An automated power ball press

By introducing filter components and fly ash collection components into the briquetting machine, the problems of powder spillage and dust were solved, achieving efficient separation and recycling of powder, and improving processing efficiency and environmental quality.

CN122143401APending Publication Date: 2026-06-05DONGTAI DONGYUAN MASCH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
DONGTAI DONGYUAN MASCH CO LTD
Filing Date
2026-03-30
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

When existing briquetting machines are in operation, some powder is not compressed and falls off with the rotation of the rollers, forming dust that needs to be collected and reprocessed, making the operation cumbersome.

Method used

The system employs a combination of a filter assembly and a fly ash collection assembly. Uncompacted powder is separated by a dual screening structure of a guide plate and a conveyor belt, and then recycled to a pre-crushing assembly for secondary processing using a conveyor auger. At the same time, fly ash is collected using exhaust fan blades and a filter plate.

Benefits of technology

It achieves efficient separation and recycling of uncompacted powder, improves processing efficiency, improves the working environment, and reduces dust pollution.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses an automatic powerful ball pressing machine and relates to the technical field of mechanical equipment. The automatic powerful ball pressing machine comprises a processing shell, two groups of power motors are installed on the rear side of the processing shell, pressing rollers are fixedly connected to the output ends of the two groups of power motors, and pressing grooves are formed in the surfaces of the pressing rollers. A filtering assembly is arranged in the processing shell, and the filtering assembly comprises a guide mesh plate arranged in the processing shell. The filtering assembly is arranged, the double-screening structure of the guide mesh plate and a conveying mesh belt is utilized, the un-compacted powder and the finished ball are efficiently separated, the powder is automatically recycled to a pre-pulverizing assembly through a conveying auger for secondary processing, the problem that the powder is discharged together with the ball in the prior art and needs to be manually collected and processed is solved, and the processing efficiency is remarkably improved. Meanwhile, the exhaust fan blades in the fly ash collecting assembly are matched with the filtering mesh plate, the fly ash raised in the processing process is actively collected, the filter screen is automatically cleaned by the scraper, and the working environment is effectively improved.
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Description

Technical Field

[0001] This invention belongs to the field of mechanical equipment technology, and in particular relates to an automated high-power briquetting machine. Background Technology

[0002] A briquetting machine is a mechanical device used to press loose powdery materials (such as coal powder, mineral powder, sludge, etc.) into briquettes with a certain strength and shape under high pressure. It uses a motor-driven roller shaft to rotate, forcing the material into a mold cavity to form the briquettes, which are then demolded to obtain the finished product. Briquetting machines are widely used in industries such as metallurgy, chemicals, building materials, and environmental protection, effectively improving material density and combustion efficiency, while reducing transportation losses and environmental pollution.

[0003] A Chinese patent application (or patent) with publication number CN219749009U discloses an automatic briquetting machine, including a machine housing. An active extrusion roller and a driven extrusion roller are rotatably mounted inside the machine housing, and the active extrusion roller and the driven extrusion roller rotate synchronously in opposite directions. A hopper is provided on the machine housing between the active extrusion roller and the driven extrusion roller. Both the active extrusion roller and the driven extrusion roller are provided with spherical grooves. A plate-shaped groove is provided inside the active extrusion roller near the spherical groove. A baffle is slidably installed inside the plate-shaped groove, and the baffle penetrates the circumferential sidewall of the active extrusion roller.

[0004] However, the above-mentioned device still has the following problems during implementation: When the briquetting machine is working, the powder is pressed together to form briquettes by the relative rotation of the active and driven extrusion rollers. During the feeding process of the briquettes, some powder will not be pressed together and will fall downwards as the extrusion rollers rotate, causing dust. Moreover, after being discharged by the conveyor belt, the discharged powder needs to be collected and processed again, which is very inconvenient.

[0005] To address this issue, we provide an automated high-power briquetting machine. Summary of the Invention

[0006] The purpose of this invention is to provide an automated high-power briquetting machine. Through the structural coordination of the filter component, fly ash collection component, and drive component, it solves the problem in the prior art where some powder is not compressed during operation, and it falls off with the rotation of the roller to form dust, which requires collection and reprocessing, resulting in cumbersome operation.

