the rotation, the raw materials move and are ground along with the conveying screw roller. The front section of the conveyor is equipped with a dust collection silo 206. At this time, the dust collection pump 208 is started to collect dust. Fine dust enters the dust collection silo 206 through the dust collection hole 204 and is conveyed to the dust collection silo 201 through the connecting pipe 207 and the conveying pipe 202. The fine dust then falls into the collection frame 205. After use, the staff removes the collection frame 205 through the handle 203 to collect and process the dust.

[0033] In specific application scenarios, the raw material dust removal component 2 is suitable for the raw material conveying and grinding process. That is, the raw material dust removal component 2 can handle the fine dust mixed inside the raw material during the conveying and grinding process. When in use, the raw material dust removal component 2 can perform dust removal treatment on the raw material before grinding to the final transformation state. The device is located in the grinding area at the front of the conveying screw 11 to avoid sucking in the raw material during dust removal, thus ensuring the effectiveness of the device. At the same time, the dust removal treatment can increase the quality during molding, and the dust can be collected by the collection box 205 for easy handling by the staff.

[0034] Reference Figure 2 , Figure 5 and Figure 7 In a preferred embodiment, the material distribution assembly 6 includes a material distribution bin 601. The bottom of the raw material bin 10 has a discharge port. The outer wall of the material distribution bin 601 is fixedly connected to the inner wall of the discharge port, and a fixed pipe 609 is fixedly connected to the bottom of the material distribution bin 601. An anti-spill frame 608 is fixedly connected to the output end of the fixed pipe 609. A discharge component 605 is rotatably connected to the bottom of the inner wall of the anti-spill frame 608. Two rotating plates 606 are fixedly connected to the outer wall of the discharge component 605, and discharge ports 607 are opened on both sides of the outer wall of the discharge component 605. A second motor 604 is fixedly connected to one side of the outer wall of the material distribution bin 601. The output shaft of the second motor 604 is connected to a shaft 602 through a coupling. One end of the shaft 602 is connected to the inner wall of one side of the material distribution bin 601 through a bearing, and a material distribution roller 603 is fixedly connected to the outer wall of the shaft 602. The material distribution roller 603 is located inside the material distribution bin 601.

[0035] Specifically, when the raw material is fed into the mold, motor 604 is started. At this time, motor 604 drives shaft 602 to rotate, which in turn drives the distribution roller 603 to rotate, and moves the raw material to the notch of the distribution roller 603 to ensure consistent material feeding in a single operation. Then, the raw material is transported to the inside of the anti-spill frame 608 through the fixed pipe 609 and falls into the inside of the discharge part 605. At this time, the mold base 406 drives the limiting rod 407 to move. One of the limiting rods 407 contacts the rotating plate 606, causing it to rotate and rotate the discharge port 607 to one side of the mold base 406 for material discharge. After the discharge is completed, the other limiting rod 407 contacts the discharge port 607 of the discharge part 605, causing it to rotate again and move both discharge ports 607 into the inside of the anti-spill frame 608, thus completing the raw material feeding process.

[0036] In specific application scenarios, the material distribution component 6 is suitable for the raw material feeding stage before molding. That is, the material distribution component 6 can ensure that the amount of raw material conveyed in a single molding process is consistent, thereby ensuring the uniformity of product specifications after molding and improving the overall quality of the device. Moreover, when discharging material, the material discharge component 605 and the rotating plate 606 enable the device to automatically perform material discharge and mold feeding operations according to the position of the mold base 406, thereby increasing the effectiveness and practicality of the device.

[0037] Working principle: During use, the raw material is conveyed into the raw material hopper 10 through the feed inlet 3. The drive motor 9 is then activated, which rotates the conveying screw 11. During rotation, the raw material moves and is ground along with the conveying screw roller. A dust collection hopper 206 is located at the front of the conveyor. The dust pump 208 is then activated to collect dust. Fine dust enters the dust collection hopper 206 through the dust suction hole 204 and is then conveyed to the dust collection hopper 201 through the connecting pipe 207 and the conveying pipe 202. The fine dust then falls into the collection frame 205. After use... Workers remove the collection frame 205 using handle 203 to collect and process the dust. When raw materials are fed into the mold, motor 604 starts, driving shaft 602 to rotate, which in turn rotates the distribution roller 603, moving the raw material to the notch of the distribution roller 603 to ensure consistent material intake. The raw material is then transported through fixed pipe 609 to the spill prevention frame 608 and falls into the discharge part 605. At this time, mold base 406 moves limiting rods 407, one of which contacts the rotating plate 606, causing it to rotate. The discharge port 607 is rotated to one side of the mold base 406 to discharge material. After discharge, another limiting rod 407 contacts the discharge port 607 of the discharge component 605, causing it to rotate again and move both discharge ports 607 into the anti-spill frame 608, thus completing the material feeding into the mold. During the molding operation, motor 404 is started, driving the conveyor belt 402 to move, which in turn moves the mold base 406 to below the extrusion plate 7. At this time, the hydraulic rod 8 is activated, driving the extrusion plate 7 to press down. The molding plate 401 moves on the limiting rod 407 and presses against the mold base 406. The raw materials are extruded and molded. At the same time, when the molding plate 401 descends, it drives the adjusting fastener 411 to descend and move it between the fixed plates 410, so that the elastic element 412 engages with the fixed plates 410 and the pressing is completed. The moving conveyor belt 402 allows the extrusion plate 7 to perform the next molding operation. The single molding operation time is fast. After the molding is completed, the operator rotates the adjusting fastener 411, so that the elastic element 412 moves to the gap between the fixed plates 410. At this time, the pressure spring 408 resets, thereby driving the molding plate 401 to rise, which makes it easier for the operator to collect the material.