[0007] To solve the above-mentioned technical problems, the present invention is achieved through the following technical solution.

[0008] This invention relates to an automated high-strength briquetting machine, comprising a processing shell, two sets of power motors mounted on the rear side of the processing shell, and pressure rollers fixedly connected to the output ends of both sets of power motors, the pressure rollers having pressure grooves on their surfaces; a filter assembly is provided inside the processing shell, the filter assembly including a guide mesh plate installed inside the processing shell, a first conveyor roller and a second conveyor roller installed inside the processing shell, a conveyor belt sleeved on the surfaces of the first conveyor roller and the second conveyor roller, a conveying pipe located on one side of the processing shell, a drive motor installed at the top of the conveying pipe, and a conveying auger installed at the output end of the drive motor, the filter assembly collecting and filtering uncompacted powder; a fly ash collection assembly is also provided inside the processing shell. The system includes an exhaust duct connected to one side of the processing housing, a filter screen installed inside the exhaust duct, a scraper located on one side of the filter screen, a connecting pipe movably connected to the surface of the exhaust duct, a drive shaft movably connected to the inside of the connecting pipe, and exhaust fan blades installed on the surface of the drive shaft. A fly ash collection assembly collects the raised fly ash. A drive assembly is located on one side of the processing housing. The drive assembly includes a first pulley installed on the surface of a first conveyor roller, a second pulley installed on the surface of the drive shaft, a rotating shaft movably connected to one side of the processing housing, a third pulley installed on the surface of the rotating shaft, a first gear installed on the surface of the rotating shaft, and a second gear installed on the surface of a second conveyor roller. The drive assembly provides driving force for filtering and conveying the powder.

[0009] The present invention is further configured such that the drive assembly includes a servo motor mounted on one side of the machining housing, a third gear mounted on the surface of the drive shaft, and a fourth gear mounted on the surface of the exhaust pipe.

[0010] The invention is further configured such that one side of the third gear meshes with the fourth gear, and the surface of the exhaust pipe is movably connected to the machining shell and the inner wall of the connecting pipe via a bearing.

[0011] The present invention is further configured such that the output end of the servo motor is fixedly connected to the first conveying roller, one side of the first gear meshes with the second gear, and the first belt pulley, the second belt pulley and the third belt pulley are connected by belt drive.

[0012] The present invention is further configured such that an auxiliary roller is provided inside the conveyor belt, and the surface of the auxiliary roller is movably connected to the inner wall of the processing shell through a bearing.

[0013] The present invention is further configured such that a guide shell is connected to the bottom of the processing shell, and one side of the guide shell is connected to the conveying pipe.

[0014] The present invention is further configured such that a pre-crushing assembly is provided on the top of the processing shell, the pre-crushing assembly including a feeding shell installed on the top of the processing shell, a crushing cylinder installed inside the feeding shell, a rotary motor installed on the top of the crushing cylinder, and crushing blades installed at the output end of the rotary motor.

[0015] The present invention is further configured such that a feeding pipe is connected to one side of the conveying pipe, and the other end of the feeding pipe is connected to the crushing cylinder.

[0016] The present invention is further configured such that a bracket is mounted on the surface of the rotary motor, and one side of the bracket is fixedly connected to the crushing cylinder.

[0017] The present invention is further configured such that both the guide plate and the conveyor belt have filter holes on their surfaces for filtering powder.

[0018] This invention offers the following advantages: By incorporating a filtration assembly and utilizing a dual screening structure of a guide plate and a conveyor belt, it efficiently separates uncompacted powder from finished pellets. The powder is then automatically recycled to a pre-crushing assembly for secondary processing via a conveyor auger. This solves the problem in existing technologies where powder is discharged along with the pellets, requiring manual collection and reprocessing, thus significantly improving processing efficiency. Simultaneously, the fly ash collection assembly, through its exhaust fan blades working in conjunction with the filter plate, actively collects fly ash generated during processing, and automatically cleans the filter using a scraper, effectively improving the working environment.

[0019] Of course, any product implementing this invention does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description

[0020] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings used in the description of the embodiments will be briefly introduced below.

[0021] Figure 1 This is a 3D view of an automated high-power briquetting machine.

[0022] Figure 2 This is a rear view of an automated high-power briquetting machine.

[0023] Figure 3 This is a cross-sectional view of the conveying pipe in an automated high-power briquetting machine.

[0024] Figure 4 This is a schematic diagram of the internal structure of the processing shell in an automated high-strength briquetting machine.

[0025] Figure 5 This is a schematic diagram of the pre-crushing component in an automated high-power briquetting machine.

[0026] Figure 6 This is a schematic diagram showing the connection between the exhaust pipe and the processing shell in an automated high-strength briquetting machine.

[0027] Figure 7 This is a schematic diagram of the fly ash collection component in an automated high-power briquetting machine.

[0028] Figure 8 This is a cross-sectional view of the connecting pipe in an automated high-power briquetting machine.

[0029] In the attached diagram: 1. Processing shell; 2. Power motor; 3. Pressure roller; 4. Pressure groove; 5. Filter assembly; 501. Guide screen plate; 502. First conveyor roller; 503. Second conveyor roller; 504. Conveyor belt; 505. Conveying pipe; 506. Drive motor; 507. Conveying auger; 6. Fly ash collection assembly; 601. Exhaust pipe; 602. Filter screen plate; 603. Scraper; 604. Connecting pipe; 605. Drive shaft; 606. Exhaust fan blade; 7. Drive assembly; 701, First pulley; 702, Second pulley; 703, Rotating shaft; 704, Third pulley; 705, First gear; 706, Second gear; 707, Servo motor; 708, Third gear; 709, Fourth gear; 8, Auxiliary roller; 9, Guide shell; 10, Pre-crushing assembly; 1001, Feeding shell; 1002, Crushing cylinder; 1003, Rotary motor; 1004, Crushing blades; 11, Feeding pipe; 12, Support. Detailed Implementation

[0030] The technical solutions of the present invention will be described below with reference to the accompanying drawings. The described embodiments are only some embodiments of the present invention, and not all embodiments. Example

[0031] Please see Figures 1-8This invention relates to an automated high-strength briquetting machine, comprising a processing shell 1, two sets of power motors 2 mounted on the rear side of the processing shell 1, and pressure rollers 3 fixedly connected to the output ends of both sets of power motors 2, with pressure grooves 4 formed on the surface of the pressure rollers 3; a filter assembly 5 is provided inside the processing shell 1, the filter assembly 5 including a guide mesh plate 501 installed inside the processing shell 1, a first conveying roller 502 and a second conveying roller 503 installed inside the processing shell 1, a conveying mesh belt 504 sleeved on the surface of the first conveying roller 502 and the second conveying roller 503, a conveying pipe 505 located on one side of the processing shell 1, a drive motor 506 installed at the top of the conveying pipe 505, and a conveying auger 507 installed at the output end of the drive motor 506, the filter assembly 5 collecting and filtering uncompacted powder; a fly ash collection assembly 6 is provided inside the processing shell 1, the fly ash collection assembly 6 including an exhaust pipe 6 connected to one side of the processing shell 1. 01. A filter screen plate 602 installed inside the exhaust pipe 601, a scraper 603 set on one side of the filter screen plate 602, a connecting pipe 604 movably connected to the surface of the exhaust pipe 601, a drive shaft 605 movably connected to the inside of the connecting pipe 604, and an exhaust fan blade 606 installed on the surface of the drive shaft 605, which collects the fly ash raised by the fly ash collection assembly 6; A drive assembly 7 is provided on one side of the processing shell 1. The drive assembly 7 includes a first pulley 701 installed on the surface of the first conveying roller 502, a second pulley 702 installed on the surface of the drive shaft 605, a rotating shaft 703 movably connected to one side of the processing shell 1, a third pulley 704 installed on the surface of the rotating shaft 703, a first gear 705 installed on the surface of the rotating shaft 703, and a second gear 706 installed on the surface of the second conveying roller 503. The drive assembly 7 provides driving force for the filtration and conveying of powder.