[0038] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.

Claims

1. A low-temperature film forming apparatus for ceramic membrane production, comprising a working frame (1), characterized in that, The working frame (1) has a through mounting opening on one side of its outer wall. The same mounting frame (5) is fixedly connected to the inner walls on both sides of the mounting opening. A pressing and forming assembly (4) is provided inside the mounting frame (5). A raw material silo (10) is fixedly connected inside the working frame (1). The top of the raw material silo (10) and the top of the working frame (1) have the same feed inlet (3). A raw material dust removal assembly (2) is provided at the top of the working frame (1). A drive motor (9) is fixedly connected to one side of the outer wall of the working frame (1). The output shaft of the drive motor (9) is connected to a conveying screw (11) through a coupling. The conveying screw (11) is located inside the raw material silo (10). A material distribution assembly (6) is provided at the bottom of the raw material silo (10). A hydraulic rod (8) is fixedly connected to the bottom of the raw material silo (10). An extrusion plate (7) is fixedly connected to the bottom end of the hydraulic rod (8). The pressing and forming assembly (4) includes conveying rollers (403), the two ends of the four conveying rollers (403) are respectively movably connected to the inner walls of the two sides of the mounting frame (5), a motor (404) is fixedly connected to one side of the outer wall of the mounting frame (5), the output shaft of the motor (404) is connected to one end of one of the conveying rollers (403) through a coupling, and the outer walls of the four conveying rollers (403) are provided with the same conveying belt (402), and the inner walls of the two sides of the mounting frame (5) are fixedly connected with the same pressure plate (12), and the pressure plate (12) is located inside the conveying belt (402); The raw material dust removal component (2) includes a dust collection bin (201), which is fixedly connected to the top of the working frame (1), and the dust collection bin (201) is provided with a collection frame (205) inside, and a handle (203) is fixedly connected to one side of the outer wall of the collection frame (205). The material distribution component (6) includes a material distribution bin (601), a material outlet is provided at the bottom of the raw material bin (10), the outer wall of the material distribution bin (601) is fixedly connected to the inner wall of the material outlet, and a fixed pipe (609) is fixedly connected to the bottom of the material distribution bin (601).

2. The low-temperature film forming apparatus for ceramic film production according to claim 1, characterized by The outer wall of the conveyor belt (402) is provided with two fixed base plates (405). The top of each of the two fixed base plates (405) is fixedly connected to a model seat (406). The outer walls of the two model seats (406) are fixedly connected to two fixed plates (410). The top of each of the two fixed plates (410) is fixedly connected to four limiting rods (407). The outer walls of the eight limiting rods (407) are fixedly connected to the two model seats (406) respectively. The outer walls of the four limiting rods (407) on the same side are movably connected to the same forming plate (401). The outer walls of the eight limiting rods (407) are provided with pressure springs (408). The bottom ends of the eight pressure springs (408) are fixedly connected to the two model seats (406) respectively. The top ends of the two pressure springs (408) are fixedly connected to the bottom of the two forming plates (401) respectively.

3. The low-temperature film-forming apparatus for ceramic film manufacturing according to claim 2, characterized in that, Mounting plates (409) are fixedly connected to the outer walls of both sides of the two molding plates (401). The top of each of the four mounting plates (409) is provided with a circular opening. The inner walls of each of the four circular openings are movably connected with adjusting openings. The outer walls of each of the four adjusting fasteners (411) are provided with fixing openings. The interior of each of the four fixing openings is provided with two elastic elements (412). The inner walls of the two model bases (406) are provided with heat-conducting frames (415). The outer walls of both sides of the two heat-conducting frames (415) are fixedly connected with heat dissipation plates (413). The outer walls of one side of each of the four heat dissipation plates (413) are provided with two through holes (414).

4. The low-temperature film-forming apparatus for ceramic film manufacturing according to claim 1, characterized in that, The top of the dust collection chamber (201) is fixedly connected to four conveying pipes (202). The input ends of two conveying pipes (202) on the same side are fixedly connected to the same dust pump (208), and the input ends of the two dust pumps (208) are fixedly connected to a connecting pipe (207).

5. The low-temperature film-forming apparatus for ceramic film manufacturing according to claim 4, characterized in that, The input ends of the two connecting pipes (207) are fixedly connected to a dust collection chamber (206). The two dust collection chambers (206) are located inside the raw material chamber (10). The two dust collection chambers (206) are located on both sides of the conveying screw (11), and multiple dust collection holes (204) are opened at equal intervals on the outer wall of the opposite side of the two dust collection chambers (206).

6. The low-temperature film-forming apparatus for ceramic film manufacturing according to claim 1, characterized in that, The output end of the fixed pipe (609) is fixedly connected to an anti-spill frame (608), and the bottom of the inner wall of the anti-spill frame (608) is movably connected to a discharge component (605). The outer wall of the discharge component (605) is fixedly connected to two rotating plates (606), and discharge ports (607) are opened on both sides of the outer wall of the discharge component (605).

7. The low-temperature film-forming apparatus for ceramic film manufacturing according to claim 6, characterized in that, A second motor (604) is fixedly connected to one side of the outer wall of the material distribution bin (601). The output shaft of the second motor (604) is connected to a shaft (602) through a coupling. One end of the shaft (602) is movably connected to one side of the inner wall of the material distribution bin (601), and a material distribution roller (603) is fixedly connected to the outer wall of the shaft (602). The material distribution roller (603) is located inside the material distribution bin (601).

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