[0032] Specifically: the power motor 2 drives the pressure rollers 3 to rotate synchronously in opposite directions, providing the core power for spherical forming. This allows the two sets of pressure rollers 3 to rotate in opposite directions, achieving strong extrusion of the powder entering between the pressure rollers 3 to form spherical pellets. The pressure rollers 3 receive and extrude the powder falling from above, forcing it into the pressure groove 4 through relative rotation. The high-pressure forming of the pellets is completed during the interlocking of the roller surfaces. The pressure groove 4 is formed on the surface of the pressure rollers 3 to accommodate and shape the powder when the pressure rollers 3 rotate relative to each other, ensuring that the powder is compacted and formed within the groove, thus guaranteeing that the formed pellets are regular in shape and dense. The guide plate 501 is installed inside the processing shell 1 to receive pellets and uncompacted powder falling from the pressure roller 3. Fine powder is sieved through filter holes on its surface. Simultaneously, the finished pellets are guided along the plate surface to the next conveying stage. The first conveyor roller 502 and the second conveyor roller 503 are installed inside the processing shell 1 as the drive wheels of the conveyor belt 504, driving the conveyor belt 504 to circulate and achieve stable conveying of the pellets. The conveyor belt 504 is fitted onto the surfaces of the first conveyor roller 502 and the second conveyor roller 503 to receive and convey the pellets from the guide plate 501. The falling pellets, along with the filter holes on their surface, allow residual powder to fall further during transport, improving pellet cleanliness. A conveying pipe 505, located on one side of the processing shell 1, collects and holds uncompacted powder entering from the guide shell 9, providing a channel for secondary powder transport. A drive motor 506, mounted on top of the conveying pipe 505, drives the conveying auger 507 to rotate, providing power for the vertical lifting of the powder. The conveying auger 507, installed at the output end of the drive motor 506, transports the collected uncompacted powder upwards inside the conveying pipe 505, allowing the powder to be re-concentrated. The material enters the pre-crushing component 10 for secondary processing to achieve the recycling of powder. The exhaust pipe 601 is connected to one side of the processing shell 1 to guide the dust-laden airflow inside the processing shell 1 to the outside, providing a flow channel for fly ash collection. The filter screen 602 is installed inside the exhaust pipe 601 to block dust particles in the airflow and prevent fly ash from being directly discharged into the external environment, thus achieving dust interception and collection. The scraper 603 is set on one side of the filter screen 602 to continuously scrape off the dust attached to its surface when the filter screen 602 rotates, preventing the filter holes from being blocked and maintaining the unobstructed flow of the filter screen 602. Example

[0033] Please see Figures 1-8Based on embodiment 1, the drive assembly 7 further includes a servo motor 707 mounted on one side of the processing housing 1, a third gear 708 mounted on the surface of the drive shaft 605, and a fourth gear 709 mounted on the surface of the exhaust pipe 601. One side of the third gear 708 meshes with the fourth gear 709. The surface of the exhaust pipe 601 is movably connected to the processing housing 1 and the inner wall of the connecting pipe 604 through bearings. The output end of the servo motor 707 is fixedly connected to the first conveying roller 502. One side of the first gear 705 meshes with the second gear 706. The first belt pulley 701, the second belt pulley 702, and the third belt pulley 704 are connected by belt drive. An auxiliary roller 8 is provided inside the conveyor belt 504. The surface of the auxiliary roller 8 is movably connected to the inner wall of the processing housing 1 through bearings.

[0034] Specifically: The drive shaft 605 is movably connected inside the connecting pipe 604 to drive the exhaust fan blades 606 to rotate, providing power for airflow. Simultaneously, it drives the exhaust pipe 601 to rotate via the third gear 708. The exhaust fan blades 606 are mounted on the surface of the drive shaft 605 and rotate at high speed under the drive of the drive shaft 605, creating a negative pressure inside the processing housing 1 to draw in the raised fly ash into the exhaust pipe 601, achieving active dust collection. The first pulley 701 is mounted on the surface of the first conveyor roller 502 and transmits the power of the servo motor 707 to the second pulley 702 and the third pulley 704 via belt, achieving synchronous drive of multiple components. The second pulley 702 is mounted on the surface of the drive shaft 605. The first belt pulley 704 receives power from the first belt pulley 701, drives the drive shaft 605 to rotate, and thus drives the exhaust fan blades 606 to work. The rotating shaft 703 is movably connected to one side of the processing housing 1, and carries the third belt pulley 704 and the first gear 705. It rotates under the drive of the belt and transmits power to the second conveyor roller 503. The third belt pulley 704 is mounted on the surface of the rotating shaft 703 and receives power transmitted from the first belt pulley 701 through the belt, driving the rotating shaft 703 to rotate. The first gear 705 is mounted on the surface of the rotating shaft 703 and meshes with the second gear 706, transmitting the rotational power of the rotating shaft 703 to the second conveyor roller 503. The second gear 706 is mounted on the surface of the second conveyor roller 503 and meshes with the second gear 706. The first gear 705 meshes with the second conveyor roller 503, driving it to rotate. This causes the second conveyor roller 503 to rotate synchronously and in opposite directions with the first conveyor roller 502, thus driving the conveyor belt 504 to run smoothly. The servo motor 707 is mounted on one side of the processing housing 1, with its output end fixedly connected to the first conveyor roller 502. It provides a stable and controllable power source for the entire drive assembly 7, simultaneously driving the first conveyor roller 502 to rotate, thus enabling the active operation of the conveyor belt 504. The third gear 708 is mounted on the surface of the drive shaft 605 and meshes with the fourth gear 709, transmitting the rotational power of the drive shaft 605 to the exhaust pipe 601, causing the exhaust pipe 601 to rotate. The fourth gear 709 is mounted on the surface of the exhaust pipe 601 and meshes with the fourth gear 709. The three gears 708 mesh, causing the exhaust pipe 601 to rotate around its own axis under the drive of the drive shaft 605, which in turn drives the filter screen plate 602 to rotate together. This, together with the scraper 603, enables automatic cleaning of the filter screen surface. The auxiliary roller 8 is set inside the conveyor belt 504, and its surface is movably connected to the inner wall of the processing shell 1 through bearings. It is used to support and tension the conveyor belt 504, preventing it from sagging or deviating during the conveying of pellets. The guide shell 9 is connected to the bottom of the processing shell 1, and one side is connected to the conveying pipe 505. It is used to collect the powder screened by the guide screen plate 501 and the filter screen plate 602 and guide it to the bottom of the conveying pipe 505, so that the conveying auger 507 can lift the powder uniformly. Example

[0035] Please see Figures 1-8Based on Embodiments 1 and 2, the bottom of the processing shell 1 is connected to a guide shell 9, one side of the guide shell 9 is connected to the conveying pipe 505, and the top of the processing shell 1 is provided with a pre-crushing component 10. The pre-crushing component 10 includes a feeding shell 1001 installed on the top of the processing shell 1, a crushing cylinder 1002 installed inside the feeding shell 1001, a rotary motor 1003 installed on the top of the crushing cylinder 1002, and crushing blades 1004 installed at the output end of the rotary motor 1003. One side of the conveying pipe 505 is connected to a feeding pipe 11, and the other end of the feeding pipe 11 is connected to the crushing cylinder 1002. A bracket 12 is installed on the surface of the rotary motor 1003, and one side of the bracket 12 is fixedly connected to the crushing cylinder 1002. The guide mesh plate 501 and the conveying mesh belt 504 are both provided with filter holes for filtering powder.

[0036] Specifically: The feeding shell 1001 is installed on top of the processing shell 1 to receive powder from the pre-crushing component 10 and the feeding pipe 11, and to evenly guide the powder to the feeding area between the two sets of pressure rollers 3. The crushing cylinder 1002 is installed inside the feeding shell 1001 to contain the powder to be crushed and to provide rotation space for the crushing blades 1004, preventing the powder from splashing and scattering during the crushing process. The rotary motor 1003 is located on top of the crushing cylinder 1002 to drive the crushing blades 1004 to rotate at high speed, providing power for the pre-crushing of the powder. The crushing blades 1004 are installed at the output end of the rotary motor 1003 to crush agglomerated powder inside the crushing cylinder 1002. High-speed dispersing makes the powder more uniform and delicate, improving the quality and uniformity of subsequent briquetting. One end of the feeding pipe 11 is connected to the conveying pipe 505, and the other end is connected to the crushing cylinder 1002. It is used to send the uncompacted powder lifted by the conveying auger 507 back to the crushing cylinder 1002, mix it with fresh powder, and then perform pre-crushing and briquetting again to realize the closed-loop recycling of powder. The bracket 12 is installed on the surface of the rotary motor 1003 and is fixedly connected to the crushing cylinder 1002 on one side. It is used to firmly fix the rotary motor 1003 to ensure that the rotary motor 1003 does not shake or shift during operation and to ensure the stability of the crushing blade 1004 when rotating at high speed.

[0037] The working principle of this invention is as follows: The operator first puts the powder to be processed into the crushing cylinder 1002, and then starts the rotary motor 1003 through the external controller. The rotary motor 1003 drives the crushing blades 1004 to rotate and break up the clumps of powder, so that the powder can enter the feeding shell 1001 evenly. Then it is discharged between the two sets of pressure rollers 3. By starting the two sets of power motors 2, the two sets of pressure rollers 3 are driven to rotate relative to each other, and the powder entering the pressure groove 4 is compacted to realize the balling process.

[0038] The compacted ball falls onto the guide plate 501 and is then discharged onto the conveyor belt 504. Both the guide plate 501 and the conveyor belt 504 have filter holes on their surfaces. When the powder and the ball fall together, the uncompacted powder can pass through the filter holes and enter the guide shell 9.

[0039] Then, the servo motor 707 is started. The servo motor 707, together with the first conveyor roller 502, drives the first belt pulley 701 to rotate. The first belt pulley 701, together with the belt, drives the second belt pulley 702 and the third belt pulley 704 to rotate. The third belt pulley 704, together with the rotating shaft 703, drives the first gear 705 to rotate. The first gear 705, together with the second gear 706, drives the second conveyor roller 503 to rotate. Under the drive of the servo motor 707, the first conveyor roller 502 and the second conveyor roller 503 rotate in opposite directions, discharging the compressed ball head.

[0040] While the third belt pulley 704 rotates, it drives the drive shaft 605 to rotate. The drive shaft 605 drives the exhaust fan blades 606 to rotate, which in turn drives the airflow, drawing out the air inside the processing shell 1 and filtering the fly ash carried inside through the filter screen 602. At the same time, the drive shaft 605 rotates, which in turn drives the third gear 708 to rotate. The third gear 708, in conjunction with the fourth gear 709, drives the exhaust pipe 601 to rotate, which in turn drives the filter screen 602 to rotate. Meanwhile, the scraper 603 remains in the same position. As the filter screen 602 rotates, the scraper 603 scrapes off the powder agglomerated on the surface of the filter screen 602, which falls into the guide shell 9. Then, the drive motor 506 is started, which drives the conveying auger 507 to rotate, conveying the powder that has entered the conveying pipe 505. The powder is then discharged back into the crushing cylinder 1002 through the feeding pipe 11, facilitating secondary processing and effectively improving processing efficiency.

[0041] The foregoing has only described certain exemplary embodiments of the present invention by way of illustration. Undoubtedly, those skilled in the art can modify the described embodiments in various ways without departing from the spirit and scope of the present invention. Therefore, the foregoing drawings and descriptions are illustrative in nature and should not be construed as limiting the scope of protection of the claims of the present invention.

Claims

1. An automated high-strength briquetting machine, comprising a processing shell (1), characterized in that: Two sets of power motors (2) are installed on the rear side of the processing shell (1). The output ends of the two sets of power motors (2) are fixedly connected to pressure rollers (3). Pressure grooves (4) are opened on the surface of the pressure rollers (3). The processing shell (1) is equipped with a filter assembly (5). The filter assembly (5) includes a guide mesh plate (501) installed inside the processing shell (1), a first conveying roller (502) and a second conveying roller (503) installed inside the processing shell (1), a conveying mesh belt (504) sleeved on the surface of the first conveying roller (502) and the second conveying roller (503), a conveying pipe (505) set on one side of the processing shell (1), a drive motor (506) installed on the top of the conveying pipe (505), and a conveying auger (507) installed at the output end of the drive motor (506). The filter assembly (5) collects and filters uncompacted powder. The processing shell (1) is equipped with a fly ash collection assembly (6). The fly ash collection assembly (6) includes an exhaust pipe (601) connected to one side of the processing shell (1), a filter screen (602) installed inside the exhaust pipe (601), a scraper (603) set on one side of the filter screen (602), a connecting pipe (604) movably connected to the surface of the exhaust pipe (601), a drive shaft (605) movably connected to the inside of the connecting pipe (604), and an exhaust fan blade (606) installed on the surface of the drive shaft (605). The fly ash is collected by the fly ash collection assembly (6). A drive assembly (7) is provided on one side of the processing shell (1). The drive assembly (7) includes a first pulley (701) mounted on the surface of the first conveying roller (502), a second pulley (702) mounted on the surface of the drive shaft (605), a rotating shaft (703) movably connected to one side of the processing shell (1), a third pulley (704) mounted on the surface of the rotating shaft (703), a first gear (705) mounted on the surface of the rotating shaft (703), and a second gear (706) mounted on the surface of the second conveying roller (503). The drive assembly (7) provides driving force for the filtration and conveying of powder.

2. The automated high-strength briquetting machine according to claim 1, characterized in that: The drive assembly (7) also includes a servo motor (707) mounted on one side of the processing housing (1), a third gear (708) mounted on the surface of the drive shaft (605), and a fourth gear (709) mounted on the surface of the exhaust pipe (601).

3. An automated high-strength briquetting machine according to claim 2, characterized in that: The third gear (708) meshes with the fourth gear (709) on one side, and the surface of the exhaust pipe (601) is movably connected to the inner wall of the machining shell (1) and the connecting pipe (604) through bearings.

4. An automated high-strength briquetting machine according to claim 2, characterized in that: The output end of the servo motor (707) is fixedly connected to the first conveyor roller (502), one side of the first gear (705) meshes with the second gear (706), and the first pulley (701), the second pulley (702) and the third pulley (704) are connected by belt drive.

5. An automated high-strength briquetting machine according to claim 1, characterized in that: An auxiliary roller (8) is provided inside the conveyor belt (504), and the surface of the auxiliary roller (8) is movably connected to the inner wall of the processing shell (1) through a bearing.

6. An automated high-strength briquetting machine according to claim 1, characterized in that: The bottom of the processing shell (1) is connected to a guide shell (9), and one side of the guide shell (9) is connected to the conveying pipe (505).

7. An automated high-strength briquetting machine according to claim 1, characterized in that: The processing shell (1) is provided with a pre-crushing component (10) on the top. The pre-crushing component (10) includes a feeding shell (1001) installed on the top of the processing shell (1), a crushing cylinder (1002) installed inside the feeding shell (1001), a rotary motor (1003) installed on the top of the crushing cylinder (1002), and crushing blades (1004) installed at the output end of the rotary motor (1003).

8. An automated high-strength briquetting machine according to claim 7, characterized in that: The conveying pipe (505) is connected to a feeding pipe (11) on one side, and the other end of the feeding pipe (11) is connected to a crushing cylinder (1002).

9. An automated high-strength briquetting machine according to claim 7, characterized in that: A bracket (12) is mounted on the surface of the rotary motor (1003), and one side of the bracket (12) is fixedly connected to the crushing cylinder (1002).

10. An automated high-strength briquetting machine according to claim 1, characterized in that: The guide plate (501) and the conveyor belt (504) are both provided with filter holes for filtering powder.